野生棉种渐渗创新的优质棉种质及其遗传研究
|
摘要
棉花是重要的经济作物,是纺织工业的重要原料。棉属除陆地棉、海岛棉、亚洲棉、草棉四个栽培种外,还有46个野生种,分属于A、B、c、D、E、F、G、K和AD基因组,是改良栽培棉花的重要基因资源。但由于种间存在生物学隔离,陆地棉与野生二倍体种杂交转育,存在杂交不亲和性、杂种F_1的不育性以及杂种后代不易稳定等障碍,给野生棉的育种利用带来了很大困难。
为了进一步拓宽陆地棉的遗传基因库,丰富品质育种的基因资源,本研究利用棉属野生种广泛开展了棉花种间杂交研究,包括种间杂交不可交配性和杂种F_1不育性等种间杂交育种障碍的克服,将野生棉的优良基因广泛转入栽培品种,改良栽培棉花品种的纤维品质,为育种利用野生棉架起桥梁。此外,利用细胞遗传学手段对棉花种间关系进行研究。对种间杂交后代进行分子细胞遗传鉴定、外源DNA/染色体的检测鉴定、渐渗系纤维品质性状QTL的分子标记筛选及杂交后代的辅助选择、纤维品质性状的遗传和偏相关分析,为棉花育种利用提供理论依据。
主要研究结果如下:
1.只要针对棉花不同的生长环境,采取适宜的杂交手段,都可以克服种间杂交的不可交配性,成功获得种间杂种。如在南京,则必须进行栽培环境的控制(主要是温度)并与激素保铃相结合;在海南三亚冬季,棉花开花时适逢旱季,空气湿度较低,天气较凉爽,有利于棉花的种间杂交工作,无需附加其它辅助条件。共获得了细胞学和形态学证实的种间杂种F_1植株组合60个,涉及B、C、D、E、G、K等8个染色体组中的6个,这些种间杂种的获得为棉花种间杂交育种研究奠定了基础。
2.采用以海岛棉7124为桥梁亲本法,与瑟伯氏棉、松散棉、拟似棉杂交,然后与陆地棉直接杂交,成功地获得了[(栽培四倍体海岛棉×野生二倍体棉)F_1×陆地棉]F_1的可育三元杂种;采用直接回交法,成功克服了栽培四倍体陆地棉与野生二倍体棉斯特提棉种间三倍体杂种F_1的不育性。共使4个野生二倍体棉成功进入育种程度,为育种利用提供了非常宝贵的中间材料。桥梁亲本法和直接回交法的优点是无需经过染色体加倍、无需经历六倍体和五倍体阶段,可以缩短育种年限,也为今后野生棉的育种应用提供了技术基础。
3.对棉属的22个种间杂种F_1花粉母细胞(PMC)减数分裂中期Ⅰ(MⅠ)的染色体行为进行了细胞遗传学研究,涉及到A、B、C、D、E、G、AD等七个染色体组棉种,从细胞学上证实了所获得的杂种为真杂种,获得了它们的染色体构型。这22个种间杂种F_1的PMCMⅠ的染色体行为研究表明,①Gherbaceum与Ganomalum,Gbarbosanum间的亲缘关系非常近,染色体间的同源性非常高,但由于出现较高频率的四价体,表明其存在染色体的易位等结构变异。②A与E、G染色体组棉种间的亲缘关系较远,染色体间的同源性不高。③异源四倍体棉的A、D染色体亚组与C或G染色体的亲缘关系较远,染色体间的同源程度很低。④异源四倍体棉(拟似棉除外)的D染色体亚组与D染色体组棉种的染色体同源性较好,其中与雷蒙德氏棉的亲缘关系最近,它最接近于四倍体D亚组的供体;但拟似棉的D染色体与AD四倍体的D亚组染色体配对频率明显低于其它D染色体组棉种,与四倍体中的D亚组染色体同源性较低。'
4.采用陆地棉(G hirsutum L)标准系TM-1体细胞有丝分裂中期染色体为靶标,以野生种斯特提棉(G sturtianum Willis)为探针,通过提高封阻DNA与探针浓度比例、洗脱液中甲酰胺浓度、洗脱温度、延长洗脱时间等,以增强DNA杂交反应的严谨性,使靶标中刚刚没有杂交信号为止。结果,封阻DNA与探针之比为100:1、洗脱液中甲酰胺浓度为60%、洗脱温度为43℃、洗脱时间13 min时,TM-1的靶标染色体上无杂交信号,而以TM.1与斯特提棉杂种F_1(基因组组成为A_tD_tC_1)体细胞有丝分裂中期DNA为靶标,则可清晰地将斯特提棉的C_1基因组染色体与陆地棉基因组染色体鉴定出来,建立了棉花外源染色体鉴定的基因组原位杂交(GISH)技术体系。并在此基础上,以A_1基因组的阿非利加草棉(G herbaceum Lvar.africanum)和C_1基因组的斯特提棉两个棉种的DNA同时为探针,可以清晰地区分A_t、D_t和C_1基因组染色体,且重复性好,建立了棉花多色GISH技术体系,并成功应用于种间杂种的鉴定。对引自澳大利亚CSIRO的陆地棉与澳洲棉(G australe F.v.M.)(G_2基因组)六倍体杂种(基因组组成为A_tA_tD_tD_tG_2G_2)进行的多色GISH,可清晰地区分A_1、D_t和G_2基因组染色体。为渐渗系中的外源DNA片段及其整合方式提供了技术基础。
5.对比克氏棉(G基因组)、澳洲棉(G基因组)、斯特提棉(C基因组)、雷蒙德氏棉(D基因组)、异常棉(B基因组)、司笃克氏棉(E基因组)等6个野生棉渐渗后代的22个种质系利用SSR标记进行基于高密度分子图谱的全基因组扫描,发现中遗红9种质系中存在比克氏棉特异的NAU 2628、NAU 2186、NAU 2627、NAU 2620标记的DNA片段,位于陆地棉D_7染色体上,长度为1.6cM。为野生棉DNA片段在栽培棉背景中的遗传效应研究提供了可能。
6.通过对异常棉、辣根棉、雷蒙德氏棉与陆地棉种间杂交后代连续定向的纤维品质选择,培育出了一系列的纤维细、长、强的高品质棉花新种质,成为高品质育种的种质基因库和基因组学研究的重要资源。J415等10个种质系,其纤维长度都达到35mm,纤维比强度均在40cN/tex以上,马克隆值在3.6-4.2之间。在上述三个野生棉渐渗后代中,以异常棉后代的纤维品质最优;其次为辣根棉后代种质系;再次为雷蒙德氏棉后代种质系。纤维品质远优于陆地棉常规品种。
7.以高品质的异常棉渐渗系J381和J415为母本,分别与苏棉12杂交,开展亲本P_1、P_2,杂种F1,回交后代B_1、B_2等6个世代纤维品质性状偏相关分析。结果表明,有7个性状在所有世代均表现出一致的极显著相关,即长度、整齐度、比强度、反射率、黄度等两两间呈极显著负相关,与马克隆值、纺纱均匀性指数均为极显著正相关;马克隆值与纺纱均匀性指数间为极显著负相关。
8.利用野生种异常棉渐渗后代获得的高品质种质系J381和J415为材料,分别与推广品种苏棉12号杂交,构建了亲本P_1、P_2、F_1、B_1、B_2等六个世代群体,采用盖钧镒等提出的主基因-多基因遗传模型进行纤维品质的遗传分析。结果表明:(1)纤维长度存在1对主效基因,多基因的遗传率较高,F_2世代多基因的遗传率分别为34.34%和32.98%;(2)纤维强度存在2对主效基因,其遗传率较高,F_2的主基因遗传率分别30.42%和38.77%;(3)马克隆值存在1对主效基因,F_2的主基因遗传率仅为0.41%和0.15%。
9.利用BSA法,对J415×苏棉12的F_2群体及其F_(2:3)群体根据纤维长度、强度、马克隆值、整齐度建立了4个极端值库,经单标记分析,获得了与纤维强度QTL密切相关的SSR标记4个,所解释的表型变异为3.0-9.2%,与纤维长度OTL密切相关的SSR标记4个,所解释的表型变异为4.5-18.3%,与纤维长度整齐度QTL密切相关的SSR分子标记6个,所解释的表型变异为5.2-11.6%。
10.采用从J415中筛选获得的与强度紧密连锁的分子标记,对(苏棉12号xJ415)F_(2:4)群体,同时采用NAU1125和NAU1336两个强度QTL标记进行强度选择,结果纤维比强度可提高3.9 cN/tex,获得了05-342、05-343、05-344和05-352等4个高强优异种质系,连续三年平均比强度均在37.2 cN/tex以上,最高的达42.8 cN/tex。
Cotton is a very important cash crop and cotton fiber was being used as raw materials for textile industry. Gossypium contains about 50 diploid and tetraploid species distributed worldwide in both tropical and subtropical areas. The diploid species (2n=2x=26) fall into eight different cytotypes designated A,B, C, D, E, F, G and K.The tetraploid species (2n=4x=52,AADD) contain two distinct subgenomes which are related to the A genome of the Asiatic cultivated diploid species and the D genome of the American wild diploid species, respectively. Four Gossypium species namely G. arboreum,G. barbadense, G. herbaceum and G. hirsutum are cultivated, the upland cotton (G. hirsutum L.) being the most important. The introduction of alien chromosome from the genus Gossypium wild species through interspecific or intergenomic hybridization into upland cotton is a valuable and proven technique for cotton improvement. A number of economically important traits have been transferred into cotton from wild species in the last century. Successful transfers can be greatly assisted by the precise identification of alien chromosome in the recipient progenies. There are biological barriers existed, such as interspecific incompatibility, hybrid sterility and instability in successive generations,hence, hindering wild cotton usage in breeding.
To further expand the cotton genetic basis and enrich the gene pool for breeding, widely interspecific hybridizations were carried out to transfer useful gene into cultivated cotton from wild species, construct gene pools with superior fiber properties, and build the bridge for wild species usage in breeding by overcomeing interspecific incompatibility and hybrid F1 sterility. The relationships among species were also studied by cytogenetics. Multi-FISH technique was established to identify exotic chromosome in hybrid. High density SSR-based maps established in our institute were used to identify exotic DNA of wild species and screen molecular markers linked with fiber QTL for MAS in fiber quality improvement. Genetic and partial correlate coefficients analyses were performed on introgression lines for offering scientific significance in cotton breeding.
The main results were as follows.
1.Interspecific hybridization incompatibility could be overcome and hybrids could be obtained when proper measure had been taken under different growing conditions. For example, in Nanjing, the extra measures merit to be taken for hybridization. The extra measures were a combination of three factors, including coordination of vegetative and productive growing, controlling of temperature to 25-28℃/20℃for day/night and adding of 50 mg/L of GA_3 to the flowers pollinated. But in winter at Sanya, Hainan, interspecific hybridizations were also successfully carried out under the natural conditions as intraspecific hybridizations because the natural proper environmental conditions existed. In this study, 60 interspecific hybridization combination, involving 6 geneomes of B、C、D、E、G、K in Gossypium, have been produced through confirmation of cytological and morphological observation.
2. Using G. barbadense as bridge parent and to be crossed with G. thurberi, G. laxum, G. australe, G. gossypioides, three triploid F_1s produced were directly crossed with G. hirsutum and fertile tri-species hybrids were obtained. Using direct backcrossing method, sterility of one another triploid F_1S of G. hirsutum×G. stUrtianuM had been overcome under the control conditions of temperature and plant hormone addition. At the present, four wild species have come into breeding procedure. These two techniques may be with the advantages of omitting the chromosome doubling of hybrid F_1 and the stage of undergoing hexaploid and pentaploid and additionally breeding progress will be quickened.
3. Cytogenetic observations were made on chromosome configuration of pollen mother cells at metaphase I of 22 interspecific F1 hybrids in Gossypium. These hybrids involved A, B, C, D, E, G and AD genome had been confirmed by cytology.
The results of chromosome pairing at 11 pairs of bivalents plus 4 univalents in hybrids A_1B_1and A_1B_3 indicated that there are very close relationships and high chromosome homologus between G herbaceum, G anomalum and G barbosahum.High frequent tetravalents in the intergenomic hybrids between A_2 and B showed there were chromosome translocations. Average 6 to 7 pairs of bivalents (range from 4 to 9) in the intergenomic hybrids between A and E/G may be implied that there were distant relationships and low chromosome homologous. Three to five pairs of bivalents plus 28 to 30 univalnts in intergenomic hybrids of AD and C/G indicated that there were far relationshipd between these species. Chromosome paired as 13 bivalents plus 13 univalents in the F_1 hybrids of tetraploid and diploid D genome (except D_6 genome of G gossypioides) means that D subgenome chromosomes and D chromosomes from diploid have very high homologous and these species have very close relations. Based on cytological observations, among D genome species,D_5 of G. raimondii showing the closet relations with tetraploids, it was presumed that G. raimondii is the closest donor species of D subgenome of tetraploids. More univalents in the F_1 hybrids of tetraploid and G. gossypioides indicated that G.gossypioides has a distinctive origin.
4.Increased stringency conditions was employed to establish the GISH technique forcotton by optimizing ratios of block DNA to probe, the formamide concentration in wash solution, and wash temperature and duration in wash solution, after DNA hybridization using mitotic metaphase chromosome of somatic cell of upland cotton standard line TM-1 (G. hirsutum L.) as target, genomic DNA from TM-1 and G. sturtianum Willis originated from Australia as blocking DNA and labeled probe, respectively. The results showed that the proper stringency conditions were the combination of four factors, including the ratios of blocking DNA to labeled probe being 100:1, 60% of formamide wash solution, 43℃of wash temperature and duration of 13 min for wash, under which there is just no probe signal on the target chromosome. Under the proper stringency conditions, GISH technique established was tested to discern chromosomes of G. sturtianum (C_1 genome) from intergenomic triploid hybrid F_1 (2n=3X=A_tD_tC_1=39) between upland cotton and G. sturtianum. The results indicated that every donor chromosomes of the two species showed different color and were readily distinguished. So it is proposed that the GISH technique established was feasible for chromosome identification in intergenomic cotton hybrid. Based on the above results, the Multi-color GISH was developed using two species DNA from G. stuitianum and G. herbaceum L. var.africanum (A_1 genome) as labeled probes simultaneously and DNA from G. davidsonii (D_(3-d) genome) as blocking DNA, to simultaneously discriminate three genomes of the above intergenomic hybrid. The results also indicated that the three genome, A_t、D_t和C_1,each set of chromosomes were vividly recognized in different color repetitively. The power of the Multi-color GISH has been proven in analysis hexaploid hybrid (2n=6X=AADDGG=78) from (G.hirsutum×G. australe)F_1 chromosome doubling (kindly provided by CSIRO of Australia) and each of three genomes,A_t,D_t,G_2,of chromosomes display one color. It is believed that the powerful Multi-color GISH technique established in the research could be applied extensively in analysis component in polyploidy and precisely identification of alien chromosome in the recipient progenies, which will greatly assist to transfer much more economically important traits from wild species into upland cotton in the future.
5.To identify exotic DNA fragment or alien chromosomal segment, genomes of 22 introgression lines from six species, namely, G. bickii and G. australe (G genome),G. sturtianum (C genome),G. raimondii (D genome),G. anomalum (B genome) and G. stocksii (E genome), were globally scanned using SSR markers based on high density backbone map constructed by our institute. The results revealed that exotic DNA fragment from G. bickii have been transferred into D_7 chromosome of G. hirsutum, covering the genetic distance of 1.2 cM.It will facilitate genetic analysis on effect of exotic DNA of wild species in G. hirsutum.
6.After direct selection performed on the introgression lines from G. anomalum,G. armourianum and G. raimondii a series of germplasm with finer, longer and stronger fiber had been developed, becoming the gene pool for breeding and genomic study. Their fiber length was longer than 35 mm, strength stronger than 40cN/tex,micronaire reading ranged from 3.6-4.2 in the best area for J415, J414, J405, J400, J416, J402, J371, J372, J406, J401. These fiber qualities will meet the needs of producing yarns with high yarn number. Among introgression lines from three wild species, the best fiber qualities were in lines from G. anomalum, followed by G. armourianum and G. raimondii. They are similar to that of G. barbadense and much better than that of Upland commercial varieties.
7.Germplasm lines J381 and J415 with the desired combination of fiber properties were developed through introgression from G. anomalum into G. hirsutum during the past research.In the present study, partial correlation analysis was carried out to elucidate the relations among fiber properties, namely, length, strength, micronaire, length uniformity, elongation, short fiber index (SFI),reflectance degree (Rd),spinning consistency index (SCI),brownness, fiber maturity, and moist-regain at each generation in J381×Sumian 12 and/or J415×Sumian 12. The results showed that there were significant negative relationship between each two of length, strength, length uniformity, Rd and brownness, and between micronaire and SCI, but significant positive between the former five and the latter two in every generation.The average values indicated that J381 and J415 were much better than Sumian 12; F_1 was being close to the average of their parents and backcross generation leaning to their backcrossing parents. Variation was small in parents but big insegregation generations.
8.All of fiber properties studied before showed that they were controlled by minor genes. Further researches indicated that these minor genes had different effects on fiber quality and some of them had played a role as major genes. Therefore, in order to elucidate whether major genes exit and how their role is, the mixed major gene plus polygene genetic model established by the group led by Gai (1997) were employed to research on inheritance of three traits of cotton fiber, namely, fiber strength in two repeats was controlled by two major genes plus polygene, fiber length and micronaire in two repeats were controlled by one major gene plus polygene. The heritability values of major gene were estimated as 30.42% and 38.77% in F_2 and 69.47% and 45.63% in B_1 for fiber strength, 0.007% and 0.15% for fiber length, 0.41% and 0.15% for micronaire in F_2,respectively. That of polygene in F_2 as 12.21% and 19.11% for fiber strength, 34.34% and 32.98% for fiber length, and 8.09% and 36.16% for micronaire in RepeatⅠandⅡ,respectively. The results indicated that fiber strength and length in both repeats and micronaire in RepeatⅡwere highly inheritable.
9.Using bulked segregation analysis (BSA) on F2 and F2:3 populations of J 415×Sumian 12, 4, 4 and 6 SSR markers related to QTLs of fiber strength, length and length uniformity were screened. They explained 3.0-9.2% of phenotypic variation for strength, 4.5-18.3% for length, and 5.2-11.6% for length uniformity.
10.Using two SSR markers assisted selection on the population of Sumian 12×J415, fiber strength of the progenies from it had been increased by 3.9 cN/tex, and four lines (05-342,05-343,05-344 and 05-352) reaching 37.2 cN/tex at the minimum and 42.8 cN/tex at the maximum of three years average.
