芥菜型油菜细胞质雄性不育hau CMS的研究
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摘要
油菜是世界上重要的油料作物之一,油菜杂种优势已得到广泛应用,而细胞质雄性不育是油菜杂种优势最重要的途径。芥菜型油菜hau细胞质雄性不育是傅廷栋教授于1999年在华中农业大学发现的,通过回交转育已获得了稳定的油菜细胞质雄性不育系。本研究从育性调查、细胞学观察、恢保关系分析以及分子水平鉴定等方面对芥菜型油菜细胞质雄性不育hau CMS(Cytoplasmic male sterility)进行综合遗传分类;在遗传分类的基础上,通过线粒体DNA位点和RNA表达水平的差异分析,初步进行了hau CMS不育分子机理研究;利用hau CMS不育的稳定性,将不育细胞质转育到甘蓝型油菜和芸薹属十字花科蔬菜中;同时进行了恢复基因的筛选。主要研究结果如下:
1.对芥菜型油菜细胞质hau不育系00-6-102A在武汉和兰州进行了6年12个回交世代的育性观察,hau CMS的不育性稳定彻底,雄蕊通常败育为小花瓣。不育株率和不育度均为100%,且不受环境条件的影响;将芥菜型细胞质转移到甘蓝型油菜6-W301和6-W307中,获得了同样稳定的甘蓝型油菜细胞质雄性不育系。
2.在所有320份测交材料中,用14个来源不同的甘蓝型油菜已知恢复系、保持系材料分别与hau、pol、nap、ogu、tour等5种CMS进行恢保关系测定,鉴定测交F_1的育性,结果表明:hau CMS与nap、pol、ogu、tour胞质不育型具有明显不同的恢保关系。
3.制作石蜡切片对hau CMS不育系00-6-102A和保持系00-6-102B进行了细胞学显微结构观察,hau CMS的花药败育发生于雄蕊原基分化时期。其特点是,败育时期很早,没有孢原细胞的分化,6枚雄蕊都败育为小花瓣,雄蕊偏离正常的分化轨道。Hau CMS的花药败育特点明显不同于以前研究过的油菜胞质不育类型(如ogu、pol、nap、tour CMS等)。
4.用10个线粒体基因的40个探针/酶组合进行RFLP分析,总共有16个探针/酶组合(atp6/HindⅢ、atp6/EcoRI、atp6/EcoRV、atp9/BamHI、atp9/EcoRI和atpl/BamHI等)可以将hau CMS与pol、nap、ogu、tour CMS区分开。其中,5个探针/酶组合(atp1/BamHI、atp6/BamHI、orf222/EcoRI、Orf263-atp6/EcoRI、Drj222/HinaⅢ)能将5个CMS彼此区分开,可以作为鉴定油菜细胞质类型的标记使用。RFLP分析结果进一步证明,hau CMS在线粒体DNA水平上与pol、nap、ogu、tour不育胞质不同,是一种新的油菜不育胞质类型。
5.在hau CMS育性分子机理研究方面,通过已经公布的甘蓝型油菜品种westar线粒体基因组序列和拟南芥线粒体基因组序列,PCR扩增获得34个油菜线粒体探针,对hau CMS不育系00-6-102A和保持系进行Realtime-PCR和Northern blot分析,结合线粒体DNA水平上的位点差异,获得6个可能与hauCMS不育相关的线粒体基因,经过PCR-walking和序列分析,其中位于atp6基因下游的一个新的开放阅读框orf288可能是与hau CMS密切相关的线粒体基因,其与已经公布的主要油菜细胞质雄性不育的基因区域不同。
6.通过杂交和回交已将hau不育细胞质转移到芸薹属十字花科蔬菜(白菜、榨菜、雪里蕻、包心芥和红菜薹)中,获得稳定的蔬菜雄性不育系,且不育株率和不育度均为100%。
7.用不同来源的320份芥菜型、甘蓝型油菜、埃芥及种间杂种与不育系测交,目前还未找到完全恢复的材料,只有2份部分恢复的材料,但还需要进一步测定。
Rapeseed is one of the major oilseed crops.Utilization of rapeseed heterosis is widely applied.Cytoplasmic male sterility(CMS) is an important approach to exploit heterosis in this crop.The hau CMS(00-6-102A) was originally found as a spontaneous male sterile mutant in B.juncea in the experimental field of HAU in 1999.Stable CMS line was obtained by backcrossing.We adopted an integrated approach to classify the five types of CMS systems at morphological,cellular,genetic and molecular levels and confirmed that the hau CMS is different from others.Fertility mechanism of hau CMS was primarily confirmed by analysis of the Realtime-PCR,Northern blot and mitochondrial DNA Polymorphism As the sterility of hau CMS lines was stable and complete,this CMS was introgressed to B.napus and Cruciferous vegetables by hybridization.At the same time, the restorer lines were being screened.