为了进一步拓宽陆地棉的遗传基因库,丰富品质育种的基因资源,本研究利用棉属野生种广泛开展了棉花种间杂交研究,包括种间杂交不可交配性和杂种F_1不育性等种间杂交育种障碍的克服,将野生棉的优良基因广泛转入栽培品种,改良栽培棉花品种的纤维品质,为育种利用野生棉架起桥梁。此外,利用细胞遗传学手段对棉花种间关系进行研究。对种间杂交后代进行分子细胞遗传鉴定、外源DNA/染色体的检测鉴定、渐渗系纤维品质性状QTL的分子标记筛选及杂交后代的辅助选择、纤维品质性状的遗传和偏相关分析,为棉花育种利用提供理论依据。
主要研究结果如下:
1.只要针对棉花不同的生长环境,采取适宜的杂交手段,都可以克服种间杂交的不可交配性,成功获得种间杂种。如在南京,则必须进行栽培环境的控制(主要是温度)并与激素保铃相结合;在海南三亚冬季,棉花开花时适逢旱季,空气湿度较低,天气较凉爽,有利于棉花的种间杂交工作,无需附加其它辅助条件。共获得了细胞学和形态学证实的种间杂种F_1植株组合60个,涉及B、C、D、E、G、K等8个染色体组中的6个,这些种间杂种的获得为棉花种间杂交育种研究奠定了基础。
2.采用以海岛棉7124为桥梁亲本法,与瑟伯氏棉、松散棉、拟似棉杂交,然后与陆地棉直接杂交,成功地获得了[(栽培四倍体海岛棉×野生二倍体棉)F_1×陆地棉]F_1的可育三元杂种;采用直接回交法,成功克服了栽培四倍体陆地棉与野生二倍体棉斯特提棉种间三倍体杂种F_1的不育性。共使4个野生二倍体棉成功进入育种程度,为育种利用提供了非常宝贵的中间材料。桥梁亲本法和直接回交法的优点是无需经过染色体加倍、无需经历六倍体和五倍体阶段,可以缩短育种年限,也为今后野生棉的育种应用提供了技术基础。
3.对棉属的22个种间杂种F_1花粉母细胞(PMC)减数分裂中期Ⅰ(MⅠ)的染色体行为进行了细胞遗传学研究,涉及到A、B、C、D、E、G、AD等七个染色体组棉种,从细胞学上证实了所获得的杂种为真杂种,获得了它们的染色体构型。这22个种间杂种F_1的PMCMⅠ的染色体行为研究表明,①Gherbaceum与Ganomalum,Gbarbosanum间的亲缘关系非常近,染色体间的同源性非常高,但由于出现较高频率的四价体,表明其存在染色体的易位等结构变异。②A与E、G染色体组棉种间的亲缘关系较远,染色体间的同源性不高。③异源四倍体棉的A、D染色体亚组与C或G染色体的亲缘关系较远,染色体间的同源程度很低。④异源四倍体棉(拟似棉除外)的D染色体亚组与D染色体组棉种的染色体同源性较好,其中与雷蒙德氏棉的亲缘关系最近,它最接近于四倍体D亚组的供体;但拟似棉的D染色体与AD四倍体的D亚组染色体配对频率明显低于其它D染色体组棉种,与四倍体中的D亚组染色体同源性较低。'
4.采用陆地棉(G hirsutum L)标准系TM-1体细胞有丝分裂中期染色体为靶标,以野生种斯特提棉(G sturtianum Willis)为探针,通过提高封阻DNA与探针浓度比例、洗脱液中甲酰胺浓度、洗脱温度、延长洗脱时间等,以增强DNA杂交反应的严谨性,使靶标中刚刚没有杂交信号为止。结果,封阻DNA与探针之比为100:1、洗脱液中甲酰胺浓度为60%、洗脱温度为43℃、洗脱时间13 min时,TM-1的靶标染色体上无杂交信号,而以TM.1与斯特提棉杂种F_1(基因组组成为A_tD_tC_1)体细胞有丝分裂中期DNA为靶标,则可清晰地将斯特提棉的C_1基因组染色体与陆地棉基因组染色体鉴定出来,建立了棉花外源染色体鉴定的基因组原位杂交(GISH)技术体系。并在此基础上,以A_1基因组的阿非利加草棉(G herbaceum Lvar.africanum)和C_1基因组的斯特提棉两个棉种的DNA同时为探针,可以清晰地区分A_t、D_t和C_1基因组染色体,且重复性好,建立了棉花多色GISH技术体系,并成功应用于种间杂种的鉴定。对引自澳大利亚CSIRO的陆地棉与澳洲棉(G australe F.v.M.)(G_2基因组)六倍体杂种(基因组组成为A_tA_tD_tD_tG_2G_2)进行的多色GISH,可清晰地区分A_1、D_t和G_2基因组染色体。为渐渗系中的外源DNA片段及其整合方式提供了技术基础。
5.对比克氏棉(G基因组)、澳洲棉(G基因组)、斯特提棉(C基因组)、雷蒙德氏棉(D基因组)、异常棉(B基因组)、司笃克氏棉(E基因组)等6个野生棉渐渗后代的22个种质系利用SSR标记进行基于高密度分子图谱的全基因组扫描,发现中遗红9种质系中存在比克氏棉特异的NAU 2628、NAU 2186、NAU 2627、NAU 2620标记的DNA片段,位于陆地棉D_7染色体上,长度为1.6cM。为野生棉DNA片段在栽培棉背景中的遗传效应研究提供了可能。
6.通过对异常棉、辣根棉、雷蒙德氏棉与陆地棉种间杂交后代连续定向的纤维品质选择,培育出了一系列的纤维细、长、强的高品质棉花新种质,成为高品质育种的种质基因库和基因组学研究的重要资源。J415等10个种质系,其纤维长度都达到35mm,纤维比强度均在40cN/tex以上,马克隆值在3.6-4.2之间。在上述三个野生棉渐渗后代中,以异常棉后代的纤维品质最优;其次为辣根棉后代种质系;再次为雷蒙德氏棉后代种质系。纤维品质远优于陆地棉常规品种。
7.以高品质的异常棉渐渗系J381和J415为母本,分别与苏棉12杂交,开展亲本P_1、P_2,杂种F1,回交后代B_1、B_2等6个世代纤维品质性状偏相关分析。结果表明,有7个性状在所有世代均表现出一致的极显著相关,即长度、整齐度、比强度、反射率、黄度等两两间呈极显著负相关,与马克隆值、纺纱均匀性指数均为极显著正相关;马克隆值与纺纱均匀性指数间为极显著负相关。
8.利用野生种异常棉渐渗后代获得的高品质种质系J381和J415为材料,分别与推广品种苏棉12号杂交,构建了亲本P_1、P_2、F_1、B_1、B_2等六个世代群体,采用盖钧镒等提出的主基因-多基因遗传模型进行纤维品质的遗传分析。结果表明:(1)纤维长度存在1对主效基因,多基因的遗传率较高,F_2世代多基因的遗传率分别为34.34%和32.98%;(2)纤维强度存在2对主效基因,其遗传率较高,F_2的主基因遗传率分别30.42%和38.77%;(3)马克隆值存在1对主效基因,F_2的主基因遗传率仅为0.41%和0.15%。
9.利用BSA法,对J415×苏棉12的F_2群体及其F_(2:3)群体根据纤维长度、强度、马克隆值、整齐度建立了4个极端值库,经单标记分析,获得了与纤维强度QTL密切相关的SSR标记4个,所解释的表型变异为3.0-9.2%,与纤维长度OTL密切相关的SSR标记4个,所解释的表型变异为4.5-18.3%,与纤维长度整齐度QTL密切相关的SSR分子标记6个,所解释的表型变异为5.2-11.6%。
10.采用从J415中筛选获得的与强度紧密连锁的分子标记,对(苏棉12号xJ415)F_(2:4)群体,同时采用NAU1125和NAU1336两个强度QTL标记进行强度选择,结果纤维比强度可提高3.9 cN/tex,获得了05-342、05-343、05-344和05-352等4个高强优异种质系,连续三年平均比强度均在37.2 cN/tex以上,最高的达42.8 cN/tex。
Cotton is a very important cash crop and cotton fiber was being used as raw materials for textile industry. Gossypium contains about 50 diploid and tetraploid species distributed worldwide in both tropical and subtropical areas. The diploid species (2n=2x=26) fall into eight different cytotypes designated A,B, C, D, E, F, G and K.The tetraploid species (2n=4x=52,AADD) contain two distinct subgenomes which are related to the A genome of the Asiatic cultivated diploid species and the D genome of the American wild diploid species, respectively. Four Gossypium species namely G. arboreum,G. barbadense, G. herbaceum and G. hirsutum are cultivated, the upland cotton (G. hirsutum L.) being the most important. The introduction of alien chromosome from the genus Gossypium wild species through interspecific or intergenomic hybridization into upland cotton is a valuable and proven technique for cotton improvement. A number of economically important traits have been transferred into cotton from wild species in the last century. Successful transfers can be greatly assisted by the precise identification of alien chromosome in the recipient progenies. There are biological barriers existed, such as interspecific incompatibility, hybrid sterility and instability in successive generations,hence, hindering wild cotton usage in breeding.
To further expand the cotton genetic basis and enrich the gene pool for breeding, widely interspecific hybridizations were carried out to transfer useful gene into cultivated cotton from wild species, construct gene pools with superior fiber properties, and build the bridge for wild species usage in breeding by overcomeing interspecific incompatibility and hybrid F1 sterility. The relationships among species were also studied by cytogenetics. Multi-FISH technique was established to identify exotic chromosome in hybrid. High density SSR-based maps established in our institute were used to identify exotic DNA of wild species and screen molecular markers linked with fiber QTL for MAS in fiber quality improvement. Genetic and partial correlate coefficients analyses were performed on introgression lines for offering scientific significance in cotton breeding.
The main results were as follows.
1.Interspecific hybridization incompatibility could be overcome and hybrids could be obtained when proper measure had been taken under different growing conditions. For example, in Nanjing, the extra measures merit to be taken for hybridization. The extra measures were a combination of three factors, including coordination of vegetative and productive growing, controlling of temperature to 25-28℃/20℃for day/night and adding of 50 mg/L of GA_3 to the flowers pollinated. But in winter at Sanya, Hainan, interspecific hybridizations were also successfully carried out under the natural conditions as intraspecific hybridizations because the natural proper environmental conditions existed. In this study, 60 interspecific hybridization combination, involving 6 geneomes of B、C、D、E、G、K in Gossypium, have been produced through confirmation of cytological and morphological observation.
2. Using G. barbadense as bridge parent and to be crossed with G. thurberi, G. laxum, G. australe, G. gossypioides, three triploid F_1s produced were directly crossed with G. hirsutum and fertile tri-species hybrids were obtained. Using direct backcrossing method, sterility of one another triploid F_1S of G. hirsutum×G. stUrtianuM had been overcome under the control conditions of temperature and plant hormone addition. At the present, four wild species have come into breeding procedure. These two techniques may be with the advantages of omitting the chromosome doubling of hybrid F_1 and the stage of undergoing hexaploid and pentaploid and additionally breeding progress will be quickened.
3. Cytogenetic observations were made on chromosome configuration of pollen mother cells at metaphase I of 22 interspecific F1 hybrids in Gossypium. These hybrids involved A, B, C, D, E, G and AD genome had been confirmed by cytology.
The results of chromosome pairing at 11 pairs of bivalents plus 4 univalents in hybrids A_1B_1and A_1B_3 indicated that there are very close relationships and high chromosome homologus between G herbaceum, G anomalum and G barbosahum.High frequent tetravalents in the intergenomic hybrids between A_2 and B showed there were chromosome translocations. Average 6 to 7 pairs of bivalents (range from 4 to 9) in the intergenomic hybrids between A and E/G may be implied that there were distant relationships and low chromosome homologous. Three to five pairs of bivalents plus 28 to 30 univalnts in intergenomic hybrids of AD and C/G indicated that there were far relationshipd between these species. Chromosome paired as 13 bivalents plus 13 univalents in the F_1 hybrids of tetraploid and diploid D genome (except D_6 genome of G gossypioides) means that D subgenome chromosomes and D chromosomes from diploid have very high homologous and these species have very close relations. Based on cytological observations, among D genome species,D_5 of G. raimondii showing the closet relations with tetraploids, it was presumed that G. raimondii is the closest donor species of D subgenome of tetraploids. More univalents in the F_1 hybrids of tetraploid and G. gossypioides indicated that G.gossypioides has a distinctive origin.
4.Increased stringency conditions was employed to establish the GISH technique forcotton by optimizing ratios of block DNA to probe, the formamide concentration in wash solution, and wash temperature and duration in wash solution, after DNA hybridization using mitotic metaphase chromosome of somatic cell of upland cotton standard line TM-1 (G. hirsutum L.) as target, genomic DNA from TM-1 and G. sturtianum Willis originated from Australia as blocking DNA and labeled probe, respectively. The results showed that the proper stringency conditions were the combination of four factors, including the ratios of blocking DNA to labeled probe being 100:1, 60% of formamide wash solution, 43℃of wash temperature and duration of 13 min for wash, under which there is just no probe signal on the target chromosome. Under the proper stringency conditions, GISH technique established was tested to discern chromosomes of G. sturtianum (C_1 genome) from intergenomic triploid hybrid F_1 (2n=3X=A_tD_tC_1=39) between upland cotton and G. sturtianum. The results indicated that every donor chromosomes of the two species showed different color and were readily distinguished. So it is proposed that the GISH technique established was feasible for chromosome identification in intergenomic cotton hybrid. Based on the above results, the Multi-color GISH was developed using two species DNA from G. stuitianum and G. herbaceum L. var.africanum (A_1 genome) as labeled probes simultaneously and DNA from G. davidsonii (D_(3-d) genome) as blocking DNA, to simultaneously discriminate three genomes of the above intergenomic hybrid. The results also indicated that the three genome, A_t、D_t和C_1,each set of chromosomes were vividly recognized in different color repetitively. The power of the Multi-color GISH has been proven in analysis hexaploid hybrid (2n=6X=AADDGG=78) from (G.hirsutum×G. australe)F_1 chromosome doubling (kindly provided by CSIRO of Australia) and each of three genomes,A_t,D_t,G_2,of chromosomes display one color. It is believed that the powerful Multi-color GISH technique established in the research could be applied extensively in analysis component in polyploidy and precisely identification of alien chromosome in the recipient progenies, which will greatly assist to transfer much more economically important traits from wild species into upland cotton in the future.
5.To identify exotic DNA fragment or alien chromosomal segment, genomes of 22 introgression lines from six species, namely, G. bickii and G. australe (G genome),G. sturtianum (C genome),G. raimondii (D genome),G. anomalum (B genome) and G. stocksii (E genome), were globally scanned using SSR markers based on high density backbone map constructed by our institute. The results revealed that exotic DNA fragment from G. bickii have been transferred into D_7 chromosome of G. hirsutum, covering the genetic distance of 1.2 cM.It will facilitate genetic analysis on effect of exotic DNA of wild species in G. hirsutum.
6.After direct selection performed on the introgression lines from G. anomalum,G. armourianum and G. raimondii a series of germplasm with finer, longer and stronger fiber had been developed, becoming the gene pool for breeding and genomic study. Their fiber length was longer than 35 mm, strength stronger than 40cN/tex,micronaire reading ranged from 3.6-4.2 in the best area for J415, J414, J405, J400, J416, J402, J371, J372, J406, J401. These fiber qualities will meet the needs of producing yarns with high yarn number. Among introgression lines from three wild species, the best fiber qualities were in lines from G. anomalum, followed by G. armourianum and G. raimondii. They are similar to that of G. barbadense and much better than that of Upland commercial varieties.
7.Germplasm lines J381 and J415 with the desired combination of fiber properties were developed through introgression from G. anomalum into G. hirsutum during the past research.In the present study, partial correlation analysis was carried out to elucidate the relations among fiber properties, namely, length, strength, micronaire, length uniformity, elongation, short fiber index (SFI),reflectance degree (Rd),spinning consistency index (SCI),brownness, fiber maturity, and moist-regain at each generation in J381×Sumian 12 and/or J415×Sumian 12. The results showed that there were significant negative relationship between each two of length, strength, length uniformity, Rd and brownness, and between micronaire and SCI, but significant positive between the former five and the latter two in every generation.The average values indicated that J381 and J415 were much better than Sumian 12; F_1 was being close to the average of their parents and backcross generation leaning to their backcrossing parents. Variation was small in parents but big insegregation generations.
8.All of fiber properties studied before showed that they were controlled by minor genes. Further researches indicated that these minor genes had different effects on fiber quality and some of them had played a role as major genes. Therefore, in order to elucidate whether major genes exit and how their role is, the mixed major gene plus polygene genetic model established by the group led by Gai (1997) were employed to research on inheritance of three traits of cotton fiber, namely, fiber strength in two repeats was controlled by two major genes plus polygene, fiber length and micronaire in two repeats were controlled by one major gene plus polygene. The heritability values of major gene were estimated as 30.42% and 38.77% in F_2 and 69.47% and 45.63% in B_1 for fiber strength, 0.007% and 0.15% for fiber length, 0.41% and 0.15% for micronaire in F_2,respectively. That of polygene in F_2 as 12.21% and 19.11% for fiber strength, 34.34% and 32.98% for fiber length, and 8.09% and 36.16% for micronaire in RepeatⅠandⅡ,respectively. The results indicated that fiber strength and length in both repeats and micronaire in RepeatⅡwere highly inheritable.
9.Using bulked segregation analysis (BSA) on F2 and F2:3 populations of J 415×Sumian 12, 4, 4 and 6 SSR markers related to QTLs of fiber strength, length and length uniformity were screened. They explained 3.0-9.2% of phenotypic variation for strength, 4.5-18.3% for length, and 5.2-11.6% for length uniformity.
10.Using two SSR markers assisted selection on the population of Sumian 12×J415, fiber strength of the progenies from it had been increased by 3.9 cN/tex, and four lines (05-342,05-343,05-344 and 05-352) reaching 37.2 cN/tex at the minimum and 42.8 cN/tex at the maximum of three years average.
引文
1.安泽伟,李炳林,刘向新,等.棉属[AG]与[AD]两个复合染色体组种间杂种的同工酶与核型研究[J].棉花学报,2001,13(1):20-25
2.别墅,孔繁玲,周有耀,等.中国3大主产棉区棉花品种遗传多样性的RAPD及其与农艺性状关系的研究[J].冲国农业科学2001,34(6):597-603
3.别墅,王坤波,王春英,等.二倍体栽培棉45S rDNA-FISH作图及核型比较[J].棉花学报,2004,16(4):223-228
4.陈国平,周宝良,沈新莲,等.不同强度棉纤维超微结构差异及其与比强度和马克隆值关系[J].纤维标准与检验,1997,(6)(总第192期):21-24
5.陈国平,沈新莲,周宝良,等.高强纤维棉花种质系的纤维品质初析[J].江苏农业科学,1996,(1),(总第89期):25-27
6.陈国平,沈新莲,周宝良,等.具有野生种质的棉花高品质品系与常规品种纤维品质差异分析[J].江西棉花,1996,(2)(总第64期):8-10
7.陈松,应苗成,彭跃进,黄骏麒,钱思颖,徐英俊.棉属CGossypium)种子蛋白质电泳图谱与种间关系[J].江苏农业学报,1990,6(1):17-23
8.陈卫国,郝林,渠云芳,等.棉花[AGD]三种杂种核型分析[J].山西农业科学,2004,32(2):41-45
9.陈仲方,张治伟,承泓良.陆地棉品种棉籽品质分析研究[J].作物学报,1986,12:195-200
10.崔荣霞,胡绍安,王春英.陆地棉×斯特提棉F1及BC1遗传学研究[J].中国棉花,1995,22(12):7-8
11.丁亮,祝水金,胡丹艳,等.比克氏棉和司笃克氏棉色素腺体形态建成的组织结构观察[J].棉花学报,2003,15(1):17-21
12.丁亮,祝水金,胡丹艳,等.司笃克氏棉(G stockii)色素腺体的形态建成与棉酚动态研究[J].作物学报,2004,30(2):100-103,
13.丁世萍,武萍生,彭锁堂.((亚洲棉×比克氏棉)F1双二倍体×海岛棉)F1茸毛性状研究[J].山西农业大学学报,1998,18(2):99-101
14.丁世萍,李炳林,张伯静,等.(亚洲棉×比克氏棉)F1 双二倍体与海岛棉的种间杂种F1的形态学和细胞学研究[J].浙江农业大学学报,1999,25(1):31-35
15.杜雄明,汪若海,刘国强,等.棉花纤维相关性状的主基因-多基因混合遗传分析[J].棉花学报,1999,11(2):73-78.
16.董俊梅,段永红.棉属异源四倍体杂种性状研究[J].山西农业大学学报,2003,23(1):1-6
17.杜珉.世界棉花生产与市场贸易[J].国际农业,2006,(3):32-36
18.段永红,崔俊梅.三元杂种回交后代性状遗传学研究[J].山西农业大学学报,2003,23(1): 15-19
19.范玲.新疆棉花栽培种遗传多样性研究[硕士论文].新疆乌鲁木齐:新疆农业大学,2004
20.冯泽芳.冯泽芳先生论文选集[M].中国棉业出版社,1948
21.盖钧镒,章元明,王建康.Q T L混合遗传模型扩展至2对主基因+多基因时的多世代联合分析[J].作物学报,2000,26(4):385-391.
22.盖钧镒,王建康.大豆对豆秆黑潜蝇抗性的主基因+多基因遗传[M].全国作物育种学术讨论会论文集,北京:中国农业科技出版社,1998,241-248.
23.高国强,朱斗北,苏学合,等.四倍体与二倍体棉花远缘杂交后代同工酶电泳分析[J].核农学报,1997,11(2):79-83
24.高峰.世界棉花生产与进出口贸易概览[J].中国棉花,2006,33(7):7-9
25.高燕会,祝水金,季道藩.四种栽培棉合成的四元杂种F1细胞遗传学研究[J].棉花学报,2003,15(5):259-263
26.高燕会,祝水金,季道藩.四个栽培棉种间的杂种F1细胞遗传学与亲缘关系研究[J].遗传学报,2005,32(7):744-752
27.高燕会.四个栽培棉种间的种间杂交及其遗传与系统发育研究[博士论文].浙江杭州:浙江大学,2004
28.刘三宏.四倍体棉种起源与演化的FISH研究[硕士论文].北京:中国农业科学院,2004
29.高玉千,聂以春,张献龙.棉花抗黄萎病基因的QTL定位[J].棉花学报,2003,15(2):73-78
30.郭江勇,王义琴,吴明刚,等.利用RAPD标记对彩色棉遗传多样性的分析[J].棉花学报,2003,15(5):269-273
31.郭江勇,王义琴,吴明刚,等.棕色棉和绿色棉遗传多样性的比较研究[J].遗传,2004,26(1):63-68
32.龚云程,李德华,杨民权,等.棉花×泡桐远缘杂交初探[J].湖北农业科学,2001,(4):25-28
33.郭江勇,王义琴,吴明刚,等.利用RAPD标记对彩色棉遗传多样性的分析[J].棉花学报,2003,15(5):269-273
34.郭江勇,王义琴,吴明刚,等.棕色棉和绿色棉遗传多样性的比较研究[J].遗传,26(1):63-68,2004
35.郭旺珍,彭锁堂.陆地棉与毛棉杂种性状遗传学和细胞学研究[J].棉花学报,1997,9(1),21-24
36.郭旺珍,孙敬,张天真,棉花纤维品质的基因克隆与分子育种[J].科学通报,2003,48(5):410-417
37.韩祥铭,刘英欣,宋宪亮.陆地棉新种质纤维品质性状的遗传分析[J].作物学报,2002,28(2):245-248.