1.After twelve generations of backerossings with B.juncea 00-6-102B,a stable sterile B.juncea line(hau CMS) was established.The anthers in CMS plants were replaced by thickened petal-like structures and pollen grains were not detected. The"sterility degree" of 3,000 flowers was 100%and the "sterility rate" of 300 plants was also 100%in Lanzhou and Wuhan,indicating the stability of hau CMS in two different environments.This CMS was transferred to B.napus through interspecific hybridization. The resultant B.napus CMS was also absolute and stable when 6w-301 and 6w-307 were used as maintainers.
2.Out of 320 materials of different origin,14 known resteror and maintainer lines in B.napus were selected for test-crossing with hau,pol,ogu,nap and tour CMS.The hau CMS line 6W-301A has the same nucleus genetic background as its B.napus maintainer line 6W-301 after eight backcross generations(BC8).The results of test-crossing with restorer lines indicated that fertility in the hau CMS was not restored by restorer lines from pol,ogu,nap and tour CMS systems.Therefore we concluded that hau CMS was a distinct type of cytoplasmic male sterility.
3.Cytological observation of hau CMS anther development indicated the transverse section were thicker with increased cellular layers than normal petals and had no pollen sacs.The stamen primordium deviated from the normal polarization and formed petal primordium,which developed into petal-type structures at the stamen location.These characteristics differed from other CMS systems reported so far.The pollen abortion stage was earlier than other CMS types.The anther development of maintainer 00-6-102B was normal,and each anther had four normal pollen sacs in papilionaceous shape.The A-lines of pol,nap,tour,and ogu CMS systems formed anthers,but were devoid of functional pollen.
4.The polymorphism of mitochondrial DNA was detected with mitochondrial probes atpl,orf222,atp6,atp9,cob,coxⅡ,Orf222-nad5-orf139,coxⅠ,atpa and Orf263-atp6.Out of 40 mitochondrial probe/enzyme combinations,16 combinations exhibited polymorphism such as atp6/HindⅢ,atp6/EcoRI,atp6/EcoRV,atp9/BamHI,atp9/EcoRI and atp1/BamHI.Hau CMS 00-6-102A showed different band patterns from the other four CMS lines and five probe/enzyme combinations alone distinguished the five CMS systems from each other.These results indicated that the mitoehondrial DNA of hau CMS 00-6-102A was different from those of pol,nap,ogu and tour CMS.
5.By analysis of the Realtime PCR,Northern blot and mitochondrial DNA Polymorphism,six genes were possibly associated with fertility mechanism of hau CMS. Furthermore,PCR-walking and sequence analysis were conducted.The results showed that a new open reading frame 'ORF288' probably associated with hau CMS was located at the downstream of atp6 gene.
6.This CMS was introgressed to Cruciferous vegetables(such as B.juncea var.capitata Hort.ex Li,B.juncea var.multiceps Tsen et Lee,B.juncea Czern.et Coss.var.tsatsaiMao,B.rapa Linn.var.purpurea Bailey and B.rapa var.pekinensis ) by hybridization and backcross.The sterility of obtained CMS lines was stable and complete,in contrast to other four CMS types.
7.Test crossing with 320 materials of different origins including B.juncea,B.napus, B.carinata and interspecific hybrids indicated material completely restoring the fertility of hau CMS was not found so far.The individuals obtained from test-crossing with two materials were partially fertile.