38.郝林,宋国立,李炳林,等.亚比棉基因组原位杂交及核型分析[J].遗传学 报,2006,33(6):572-579
39.何鉴星,梁正兰.中棉×戴维逊氏棉胚胎发育的研究[J].遗传学报,1989,16(4):256-262
40.何鉴星,姜茹琴,张欣雪,等.陆地棉×索马里棉异源六倍体杂种的细胞学和纤维特性[J].科学通报,2000,45(16):1742-1747
41.何鉴星,孙传渭.向陆地棉渐渗野生比克氏棉腺体延缓形成基因的方法研究[J].遗传学报,1994,21(1):52-58
42.胡丹艳,祝水金.(亚洲棉×比克氏棉)F1双二倍体不育系的花粉败育机理研究[J].棉花学报,2002,14(6):330-335
43.胡建斌.三元杂种[A2A2 G1 G1]×[A2×(AD)1]的形态及核型分析[J].山西农业大学学报,2005,25(3):217-219
44.胡绍安,李秀兰.棉属二倍体野生棉与四倍体栽培棉种间杂交的胚珠培养[J].遗传学报,1982,9(1):57-62
45.胡绍安,崔荣霞,王春英,等.陆地棉野生种系的利用研究[J].棉花学报,1994,6(增刊):15-18
46.华金平,张成,易先达,等.棉花远缘核质杂种的培育与育种应用[J].湖北农业科学,2003,14:25-28
47.姜保功,孔繁玲,张群远,等.2000建国以来我国黄淮棉区棉花品种的遗传改良.Ⅱ.纤维品质性状的改良[J].作物学报,2000,26(5):528-535
48.姜茹琴,苗春生,潘河山,等.棉花种间杂交抗棉铃虫资源选育[J].棉花学报,1999,11(6):306-311
49.姜茹琴,梁正兰,钟文南,等.陆地棉×索马里棉(G.somalense)杂种的研究和利用[J].科学通报,1996,41(1):60-64
50.李炳林.亚洲棉与比克氏棉杂交研究简报[J].中国棉花,1982(4):15-16
51.李炳林,李宏运,安泽伟,等.棉花染色体工程育种[J].山西农业大学学报,2001,21(1):1-6
52.李炳林,武晶,李欣,等.[AAGG]异源四倍体新棉种的核型及同功酶分析[J].植物遗传资源学报,2003,4(3):195-198
53.李成奇,黄晋玲,渠云芳,等.棉花四元杂种F1的形态性状遗传及不育性研究[J].山西农业大学学报,2004,24(4):369-382
54.李俊兰,崔淑芳,韩泽林.远缘杂交创造棉花优异种质的研究初报[J].河北农业科学,2003,7(增刊):150-151
55.李志坤.低酚棉遗传资源基于农艺性状、SSR、AFLP的遗传多样性[硕士论文].河北保定:河北农业大学,2005
56.梁理民,王增信,刘有良,等.棉花种间杂交新品系及新种质的育成[J].西北农林科技大学学报(自然科学版)2003,31(5):9-12
57.梁理民,刘有良,王增信,等.陆地棉×斯特提棉种间杂交创造抗枯黄萎病新种质[J].西北农业学报,2002,11(4):16-18
58.梁理民,刘有良,王增信,等.棉花种间杂交新品种秦远4号的选育[J].西北农业学报,2000,9(4):10-13
59.梁正兰,孙传渭,刘棣良,等.克服种间不亲和性的试验效果[J].遗传学报,1978,5(3):171-181
60.梁正兰,孙传渭.棉花远缘杂交[M].科学出版社,1982,北京
61.梁正兰,姜茹琴,钟文南.陆地棉.野生比克氏棉杂种红花种质系的育成[J].中国科学(C辑),1996,26(4):369-376
62.梁正兰,姜茹琴,钟文南,等.三元杂种(海岛棉-瑟伯氏棉-陆地棉)的研究及新品种选育[J].作物学报,1996,22(6):673-680
63.梁正兰,姜茹琴,钟文南,等.棉花种间杂交技术创新及育种程序的建立[J].中国科学(C辑),2001,31(2):120-124
64.林忠旭,张献龙,聂以春.新型标记SRAP在棉花F2分离群体及遗传多样性评价中的适用性分析[J].遗传学报,2004,31(6):622-626
65.刘根齐,焦传珍,姜茹琴,等用同工酶和RAPD技术研究棉花三元杂种石远321新品种的遗传特性[J].遗传学报,2000a,27(11):999-1005
66.刘根齐,焦传珍,姜茹琴,等.陆地棉×比克氏棉育成种质系的同工酶和RAPD分析[J].遗传学报,2000b,27(12):1094-1099
67.刘金兰,聂以春.植物激素对棉属(Gossypium)远缘杂种胚囊发育的影响[J].华中农业大学学报,1990,9(3),211-216
68.刘金兰,徐珍秀,聂以春.棉花胚囊超微结构的观察[J].棉花学报,1992,4(1):9-12
69.刘金兰,聂以春.4倍体(亚×司)F1×陆杂种后代花粉和胚囊发育研究[J].棉花学报,1997,9(3):120-125
70.刘文欣,孔繁玲,郭志丽,等,杨付新.建国以来我国棉花品种遗传基础的分子标记分析[J].遗传学报,2003,30(6):560-570
71.刘耀斌,景忆莲,范万法,等.哈克尼西棉细胞质对陆地棉主要经济性状的影响[J].西北农业学报,1996,5(3):49-53
72.聂汝芝,李懋学.棉属植物核型研究[M].科学出版社,北京,1993
73.聂以春,刘金兰.棉属异源四倍体(亚洲棉×司笃克氏棉)的植物形态及农艺性状研究[J].华中农业大学学报,1995,14(4):333-338
74.聂以春,刘金兰,张献龙.人工合成的棉属异源四倍体(亚洲棉×司笃克氏棉)种质的胚胎发育.华中农业大学学报,1997,16(6):533-537
75.聂以春,刘金兰,张献龙.新合成的棉花遗传资源-异源四倍体(亚洲棉×司笃克氏棉)初报[J].作物品种资源1999,(3):22
76.聂以春,左开井,张献龙,等。RAPD标记在棉属种间杂种后代检测中的应用[J].中国农业科学,2000a,33(5):1-7
77.聂以春,左开井,张献龙,等.RAPD标记分析棉花种间杂种后代的遗传相似性[J].华中农业大学学报,2000b,19(6),:523-527聂汝芝,李懋学.二倍体野生棉的核型变异与进化[J].植物学报,1989,31(3):178-184
78.潘玉欣.转基因抗虫棉品种DNA指纹图谱建立和遗传多样性评价[硕士论文].河北保定:河北农业大学,2005
79.庞朝友.棉花种间杂交种质创新效果及其遗传多样性研究[博士论文].河北保定:河北农业大学,2005
80.庞朝友,杜雄明,马峙英.棉花种间杂交渐渗系创新效果评价及特异种质筛选[J].科学通报,2006,51(1):55-62
81.彭跃进,钱思颢.陆地棉与雷蒙德氏棉种间杂种后代的胚胎学观察[J].作物学报,1989,15(3),243-252
82.戚存扣,盖钧镒,章元明.甘蓝型油菜芥酸含量的主基因+多基因遗传[J].遗传学报,2001,28(2):182-187
83.钱思颖,周行。陆地棉与中棉种间杂交的研究及其在育种上的就用[J].作物学报,1963,2(1):29-45
84.钱思颖,黄骏麒,洪爱华,徐英俊.棉属酯酶同工酶的分析[J].江苏农业学报,1985,4:15-20
85.钱思颖,黄骏麒,刘桂花玲等.棉属种间杂交研究.作物学报,1988,14(2):96-102
86.钱思颖,黄骏麒,彭跃进,等.陆地棉与异常棉(Ganomalum)种间杂种的研究及其在育种上的应用[J].中国农业科学,1992a,25(6):44-51
87.钱思颖,黄骏麒,彭跃进,等.棉花高纤维品质新种质培育研究初报[J].江苏农业科学,1992b,(3)(总第69期):19-20
88.钱思颖,周宝良,黄骏麒,等.陆地棉86-1与辣根棉(G.armourianum Keam)种间杂种及其利用的研究[J].作物学报,1995,21(5):592-597
89.钱思颖,黄骏麒,周宝良,等.陆地棉与克劳茨基棉(G klotzschianum Anderss)的研究和利用[J].江苏农业学报,1996,12(4):18-22
90.钱思颖,黄骏麒,周宝良,等.陆地棉与旱地棉、裂片棉、松散棉、特尼氏棉种间杂种F1的形态和细胞学研究[J].江苏农业学报,1996,12(3):10-14
91.冉鸿昌,肖炎农,姜道宏,等.湖北省棉花黄萎病菌致病力分化和遗传多样性分析[J].华中农业大学学报,2005,24(5):,442-447
92.时香玉,高国强,苏学合,等.胚珠培养技术在棉花远源杂交中的应用[J].山东农业科学,1999,(3):5-9
93.宋国立,崔荣霞,王坤波,等.澳洲棉种遗传多样性的RAPD分析[J].棉花学 报,1999,11(2):65-69
94.宋建中,姜艳丽,李江辉,等.棉花远缘杂交选育特早熟新品种的研究[J].中国棉花2001,28(6):9-11
95.宋宪亮,孙学振,张天真,等.棉花遗传多态性研究进展[J].西北植物学报,2004,24(12):2393-2397
96.沈新莲,周宝良,吴敬音,等.棉属野生种稀毛棉、皱壳棉、杨叶棉的核型研究[J].棉花学报,1997,9(4):217-221
97.沈新莲,袁有禄,郭旺珍,朱协飞,张天真.棉花高强纤维主效QTL的遗传稳定性及它的分子标记辅助选择效果[J].高技术通讯,2001,10,13-16
98.眭书祥.棉花抗黄萎病育种研究初报[J].中国棉花,1995,22(6):12-13.
99.孙黛珍,王曙光,李淑芳,等.HAG三种杂种回交后代腺体性状及形态特征遗传的研究[J].山西农业大学学报,1999,19(1):19-22
100.孙黛珍,崔克俭,李炳林,等.(棉花[(亚×比)×(陆×褐)]种间杂种的研究[J].西农业科学2000,28(2):3-6
101.孙黛珍,李炳林,王曙光,等.三元杂种及回交后代的遗传性状和细胞学研究[J].棉花学报,2000,12(2):57-61
102.孙黛珍,高培芳,王曙光,等.棉花四元杂种F1不育性的研究[J].西北农业大学学报,2000,28(2):103-107
103.孙黛珍,王曙光,李炳林.棉花四元杂种[(亚×比)×(陆×夏)]F1的性状遗传及细胞学研究[J].山西农业科学2001,29(1):23-26
104.孙黛珍,王曙光,李炳林.陆地棉、亚洲棉与比克氏棉杂种F1及回交后代的育性研究[J].华北农学报2001,16(1):38-43
105.孙黛珍,王曙光,董俊梅.棉属三染色体组(A、D、G)杂种的细胞遗传学研究[J].棉花学报,2001,13(4):204-208
106.孙东磊.彩色棉纤维色泽遗传及多样性分析[硕士论文].河北保定:河北农业大学,2006
107.孙济中,刘金兰,万年青,等.亚洲棉同源四倍体与陆地棉杂交和回交后代育性遗传的研究[J].遗传学报,1981,8(2):149-157
108.童旭宏,祝水金,季道藩.陆地棉子叶色素腺体延缓形成性状的表现与组织结构观察[J].棉花学报,2005,17(3):137-140
109.徐秋华,张献龙,聂以春.长江、黄河流域两棉区陆地棉品种的遗传多样性比较研究[J].遗传学报,2001,28(7):683-690
110.徐秋华,张献龙,冯纯大,等.河北省和中棉所育成陆地棉品种的遗传多样性分析[J].棉花学报,2001,13(4):238-242
111.徐秋华,张献龙,聂以春,等.我国棉花抗枯萎病品种的遗传多样性分析[J].中国农业科 学:2002,35(3):272-276
112.王坤波,李懋学,张香娣,等.陆地棉与7个野生棉杂种细胞学研究[J].作物学报,1996,22(1):27-35
113.万黎明,彭锁堂.棉花三种杂种色素腺体性状的研究[J].山西农业大学学报,1998,18(2):102-104
114.王朝生,柴友荣,董顺文,等.川棉109多质源育种的实践[J].西南农业学报,1998,11:235-241
115.王春英,王坤波,王文奎,等.棉花gDNA体细胞染色体FISH技术[J].棉花学报,1999,11(2):79-83
116.王春英,王坤波,宋国立,等.棉花体细胞染色体rDNA-FISH技术[J].棉花学报,2001,13(2):75-77
117.王凯.异源四倍体棉花遗传图谱的构建与分子细胞遗传学研究[博士论文].江苏南京:南京农业大学,2006
118.王坤波,李懋学.棉属D染色体组的核型变异和进化[J].作物学报,1991,16(3):200-207
119.王坤波,王文奎,王春英,等.海岛棉原位杂交及核型比较[J].遗传学报,2001,28(1):69-75
120.王建康,盖钧镒.利用杂种F2世代鉴定数量性状主基因-多基因混合遗传模型并估计其遗传效应[J].遗传学报,1997,24(5):432-440.
121.王建康,盖钧镒.利用回交或F2:3世代鉴定主基因和多基因的混合遗传模型[J].作物学报,1998a,24(4):402-409.
122.王建康,盖钧镒.数量性状主基因.多基因混合遗传的P1、P2、F1、F2和F2:3的联合分析方法[J].作物学报,1998b,24(6):651-659.
123.王建设,王建康,朱立宏,等.水稻主基因-多基因混合遗传控制白叶枯病抗性的基因效应分析[J].遗传学报,2000,27(1):34-38.
124.王立平,王坤波,简桂良,等.“九五”与“八五”我国自育棉花品种纤维品质比较分析[J].棉花学报,2003,15(4):231-234
125.王省芬,张桂寅,李喜焕,等.黄河、长江流域棉区棉花抗病品种的AFLP分析[J].遗传学报,2004,31(12):1426-1433
126.王省芬,马峙英,张桂寅,等.我国棉花抗枯、黄萎病骨干品种(系)基于AFLP的遗传多样性[J].棉花学报,2005,17(1):23-28
127.王省芬,马峙英,潘玉欣,等.转基因抗虫棉SSR和AFLP遗传变异研究[J].植物遗传资源学报,2006,7(2):153-158
128.王志龙,孙传渭,张欣雪,等.棉属种间高代系的过氧化物酶同工酶研究[J].植物学报,1995,37(6):465-470
129.王志宁,季道藩,许馥华.栽培棉种间多棉种杂种的形态学和细胞遗传学研究[J].浙江农业 大学,1996,22(2):127-136
130.王志宁,季道藩,许复华.栽培棉种间二、三、四元杂种的研究.Ⅰ.杂种F1的产生及其形态特性[J].浙江农业大学学报,1990,16(4):363-368
131.王志忠,王兆晓,崔瑞敏.棉花种间杂交新品种冀棉25号的选育[J].华北农学报,1999,14(增刊):28-34
132.魏守军,袁有禄,陆作楣.1973-2000年黄河流域棉花品种改良与应用状况分析[J].棉花学报,2003,15(6):367-371
133.韦贞国,刘素纹,舒金树.陆地棉远缘异质系培育研究初报[J].湖北农业科学,1982(10):11-13
134.韦贞国,李宗友,易先达,等.哈克尼西棉雄性不育胞质的遗传效应[J].棉花学报,1995,7(2):76-81
135.武晶,段永红,郭志爱,等.棉花三种杂种色素腺体密度空间分布的研究[J].山西农业大学学报,2005,25(1):58-63
136.吴玉香,孙玉强,陈崇乾,等.利用RAPD检测棉属种间亲缘关系的研究[J].作物学报,2007,33(6):909-913
137.杨伟华,项时康,唐淑荣,等.20年来我国自育棉花品种纤维品质分析[J]。棉花学报,2001,13(6):377-384
138.殷剑美,武耀廷,朱协飞,等.陆地棉产量与品质性状的主基因与多基因遗传分析[J].棉花学报 2003,15(2):67-72
139.于霁雯,喻树迅,王武,等.应用RAID对短季棉品种遗传多样性的初步评价[J].棉花学报,2006,18(3):186-189
140.袁有禄.棉花优质纤维特性的遗传及分子标记研究[博士论文].南京:南京农业大学
141.袁有禄,张天真,郭旺珍,等.棉花高品质纤维性状的主基因与多基因遗传分析[J].遗传学报,2002,29(9):827-834
142.袁有禄,张天真,郭旺珍,等.棉花高品质纤维性状QTLs的分子标记筛选及其定位[J].遗传学报,2001,28(12):1151-1161
143.詹秋文,盖钧镒,章元明,等.大豆对斜纹夜蛾幼虫抗性遗传的发展表达过程[J].遗传学报,2001,28(10):956-963.
144.张凤银,孙济中,刘金兰,等.棉属(Gossypium)种间杂种一代雌配子体发育过程[J].湖北农业科学,1998,(4):3-7
145.张凤银,孙济中,刘金兰,等.棉属(Gossypium)种间杂种F1形态特征与细胞遗传学研究[J].江汉大学学报,1998,15(6):97-101
146.张正圣,李先碧,刘大军,等.陆地棉高品质系的杂种优势利用研究[J].棉花学报,2002,14(5):264-268.
147.赵国忠,冯恒文,李爱国,等.棉属8个野生种2个二倍体栽培种对陆地棉的改良效应[J].华北农学报,1994,9(4):44-48.
148.周宝良,彭跃进,黄骏麒,等.海岛棉与旱地棉、雷蒙德氏棉和拟似棉的F1杂种细胞学观察[J].江苏农业学报,1991,7(2):15-21。
149.周宝良,黄骏麒,彭跃进,等.二倍体棉种间杂种F1的形态和细胞学[J].江苏农业学报,1992,8(1):19-24
150.周宝良,钱思颖,黄骏麒,等.江苏引进及利用棉属野生种研究.作物品种资源[J],1993a(增刊):149-151
151.周宝良,彭跃进,黄骏麒,等.海岛棉与瑟伯氏棉、辣根棉、裂片棉、松散棉的杂种F1细胞学研究[J].浙江农业大学学报,1993b,19(1):24-29
152.周宝良,黄骏麒,彭跃进,等.中棉与纳尔逊氏棉(Gnelsonii Fryx.)种间杂种F1的研究[J].作物学报,1994a,20(2):217-222
153.周宝良,钱思颖.棉属野生种在棉花育种上的利用研究新进展[J].江苏农业科学,1994b,(4)(总第80期):25-28
154.周宝良,黄骏麒,沈新莲,等.海岛棉与澳洲棉、黄褐棉种间杂种F1的细胞学研究[J].棉花学报,1995a,7(4):209-212
155.周宝良,陈松,沈新莲,等.棉属(Gossypium ssp.)种子SOD酶的凝胶电泳图谱与种间关系[J].江苏农业学报,1995b,11(1):11-15
156.周宝良,彭跃进,沈新莲,等.陆地棉与三裂棉、斯特提棉和A111种间杂种F1的形态与细胞学[J].作物学报,1996a,22(1):84-88
157.周宝良,沈新莲,陈国平,等.异常棉和陆地棉渐渗杂交种质的高强纤维特性及超分子结构相关分析[J].江苏农业学报,1996b,12(4):23-29
158.周宝良,沈新莲,陈国平,等.含异常棉基因棉纤维品质及超分子结构遗传效应[J].棉花学报,1996c,8(4):193-198
159.周宝良,陈松.沈新莲,等.陆地棉高品质纤维种质基因库的拓建[J].作物学报,2003a,29(4):514-519
160.周宝良,沈新莲,陈松,等.利用三个野生棉种进行陆地棉纤维品质改良的效应比较[J].棉花学报,2003b,15(1):22-25
161.周有耀.棉花数量性状遗传.中国棉花遗传育种学(黄滋康主编)[M].山东济南:山东科学技术出版社,2003,68-94.
162.周仲华,何鉴星,陈金湘.陆×索棉异附加单体系的形态学及细胞学鉴定[J].湖南农业大学学报(自然科学版),2004,30(4):316-318
163.周仲华,余萍,刘光辉,等.索马里棉异源单体附加系的形态及分子特征研究[J].科学通报,2004,49(5):558-562
164.周曙霞,刘文国,程鲁军,等.哈克尼西棉细胞质对陆海种间杂种优势的影响[J].中国棉花,2003,30(4):8-10
165.邹美娟.四倍体栽培棉、二倍体野生棉减数分裂的FISH研究[硕士论文].北京:中国农业科学院,2002
166.朱龙付,张献龙,聂以春,等.转基因抗虫棉品种(系)的遗传多样性初步研究[J].华中农业大学学报,2002,21(5):401-405
167.朱龙付.棉花遗传多样性研究及抗黄萎病相关基因的克隆与分析[博士论文].湖北武汉:华中农业大学,2004
168.朱四元,陈金湘,刘爱玉,等.利用SSR标记对不同类型抗虫棉品种的遗传多样性分析[J].湖南农业大学学报(自然科学版),2006,32(5):469-472
169.朱四元,陈金湘,刘海荷,等.不同类型抗虫棉品种基于RAPD的遗传多样性分析[J].棉花学报,2007,19(2):83-87
170.祝水金,王红梅,吴汉北,等.有酚与低酚陆地棉亲本配制的种间三元杂种腺体遗传性状研究[J].棉花学报,1994,6(增刊):19-24
171.祝水金,李炳林,汪若海,等.亚洲棉、比克氏棉和海岛棉种间杂种的合成及性状研究[J].棉花学报,1995,7(3):160-163
172.祝水金,季道藩,汪若海,等.5个澳洲野生棉种植株形态性状与叶片过氧化物同工酶谱研究[J].西北植物学报,1997,17(4):433-438
173.祝水金,季道藩,汪若海,等.五个澳洲野生棉种色素腺体和棉酚性状研究[J].棉花学报,1997,9(2):84-89
174.祝水金,季道藩,汪若海,等.5个澳洲野生棉种植株形态性状与叶片过氧化物同工酶谱研究[J].西北植物学报,1997;17(4):433-438
175.祝水金,季道藩,汪若海,等.澳洲野生棉种的子叶棉酚动态及与色素腺体形态的关系[J].棉花学报,1999,11(4):169-173
176.祝水金,季道藩,汪若海,等.陆地棉不同色素腺体基因对比克氏棉子叶色素腺体延缓形成性状的遗传效应[J].作物学报,1999,25(5):585-590
177.祝水金,季道藩,汪若海,等.陆地棉与斯特提棉的种间杂种及其色素腺体性状的遗传[J].遗传学报,1999,26(4):403-409
178.祝水金,季道藩.澳洲野生棉种子叶色素腺体延缓形成性状的遗传研究[J].科学通报,2001,48(2):132-137
179.祝水金,蒋玉蓉,Reddy N,等.陆地棉子叶色素腺体延缓形成种质系的育成及其遗传研究[J].科学通报,2004,49(19):1987-1992
180.朱四元,陈金湘,刘爱玉,等.利用SSR标记对不同类型抗虫棉品种的遗传多样性分析[J].湖南农业大学学报(自然科学版),2006,32(5):469-472
181.朱四元,陈金湘,刘海荷,等.不同类型抗虫棉品种基于RAPD的遗传多样性分析[J].棉花学报,2007,19(2):83-87
182.左开井,孙济中,张金发,等用RAPD标记评估我国棉花品种遗传多样性[J].遗传学报,2000,27(9):817-823
183. Abdalla AM,Reddy OUK,E1-Zik KM, et al.Genetic diversity and relationships of diploid and tetraploid cottons revealed using AFLP [J]. Theor Appl Genet, 2001,102:222-229
184. Abraham P.Cytological studies in Gossypium.I:Chromosome behaviour in interspecific hybrid G.arboreun×G. stocksii[J]. India J. Agric.Sci.,1940,10:285-298
185. Adams KL,Wendel JF.Exploring the genomic mysteries of polyploidy in cotton [J].Biological Journal of the Linnean Society, 2004, 82: 573-581
186. Adams KL,Cronn R, Percifield R, et al. Genes duplicated by polyploidy show unequal contributions to the transcriptome and organ-specific reciprocal silencing [J]. PNAS, 2003,100 (8): 4649-4654
187. Adams KL,Percifield R, Wendel JF. Organ-Specific Silencing of Duplicated Genes in a Newly Synthesized Cotton Allotetraploid [J]. Genetics, 2004,168:2217-2226
188. Adams KL,Percifield R, Wendel JF. Allele-specific, sidirectional silencing of an alcohol dehydrogenase gene in different organs of interspecific diploid cotton hybrids [J]. Genetics,2005,171:2139-2142
189. Adams KL,Percifield R, Wendel JF. Novel patterns of gene expression in polyploid plants [J]. TRENDS in Genetics, 2005,21(10): 539-543
190. Adams KL,Psrcifield R, Wendel JF. Polyploidy and genome evolution in plants [J]. Current Opinion in Plant Biology 2005, 8:135-141
191. Ahoton L,Lacape JM, Baudoin JP, et al. Introduction of Australian diploid cotton genetic variation into upland cotton [J]. Crop Science, 2003,43,6:1999-2005
192. Applequist WL,Cronn R,Wendel JF. Comparative development of fiber in wild and cultivated cotton [J]. Evolution & Development, 2001,3(1): 3-17
193. Altaf MK,Stewart JM,Wajahatullah MK et al. Molecular and morphological genetics F2 population of cotton [M]. Proceedings Belt wide Cotton Coferences, 1997, l:448-452.New Orleans, LA, USA, January6-10
194. Altaf MK,Cantrell RG,Zhang J et al. Segregation patterns of molecular, morphological and quantitative traits in a trispecies F2 cotton population [M]. Special Report Agricultural Experiment Station, Division of Agricultural, University of Arkansas, 1997,183:147-1498
195. Alrman DW, Stelly DM, Kohel RJ.Introgression of the glanded-plant and glandless-seed trait from Gossypium sturtianum Willis into cultivated upland cotton using ovule culture [J]. Crop Sci, 1987,27:880-884
196. Alvarez I, Wendel JF. Ribosomal ITS sequences and plant phylogenetic inference [J].Molecular Phylogenetics and Evolution, 2003,29: 417-434
197. Alvarez I, Cronn R, Wendel JF. Phytogeny of the New World diploid cottons (Gossypium L.,Malvaceae) based on sequences of three low-copy nuclear genes [J]. PL Syst. Evol. , 2005,252:199-214
198. Alvarez I, Wendel JF. Cryptic interspecific introgression and genetic differentiation within Gossypium aridum (Malvaceae) and its relatives [J]. Evolution, 2006,60(3): 505-517
199. Amin KC.Interspecific hybridization between Asiatic and New World cottons [J].Ind J Agr Sci, 1940,10:404-413
200. An CF, Saha S, Jenkins JN et al.Transcriptome proWling, sequence characterization, and SNP-based chromosomal assignment of the EXPANSIN genes in cotton. Mol Genet Genomics, 2007, 278:539-553
201. Arpat AB, Waugh M, Sullivan JP et al. Functional genomics of cell elongation in developing cotton Wbers. Plant Mol Biol,2004,54:911-929
202. Beasley JO. The production of polyploids in Gossypium [J]. J. Hered., 1940a, 31, 39-48
203. Beasley JO. The origin of the American tetraploid species[J]. Amer.Nat., 1940b, 74,285-286
204. Beasley JO.Hybridization of Amer.can 26-chromosome and Asiatic 13-chromosome species of Gossypium[J]. J. Agr. Res., 1940c, 60,175-181
205. Beasley JO. Meiotic chromosome behaviour in species, species hybrids, haploids, and induced polyploids of Gossypium [J]. Genetics, 1942,27,25-54
206. Becerra Lopea-Lavalle LA, Brubaker CL. Frequency and fidelity of alien chromosome transmission in Gossypium hexaploid bridging populations [J]. Genome, 2007a, 50: 479-491
207. Becerra Lopea-Lavalle LA, Brubaker CL. The effect of Gossypium C-genome chromosomes on resistance to fusarium wilt in allotetraploid cotton [J]. Theor Appl Genet, 2007b,DOI 10.1007/s00122-007-0581-6
208. Bergey DR, Stelly DM, Price HJ. In situ hybridization of biotinylated DNA probes to cotton meiotic chromosomes [J]. Stain Technol, 1989, 64, 25-37
209. Bi VI, Baudoin JP, Mergeai G. Cytogenetics of the 'glandless-seed and glanded-plant' trait from Gossypium sturtianum Willis introgressed into upland cotton (Gossypium hirsutum L.) [J]. Plant Breed, 1998,117:235-241
210. Bi VI, Baudoin JP, Hau B, et al. Development of high-gossypol cotton plants with low-gossypol seeds using trispecies bridge crosses and in vitro culture of seed embryos [J]. Euphytica, 1999,106:243-251
211. Bi VI, Maquet A, Baudoin JP, et al. Breeding for "low-gossypol seed and high-gossypol plants"in upland cotton. Analysis of tri-species hybrids and backcross progenies using AFLPs and mapped RFLPs [J]. Theor Appl Genet, 1999,99:1233-1244
212. Bowman DT, May OL, Calhoun, DS. Genetic base of upland cotton cultivars released between 1970 and 1990[J]. Crop Science, 1996,36(3): 577-581
213. Bowman DT. Public cotton breeders—Do we need them? [J] J Cotton Science, 1999, 3:139-152
214. Bowman DT.and Gutierrez OA. Sources of fiber strength in the U.S. Upland cotton crop from 1980 to 2000[J]. The Journal of Cotton Science 2003,7:164-169
215. Bowman DT, May OL, Creech JB. Genetic uniformity of the U.S. upland cotton crop since the introduction of transgenic cottons [J]. Crop Science, 2003,43(2): 515-518
216. Brubaker CL, Wendel JF. Reevaluating the origin of domesticated cotton (Gossypium hirsutum, Malvaceae) using nuclear restriction fragment length polymorphisms (RFLPs) [J].American Journal of Botany, 1994,81(10): 1309-1326.
217. Brubaker CL, Brown AHD, Stewart JMcD, et al. Production of fertile hybrid germplasm with diploid Australian Gossypium species for cotton improvement [J]. Euphytica 1999,108:199-213,
218. Brubaker CL, Brown AHD. The use of multiple alien chromosome addition aneuploids facilitates genetic linkage mapping of the Gossypium G genome [J]. Genome, 2003, 46, (5):774-791
219. Brubaker, CL, Paterson AH, Wendel JF. Comparative genetic mapping of allotetraploid cotton and its diploid progenitors [J]. Genome, 1999,42:184-203
220. Cedroni ML, Cronn RC, Adams KL, et al. Evolution and expression of MYB genes in diploid and polyploid cotton [J]. Plant Molecular Biology, 2003,51: 313-325.
221. Chen XY, Zhang TZ, Zhu YQ, et al. Functional genomic studies of cotton fiber development [J]. Cotton Science, 2002,14 (supplement): 39
222. Cherry JP. A comparative study of seed protein of species of Gossypium by gel electrophoresis [J]. Evolution, 1970, 24: 431- 447.
223. Crane CF, Price HJ, Stelly DM, et al. Identification of a homeologous chromosome pair by in situ DNA hybridization to ribosomal RNA loci in meiotic chromosomes of cotton (Gossypium hirsutum) [J]. Genome, 1993, 36: 1015-1022
224. Cronn, RC, Zhao X, Paterson AH, et al. Polymorphism and Concerted Evolution in a Tandemly Repeated Gene Family: 5S Ribosomal DNA in Diploid and Allopolyploid Cottons[J]. J Mol Evol,1996,42:685-705
225. Cronn R, Small RL,Wendel JF. Duplicated genes evolve independently after polyploid formation in cotton [J]. PNAS, 1999,96(25):14406-14411
226. Cronn R, Wendel JF. Differential evolutionary dynamics of duplicated paralogous Adh loci in allotetraploid cotton (Gossypium) [J].Mol. Biol.Evol, 2002a,19(5): 597-607
227. Cronn R, Small RL,Haselkom T, et al.Rapid diversification of the cotton genus (Gossypium:malvaceae) revealed by analysis of sixteen nuclear and chloroplast genes [J]. American Journal of Botany, 2002b, 89(4): 707-725
228. Cronn R, Cedroni M, Haselkorn T, et al. PCR-mediated recombination in amplification products derived from polyploid cotton [J]. Theor Appl Genet, 2002c, 104:482-489
229. Cronn R, Small RL,Haselkorn T, et al. Cryptic repeated genomic recombination during speciation in Gossypium gossypioides[J]. Evolution, 2003a, 57(11): 2475-2489
230. Cronn R, Wendel JF. Cryptic trysts, genomic mergers, and plant speciation [J]. New Phytologist, 2003b, 161:133-142
231. Culp TW, Harrell DC.Some genetic implications in the transfer of high fiber strength gene to Upland cotton [J]. Crop Sci., 1979,19:481-484
232. Davie JH. Cytological studies in the Malvaceae and certain related families [J]. J Genet,1933,28:33-67
233. Dejoode DR, Wendel JF. Genetic diversity and origin of the Hawaiian island cottons Gossyium tomentosum [J].American Journal of Botany, 1992,79(11): 1311-1319.
234. Denham HJ. The cytology of the cotton plant.Ⅰ.Microspore formation in Sea Island cotton [J]. Ann. Bot.,1924a, 38:407-432
235. Denham HJ. The cytology of the cotton plant.Ⅱ.Chromosome numbers of old and new world cottons [J]. Ann. Bot., 1924b, 38, 433-498
236. Dilday RH.Development of a cotton plant with glandless seeds, and glanded foliage and fruiting forms [J]. Crop Sci, 1986,26:639-941
237. Doblin MS, Kurek I, Jacob-Wilk D et al. Cellulose Biosynthesis in Plants: from Genes to Rosettes. Plant & Cell Physiology, 2002,43(12): 1407-1420
238. Dutt Y, Wang XD, Zhu YG, et al. Breeding for high yield and fibre quality in coloured cotton [J]. Plant Breeding, 2004,123:145-151
239. Edwards GA,Endrizzi, JE and Stein R. Genome DNA content and chromosome organization in Gossypium [J]. Chromosoma,1974,47:309-326
240. Endrizzi JE, Turcotte EL,Kohel RJ.1985.Genetics, cytology and evolution of Gossypium [J].Advances in Genetics, 123:271-375
241. Endrizzi JE, Kattennan FRH, Geever RF. DNA hybridization and the time of origin of three species of Gossypium[J]. Evolution Trends Plants, 1989,3,115-119
242. Esbroeck VGA, Bowman, DT, Calhoun SD, et al.Changes in the genetic diversity of cotton in the USA from 1970 to 1995[J]. Crop Science, 1998,38(1): 33-37
243. Esbroeck, VGA, Bowman DT. Cotton germplasm diversity and its improvement to cultivar development [J]. J Cotton Science, 1998,2:121-129
244. Esbroeck VGA, Bowman, DT, May OL,et al. Genetic similarity indices for ancestral cotton cultivars and their impact on genetic diversity estimates of modern cultivars [J]. Crop Science,1999,39(2): 323-328
245. Fryxell PA.A revision of Australian species of Gossypium with observation on occurrence of Thespesia in Australia (Malvaceae) [J]. Aust J Bot, 1965,18:71-102
246. Fryxell PA.Phenetic analysis and the phytogeny of the diploid species of Gossypium L [J].Evolution, 1971,25:554-562
247. Fryxell, PA.1992. A revised taxonomic interpretation of Gossypium L. (Malvaceae) [J].Rheedea 2:108-165.
248. Gai JY, Wang IK.Identification and estimation of a QTL model and its effects [J]. Theor.Appl.Genet., 1998, 97:1162-1168.
249. Gerstel DU.Chromosomal translocations in interspecific hybrids of the genus Gossypium [J].Evolution, 1953,7:234-244
250. Giband Marc,Trung-Bieu Nguyen, Jean-Marc Lacape. Mapping genes for cotton fiber quality:A.Thaliana as a source of candidate genes [J]. Cotton Science, 2002,14(supplement):57
251. Grover CE, Kim HR, Wing RA, et al. Incongruent Patterns of local and global genome size evolution in cotton [J].Genome Research, 2004,14:1474-1482
252. Guan B, Wang K,Zhou BL,et al. Establishment of a multi-color GISH technique to simultaneously discriminate the three interspecific hybrid genomes in Gossypium [J].JIPB,2007 (in press)
253. Guo WZ, Zhang TZ, Shen XL,et al. Development of SCAR marker linked to a major QTL for high fiber strength and its usage in molecular-marker assisted selection in Upland cotton[J]. Crop Sci. 2003,43:2252- 2256
254. Guo WZ, Cai CP, Wang CB, et al. A microsatellite-based, gene-rich linkage map reveals genome strucutre, function and evolution in Gossypium [J].Genetics, 2007,176: 527-541
255. Guo WZ, Wang W, Zhou BL,et al. Cross-species transferability of G arboreum-derived EST-SSRs in the diploid species of Gossypium. Theor Appl Genet, 2006,112:1573-1581
256. Gutierrez OA, Basu S, Saha S, et al.Genetic distance among selected cotton genotypes and its relationship with F2 performance[J]. Crop Science, 2002,42(6): 1841-1847
257. Hanson RE, Zwick MS, Choi SD,et al. Fluorescent in situ hybridization of a bacterial artificial chromosome [J]. Genome, 1995,38,646-651
258. Hanson RE, Islam-Faridi MN, Percival EA,et al.Distribution of 5S and 18S-28S rDNA loci in a tetraploid cotton (Gossypium hirsutum L.) and putative diploid ancestors [J].Chromosoma,1996,105,55-61
259. Hanson RE, Zhao XP, Islam-Faridi MN, et al. Evolution of interspersed repetitive elements in Gossypium (Malvaceae) [J]. American Journal of Botany, 1998,85(10):1364-1368
260. Hanson RE, Islam-Faridi MN, Crane CF, et al. Tyl-copia-retrotransposon behavior in a polyploid cotton [J]. Chromosome Research, 1999,8:73-76
261. Hanson WD. The break up of initial linkage blocks under selected mating systems [J].Genetics, 1959,44:857-868
262. Hao L,Song GL,Li BL,et al. Karyotype analysis of Gossypium arboreum×G. bickii by genome in situ hybridization [J]. Acta Genetica Sinica, June 2006,33 (6): 565-572
263. Harlan,JR,de Wet JMJ. Toward a rational classification of cultivated plants [J]. Taxon,1971, 20:509-517.
264. Harland SC.The genetics of cotton [M]. London, Jonathan Cape, 1939
265. Harland SC. The genetics of Gossypium.Ⅻ.Homologus genes for anthocyanin pigmentation in New and Old World cottons [J]. J Genet., 1935,30:465-476
266. Hutchinson JB, Silow RA and Stephens SG. The evolution of Gossypium species [J]. Ann.Bot. N.S.,1947,9:361-367
267. Hutchinson SJ. The application of genetics to cotton improvement [J]. London, Camb.Univ.Press.1959
268. Hutchinson JB. The history and relationships of the world's cottons [J]. Endeavour, 1962,21:5-15
269. Harmer SE, Orford SJ, Timmis JN. Characterisation of six a-expansin genes in Gossypium hirsutum (upland cotton) [J]. Mol Genet Genomics, 2002,268:1-9
270. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅰ.Utilisation de l'hybridation interspedifique et de la méthode des lignées d'addition pour l'amélioration du cotonnier [J].Cot Fib Trop, 1981a,36(3): 248-258
271. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅱ.Description phénotypique de quelques lignées d'addition monosomique de Gossypium anomalum et de Gossypium stocksii [J].Cct Fib Trop,1981b,36(4):287-296
272. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅲ.Evolution d'une collection de lignées d'addition de G. anomalum et de G. Stocksii sur G. hirsutum après plusieurs generations d'autofécondation [J]. Cot Fib Trop, 1982,37(2): 163-177
273. Hawkins JS, Kim HR, Nason JD, et al.Differential lineage-specific amplification of transposable elements is responsible for genome size variation in Gossypium [J]. Genome Res., 2006,16:1252-1261
274. He DH, Lin ZX, Zhang XL et al. QTL mapping for economic traits based on a dense genetic map of cotton with PCR-based markers using the interspecific cross of Gossypium hirsutum×Gossypium barbadense. Euphytica, 2007,153:181-197
275. Hendrix B,Stewart JMcD. Estimation of the nuclear DNA content of Gossypium species [J].Annals of Botany, 2005, 95(5): 789-797
276. Hsu C, An, C,Saha S, et al. Molecular and SNP characterization of two genome specific transcription factor genes GhMyb8 and GhMyb10 in cotton species. Euphytica, 2007, DOI 10.1007/s 10681- 007- 9485-4
277. Hutchinson JB.Intra-specific differentiation in Gossypium hirsutum [J]. Heredity, 1951, 5,161-193
278. Hutchinson JB and Ghose RL. Studies in crops ecology.Ⅰ.The composition of cotton crops of central India and Rajputana [J]. Indian J. Agric.Sci.,1937,7,1
279. Iqbal MJ,Reddy OUK,El-Zik KM, et al. A genetic bottleneck in the 'evolution under domestication' of upland cotton Gossypium hirsutum L. examined using DNA fingerprinting[J]. Theor Appl Genet, 2001,103:547-554
280. Iqbal MJ, Azizn N, Saeed NA, et al. Genetic diversity evaluation of some elite co tton varieties by RA PD analysis [J]. Theor. Appl. Genet., 1997,94:139-144.
281. Iyengar NK.Cytological investigations on some of the interspecific hybrids of (American×Asiatic)×American cottons and their progenies [J].Ind J Genet Plant Breed, 1945, 5:32-45
282. Johnson BL adn Thein MM. Assessment of evolutionary affinities in Gossypium by protein electrophoresis [J]. Am. J. Bot., 1970,57:1081-1092
283. Johnson BL. Symposium on the Biochemical Systematics, Genetics and origin of cultivated plants.Ⅵ.Gossypium palmeri and a polyphyletic origin of the New World cottons [J].Bulletin of the Torrey Botanical Club. 1975,102(6):340-349
284. Ji SJ, Lu YC, Feng JX,et al. Isolation and analyses of genes preferentially expressed during early cotton fiber development by subtractive PCR and cDNA array [J]. Nucleic Acids Research, 2003, 31(10): 2534-2543
285. Ji Y, Raska WA,McKnight TO, et al.Use of meiotic FISH for identification of a new monosome in Gossypium hirsutum L [J]. Genome, 1997,40:34-40
286. Ji Y, Donato MD,Crane CF, et al. New ribosomal RNA gene locations in Gossypium hirsutum mapped by meiotic FISH [J].Chromosoma, 1999a, 108:200-207
287. Ji Y, Raska WA,Donato MD,et al. Identification and distinction among segmental duplication-deficiencies by fluorescence in situ hybridization (FISH)-adorned multivalent analysis[J]. Genome, 1999b, 42(4): 763-771
288. Ji Y, Pertuze R, Chetelat RT. Genome differentiation by GISH in interspecific and intergeneric hybrids of tomato and related nightshades [J]. Chromosome Research, 2004,12:107-116
289. Jiang CX, Chee PW, Draye X, et al. Multilocus interactions restrict gene introgression in interspecific populations of polyploid Gossypium (cotton) [J]. Evolution, 2000, 54(3):798-814
290. Jiang CX, Wright RJ, El-ZikKM, et al. Polyploid formation created unique avenues for response to selection in Gossypium (cotton) [J]. Proc.Natl.Acad. Sci. USA, 1998,95:4419-4424
291. KattermantFRH and Ergle DR.A study of quantitative variations of nucleic acids in Gossypium [J]. Phytochemistry, 1970,9:2007-2010
292. Khan SA,Hussain D, Askari E, et al. Molecular phytogeny of Gossypium species by DNA fingerprinting [J]. Theor Appl Genet, 2000,101:931-938
293. Kim HJ, Triplett BA.Characterization of GhRacl GTPase expressed in developing cotton (Gossypium hirsutum L.) fibers. Biochimica et Biophysica Acta, 2004,1679:214-221
294. Kohel RJ,Endrizzi JE, White TG. An evaluation of Gossypium barbadense L. chromosomes 6 and 17 in the G.hirsutum L [J]. genome. Crop Sci., 1977,17:404-406.
295. Kohel RJ, Yu J, Park YH, et al. Molecular mapping and characterization of traits controlling fiber quality in cotton [J]. Euphytica, 2001,121:163-172.
296. Lawton-Rauh A. Evolutionary dynamics of duplicated genes in plants. Molecular Phylogenetics and Evolution [J], 2003,29:396-409
297. Lee JA. A genetical scheme for isolating cotton cultivars [J]. Crop Sci, 1981,21,339-341
298. Liu B, Brubaker CL,Mergeai G, et al. Polyploid formation in cotton is not accompanied by rapid genomic changes [J]. Genome, 2001a,44: 321-330
299. Liu B, Wendel JF.Intersimple sequence repeat (ISSR) polymorphisms as a genetic marker system in cotton [J]. Molecular Ecology Notes, 2001b,1:205-208
300. Liu B, Wendel JF. Non-Mendelian Phenomena in allopolyploid genome evolution [J]. Current Genomics, 2002,3(6): 489-505
301. Liu B, Wendel JF. Epigenetic phenomena and the evolution of plant allopolyploids [J].Molecular Phylogenetics and Evolution, 2003a,29: 365-379
302. Liu Q, Brubaker CL, Green AG, et al. Evolution of the fad2-l fatty acid desaturase 5'utr intron and the molecular systematics of Gossypium (Malvaceae) [J]. American Journal of Botany, 2001b, 88(1): 92-102
303. Liu Q, Singh SP, Green AG. High-stearic and high-oleic cottonseed oils produced by hairpin RNA-mediated post-transcriptional gene silencing [J]. Plant Physiology, 2002,129:1732-1743
304. Liu S, Cantrell RG, McCarty JC Jr, et al. Simple sequence repeat-based assessment of genetic diversity in cotton race stock accessions [J]. Crop Science, 2000,40(5): 1459-1460
305. Liu SH, Wang KB, Song GL, et al. Primary investigation on GISH-NOR in cotton [J].Chinese Science Bulletin, 2005,50(5): 425-429
306. Loguercio LL, Zhang JQ, Wilkins TA. Differential regulation of six novel MYB-domain genes defines two distinct expression patterns in allotetraploid cotton (Gossypium hirsutum L.) [J]. Mol Gen Genet, 1999,261: 660-671
307. Lu HJ, Myers GO. Genetic relationships and discrimination of ten influential Upland cotton varieties using RAPD markers [J]. Theor Appl Genet, 2002,105:325-331
308. May OL, Green CC, Roach SH, et al. Registration of PD93001, PD93002, PD93003, and PD93004 germplasm lines of Upland cotton with brown lint and high fiber quality [J]. Crop Sci., 1994,34:542
309. May OL, Bowman DT, Calhoun DS. Genetic diversity of U.S. Upland cotton cultivars released between 1980 and 1990[J]. Crop Science, 1995,35(6): 1570-1576
310. May OL. Genetic variation in fiber quality. Basra AS(ed). In Cotton Fiber: developmental biology, quality improvement and textile processing [M]. Food Product Press. NY 1999,pp183-229
311. McFadden Helen, Dean Beasley and Curt L. Brubaker. Assessment of Gossypium sturtianum and G. australe as potential sources of Fusarium wilt resistance to cotton [J]. Euphytica,2004,138:61-72
312. Mckhann Heather I, Christine Camilleri, Aurelie Berard, et al. Nested core collections maximizing genetic diversity in Arabidopsis thaliana [J]. The Plant Journal, 2004,38:193-202
313. Mei MN, Syed H, Gao W, et al. Genetic mapping and QTL analysis of fiber-related traits in cotton (Gossypium) [J].Theor Appl Genet, 2004,108:280-291
314. Meredith WR Jr. Cotton breeding for fiber strength. In Proceedings from cotton fiber cellulose: structure, function, and utilization conference [M]. Memphis, TN, National Cotton Council of American, 1992,289-302.
315. Mergeai G. New perspectives concerning the methodology to be used for introgression of the glanded plant and glandless seed character in cultivated cotton (Gossypium hirsutum L.) [J].Cot Fib Trop, 1992,47:113-118
316. Mert M, Kurt S, Gencer O,et al.Inheritance of resistance to Verticillium wilt (Verticillium dahliae) in cotton (Gossypium hirsutum L.) [J]. Plant Breeding, 2005,124:102-104
317. Meyer VG. Cytoplasmic effect on anther numbers in interspecific hybrids of cotton [J].J Heredity,1971,62:77-78
318. Meyer VG. Interspecific cotton breeding [M]. Econ Bot, 1974,28:56-60
319. Miller PA,Rawling UO. Break-up of initial linkage blocks through intermating in a cotton breeding population [J]. Crop Sci, 1967,7:199-204
320. Multani DS, Lyon BR. Genetic fmgerpringting of Australian cotton cultivars with RAPD markers [J]. Genome, 1995, 38:1005-1008.