1.对芥菜型油菜细胞质hau不育系00-6-102A在武汉和兰州进行了6年12个回交世代的育性观察,hau CMS的不育性稳定彻底,雄蕊通常败育为小花瓣。不育株率和不育度均为100%,且不受环境条件的影响;将芥菜型细胞质转移到甘蓝型油菜6-W301和6-W307中,获得了同样稳定的甘蓝型油菜细胞质雄性不育系。
2.在所有320份测交材料中,用14个来源不同的甘蓝型油菜已知恢复系、保持系材料分别与hau、pol、nap、ogu、tour等5种CMS进行恢保关系测定,鉴定测交F_1的育性,结果表明:hau CMS与nap、pol、ogu、tour胞质不育型具有明显不同的恢保关系。
3.制作石蜡切片对hau CMS不育系00-6-102A和保持系00-6-102B进行了细胞学显微结构观察,hau CMS的花药败育发生于雄蕊原基分化时期。其特点是,败育时期很早,没有孢原细胞的分化,6枚雄蕊都败育为小花瓣,雄蕊偏离正常的分化轨道。Hau CMS的花药败育特点明显不同于以前研究过的油菜胞质不育类型(如ogu、pol、nap、tour CMS等)。
4.用10个线粒体基因的40个探针/酶组合进行RFLP分析,总共有16个探针/酶组合(atp6/HindⅢ、atp6/EcoRI、atp6/EcoRV、atp9/BamHI、atp9/EcoRI和atpl/BamHI等)可以将hau CMS与pol、nap、ogu、tour CMS区分开。其中,5个探针/酶组合(atp1/BamHI、atp6/BamHI、orf222/EcoRI、Orf263-atp6/EcoRI、Drj222/HinaⅢ)能将5个CMS彼此区分开,可以作为鉴定油菜细胞质类型的标记使用。RFLP分析结果进一步证明,hau CMS在线粒体DNA水平上与pol、nap、ogu、tour不育胞质不同,是一种新的油菜不育胞质类型。
5.在hau CMS育性分子机理研究方面,通过已经公布的甘蓝型油菜品种westar线粒体基因组序列和拟南芥线粒体基因组序列,PCR扩增获得34个油菜线粒体探针,对hau CMS不育系00-6-102A和保持系进行Realtime-PCR和Northern blot分析,结合线粒体DNA水平上的位点差异,获得6个可能与hauCMS不育相关的线粒体基因,经过PCR-walking和序列分析,其中位于atp6基因下游的一个新的开放阅读框orf288可能是与hau CMS密切相关的线粒体基因,其与已经公布的主要油菜细胞质雄性不育的基因区域不同。
6.通过杂交和回交已将hau不育细胞质转移到芸薹属十字花科蔬菜(白菜、榨菜、雪里蕻、包心芥和红菜薹)中,获得稳定的蔬菜雄性不育系,且不育株率和不育度均为100%。
7.用不同来源的320份芥菜型、甘蓝型油菜、埃芥及种间杂种与不育系测交,目前还未找到完全恢复的材料,只有2份部分恢复的材料,但还需要进一步测定。
Rapeseed is one of the major oilseed crops.Utilization of rapeseed heterosis is widely applied.Cytoplasmic male sterility(CMS) is an important approach to exploit heterosis in this crop.The hau CMS(00-6-102A) was originally found as a spontaneous male sterile mutant in B.juncea in the experimental field of HAU in 1999.Stable CMS line was obtained by backcrossing.We adopted an integrated approach to classify the five types of CMS systems at morphological,cellular,genetic and molecular levels and confirmed that the hau CMS is different from others.Fertility mechanism of hau CMS was primarily confirmed by analysis of the Realtime-PCR,Northern blot and mitochondrial DNA Polymorphism As the sterility of hau CMS lines was stable and complete,this CMS was introgressed to B.napus and Cruciferous vegetables by hybridization.At the same time, the restorer lines were being screened.
1.After twelve generations of backerossings with B.juncea 00-6-102B,a stable sterile B.juncea line(hau CMS) was established.The anthers in CMS plants were replaced by thickened petal-like structures and pollen grains were not detected. The"sterility degree" of 3,000 flowers was 100%and the "sterility rate" of 300 plants was also 100%in Lanzhou and Wuhan,indicating the stability of hau CMS in two different environments.This CMS was transferred to B.napus through interspecific hybridization. The resultant B.napus CMS was also absolute and stable when 6w-301 and 6w-307 were used as maintainers.