321. Muramoto H. Hexaploid cotton: Some plant and fiber properties [J]. Crop Sci, 1969, 9: 27-29
322. Muravenko Olga V,Alexander R Fedotov, Elizabeth O Punina, et al. Comparison of chromosome BrdU-Hoechst-Giemsa banding patterns of the Al and (AD) 2 genomes of cotton [J]. Genome, 1998,41(4): 616-625
323. Murray Allen K,Robert L Nichols, Gretchen F Sassenrath-Cole.Cell wall biosynthesis:glycan- containing oligomers in developing cotton fibers, cotton fabric, wood and paper [J].Phytochemistry, 2001,57:975-986
324. Osborn TC, Pires JC, Birchler JA, et al. Understanding mechanisms of novel gene expression in polyploids [J]. TRENDS in Genetics, 2003,19(3):141-147
325. Palmer TP. Progressive improvement in self fertilized crops [J]. Heredity, 1953,7:127-130
326. Paterson AH, Bowers JE, Burow MD, et al. Comparative Genomics of Plant Chromosomes[J]. The Plant Cell, 2000,12:1523-1539
327. Paterson AH, Brubaker KL,Wendel JF. A rapid method for extraction of cotton (Gossypium spp.) genomic DNA suitable for RFLP or PCR analysis [J]. Plant Mol Biol Rep, 1993, 11:122-127
328. Paterson AH, Boman RK,Brown SM, et al. Reducing the genetic vulnerability of cotton [J].Crop Science, 2004,44(6):1900 -1901
329. Phillips LL. The cytogenetics of Gossypium and the origin of New World cottons [J].Evolution, 1963,17, 460-469
330. Phillips LL.The cytology and phylogenetics of the diploid species of Gossypium [J]. Am. J.Bot., 1966a,53:328-335
331. Phillips LL and Strickland MA. The cytology of a hybrid between Gossypium hirsutum and G. longicalyx [J].Can. J. Genet. Cytol.,1966,8,91-95
332. Phillips LL. Interspecific incompatibility in Gossypium.Ⅳ.Temperature-conditional lethality in hybrids of G klotzschianum [J].Am J Bot, 1977,64, 914-915
333. Phillips LL Cotton (Gossypium). In Hnadbook of Genetics [M]. Plenum Press, N.Y., and London, 1974 12:111-133
334. Pikaard, Craig S. Genomic change and gene silencing in polyploids [J]. TRENDS in Genetics,2001,17 (12): 675-677
335. Pillay M, Myers GO. Genetic diversity in cotton assessed by variation in ribosomal RNA genes and AFLP markers [J]. Crop Science, 1999,39(6): 1881-1886
336. Poisson C. Exploitation of the cross G. hirsutun × G. anomalum [J]. Cot Fib Trop,1968, 23,356-358
337. Poisson C. Use of G. hirsutum × G.anomalum [J]. Cot Fib Trop, 1968,23,359-364
338. Price HJ, Stelly DM, McKnight TD, et al.Molecular cytogenetic mapping of a nucleolar organizer region in cotton [J]. J Hered, 1990, 81: 365-370
339. Qin YM, Hu, CY, Pang Y, et al. Saturated Very-Long-Chain Fatty Acids Promote Cotton Fiber and Arabidopsis Cell Elongation by Activating Ethylene Biosynthesis. The Plant Cell,2007, www.plantcell.org/cgi/doi/10.1105/tpc.107.054437
340. Rahman M, Hussain D, Zafar Y. Estimation of genetic divergence among elite cotton cultivars-genotypes by DNA fingerprinting technology [J]. Crop Science, 2002, 42( 6): 2137-2144
341. Ren LH, Zhang TZ. Genetic evaluation of seven substitution lines in Upland cotton [J]. Acta Agron Sin, 2001,27:993 - 999. (in Chinese with English abstract)
342. Ren LH, Guo WZ,Zhang TZ. Identification of quantitative trait loci (QTLs) affecting Yield and fiber properties in chromosome 16 in cotton using substitution line [J]. Acta Botanica Sinica,2002,44(7):815 - 820
343. Reinisch A, Dong JM, Brubaker CL,et al.A detailed RFLP map of cotton (Gossypium hirsutum × G. barbaddense):chromosome organization and evolution in a disomic polyploid genome [J]. Genetics, 1994,138:829-847
344. Richmond TR. Procedures and methods of cotton breeding with special reference to American cultivated species [J]. Advances in Genetics, 1951, 4:213-245.
345. Rooney WL,Stelli DM, Altman DW. Identification of four Gossypium sturtianum monosomic alien addition derivatives from a backcrossing program with G. hirsutum [J].Crop Sci, 1991,31:337-341
346. Rohlf FJ (1998).NTSYS-pc: Numerical Taxonomy and Multivariate Analysis System [M],vers. 2.0. Applied Biostatistics, New York
347. Rong JK,Abbey C, Bowers JE, et al.A 3347-locus genetic recombination map of sequence-tagged sites reveals features of genome organization, transmission and evolution of cotton (Gossypium) [J]. Genetics, 2004,166:389-417
348. Rong JK,Bowers JE, Schulze SR, et al. Comparative genomics of Gossypium and Arabidopsis:Unraveling the consequences of both ancient and recent polyploidy [J]. Genome Research, 2005,15:1198-1210
349. Ruan YL,Llewellyn DJ, Furbank RT. The delayed initiation and slow elongation of fuzz-like short fibre cells in relation to altered patterns of sucrose synthase expression and plasmodesmata gating in a lintless mutant of cotton. Journal of Experimental Botany, 2005,56,(413): 977-984,
350. Saha S,Wu J, Jenkins JN,et al.Effect of Chromosome Substitutions from Gossypium barbadense L. 3-79 into G. hirsutum L. TM-1 on Agronomic and Fiber Traits [J]. The Journal of Cotton Science, 2004,8:162-169
351. SAS Institute (1989). SAS/STAT User's Guide Version 6[M], 4th edn. SAS Institute, Cary,NC, USA
352. Saunders JH. The wild species of Gossypium and their evolutionary history [M]. London,Oxford Univ. Press.1961
353. Schnabel A, Wendel JF. Cladistic Biogeography of Gleditsia (Leguminosae) based on ndhF and rpl16 chloroplast gene sequences [J]. American Journal of Botany, 1998, 85(12):1753-1765.
354. Seelanan T, Schnabel A,Wendel JF. Congruence and consensus in the cotton tribe (Malvaceae) [J]. Systematic Botany, 1997,22(2): 259-290
355. Senchina DS, Alvarez I, Cronn RC, et al. Rate variation among nuclear genes and the age of polyploidy in Gossypium [J]. Mol.Biol.Evol,2003, 20(4): 633-643
356. Shappley ZW, Jenkins JN, Watson CE Jr, et al. Establishment of molecular markers and linkage groups in two F2 population of Upland cotton [J]. Theor. Appl.Genet.,1996,92 :915-919
357. Shappley ZW, Jenkins JN, Meredith WR Jr, et al. An RFLP linkage map of Upland cotton,Gossypium hirsutum L [J]. Theor Appl Genet, 1998, 97: 756-761.
358. Shappley ZW, Jenkins JN, Zhu J, et al. Quantitative trait loci associated with agronomic and fiber traits of upland cotton [J]. J Cotton Science, 1998,2:153-163
359. Shen XL,Guo WZ, Zhu XF,et al. Molecular mapping of QTLs for fiber qualities in three diverse lines in Upland cotton using SSR markers. Molecular Breeding 2005,15:169-181
360. Shen XL,Guo WZ, Lu QX. Genetic mapping of quantitative trait loci for fiber quality and yield trait by RIL approach in Upland cotton. Euphytica, 2007,155:371-380
361. Shi YH, Zhu SW, Mao XZ, et al. Transcriptome Profiling, Molecular Biological, and Physiological Studies Reveal a Major Role for Ethylene in Cotton Fiber Cell Elongation. The Plant Cell, 2006,18, 651-664,
362. Silow RA. Genetics of species development in Old world cottons [J]. J. Genet., 1944,46,62
363. Skovsted A. Cytological studies in cotton IV: Chromosome configuration in interspecific hybrids [J]. J. Genet., 1937,34, 97-134
364. Skovsted A. Cytological studies in cotton. II. Two interspecific hybrids between Asiatic and new world cottons [J]. J. Genet., 1934,28,407-424
365. Small RL, Ryburn JA, Cronn RC, et al. The tortoise and the hare: Choosing between noncoding plastome and nuclear adh sequences for phylogeny reconstruction in a recently diverged plant group [J]. American Journal of Botany, 1998, 85(9): 1301-1315.
366. Small RL, Ryburn JA, Cronn RC, et al. Low Levels of Nucleotide Diversity at Homoeologous Adh Loci in Allotetraploid Cotton (Gossypium L.) [J]. Mol. Biol. Evol..1999, 16(4): 491-501.
367. Small RL, Wendel JF. The mitochondrial genome of allotetraploid cotton (Gossypium L.) [J].J Hered., 1S99, 90(1): 251-253.
368. Small RL, Wendel JF. Copy Number Lability and Evolutionary Dynamics of the Adh Gene Family in Diploid and Tetraploid Cotton (Gossypium) [J]. Genetics, 2000,155:1913-1926
369. Small RL, Wendel JF. Phylogeny, duplication, and intraspecific variation of Adh sequences in New World diploid cottons (Gossypium L., Malvaceae) [J]. Molecular Phylogenetics and Evolution, 2000,16(1): 73-84
370. Small RL, Wondel JF. Differential evolutionary dynamics of duplicated paralogous Adh loci in allotetraploid cotton (Gossypium) [J]. Mol. Biol. Evol., 2002,19(5):597-607
371. Small RL, Cronn RC, Wendel JF, et al. Review No. 2.Use of nuclear genes for phylogeny reconstruction in plants [J]. Australian Systematic Botany, 2004,17:145-170
372. Snowdon RJ, Friedt W. Molecular markers in Brassica oilseed breeding: current status and future possibilities [J]. Plant Breeding, 2004,123:1—8
373. Song Z, Li B., Chen J, et al. Genetic diversity and conservation of common wild rice (Oryza rufipogon) in China [J]. Plant Species Biology, 2005,20:83-92
374. Stanton MA, Stewart JMcD, Percival AE, et al. Morphological diversity and relationships in the A-genome cottons, Gossypium arboreum and G. herbaceum [J]. Crop Science, 1994,34(2): 519 -527
375. Stephens SG. The genetic organization of leaf-shape development in the genus Gossypium [J].J. Genet., 1944,46:28-51.
376. Stephens SG. Cytolgenetics of Gossypium and the problem of the origin of the New World cottons [J]. Adv. Genet., 1947,1:431-442
377. Stephens SG. Species differentiation in relation to crop improvement [J]. Crop Sci, 1961,1:1-5
378. Stephens SG. The potential for long range oceanic dispersal of cotton seeds [J]. Am. Nat.,1966,100:199-210.
379. Stephens SG, Phillips LL. The history and geographical distribution of a polymorphic system in new world cottons [J]. Biotropica, 1972,4: 49-60
380. Stewart JMcD, Hsu CL. Hybridization of diploid and tetraploid cottons through in-ovule embryo culture [J]. J Hered, 1978, 69:404-408
381. Stewart JMcD. In vitro fertilization and embryo rescue [J]. Environ Exp Bot, 1981, 21:301-315
382. Stewart JMcD, Craven LA, Wendel JF. A new Australian species of Gossypium [M].Proceeding of the Beltwide Cotton Conferences. 1997, National Cotton Council of America,emphis, TN. P448
383. Sun Y, Zhang X, Nie Y, et al. Production and characterization of somatic hybrids between upland cotton (Gossypium hirsutum) and wild cotton (G.klotzschianum Anderss) via electrofusion [J]. Theor Appl Genet, 2004,109:472-479
384. Sun Y, Zhang X, Nie Y, et al. Production of fertile somatic hybrids of Gossypium hirsutum + G. bickii and G. hirsutum + G. stockii via protoplast fusion [J]. Plant Cell, Tissue and Organ Culture, 2005,83: 303-310
385. Sun Y, Nie Y, Guo X, et al. Somatic hybrids between Gossypium hirsutum L. (4x) and G.davidsonii Kellog (2x) produced by protoplast fusion [J]. Euphytica, 2006,151:393-400
386. Tatineni V, Cantrell RG, Davis DD. Genetic diversity in elite cotton germplasm determined by morphological characteristics and RAPDs [J]. Crop Science, 1996,36(1):186-192
387. Tokumoto H, Kazuyuki W, Seiichiro K, et al. Changes in the sugar composition and molecular mass distribution of matrix polysaccharides during cotton fiber development [J].Plant & Cell Physiology; 2002,43 (4): 411-418
388. Ulloa M,Meredith WR Jr.Genetic linkage map and QTL analysis of agronomic and fiber quality traits in. and intraspecific population [J]. J Cotton Science, 2000,4:161-170
389. Valicek P. Wild and cultivated cottons [J]. Coton et Fibres Tropicales (English edition), 1978,33:363-387
390. Vander Wiel PL,Voytas DF, Wendel JF. Copia-like retrotransposable element evolution in diploid and polyploid cotton (Gossypium L.) [J]. J Mol Evol,1993,36(5): 429-47
391. Wang K,Song XL,Han ZG, et al.Complete assignment of the chromosomes of Gossypium hirsutum L.by translocation and fluorescence in situ hybridization mapping [J]. Theor Appl Genet, 2006,113:73-80
392. Wang S, Wang JW,Yu N, et al. Control of plant trichome development by a cotton fiber MYB gene [J]. The Plant Cell, 2004.16:2323-2334
393. Wang J, Xiang, FN, Xia GM, et al. Transfer of small chromosome fragments of Agropyron elongatum to wheat chromosome via asymmetric somatic hybridization [J]. Science in China Ser. C life Sciences, 2004,47(5): 434-441
394. Webber JM. Cytogenetic notes on cotton and cotton relatives [J]. Science, 1934, 80:268-269
395. Watt SG The wild and cultivated cotton plants of the world [J]. Longmans, London.1907
396. Wendel JF.New World tetraplold cottons contain Old World cytoplasm [J]. Proc.Natl.Acad.Sci.USA, 1989, 86: 4132-4136
397. Wendel JF. Olson PD, Stewart JMcD. Genetic diversity, introgression, and independent domestication of old world cultivated cottons [J]. American J Botany, 1989, 76(12):1795-1806
398. Wendel JF,Percy RG. Allozyme diversity and introgression in the Galapagos Islands endemic Gossypium darwinii and its relationship to continental G. barbadense [J].Biochemical Systematics and Ecology, 1990,18: 517-528
399. Wendel JF,Stewart JMcD, Rettig JH. Molecular evidence for homoploid reticulate evolution among Australian species of Gossypium [J]. Evolution, 1991.45:694- 711.
400. Wendel JF, Brubaker CL,Percival AE. Genetic diversity in Gossypium and the origin of upland cotton [J]. American J Botany, 1992,79(11): 1291-1310
401. Wendel JF, Albert VA. Phylogenetics of the cotton genus (Gossypium): Character-state weighted parsimony analysis of chloroplast-DNA restriction site data and its systematic and biogeographic implications [J]. Systematic Botany, 1992,17(1): 115-14
402. Wendel JF, Schnabel A, Seelanan T. Bidirectional interlocus concerted evolution following allopolyploid speciation in cotton (Gossypium) [J]. Proc. Natl.Acad. Sci. USA, 1995, 92:280-284
403. Wendel, JF. Genome evolution in polyploids [J]. Plant Molecular Biology, 2000, 42:225-249
404. Wendel JF, Cronn RC, Johnston JS, et al.Feast and famine in plant genomes [J]. Genetica,2002,115: 37-47
405. Wendel JF, Cronn RC. Polyploidy and the evolutionary history of cotton [J]. Advances in Agronomy, 2003,78:139-186
406. Wilkins T, Arpat A,Sickler B. Cotton fiber genomics: Developmental mechanisms.Pflanzenschutz- Nachrichten Bayer, 2005,58(1):119-139
407. Yang X, Zhang X, Jin S, et al. Production and characterization of asymmetric hybrids between upland cotton Coker 201 (Gossypium hirsutum) and wild cotton (G. klozschianum Anderss) [J]. Plant Cell Tiss Organ Cult, 2007,89:225-235
408. Yu J, Park Yong Ha, Lazo GR, et al. Mapping cotton genome with molecular markers [M].Proceedings Belt wide Cotton conferences, 1997, 1, 447. New Orleans, LA, USA, January 6-10
409. Zaitzev GS. A hybrid between Asiatic and American cotton plants-Gossypium herbaceum L.and Gossypium hirsutum L [M]. Bull. Appl.Bot. Plant Breed., 1923,13,117-13
410. Zhang J, Guo W, Zhang T. Molecular linkage map of allotetraploid cotton (Gossypium hirsutum L.× Gossypium barbadenseL.) with a haploid population [J]. Theor Appl Genet,2002,105:1166-1174
411. Zhang T, Yuan Y, Yu J, et al. Molecular tagging of a major QTL for fiber strength in Upland cotton and its marker-assisted selection [J]. Theor Appl Genet, 2003,106:262.268
412. Zhang Z, Xiao Y, Luo M,et al. Construction of a genetic linkage map and QTL analysis of fiber-related traits in upland cotton (Gossypium hirsutum L.). Euphytica, 2005,144: 91-99
413. ZhaoX,Si Y, Hanson RE, et al, Paterson AH. Dispersed repetitive DNA has spread to new genomes since polyploid formation in cotton [J]. Genome Research, 1998,8:479-492
414. Zhao X,Ji Y, Ding X,et al. Macromolecular organization and genetic mapping of a rapidly evolving chromosome-specific tandem repeat family (B77) in cotton (Gossypium) [J]. Plant Molecular Biology, 1998,38:1031-1042
415. Zhu SJ, Reddy N, Jiang YR. Introgression of a gene for delayed pigment gland morphogenesis from Gossypium bickii into upland cotton [J]. Plant Breeding, 2005,124:590-594
416. Zuo KJ, Sun JZ, Zhang JF, et al. Genetic diversity evaluation of some Chinese elite cotton varieties with RAPD markers [J]. Acata Genetica Sinica, 2000,27(9): 817-823
2.别墅,孔繁玲,周有耀,等.中国3大主产棉区棉花品种遗传多样性的RAPD及其与农艺性状关系的研究[J].冲国农业科学2001,34(6):597-603
3.别墅,王坤波,王春英,等.二倍体栽培棉45S rDNA-FISH作图及核型比较[J].棉花学报,2004,16(4):223-228
4.陈国平,周宝良,沈新莲,等.不同强度棉纤维超微结构差异及其与比强度和马克隆值关系[J].纤维标准与检验,1997,(6)(总第192期):21-24
5.陈国平,沈新莲,周宝良,等.高强纤维棉花种质系的纤维品质初析[J].江苏农业科学,1996,(1),(总第89期):25-27
6.陈国平,沈新莲,周宝良,等.具有野生种质的棉花高品质品系与常规品种纤维品质差异分析[J].江西棉花,1996,(2)(总第64期):8-10
7.陈松,应苗成,彭跃进,黄骏麒,钱思颖,徐英俊.棉属CGossypium)种子蛋白质电泳图谱与种间关系[J].江苏农业学报,1990,6(1):17-23
8.陈卫国,郝林,渠云芳,等.棉花[AGD]三种杂种核型分析[J].山西农业科学,2004,32(2):41-45
9.陈仲方,张治伟,承泓良.陆地棉品种棉籽品质分析研究[J].作物学报,1986,12:195-200
10.崔荣霞,胡绍安,王春英.陆地棉×斯特提棉F1及BC1遗传学研究[J].中国棉花,1995,22(12):7-8
11.丁亮,祝水金,胡丹艳,等.比克氏棉和司笃克氏棉色素腺体形态建成的组织结构观察[J].棉花学报,2003,15(1):17-21
12.丁亮,祝水金,胡丹艳,等.司笃克氏棉(G stockii)色素腺体的形态建成与棉酚动态研究[J].作物学报,2004,30(2):100-103,
13.丁世萍,武萍生,彭锁堂.((亚洲棉×比克氏棉)F1双二倍体×海岛棉)F1茸毛性状研究[J].山西农业大学学报,1998,18(2):99-101
14.丁世萍,李炳林,张伯静,等.(亚洲棉×比克氏棉)F1 双二倍体与海岛棉的种间杂种F1的形态学和细胞学研究[J].浙江农业大学学报,1999,25(1):31-35
15.杜雄明,汪若海,刘国强,等.棉花纤维相关性状的主基因-多基因混合遗传分析[J].棉花学报,1999,11(2):73-78.
16.董俊梅,段永红.棉属异源四倍体杂种性状研究[J].山西农业大学学报,2003,23(1):1-6
17.杜珉.世界棉花生产与市场贸易[J].国际农业,2006,(3):32-36
18.段永红,崔俊梅.三元杂种回交后代性状遗传学研究[J].山西农业大学学报,2003,23(1): 15-19
19.范玲.新疆棉花栽培种遗传多样性研究[硕士论文].新疆乌鲁木齐:新疆农业大学,2004
20.冯泽芳.冯泽芳先生论文选集[M].中国棉业出版社,1948
21.盖钧镒,章元明,王建康.Q T L混合遗传模型扩展至2对主基因+多基因时的多世代联合分析[J].作物学报,2000,26(4):385-391.
22.盖钧镒,王建康.大豆对豆秆黑潜蝇抗性的主基因+多基因遗传[M].全国作物育种学术讨论会论文集,北京:中国农业科技出版社,1998,241-248.
23.高国强,朱斗北,苏学合,等.四倍体与二倍体棉花远缘杂交后代同工酶电泳分析[J].核农学报,1997,11(2):79-83
24.高峰.世界棉花生产与进出口贸易概览[J].中国棉花,2006,33(7):7-9
25.高燕会,祝水金,季道藩.四种栽培棉合成的四元杂种F1细胞遗传学研究[J].棉花学报,2003,15(5):259-263
26.高燕会,祝水金,季道藩.四个栽培棉种间的杂种F1细胞遗传学与亲缘关系研究[J].遗传学报,2005,32(7):744-752
27.高燕会.四个栽培棉种间的种间杂交及其遗传与系统发育研究[博士论文].浙江杭州:浙江大学,2004
28.刘三宏.四倍体棉种起源与演化的FISH研究[硕士论文].北京:中国农业科学院,2004
29.高玉千,聂以春,张献龙.棉花抗黄萎病基因的QTL定位[J].棉花学报,2003,15(2):73-78
30.郭江勇,王义琴,吴明刚,等.利用RAPD标记对彩色棉遗传多样性的分析[J].棉花学报,2003,15(5):269-273
31.郭江勇,王义琴,吴明刚,等.棕色棉和绿色棉遗传多样性的比较研究[J].遗传,2004,26(1):63-68
32.龚云程,李德华,杨民权,等.棉花×泡桐远缘杂交初探[J].湖北农业科学,2001,(4):25-28
33.郭江勇,王义琴,吴明刚,等.利用RAPD标记对彩色棉遗传多样性的分析[J].棉花学报,2003,15(5):269-273
34.郭江勇,王义琴,吴明刚,等.棕色棉和绿色棉遗传多样性的比较研究[J].遗传,26(1):63-68,2004
35.郭旺珍,彭锁堂.陆地棉与毛棉杂种性状遗传学和细胞学研究[J].棉花学报,1997,9(1),21-24
36.郭旺珍,孙敬,张天真,棉花纤维品质的基因克隆与分子育种[J].科学通报,2003,48(5):410-417
37.韩祥铭,刘英欣,宋宪亮.陆地棉新种质纤维品质性状的遗传分析[J].作物学报,2002,28(2):245-248.
38.郝林,宋国立,李炳林,等.亚比棉基因组原位杂交及核型分析[J].遗传学 报,2006,33(6):572-579
39.何鉴星,梁正兰.中棉×戴维逊氏棉胚胎发育的研究[J].遗传学报,1989,16(4):256-262
40.何鉴星,姜茹琴,张欣雪,等.陆地棉×索马里棉异源六倍体杂种的细胞学和纤维特性[J].科学通报,2000,45(16):1742-1747
41.何鉴星,孙传渭.向陆地棉渐渗野生比克氏棉腺体延缓形成基因的方法研究[J].遗传学报,1994,21(1):52-58
42.胡丹艳,祝水金.(亚洲棉×比克氏棉)F1双二倍体不育系的花粉败育机理研究[J].棉花学报,2002,14(6):330-335
43.胡建斌.三元杂种[A2A2 G1 G1]×[A2×(AD)1]的形态及核型分析[J].山西农业大学学报,2005,25(3):217-219
44.胡绍安,李秀兰.棉属二倍体野生棉与四倍体栽培棉种间杂交的胚珠培养[J].遗传学报,1982,9(1):57-62
45.胡绍安,崔荣霞,王春英,等.陆地棉野生种系的利用研究[J].棉花学报,1994,6(增刊):15-18
46.华金平,张成,易先达,等.棉花远缘核质杂种的培育与育种应用[J].湖北农业科学,2003,14:25-28
47.姜保功,孔繁玲,张群远,等.2000建国以来我国黄淮棉区棉花品种的遗传改良.Ⅱ.纤维品质性状的改良[J].作物学报,2000,26(5):528-535
48.姜茹琴,苗春生,潘河山,等.棉花种间杂交抗棉铃虫资源选育[J].棉花学报,1999,11(6):306-311
49.姜茹琴,梁正兰,钟文南,等.陆地棉×索马里棉(G.somalense)杂种的研究和利用[J].科学通报,1996,41(1):60-64
50.李炳林.亚洲棉与比克氏棉杂交研究简报[J].中国棉花,1982(4):15-16
51.李炳林,李宏运,安泽伟,等.棉花染色体工程育种[J].山西农业大学学报,2001,21(1):1-6
52.李炳林,武晶,李欣,等.[AAGG]异源四倍体新棉种的核型及同功酶分析[J].植物遗传资源学报,2003,4(3):195-198
53.李成奇,黄晋玲,渠云芳,等.棉花四元杂种F1的形态性状遗传及不育性研究[J].山西农业大学学报,2004,24(4):369-382
54.李俊兰,崔淑芳,韩泽林.远缘杂交创造棉花优异种质的研究初报[J].河北农业科学,2003,7(增刊):150-151
55.李志坤.低酚棉遗传资源基于农艺性状、SSR、AFLP的遗传多样性[硕士论文].河北保定:河北农业大学,2005
56.梁理民,王增信,刘有良,等.棉花种间杂交新品系及新种质的育成[J].西北农林科技大学学报(自然科学版)2003,31(5):9-12
57.梁理民,刘有良,王增信,等.陆地棉×斯特提棉种间杂交创造抗枯黄萎病新种质[J].西北农业学报,2002,11(4):16-18
58.梁理民,刘有良,王增信,等.棉花种间杂交新品种秦远4号的选育[J].西北农业学报,2000,9(4):10-13
59.梁正兰,孙传渭,刘棣良,等.克服种间不亲和性的试验效果[J].遗传学报,1978,5(3):171-181
60.梁正兰,孙传渭.棉花远缘杂交[M].科学出版社,1982,北京
61.梁正兰,姜茹琴,钟文南.陆地棉.野生比克氏棉杂种红花种质系的育成[J].中国科学(C辑),1996,26(4):369-376
62.梁正兰,姜茹琴,钟文南,等.三元杂种(海岛棉-瑟伯氏棉-陆地棉)的研究及新品种选育[J].作物学报,1996,22(6):673-680
63.梁正兰,姜茹琴,钟文南,等.棉花种间杂交技术创新及育种程序的建立[J].中国科学(C辑),2001,31(2):120-124
64.林忠旭,张献龙,聂以春.新型标记SRAP在棉花F2分离群体及遗传多样性评价中的适用性分析[J].遗传学报,2004,31(6):622-626
65.刘根齐,焦传珍,姜茹琴,等用同工酶和RAPD技术研究棉花三元杂种石远321新品种的遗传特性[J].遗传学报,2000a,27(11):999-1005
66.刘根齐,焦传珍,姜茹琴,等.陆地棉×比克氏棉育成种质系的同工酶和RAPD分析[J].遗传学报,2000b,27(12):1094-1099
67.刘金兰,聂以春.植物激素对棉属(Gossypium)远缘杂种胚囊发育的影响[J].华中农业大学学报,1990,9(3),211-216
68.刘金兰,徐珍秀,聂以春.棉花胚囊超微结构的观察[J].棉花学报,1992,4(1):9-12
69.刘金兰,聂以春.4倍体(亚×司)F1×陆杂种后代花粉和胚囊发育研究[J].棉花学报,1997,9(3):120-125
70.刘文欣,孔繁玲,郭志丽,等,杨付新.建国以来我国棉花品种遗传基础的分子标记分析[J].遗传学报,2003,30(6):560-570
71.刘耀斌,景忆莲,范万法,等.哈克尼西棉细胞质对陆地棉主要经济性状的影响[J].西北农业学报,1996,5(3):49-53
72.聂汝芝,李懋学.棉属植物核型研究[M].科学出版社,北京,1993
73.聂以春,刘金兰.棉属异源四倍体(亚洲棉×司笃克氏棉)的植物形态及农艺性状研究[J].华中农业大学学报,1995,14(4):333-338
74.聂以春,刘金兰,张献龙.人工合成的棉属异源四倍体(亚洲棉×司笃克氏棉)种质的胚胎发育.华中农业大学学报,1997,16(6):533-537
75.聂以春,刘金兰,张献龙.新合成的棉花遗传资源-异源四倍体(亚洲棉×司笃克氏棉)初报[J].作物品种资源1999,(3):22
76.聂以春,左开井,张献龙,等。RAPD标记在棉属种间杂种后代检测中的应用[J].中国农业科学,2000a,33(5):1-7
77.聂以春,左开井,张献龙,等.RAPD标记分析棉花种间杂种后代的遗传相似性[J].华中农业大学学报,2000b,19(6),:523-527聂汝芝,李懋学.二倍体野生棉的核型变异与进化[J].植物学报,1989,31(3):178-184
78.潘玉欣.转基因抗虫棉品种DNA指纹图谱建立和遗传多样性评价[硕士论文].河北保定:河北农业大学,2005
79.庞朝友.棉花种间杂交种质创新效果及其遗传多样性研究[博士论文].河北保定:河北农业大学,2005
80.庞朝友,杜雄明,马峙英.棉花种间杂交渐渗系创新效果评价及特异种质筛选[J].科学通报,2006,51(1):55-62
81.彭跃进,钱思颢.陆地棉与雷蒙德氏棉种间杂种后代的胚胎学观察[J].作物学报,1989,15(3),243-252
82.戚存扣,盖钧镒,章元明.甘蓝型油菜芥酸含量的主基因+多基因遗传[J].遗传学报,2001,28(2):182-187
83.钱思颖,周行。陆地棉与中棉种间杂交的研究及其在育种上的就用[J].作物学报,1963,2(1):29-45
84.钱思颖,黄骏麒,洪爱华,徐英俊.棉属酯酶同工酶的分析[J].江苏农业学报,1985,4:15-20
85.钱思颖,黄骏麒,刘桂花玲等.棉属种间杂交研究.作物学报,1988,14(2):96-102
86.钱思颖,黄骏麒,彭跃进,等.陆地棉与异常棉(Ganomalum)种间杂种的研究及其在育种上的应用[J].中国农业科学,1992a,25(6):44-51
87.钱思颖,黄骏麒,彭跃进,等.棉花高纤维品质新种质培育研究初报[J].江苏农业科学,1992b,(3)(总第69期):19-20
88.钱思颖,周宝良,黄骏麒,等.陆地棉86-1与辣根棉(G.armourianum Keam)种间杂种及其利用的研究[J].作物学报,1995,21(5):592-597
89.钱思颖,黄骏麒,周宝良,等.陆地棉与克劳茨基棉(G klotzschianum Anderss)的研究和利用[J].江苏农业学报,1996,12(4):18-22
90.钱思颖,黄骏麒,周宝良,等.陆地棉与旱地棉、裂片棉、松散棉、特尼氏棉种间杂种F1的形态和细胞学研究[J].江苏农业学报,1996,12(3):10-14
91.冉鸿昌,肖炎农,姜道宏,等.湖北省棉花黄萎病菌致病力分化和遗传多样性分析[J].华中农业大学学报,2005,24(5):,442-447
92.时香玉,高国强,苏学合,等.胚珠培养技术在棉花远源杂交中的应用[J].山东农业科学,1999,(3):5-9
93.宋国立,崔荣霞,王坤波,等.澳洲棉种遗传多样性的RAPD分析[J].棉花学 报,1999,11(2):65-69
94.宋建中,姜艳丽,李江辉,等.棉花远缘杂交选育特早熟新品种的研究[J].中国棉花2001,28(6):9-11
95.宋宪亮,孙学振,张天真,等.棉花遗传多态性研究进展[J].西北植物学报,2004,24(12):2393-2397
96.沈新莲,周宝良,吴敬音,等.棉属野生种稀毛棉、皱壳棉、杨叶棉的核型研究[J].棉花学报,1997,9(4):217-221
97.沈新莲,袁有禄,郭旺珍,朱协飞,张天真.棉花高强纤维主效QTL的遗传稳定性及它的分子标记辅助选择效果[J].高技术通讯,2001,10,13-16
98.眭书祥.棉花抗黄萎病育种研究初报[J].中国棉花,1995,22(6):12-13.
99.孙黛珍,王曙光,李淑芳,等.HAG三种杂种回交后代腺体性状及形态特征遗传的研究[J].山西农业大学学报,1999,19(1):19-22
100.孙黛珍,崔克俭,李炳林,等.(棉花[(亚×比)×(陆×褐)]种间杂种的研究[J].西农业科学2000,28(2):3-6
101.孙黛珍,李炳林,王曙光,等.三元杂种及回交后代的遗传性状和细胞学研究[J].棉花学报,2000,12(2):57-61
102.孙黛珍,高培芳,王曙光,等.棉花四元杂种F1不育性的研究[J].西北农业大学学报,2000,28(2):103-107
103.孙黛珍,王曙光,李炳林.棉花四元杂种[(亚×比)×(陆×夏)]F1的性状遗传及细胞学研究[J].山西农业科学2001,29(1):23-26
104.孙黛珍,王曙光,李炳林.陆地棉、亚洲棉与比克氏棉杂种F1及回交后代的育性研究[J].华北农学报2001,16(1):38-43
105.孙黛珍,王曙光,董俊梅.棉属三染色体组(A、D、G)杂种的细胞遗传学研究[J].棉花学报,2001,13(4):204-208
106.孙东磊.彩色棉纤维色泽遗传及多样性分析[硕士论文].河北保定:河北农业大学,2006
107.孙济中,刘金兰,万年青,等.亚洲棉同源四倍体与陆地棉杂交和回交后代育性遗传的研究[J].遗传学报,1981,8(2):149-157
108.童旭宏,祝水金,季道藩.陆地棉子叶色素腺体延缓形成性状的表现与组织结构观察[J].棉花学报,2005,17(3):137-140
109.徐秋华,张献龙,聂以春.长江、黄河流域两棉区陆地棉品种的遗传多样性比较研究[J].遗传学报,2001,28(7):683-690
110.徐秋华,张献龙,冯纯大,等.河北省和中棉所育成陆地棉品种的遗传多样性分析[J].棉花学报,2001,13(4):238-242
111.徐秋华,张献龙,聂以春,等.我国棉花抗枯萎病品种的遗传多样性分析[J].中国农业科 学:2002,35(3):272-276
112.王坤波,李懋学,张香娣,等.陆地棉与7个野生棉杂种细胞学研究[J].作物学报,1996,22(1):27-35
113.万黎明,彭锁堂.棉花三种杂种色素腺体性状的研究[J].山西农业大学学报,1998,18(2):102-104
114.王朝生,柴友荣,董顺文,等.川棉109多质源育种的实践[J].西南农业学报,1998,11:235-241
115.王春英,王坤波,王文奎,等.棉花gDNA体细胞染色体FISH技术[J].棉花学报,1999,11(2):79-83
116.王春英,王坤波,宋国立,等.棉花体细胞染色体rDNA-FISH技术[J].棉花学报,2001,13(2):75-77
117.王凯.异源四倍体棉花遗传图谱的构建与分子细胞遗传学研究[博士论文].江苏南京:南京农业大学,2006
118.王坤波,李懋学.棉属D染色体组的核型变异和进化[J].作物学报,1991,16(3):200-207
119.王坤波,王文奎,王春英,等.海岛棉原位杂交及核型比较[J].遗传学报,2001,28(1):69-75
120.王建康,盖钧镒.利用杂种F2世代鉴定数量性状主基因-多基因混合遗传模型并估计其遗传效应[J].遗传学报,1997,24(5):432-440.
121.王建康,盖钧镒.利用回交或F2:3世代鉴定主基因和多基因的混合遗传模型[J].作物学报,1998a,24(4):402-409.
122.王建康,盖钧镒.数量性状主基因.多基因混合遗传的P1、P2、F1、F2和F2:3的联合分析方法[J].作物学报,1998b,24(6):651-659.
123.王建设,王建康,朱立宏,等.水稻主基因-多基因混合遗传控制白叶枯病抗性的基因效应分析[J].遗传学报,2000,27(1):34-38.
124.王立平,王坤波,简桂良,等.“九五”与“八五”我国自育棉花品种纤维品质比较分析[J].棉花学报,2003,15(4):231-234
125.王省芬,张桂寅,李喜焕,等.黄河、长江流域棉区棉花抗病品种的AFLP分析[J].遗传学报,2004,31(12):1426-1433
126.王省芬,马峙英,张桂寅,等.我国棉花抗枯、黄萎病骨干品种(系)基于AFLP的遗传多样性[J].棉花学报,2005,17(1):23-28
127.王省芬,马峙英,潘玉欣,等.转基因抗虫棉SSR和AFLP遗传变异研究[J].植物遗传资源学报,2006,7(2):153-158
128.王志龙,孙传渭,张欣雪,等.棉属种间高代系的过氧化物酶同工酶研究[J].植物学报,1995,37(6):465-470
129.王志宁,季道藩,许馥华.栽培棉种间多棉种杂种的形态学和细胞遗传学研究[J].浙江农业 大学,1996,22(2):127-136
130.王志宁,季道藩,许复华.栽培棉种间二、三、四元杂种的研究.Ⅰ.杂种F1的产生及其形态特性[J].浙江农业大学学报,1990,16(4):363-368
131.王志忠,王兆晓,崔瑞敏.棉花种间杂交新品种冀棉25号的选育[J].华北农学报,1999,14(增刊):28-34
132.魏守军,袁有禄,陆作楣.1973-2000年黄河流域棉花品种改良与应用状况分析[J].棉花学报,2003,15(6):367-371
133.韦贞国,刘素纹,舒金树.陆地棉远缘异质系培育研究初报[J].湖北农业科学,1982(10):11-13
134.韦贞国,李宗友,易先达,等.哈克尼西棉雄性不育胞质的遗传效应[J].棉花学报,1995,7(2):76-81
135.武晶,段永红,郭志爱,等.棉花三种杂种色素腺体密度空间分布的研究[J].山西农业大学学报,2005,25(1):58-63
136.吴玉香,孙玉强,陈崇乾,等.利用RAPD检测棉属种间亲缘关系的研究[J].作物学报,2007,33(6):909-913
137.杨伟华,项时康,唐淑荣,等.20年来我国自育棉花品种纤维品质分析[J]。棉花学报,2001,13(6):377-384
138.殷剑美,武耀廷,朱协飞,等.陆地棉产量与品质性状的主基因与多基因遗传分析[J].棉花学报 2003,15(2):67-72
139.于霁雯,喻树迅,王武,等.应用RAID对短季棉品种遗传多样性的初步评价[J].棉花学报,2006,18(3):186-189
140.袁有禄.棉花优质纤维特性的遗传及分子标记研究[博士论文].南京:南京农业大学
141.袁有禄,张天真,郭旺珍,等.棉花高品质纤维性状的主基因与多基因遗传分析[J].遗传学报,2002,29(9):827-834
142.袁有禄,张天真,郭旺珍,等.棉花高品质纤维性状QTLs的分子标记筛选及其定位[J].遗传学报,2001,28(12):1151-1161
143.詹秋文,盖钧镒,章元明,等.大豆对斜纹夜蛾幼虫抗性遗传的发展表达过程[J].遗传学报,2001,28(10):956-963.
144.张凤银,孙济中,刘金兰,等.棉属(Gossypium)种间杂种一代雌配子体发育过程[J].湖北农业科学,1998,(4):3-7
145.张凤银,孙济中,刘金兰,等.棉属(Gossypium)种间杂种F1形态特征与细胞遗传学研究[J].江汉大学学报,1998,15(6):97-101
146.张正圣,李先碧,刘大军,等.陆地棉高品质系的杂种优势利用研究[J].棉花学报,2002,14(5):264-268.
147.赵国忠,冯恒文,李爱国,等.棉属8个野生种2个二倍体栽培种对陆地棉的改良效应[J].华北农学报,1994,9(4):44-48.
148.周宝良,彭跃进,黄骏麒,等.海岛棉与旱地棉、雷蒙德氏棉和拟似棉的F1杂种细胞学观察[J].江苏农业学报,1991,7(2):15-21。
149.周宝良,黄骏麒,彭跃进,等.二倍体棉种间杂种F1的形态和细胞学[J].江苏农业学报,1992,8(1):19-24
150.周宝良,钱思颖,黄骏麒,等.江苏引进及利用棉属野生种研究.作物品种资源[J],1993a(增刊):149-151
151.周宝良,彭跃进,黄骏麒,等.海岛棉与瑟伯氏棉、辣根棉、裂片棉、松散棉的杂种F1细胞学研究[J].浙江农业大学学报,1993b,19(1):24-29
152.周宝良,黄骏麒,彭跃进,等.中棉与纳尔逊氏棉(Gnelsonii Fryx.)种间杂种F1的研究[J].作物学报,1994a,20(2):217-222
153.周宝良,钱思颖.棉属野生种在棉花育种上的利用研究新进展[J].江苏农业科学,1994b,(4)(总第80期):25-28
154.周宝良,黄骏麒,沈新莲,等.海岛棉与澳洲棉、黄褐棉种间杂种F1的细胞学研究[J].棉花学报,1995a,7(4):209-212
155.周宝良,陈松,沈新莲,等.棉属(Gossypium ssp.)种子SOD酶的凝胶电泳图谱与种间关系[J].江苏农业学报,1995b,11(1):11-15
156.周宝良,彭跃进,沈新莲,等.陆地棉与三裂棉、斯特提棉和A111种间杂种F1的形态与细胞学[J].作物学报,1996a,22(1):84-88
157.周宝良,沈新莲,陈国平,等.异常棉和陆地棉渐渗杂交种质的高强纤维特性及超分子结构相关分析[J].江苏农业学报,1996b,12(4):23-29
158.周宝良,沈新莲,陈国平,等.含异常棉基因棉纤维品质及超分子结构遗传效应[J].棉花学报,1996c,8(4):193-198
159.周宝良,陈松.沈新莲,等.陆地棉高品质纤维种质基因库的拓建[J].作物学报,2003a,29(4):514-519
160.周宝良,沈新莲,陈松,等.利用三个野生棉种进行陆地棉纤维品质改良的效应比较[J].棉花学报,2003b,15(1):22-25
161.周有耀.棉花数量性状遗传.中国棉花遗传育种学(黄滋康主编)[M].山东济南:山东科学技术出版社,2003,68-94.
162.周仲华,何鉴星,陈金湘.陆×索棉异附加单体系的形态学及细胞学鉴定[J].湖南农业大学学报(自然科学版),2004,30(4):316-318
163.周仲华,余萍,刘光辉,等.索马里棉异源单体附加系的形态及分子特征研究[J].科学通报,2004,49(5):558-562
164.周曙霞,刘文国,程鲁军,等.哈克尼西棉细胞质对陆海种间杂种优势的影响[J].中国棉花,2003,30(4):8-10
165.邹美娟.四倍体栽培棉、二倍体野生棉减数分裂的FISH研究[硕士论文].北京:中国农业科学院,2002
166.朱龙付,张献龙,聂以春,等.转基因抗虫棉品种(系)的遗传多样性初步研究[J].华中农业大学学报,2002,21(5):401-405
167.朱龙付.棉花遗传多样性研究及抗黄萎病相关基因的克隆与分析[博士论文].湖北武汉:华中农业大学,2004
168.朱四元,陈金湘,刘爱玉,等.利用SSR标记对不同类型抗虫棉品种的遗传多样性分析[J].湖南农业大学学报(自然科学版),2006,32(5):469-472
169.朱四元,陈金湘,刘海荷,等.不同类型抗虫棉品种基于RAPD的遗传多样性分析[J].棉花学报,2007,19(2):83-87
170.祝水金,王红梅,吴汉北,等.有酚与低酚陆地棉亲本配制的种间三元杂种腺体遗传性状研究[J].棉花学报,1994,6(增刊):19-24
171.祝水金,李炳林,汪若海,等.亚洲棉、比克氏棉和海岛棉种间杂种的合成及性状研究[J].棉花学报,1995,7(3):160-163
172.祝水金,季道藩,汪若海,等.5个澳洲野生棉种植株形态性状与叶片过氧化物同工酶谱研究[J].西北植物学报,1997,17(4):433-438
173.祝水金,季道藩,汪若海,等.五个澳洲野生棉种色素腺体和棉酚性状研究[J].棉花学报,1997,9(2):84-89
174.祝水金,季道藩,汪若海,等.5个澳洲野生棉种植株形态性状与叶片过氧化物同工酶谱研究[J].西北植物学报,1997;17(4):433-438
175.祝水金,季道藩,汪若海,等.澳洲野生棉种的子叶棉酚动态及与色素腺体形态的关系[J].棉花学报,1999,11(4):169-173
176.祝水金,季道藩,汪若海,等.陆地棉不同色素腺体基因对比克氏棉子叶色素腺体延缓形成性状的遗传效应[J].作物学报,1999,25(5):585-590
177.祝水金,季道藩,汪若海,等.陆地棉与斯特提棉的种间杂种及其色素腺体性状的遗传[J].遗传学报,1999,26(4):403-409
178.祝水金,季道藩.澳洲野生棉种子叶色素腺体延缓形成性状的遗传研究[J].科学通报,2001,48(2):132-137
179.祝水金,蒋玉蓉,Reddy N,等.陆地棉子叶色素腺体延缓形成种质系的育成及其遗传研究[J].科学通报,2004,49(19):1987-1992
180.朱四元,陈金湘,刘爱玉,等.利用SSR标记对不同类型抗虫棉品种的遗传多样性分析[J].湖南农业大学学报(自然科学版),2006,32(5):469-472
181.朱四元,陈金湘,刘海荷,等.不同类型抗虫棉品种基于RAPD的遗传多样性分析[J].棉花学报,2007,19(2):83-87
182.左开井,孙济中,张金发,等用RAPD标记评估我国棉花品种遗传多样性[J].遗传学报,2000,27(9):817-823
183. Abdalla AM,Reddy OUK,E1-Zik KM, et al.Genetic diversity and relationships of diploid and tetraploid cottons revealed using AFLP [J]. Theor Appl Genet, 2001,102:222-229
184. Abraham P.Cytological studies in Gossypium.I:Chromosome behaviour in interspecific hybrid G.arboreun×G. stocksii[J]. India J. Agric.Sci.,1940,10:285-298
185. Adams KL,Wendel JF.Exploring the genomic mysteries of polyploidy in cotton [J].Biological Journal of the Linnean Society, 2004, 82: 573-581
186. Adams KL,Cronn R, Percifield R, et al. Genes duplicated by polyploidy show unequal contributions to the transcriptome and organ-specific reciprocal silencing [J]. PNAS, 2003,100 (8): 4649-4654
187. Adams KL,Percifield R, Wendel JF. Organ-Specific Silencing of Duplicated Genes in a Newly Synthesized Cotton Allotetraploid [J]. Genetics, 2004,168:2217-2226
188. Adams KL,Percifield R, Wendel JF. Allele-specific, sidirectional silencing of an alcohol dehydrogenase gene in different organs of interspecific diploid cotton hybrids [J]. Genetics,2005,171:2139-2142
189. Adams KL,Percifield R, Wendel JF. Novel patterns of gene expression in polyploid plants [J]. TRENDS in Genetics, 2005,21(10): 539-543
190. Adams KL,Psrcifield R, Wendel JF. Polyploidy and genome evolution in plants [J]. Current Opinion in Plant Biology 2005, 8:135-141
191. Ahoton L,Lacape JM, Baudoin JP, et al. Introduction of Australian diploid cotton genetic variation into upland cotton [J]. Crop Science, 2003,43,6:1999-2005
192. Applequist WL,Cronn R,Wendel JF. Comparative development of fiber in wild and cultivated cotton [J]. Evolution & Development, 2001,3(1): 3-17
193. Altaf MK,Stewart JM,Wajahatullah MK et al. Molecular and morphological genetics F2 population of cotton [M]. Proceedings Belt wide Cotton Coferences, 1997, l:448-452.New Orleans, LA, USA, January6-10
194. Altaf MK,Cantrell RG,Zhang J et al. Segregation patterns of molecular, morphological and quantitative traits in a trispecies F2 cotton population [M]. Special Report Agricultural Experiment Station, Division of Agricultural, University of Arkansas, 1997,183:147-1498
195. Alrman DW, Stelly DM, Kohel RJ.Introgression of the glanded-plant and glandless-seed trait from Gossypium sturtianum Willis into cultivated upland cotton using ovule culture [J]. Crop Sci, 1987,27:880-884
196. Alvarez I, Wendel JF. Ribosomal ITS sequences and plant phylogenetic inference [J].Molecular Phylogenetics and Evolution, 2003,29: 417-434
197. Alvarez I, Cronn R, Wendel JF. Phytogeny of the New World diploid cottons (Gossypium L.,Malvaceae) based on sequences of three low-copy nuclear genes [J]. PL Syst. Evol. , 2005,252:199-214
198. Alvarez I, Wendel JF. Cryptic interspecific introgression and genetic differentiation within Gossypium aridum (Malvaceae) and its relatives [J]. Evolution, 2006,60(3): 505-517
199. Amin KC.Interspecific hybridization between Asiatic and New World cottons [J].Ind J Agr Sci, 1940,10:404-413
200. An CF, Saha S, Jenkins JN et al.Transcriptome proWling, sequence characterization, and SNP-based chromosomal assignment of the EXPANSIN genes in cotton. Mol Genet Genomics, 2007, 278:539-553
201. Arpat AB, Waugh M, Sullivan JP et al. Functional genomics of cell elongation in developing cotton Wbers. Plant Mol Biol,2004,54:911-929
202. Beasley JO. The production of polyploids in Gossypium [J]. J. Hered., 1940a, 31, 39-48
203. Beasley JO. The origin of the American tetraploid species[J]. Amer.Nat., 1940b, 74,285-286
204. Beasley JO.Hybridization of Amer.can 26-chromosome and Asiatic 13-chromosome species of Gossypium[J]. J. Agr. Res., 1940c, 60,175-181
205. Beasley JO. Meiotic chromosome behaviour in species, species hybrids, haploids, and induced polyploids of Gossypium [J]. Genetics, 1942,27,25-54
206. Becerra Lopea-Lavalle LA, Brubaker CL. Frequency and fidelity of alien chromosome transmission in Gossypium hexaploid bridging populations [J]. Genome, 2007a, 50: 479-491
207. Becerra Lopea-Lavalle LA, Brubaker CL. The effect of Gossypium C-genome chromosomes on resistance to fusarium wilt in allotetraploid cotton [J]. Theor Appl Genet, 2007b,DOI 10.1007/s00122-007-0581-6
208. Bergey DR, Stelly DM, Price HJ. In situ hybridization of biotinylated DNA probes to cotton meiotic chromosomes [J]. Stain Technol, 1989, 64, 25-37
209. Bi VI, Baudoin JP, Mergeai G. Cytogenetics of the 'glandless-seed and glanded-plant' trait from Gossypium sturtianum Willis introgressed into upland cotton (Gossypium hirsutum L.) [J]. Plant Breed, 1998,117:235-241
210. Bi VI, Baudoin JP, Hau B, et al. Development of high-gossypol cotton plants with low-gossypol seeds using trispecies bridge crosses and in vitro culture of seed embryos [J]. Euphytica, 1999,106:243-251
211. Bi VI, Maquet A, Baudoin JP, et al. Breeding for "low-gossypol seed and high-gossypol plants"in upland cotton. Analysis of tri-species hybrids and backcross progenies using AFLPs and mapped RFLPs [J]. Theor Appl Genet, 1999,99:1233-1244
212. Bowman DT, May OL, Calhoun, DS. Genetic base of upland cotton cultivars released between 1970 and 1990[J]. Crop Science, 1996,36(3): 577-581
213. Bowman DT. Public cotton breeders—Do we need them? [J] J Cotton Science, 1999, 3:139-152
214. Bowman DT.and Gutierrez OA. Sources of fiber strength in the U.S. Upland cotton crop from 1980 to 2000[J]. The Journal of Cotton Science 2003,7:164-169
215. Bowman DT, May OL, Creech JB. Genetic uniformity of the U.S. upland cotton crop since the introduction of transgenic cottons [J]. Crop Science, 2003,43(2): 515-518
216. Brubaker CL, Wendel JF. Reevaluating the origin of domesticated cotton (Gossypium hirsutum, Malvaceae) using nuclear restriction fragment length polymorphisms (RFLPs) [J].American Journal of Botany, 1994,81(10): 1309-1326.
217. Brubaker CL, Brown AHD, Stewart JMcD, et al. Production of fertile hybrid germplasm with diploid Australian Gossypium species for cotton improvement [J]. Euphytica 1999,108:199-213,
218. Brubaker CL, Brown AHD. The use of multiple alien chromosome addition aneuploids facilitates genetic linkage mapping of the Gossypium G genome [J]. Genome, 2003, 46, (5):774-791
219. Brubaker, CL, Paterson AH, Wendel JF. Comparative genetic mapping of allotetraploid cotton and its diploid progenitors [J]. Genome, 1999,42:184-203
220. Cedroni ML, Cronn RC, Adams KL, et al. Evolution and expression of MYB genes in diploid and polyploid cotton [J]. Plant Molecular Biology, 2003,51: 313-325.
221. Chen XY, Zhang TZ, Zhu YQ, et al. Functional genomic studies of cotton fiber development [J]. Cotton Science, 2002,14 (supplement): 39
222. Cherry JP. A comparative study of seed protein of species of Gossypium by gel electrophoresis [J]. Evolution, 1970, 24: 431- 447.
223. Crane CF, Price HJ, Stelly DM, et al. Identification of a homeologous chromosome pair by in situ DNA hybridization to ribosomal RNA loci in meiotic chromosomes of cotton (Gossypium hirsutum) [J]. Genome, 1993, 36: 1015-1022
224. Cronn, RC, Zhao X, Paterson AH, et al. Polymorphism and Concerted Evolution in a Tandemly Repeated Gene Family: 5S Ribosomal DNA in Diploid and Allopolyploid Cottons[J]. J Mol Evol,1996,42:685-705
225. Cronn R, Small RL,Wendel JF. Duplicated genes evolve independently after polyploid formation in cotton [J]. PNAS, 1999,96(25):14406-14411
226. Cronn R, Wendel JF. Differential evolutionary dynamics of duplicated paralogous Adh loci in allotetraploid cotton (Gossypium) [J].Mol. Biol.Evol, 2002a,19(5): 597-607
227. Cronn R, Small RL,Haselkom T, et al.Rapid diversification of the cotton genus (Gossypium:malvaceae) revealed by analysis of sixteen nuclear and chloroplast genes [J]. American Journal of Botany, 2002b, 89(4): 707-725
228. Cronn R, Cedroni M, Haselkorn T, et al. PCR-mediated recombination in amplification products derived from polyploid cotton [J]. Theor Appl Genet, 2002c, 104:482-489
229. Cronn R, Small RL,Haselkorn T, et al. Cryptic repeated genomic recombination during speciation in Gossypium gossypioides[J]. Evolution, 2003a, 57(11): 2475-2489
230. Cronn R, Wendel JF. Cryptic trysts, genomic mergers, and plant speciation [J]. New Phytologist, 2003b, 161:133-142
231. Culp TW, Harrell DC.Some genetic implications in the transfer of high fiber strength gene to Upland cotton [J]. Crop Sci., 1979,19:481-484
232. Davie JH. Cytological studies in the Malvaceae and certain related families [J]. J Genet,1933,28:33-67
233. Dejoode DR, Wendel JF. Genetic diversity and origin of the Hawaiian island cottons Gossyium tomentosum [J].American Journal of Botany, 1992,79(11): 1311-1319.
234. Denham HJ. The cytology of the cotton plant.Ⅰ.Microspore formation in Sea Island cotton [J]. Ann. Bot.,1924a, 38:407-432
235. Denham HJ. The cytology of the cotton plant.Ⅱ.Chromosome numbers of old and new world cottons [J]. Ann. Bot., 1924b, 38, 433-498
236. Dilday RH.Development of a cotton plant with glandless seeds, and glanded foliage and fruiting forms [J]. Crop Sci, 1986,26:639-941
237. Doblin MS, Kurek I, Jacob-Wilk D et al. Cellulose Biosynthesis in Plants: from Genes to Rosettes. Plant & Cell Physiology, 2002,43(12): 1407-1420
238. Dutt Y, Wang XD, Zhu YG, et al. Breeding for high yield and fibre quality in coloured cotton [J]. Plant Breeding, 2004,123:145-151
239. Edwards GA,Endrizzi, JE and Stein R. Genome DNA content and chromosome organization in Gossypium [J]. Chromosoma,1974,47:309-326
240. Endrizzi JE, Turcotte EL,Kohel RJ.1985.Genetics, cytology and evolution of Gossypium [J].Advances in Genetics, 123:271-375
241. Endrizzi JE, Kattennan FRH, Geever RF. DNA hybridization and the time of origin of three species of Gossypium[J]. Evolution Trends Plants, 1989,3,115-119
242. Esbroeck VGA, Bowman, DT, Calhoun SD, et al.Changes in the genetic diversity of cotton in the USA from 1970 to 1995[J]. Crop Science, 1998,38(1): 33-37
243. Esbroeck, VGA, Bowman DT. Cotton germplasm diversity and its improvement to cultivar development [J]. J Cotton Science, 1998,2:121-129
244. Esbroeck VGA, Bowman, DT, May OL,et al. Genetic similarity indices for ancestral cotton cultivars and their impact on genetic diversity estimates of modern cultivars [J]. Crop Science,1999,39(2): 323-328
245. Fryxell PA.A revision of Australian species of Gossypium with observation on occurrence of Thespesia in Australia (Malvaceae) [J]. Aust J Bot, 1965,18:71-102
246. Fryxell PA.Phenetic analysis and the phytogeny of the diploid species of Gossypium L [J].Evolution, 1971,25:554-562
247. Fryxell, PA.1992. A revised taxonomic interpretation of Gossypium L. (Malvaceae) [J].Rheedea 2:108-165.
248. Gai JY, Wang IK.Identification and estimation of a QTL model and its effects [J]. Theor.Appl.Genet., 1998, 97:1162-1168.
249. Gerstel DU.Chromosomal translocations in interspecific hybrids of the genus Gossypium [J].Evolution, 1953,7:234-244
250. Giband Marc,Trung-Bieu Nguyen, Jean-Marc Lacape. Mapping genes for cotton fiber quality:A.Thaliana as a source of candidate genes [J]. Cotton Science, 2002,14(supplement):57
251. Grover CE, Kim HR, Wing RA, et al. Incongruent Patterns of local and global genome size evolution in cotton [J].Genome Research, 2004,14:1474-1482
252. Guan B, Wang K,Zhou BL,et al. Establishment of a multi-color GISH technique to simultaneously discriminate the three interspecific hybrid genomes in Gossypium [J].JIPB,2007 (in press)
253. Guo WZ, Zhang TZ, Shen XL,et al. Development of SCAR marker linked to a major QTL for high fiber strength and its usage in molecular-marker assisted selection in Upland cotton[J]. Crop Sci. 2003,43:2252- 2256
254. Guo WZ, Cai CP, Wang CB, et al. A microsatellite-based, gene-rich linkage map reveals genome strucutre, function and evolution in Gossypium [J].Genetics, 2007,176: 527-541
255. Guo WZ, Wang W, Zhou BL,et al. Cross-species transferability of G arboreum-derived EST-SSRs in the diploid species of Gossypium. Theor Appl Genet, 2006,112:1573-1581
256. Gutierrez OA, Basu S, Saha S, et al.Genetic distance among selected cotton genotypes and its relationship with F2 performance[J]. Crop Science, 2002,42(6): 1841-1847
257. Hanson RE, Zwick MS, Choi SD,et al. Fluorescent in situ hybridization of a bacterial artificial chromosome [J]. Genome, 1995,38,646-651
258. Hanson RE, Islam-Faridi MN, Percival EA,et al.Distribution of 5S and 18S-28S rDNA loci in a tetraploid cotton (Gossypium hirsutum L.) and putative diploid ancestors [J].Chromosoma,1996,105,55-61
259. Hanson RE, Zhao XP, Islam-Faridi MN, et al. Evolution of interspersed repetitive elements in Gossypium (Malvaceae) [J]. American Journal of Botany, 1998,85(10):1364-1368
260. Hanson RE, Islam-Faridi MN, Crane CF, et al. Tyl-copia-retrotransposon behavior in a polyploid cotton [J]. Chromosome Research, 1999,8:73-76
261. Hanson WD. The break up of initial linkage blocks under selected mating systems [J].Genetics, 1959,44:857-868
262. Hao L,Song GL,Li BL,et al. Karyotype analysis of Gossypium arboreum×G. bickii by genome in situ hybridization [J]. Acta Genetica Sinica, June 2006,33 (6): 565-572
263. Harlan,JR,de Wet JMJ. Toward a rational classification of cultivated plants [J]. Taxon,1971, 20:509-517.
264. Harland SC.The genetics of cotton [M]. London, Jonathan Cape, 1939
265. Harland SC. The genetics of Gossypium.Ⅻ.Homologus genes for anthocyanin pigmentation in New and Old World cottons [J]. J Genet., 1935,30:465-476
266. Hutchinson JB, Silow RA and Stephens SG. The evolution of Gossypium species [J]. Ann.Bot. N.S.,1947,9:361-367
267. Hutchinson SJ. The application of genetics to cotton improvement [J]. London, Camb.Univ.Press.1959
268. Hutchinson JB. The history and relationships of the world's cottons [J]. Endeavour, 1962,21:5-15
269. Harmer SE, Orford SJ, Timmis JN. Characterisation of six a-expansin genes in Gossypium hirsutum (upland cotton) [J]. Mol Genet Genomics, 2002,268:1-9
270. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅰ.Utilisation de l'hybridation interspedifique et de la méthode des lignées d'addition pour l'amélioration du cotonnier [J].Cot Fib Trop, 1981a,36(3): 248-258
271. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅱ.Description phénotypique de quelques lignées d'addition monosomique de Gossypium anomalum et de Gossypium stocksii [J].Cct Fib Trop,1981b,36(4):287-296
272. Hau B. Lignées d'addition sur l'espèce Gossypium hirsutum L.Ⅲ.Evolution d'une collection de lignées d'addition de G. anomalum et de G. Stocksii sur G. hirsutum après plusieurs generations d'autofécondation [J]. Cot Fib Trop, 1982,37(2): 163-177
273. Hawkins JS, Kim HR, Nason JD, et al.Differential lineage-specific amplification of transposable elements is responsible for genome size variation in Gossypium [J]. Genome Res., 2006,16:1252-1261
274. He DH, Lin ZX, Zhang XL et al. QTL mapping for economic traits based on a dense genetic map of cotton with PCR-based markers using the interspecific cross of Gossypium hirsutum×Gossypium barbadense. Euphytica, 2007,153:181-197
275. Hendrix B,Stewart JMcD. Estimation of the nuclear DNA content of Gossypium species [J].Annals of Botany, 2005, 95(5): 789-797
276. Hsu C, An, C,Saha S, et al. Molecular and SNP characterization of two genome specific transcription factor genes GhMyb8 and GhMyb10 in cotton species. Euphytica, 2007, DOI 10.1007/s 10681- 007- 9485-4
277. Hutchinson JB.Intra-specific differentiation in Gossypium hirsutum [J]. Heredity, 1951, 5,161-193
278. Hutchinson JB and Ghose RL. Studies in crops ecology.Ⅰ.The composition of cotton crops of central India and Rajputana [J]. Indian J. Agric.Sci.,1937,7,1
279. Iqbal MJ,Reddy OUK,El-Zik KM, et al. A genetic bottleneck in the 'evolution under domestication' of upland cotton Gossypium hirsutum L. examined using DNA fingerprinting[J]. Theor Appl Genet, 2001,103:547-554
280. Iqbal MJ, Azizn N, Saeed NA, et al. Genetic diversity evaluation of some elite co tton varieties by RA PD analysis [J]. Theor. Appl. Genet., 1997,94:139-144.
281. Iyengar NK.Cytological investigations on some of the interspecific hybrids of (American×Asiatic)×American cottons and their progenies [J].Ind J Genet Plant Breed, 1945, 5:32-45
282. Johnson BL adn Thein MM. Assessment of evolutionary affinities in Gossypium by protein electrophoresis [J]. Am. J. Bot., 1970,57:1081-1092
283. Johnson BL. Symposium on the Biochemical Systematics, Genetics and origin of cultivated plants.Ⅵ.Gossypium palmeri and a polyphyletic origin of the New World cottons [J].Bulletin of the Torrey Botanical Club. 1975,102(6):340-349
284. Ji SJ, Lu YC, Feng JX,et al. Isolation and analyses of genes preferentially expressed during early cotton fiber development by subtractive PCR and cDNA array [J]. Nucleic Acids Research, 2003, 31(10): 2534-2543
285. Ji Y, Raska WA,McKnight TO, et al.Use of meiotic FISH for identification of a new monosome in Gossypium hirsutum L [J]. Genome, 1997,40:34-40
286. Ji Y, Donato MD,Crane CF, et al. New ribosomal RNA gene locations in Gossypium hirsutum mapped by meiotic FISH [J].Chromosoma, 1999a, 108:200-207
287. Ji Y, Raska WA,Donato MD,et al. Identification and distinction among segmental duplication-deficiencies by fluorescence in situ hybridization (FISH)-adorned multivalent analysis[J]. Genome, 1999b, 42(4): 763-771
288. Ji Y, Pertuze R, Chetelat RT. Genome differentiation by GISH in interspecific and intergeneric hybrids of tomato and related nightshades [J]. Chromosome Research, 2004,12:107-116
289. Jiang CX, Chee PW, Draye X, et al. Multilocus interactions restrict gene introgression in interspecific populations of polyploid Gossypium (cotton) [J]. Evolution, 2000, 54(3):798-814
290. Jiang CX, Wright RJ, El-ZikKM, et al. Polyploid formation created unique avenues for response to selection in Gossypium (cotton) [J]. Proc.Natl.Acad. Sci. USA, 1998,95:4419-4424
291. KattermantFRH and Ergle DR.A study of quantitative variations of nucleic acids in Gossypium [J]. Phytochemistry, 1970,9:2007-2010
292. Khan SA,Hussain D, Askari E, et al. Molecular phytogeny of Gossypium species by DNA fingerprinting [J]. Theor Appl Genet, 2000,101:931-938
293. Kim HJ, Triplett BA.Characterization of GhRacl GTPase expressed in developing cotton (Gossypium hirsutum L.) fibers. Biochimica et Biophysica Acta, 2004,1679:214-221
294. Kohel RJ,Endrizzi JE, White TG. An evaluation of Gossypium barbadense L. chromosomes 6 and 17 in the G.hirsutum L [J]. genome. Crop Sci., 1977,17:404-406.
295. Kohel RJ, Yu J, Park YH, et al. Molecular mapping and characterization of traits controlling fiber quality in cotton [J]. Euphytica, 2001,121:163-172.
296. Lawton-Rauh A. Evolutionary dynamics of duplicated genes in plants. Molecular Phylogenetics and Evolution [J], 2003,29:396-409
297. Lee JA. A genetical scheme for isolating cotton cultivars [J]. Crop Sci, 1981,21,339-341
298. Liu B, Brubaker CL,Mergeai G, et al. Polyploid formation in cotton is not accompanied by rapid genomic changes [J]. Genome, 2001a,44: 321-330
299. Liu B, Wendel JF.Intersimple sequence repeat (ISSR) polymorphisms as a genetic marker system in cotton [J]. Molecular Ecology Notes, 2001b,1:205-208
300. Liu B, Wendel JF. Non-Mendelian Phenomena in allopolyploid genome evolution [J]. Current Genomics, 2002,3(6): 489-505
301. Liu B, Wendel JF. Epigenetic phenomena and the evolution of plant allopolyploids [J].Molecular Phylogenetics and Evolution, 2003a,29: 365-379
302. Liu Q, Brubaker CL, Green AG, et al. Evolution of the fad2-l fatty acid desaturase 5'utr intron and the molecular systematics of Gossypium (Malvaceae) [J]. American Journal of Botany, 2001b, 88(1): 92-102
303. Liu Q, Singh SP, Green AG. High-stearic and high-oleic cottonseed oils produced by hairpin RNA-mediated post-transcriptional gene silencing [J]. Plant Physiology, 2002,129:1732-1743
304. Liu S, Cantrell RG, McCarty JC Jr, et al. Simple sequence repeat-based assessment of genetic diversity in cotton race stock accessions [J]. Crop Science, 2000,40(5): 1459-1460
305. Liu SH, Wang KB, Song GL, et al. Primary investigation on GISH-NOR in cotton [J].Chinese Science Bulletin, 2005,50(5): 425-429
306. Loguercio LL, Zhang JQ, Wilkins TA. Differential regulation of six novel MYB-domain genes defines two distinct expression patterns in allotetraploid cotton (Gossypium hirsutum L.) [J]. Mol Gen Genet, 1999,261: 660-671
307. Lu HJ, Myers GO. Genetic relationships and discrimination of ten influential Upland cotton varieties using RAPD markers [J]. Theor Appl Genet, 2002,105:325-331
308. May OL, Green CC, Roach SH, et al. Registration of PD93001, PD93002, PD93003, and PD93004 germplasm lines of Upland cotton with brown lint and high fiber quality [J]. Crop Sci., 1994,34:542
309. May OL, Bowman DT, Calhoun DS. Genetic diversity of U.S. Upland cotton cultivars released between 1980 and 1990[J]. Crop Science, 1995,35(6): 1570-1576
310. May OL. Genetic variation in fiber quality. Basra AS(ed). In Cotton Fiber: developmental biology, quality improvement and textile processing [M]. Food Product Press. NY 1999,pp183-229
311. McFadden Helen, Dean Beasley and Curt L. Brubaker. Assessment of Gossypium sturtianum and G. australe as potential sources of Fusarium wilt resistance to cotton [J]. Euphytica,2004,138:61-72
312. Mckhann Heather I, Christine Camilleri, Aurelie Berard, et al. Nested core collections maximizing genetic diversity in Arabidopsis thaliana [J]. The Plant Journal, 2004,38:193-202
313. Mei MN, Syed H, Gao W, et al. Genetic mapping and QTL analysis of fiber-related traits in cotton (Gossypium) [J].Theor Appl Genet, 2004,108:280-291
314. Meredith WR Jr. Cotton breeding for fiber strength. In Proceedings from cotton fiber cellulose: structure, function, and utilization conference [M]. Memphis, TN, National Cotton Council of American, 1992,289-302.
315. Mergeai G. New perspectives concerning the methodology to be used for introgression of the glanded plant and glandless seed character in cultivated cotton (Gossypium hirsutum L.) [J].Cot Fib Trop, 1992,47:113-118
316. Mert M, Kurt S, Gencer O,et al.Inheritance of resistance to Verticillium wilt (Verticillium dahliae) in cotton (Gossypium hirsutum L.) [J]. Plant Breeding, 2005,124:102-104
317. Meyer VG. Cytoplasmic effect on anther numbers in interspecific hybrids of cotton [J].J Heredity,1971,62:77-78
318. Meyer VG. Interspecific cotton breeding [M]. Econ Bot, 1974,28:56-60
319. Miller PA,Rawling UO. Break-up of initial linkage blocks through intermating in a cotton breeding population [J]. Crop Sci, 1967,7:199-204
320. Multani DS, Lyon BR. Genetic fmgerpringting of Australian cotton cultivars with RAPD markers [J]. Genome, 1995, 38:1005-1008.
321. Muramoto H. Hexaploid cotton: Some plant and fiber properties [J]. Crop Sci, 1969, 9: 27-29
322. Muravenko Olga V,Alexander R Fedotov, Elizabeth O Punina, et al. Comparison of chromosome BrdU-Hoechst-Giemsa banding patterns of the Al and (AD) 2 genomes of cotton [J]. Genome, 1998,41(4): 616-625
323. Murray Allen K,Robert L Nichols, Gretchen F Sassenrath-Cole.Cell wall biosynthesis:glycan- containing oligomers in developing cotton fibers, cotton fabric, wood and paper [J].Phytochemistry, 2001,57:975-986
324. Osborn TC, Pires JC, Birchler JA, et al. Understanding mechanisms of novel gene expression in polyploids [J]. TRENDS in Genetics, 2003,19(3):141-147
325. Palmer TP. Progressive improvement in self fertilized crops [J]. Heredity, 1953,7:127-130
326. Paterson AH, Bowers JE, Burow MD, et al. Comparative Genomics of Plant Chromosomes[J]. The Plant Cell, 2000,12:1523-1539
327. Paterson AH, Brubaker KL,Wendel JF. A rapid method for extraction of cotton (Gossypium spp.) genomic DNA suitable for RFLP or PCR analysis [J]. Plant Mol Biol Rep, 1993, 11:122-127
328. Paterson AH, Boman RK,Brown SM, et al. Reducing the genetic vulnerability of cotton [J].Crop Science, 2004,44(6):1900 -1901
329. Phillips LL. The cytogenetics of Gossypium and the origin of New World cottons [J].Evolution, 1963,17, 460-469
330. Phillips LL.The cytology and phylogenetics of the diploid species of Gossypium [J]. Am. J.Bot., 1966a,53:328-335
331. Phillips LL and Strickland MA. The cytology of a hybrid between Gossypium hirsutum and G. longicalyx [J].Can. J. Genet. Cytol.,1966,8,91-95
332. Phillips LL. Interspecific incompatibility in Gossypium.Ⅳ.Temperature-conditional lethality in hybrids of G klotzschianum [J].Am J Bot, 1977,64, 914-915
333. Phillips LL Cotton (Gossypium). In Hnadbook of Genetics [M]. Plenum Press, N.Y., and London, 1974 12:111-133
334. Pikaard, Craig S. Genomic change and gene silencing in polyploids [J]. TRENDS in Genetics,2001,17 (12): 675-677
335. Pillay M, Myers GO. Genetic diversity in cotton assessed by variation in ribosomal RNA genes and AFLP markers [J]. Crop Science, 1999,39(6): 1881-1886
336. Poisson C. Exploitation of the cross G. hirsutun × G. anomalum [J]. Cot Fib Trop,1968, 23,356-358
337. Poisson C. Use of G. hirsutum × G.anomalum [J]. Cot Fib Trop, 1968,23,359-364
338. Price HJ, Stelly DM, McKnight TD, et al.Molecular cytogenetic mapping of a nucleolar organizer region in cotton [J]. J Hered, 1990, 81: 365-370
339. Qin YM, Hu, CY, Pang Y, et al. Saturated Very-Long-Chain Fatty Acids Promote Cotton Fiber and Arabidopsis Cell Elongation by Activating Ethylene Biosynthesis. The Plant Cell,2007, www.plantcell.org/cgi/doi/10.1105/tpc.107.054437
340. Rahman M, Hussain D, Zafar Y. Estimation of genetic divergence among elite cotton cultivars-genotypes by DNA fingerprinting technology [J]. Crop Science, 2002, 42( 6): 2137-2144
341. Ren LH, Zhang TZ. Genetic evaluation of seven substitution lines in Upland cotton [J]. Acta Agron Sin, 2001,27:993 - 999. (in Chinese with English abstract)
342. Ren LH, Guo WZ,Zhang TZ. Identification of quantitative trait loci (QTLs) affecting Yield and fiber properties in chromosome 16 in cotton using substitution line [J]. Acta Botanica Sinica,2002,44(7):815 - 820
343. Reinisch A, Dong JM, Brubaker CL,et al.A detailed RFLP map of cotton (Gossypium hirsutum × G. barbaddense):chromosome organization and evolution in a disomic polyploid genome [J]. Genetics, 1994,138:829-847
344. Richmond TR. Procedures and methods of cotton breeding with special reference to American cultivated species [J]. Advances in Genetics, 1951, 4:213-245.
345. Rooney WL,Stelli DM, Altman DW. Identification of four Gossypium sturtianum monosomic alien addition derivatives from a backcrossing program with G. hirsutum [J].Crop Sci, 1991,31:337-341
346. Rohlf FJ (1998).NTSYS-pc: Numerical Taxonomy and Multivariate Analysis System [M],vers. 2.0. Applied Biostatistics, New York
347. Rong JK,Abbey C, Bowers JE, et al.A 3347-locus genetic recombination map of sequence-tagged sites reveals features of genome organization, transmission and evolution of cotton (Gossypium) [J]. Genetics, 2004,166:389-417
348. Rong JK,Bowers JE, Schulze SR, et al. Comparative genomics of Gossypium and Arabidopsis:Unraveling the consequences of both ancient and recent polyploidy [J]. Genome Research, 2005,15:1198-1210
349. Ruan YL,Llewellyn DJ, Furbank RT. The delayed initiation and slow elongation of fuzz-like short fibre cells in relation to altered patterns of sucrose synthase expression and plasmodesmata gating in a lintless mutant of cotton. Journal of Experimental Botany, 2005,56,(413): 977-984,
350. Saha S,Wu J, Jenkins JN,et al.Effect of Chromosome Substitutions from Gossypium barbadense L. 3-79 into G. hirsutum L. TM-1 on Agronomic and Fiber Traits [J]. The Journal of Cotton Science, 2004,8:162-169
351. SAS Institute (1989). SAS/STAT User's Guide Version 6[M], 4th edn. SAS Institute, Cary,NC, USA
352. Saunders JH. The wild species of Gossypium and their evolutionary history [M]. London,Oxford Univ. Press.1961
353. Schnabel A, Wendel JF. Cladistic Biogeography of Gleditsia (Leguminosae) based on ndhF and rpl16 chloroplast gene sequences [J]. American Journal of Botany, 1998, 85(12):1753-1765.
354. Seelanan T, Schnabel A,Wendel JF. Congruence and consensus in the cotton tribe (Malvaceae) [J]. Systematic Botany, 1997,22(2): 259-290
355. Senchina DS, Alvarez I, Cronn RC, et al. Rate variation among nuclear genes and the age of polyploidy in Gossypium [J]. Mol.Biol.Evol,2003, 20(4): 633-643
356. Shappley ZW, Jenkins JN, Watson CE Jr, et al. Establishment of molecular markers and linkage groups in two F2 population of Upland cotton [J]. Theor. Appl.Genet.,1996,92 :915-919
357. Shappley ZW, Jenkins JN, Meredith WR Jr, et al. An RFLP linkage map of Upland cotton,Gossypium hirsutum L [J]. Theor Appl Genet, 1998, 97: 756-761.
358. Shappley ZW, Jenkins JN, Zhu J, et al. Quantitative trait loci associated with agronomic and fiber traits of upland cotton [J]. J Cotton Science, 1998,2:153-163
359. Shen XL,Guo WZ, Zhu XF,et al. Molecular mapping of QTLs for fiber qualities in three diverse lines in Upland cotton using SSR markers. Molecular Breeding 2005,15:169-181
360. Shen XL,Guo WZ, Lu QX. Genetic mapping of quantitative trait loci for fiber quality and yield trait by RIL approach in Upland cotton. Euphytica, 2007,155:371-380
361. Shi YH, Zhu SW, Mao XZ, et al. Transcriptome Profiling, Molecular Biological, and Physiological Studies Reveal a Major Role for Ethylene in Cotton Fiber Cell Elongation. The Plant Cell, 2006,18, 651-664,
362. Silow RA. Genetics of species development in Old world cottons [J]. J. Genet., 1944,46,62
363. Skovsted A. Cytological studies in cotton IV: Chromosome configuration in interspecific hybrids [J]. J. Genet., 1937,34, 97-134
364. Skovsted A. Cytological studies in cotton. II. Two interspecific hybrids between Asiatic and new world cottons [J]. J. Genet., 1934,28,407-424
365. Small RL, Ryburn JA, Cronn RC, et al. The tortoise and the hare: Choosing between noncoding plastome and nuclear adh sequences for phylogeny reconstruction in a recently diverged plant group [J]. American Journal of Botany, 1998, 85(9): 1301-1315.
366. Small RL, Ryburn JA, Cronn RC, et al. Low Levels of Nucleotide Diversity at Homoeologous Adh Loci in Allotetraploid Cotton (Gossypium L.) [J]. Mol. Biol. Evol..1999, 16(4): 491-501.
367. Small RL, Wendel JF. The mitochondrial genome of allotetraploid cotton (Gossypium L.) [J].J Hered., 1S99, 90(1): 251-253.
368. Small RL, Wendel JF. Copy Number Lability and Evolutionary Dynamics of the Adh Gene Family in Diploid and Tetraploid Cotton (Gossypium) [J]. Genetics, 2000,155:1913-1926
369. Small RL, Wendel JF. Phylogeny, duplication, and intraspecific variation of Adh sequences in New World diploid cottons (Gossypium L., Malvaceae) [J]. Molecular Phylogenetics and Evolution, 2000,16(1): 73-84
370. Small RL, Wondel JF. Differential evolutionary dynamics of duplicated paralogous Adh loci in allotetraploid cotton (Gossypium) [J]. Mol. Biol. Evol., 2002,19(5):597-607
371. Small RL, Cronn RC, Wendel JF, et al. Review No. 2.Use of nuclear genes for phylogeny reconstruction in plants [J]. Australian Systematic Botany, 2004,17:145-170
372. Snowdon RJ, Friedt W. Molecular markers in Brassica oilseed breeding: current status and future possibilities [J]. Plant Breeding, 2004,123:1—8
373. Song Z, Li B., Chen J, et al. Genetic diversity and conservation of common wild rice (Oryza rufipogon) in China [J]. Plant Species Biology, 2005,20:83-92
374. Stanton MA, Stewart JMcD, Percival AE, et al. Morphological diversity and relationships in the A-genome cottons, Gossypium arboreum and G. herbaceum [J]. Crop Science, 1994,34(2): 519 -527
375. Stephens SG. The genetic organization of leaf-shape development in the genus Gossypium [J].J. Genet., 1944,46:28-51.
376. Stephens SG. Cytolgenetics of Gossypium and the problem of the origin of the New World cottons [J]. Adv. Genet., 1947,1:431-442
377. Stephens SG. Species differentiation in relation to crop improvement [J]. Crop Sci, 1961,1:1-5
378. Stephens SG. The potential for long range oceanic dispersal of cotton seeds [J]. Am. Nat.,1966,100:199-210.
379. Stephens SG, Phillips LL. The history and geographical distribution of a polymorphic system in new world cottons [J]. Biotropica, 1972,4: 49-60
380. Stewart JMcD, Hsu CL. Hybridization of diploid and tetraploid cottons through in-ovule embryo culture [J]. J Hered, 1978, 69:404-408
381. Stewart JMcD. In vitro fertilization and embryo rescue [J]. Environ Exp Bot, 1981, 21:301-315
382. Stewart JMcD, Craven LA, Wendel JF. A new Australian species of Gossypium [M].Proceeding of the Beltwide Cotton Conferences. 1997, National Cotton Council of America,emphis, TN. P448
383. Sun Y, Zhang X, Nie Y, et al. Production and characterization of somatic hybrids between upland cotton (Gossypium hirsutum) and wild cotton (G.klotzschianum Anderss) via electrofusion [J]. Theor Appl Genet, 2004,109:472-479
384. Sun Y, Zhang X, Nie Y, et al. Production of fertile somatic hybrids of Gossypium hirsutum + G. bickii and G. hirsutum + G. stockii via protoplast fusion [J]. Plant Cell, Tissue and Organ Culture, 2005,83: 303-310
385. Sun Y, Nie Y, Guo X, et al. Somatic hybrids between Gossypium hirsutum L. (4x) and G.davidsonii Kellog (2x) produced by protoplast fusion [J]. Euphytica, 2006,151:393-400
386. Tatineni V, Cantrell RG, Davis DD. Genetic diversity in elite cotton germplasm determined by morphological characteristics and RAPDs [J]. Crop Science, 1996,36(1):186-192
387. Tokumoto H, Kazuyuki W, Seiichiro K, et al. Changes in the sugar composition and molecular mass distribution of matrix polysaccharides during cotton fiber development [J].Plant & Cell Physiology; 2002,43 (4): 411-418
388. Ulloa M,Meredith WR Jr.Genetic linkage map and QTL analysis of agronomic and fiber quality traits in. and intraspecific population [J]. J Cotton Science, 2000,4:161-170
389. Valicek P. Wild and cultivated cottons [J]. Coton et Fibres Tropicales (English edition), 1978,33:363-387
390. Vander Wiel PL,Voytas DF, Wendel JF. Copia-like retrotransposable element evolution in diploid and polyploid cotton (Gossypium L.) [J]. J Mol Evol,1993,36(5): 429-47
391. Wang K,Song XL,Han ZG, et al.Complete assignment of the chromosomes of Gossypium hirsutum L.by translocation and fluorescence in situ hybridization mapping [J]. Theor Appl Genet, 2006,113:73-80
392. Wang S, Wang JW,Yu N, et al. Control of plant trichome development by a cotton fiber MYB gene [J]. The Plant Cell, 2004.16:2323-2334
393. Wang J, Xiang, FN, Xia GM, et al. Transfer of small chromosome fragments of Agropyron elongatum to wheat chromosome via asymmetric somatic hybridization [J]. Science in China Ser. C life Sciences, 2004,47(5): 434-441
394. Webber JM. Cytogenetic notes on cotton and cotton relatives [J]. Science, 1934, 80:268-269
395. Watt SG The wild and cultivated cotton plants of the world [J]. Longmans, London.1907
396. Wendel JF.New World tetraplold cottons contain Old World cytoplasm [J]. Proc.Natl.Acad.Sci.USA, 1989, 86: 4132-4136
397. Wendel JF. Olson PD, Stewart JMcD. Genetic diversity, introgression, and independent domestication of old world cultivated cottons [J]. American J Botany, 1989, 76(12):1795-1806
398. Wendel JF,Percy RG. Allozyme diversity and introgression in the Galapagos Islands endemic Gossypium darwinii and its relationship to continental G. barbadense [J].Biochemical Systematics and Ecology, 1990,18: 517-528
399. Wendel JF,Stewart JMcD, Rettig JH. Molecular evidence for homoploid reticulate evolution among Australian species of Gossypium [J]. Evolution, 1991.45:694- 711.
400. Wendel JF, Brubaker CL,Percival AE. Genetic diversity in Gossypium and the origin of upland cotton [J]. American J Botany, 1992,79(11): 1291-1310
401. Wendel JF, Albert VA. Phylogenetics of the cotton genus (Gossypium): Character-state weighted parsimony analysis of chloroplast-DNA restriction site data and its systematic and biogeographic implications [J]. Systematic Botany, 1992,17(1): 115-14
402. Wendel JF, Schnabel A, Seelanan T. Bidirectional interlocus concerted evolution following allopolyploid speciation in cotton (Gossypium) [J]. Proc. Natl.Acad. Sci. USA, 1995, 92:280-284
403. Wendel, JF. Genome evolution in polyploids [J]. Plant Molecular Biology, 2000, 42:225-249
404. Wendel JF, Cronn RC, Johnston JS, et al.Feast and famine in plant genomes [J]. Genetica,2002,115: 37-47
405. Wendel JF, Cronn RC. Polyploidy and the evolutionary history of cotton [J]. Advances in Agronomy, 2003,78:139-186
406. Wilkins T, Arpat A,Sickler B. Cotton fiber genomics: Developmental mechanisms.Pflanzenschutz- Nachrichten Bayer, 2005,58(1):119-139
407. Yang X, Zhang X, Jin S, et al. Production and characterization of asymmetric hybrids between upland cotton Coker 201 (Gossypium hirsutum) and wild cotton (G. klozschianum Anderss) [J]. Plant Cell Tiss Organ Cult, 2007,89:225-235
408. Yu J, Park Yong Ha, Lazo GR, et al. Mapping cotton genome with molecular markers [M].Proceedings Belt wide Cotton conferences, 1997, 1, 447. New Orleans, LA, USA, January 6-10
409. Zaitzev GS. A hybrid between Asiatic and American cotton plants-Gossypium herbaceum L.and Gossypium hirsutum L [M]. Bull. Appl.Bot. Plant Breed., 1923,13,117-13
410. Zhang J, Guo W, Zhang T. Molecular linkage map of allotetraploid cotton (Gossypium hirsutum L.× Gossypium barbadenseL.) with a haploid population [J]. Theor Appl Genet,2002,105:1166-1174
411. Zhang T, Yuan Y, Yu J, et al. Molecular tagging of a major QTL for fiber strength in Upland cotton and its marker-assisted selection [J]. Theor Appl Genet, 2003,106:262.268
412. Zhang Z, Xiao Y, Luo M,et al. Construction of a genetic linkage map and QTL analysis of fiber-related traits in upland cotton (Gossypium hirsutum L.). Euphytica, 2005,144: 91-99
413. ZhaoX,Si Y, Hanson RE, et al, Paterson AH. Dispersed repetitive DNA has spread to new genomes since polyploid formation in cotton [J]. Genome Research, 1998,8:479-492
414. Zhao X,Ji Y, Ding X,et al. Macromolecular organization and genetic mapping of a rapidly evolving chromosome-specific tandem repeat family (B77) in cotton (Gossypium) [J]. Plant Molecular Biology, 1998,38:1031-1042
415. Zhu SJ, Reddy N, Jiang YR. Introgression of a gene for delayed pigment gland morphogenesis from Gossypium bickii into upland cotton [J]. Plant Breeding, 2005,124:590-594
416. Zuo KJ, Sun JZ, Zhang JF, et al. Genetic diversity evaluation of some Chinese elite cotton varieties with RAPD markers [J]. Acata Genetica Sinica, 2000,27(9): 817-823