2.Out of 320 materials of different origin,14 known resteror and maintainer lines in B.napus were selected for test-crossing with hau,pol,ogu,nap and tour CMS.The hau CMS line 6W-301A has the same nucleus genetic background as its B.napus maintainer line 6W-301 after eight backcross generations(BC8).The results of test-crossing with restorer lines indicated that fertility in the hau CMS was not restored by restorer lines from pol,ogu,nap and tour CMS systems.Therefore we concluded that hau CMS was a distinct type of cytoplasmic male sterility.
3.Cytological observation of hau CMS anther development indicated the transverse section were thicker with increased cellular layers than normal petals and had no pollen sacs.The stamen primordium deviated from the normal polarization and formed petal primordium,which developed into petal-type structures at the stamen location.These characteristics differed from other CMS systems reported so far.The pollen abortion stage was earlier than other CMS types.The anther development of maintainer 00-6-102B was normal,and each anther had four normal pollen sacs in papilionaceous shape.The A-lines of pol,nap,tour,and ogu CMS systems formed anthers,but were devoid of functional pollen.
4.The polymorphism of mitochondrial DNA was detected with mitochondrial probes atpl,orf222,atp6,atp9,cob,coxⅡ,Orf222-nad5-orf139,coxⅠ,atpa and Orf263-atp6.Out of 40 mitochondrial probe/enzyme combinations,16 combinations exhibited polymorphism such as atp6/HindⅢ,atp6/EcoRI,atp6/EcoRV,atp9/BamHI,atp9/EcoRI and atp1/BamHI.Hau CMS 00-6-102A showed different band patterns from the other four CMS lines and five probe/enzyme combinations alone distinguished the five CMS systems from each other.These results indicated that the mitoehondrial DNA of hau CMS 00-6-102A was different from those of pol,nap,ogu and tour CMS.
5.By analysis of the Realtime PCR,Northern blot and mitochondrial DNA Polymorphism,six genes were possibly associated with fertility mechanism of hau CMS. Furthermore,PCR-walking and sequence analysis were conducted.The results showed that a new open reading frame 'ORF288' probably associated with hau CMS was located at the downstream of atp6 gene.
6.This CMS was introgressed to Cruciferous vegetables(such as B.juncea var.capitata Hort.ex Li,B.juncea var.multiceps Tsen et Lee,B.juncea Czern.et Coss.var.tsatsaiMao,B.rapa Linn.var.purpurea Bailey and B.rapa var.pekinensis ) by hybridization and backcross.The sterility of obtained CMS lines was stable and complete,in contrast to other four CMS types.
7.Test crossing with 320 materials of different origins including B.juncea,B.napus, B.carinata and interspecific hybrids indicated material completely restoring the fertility of hau CMS was not found so far.The individuals obtained from test-crossing with two materials were partially fertile.
引文
1.崔德诉,邓德兴.甘蓝型杂交油菜的研究利用.中国油料,1979,2:15-20
2.陈凤祥,胡宝成,李成,李强生,陈维生,张曼琳.甘蓝型油菜细胞核雄性不育的遗传研究.Ⅰ.隐性核不育系9012A的遗传.作物学报,1998,24(4):22-26
3.陈凤祥,胡宝成,李强生.细胞核不育材料9012A的发现与初步遗传.见:全国植物雄性不育及杂种优势利用青年学术讨论会论文集.北京农业大学学报(增刊),1993,2:20-25
4.傅寿仲,戚存扣,唐继红.甘蓝型油菜细胞质雄性不育系MI CMS的选育.作物学报,1989,15(4):305-309
5.傅廷栋,杨小牛,杨光圣.甘蓝型油菜波里马雄性不育的选育与研究.华中农业大学学报,1989,3:201-207
6.傅廷栋,杨光圣.国内外油菜杂种优势的研究与利用概况.华中农业大学一九九四年油菜研究年报,1995,39-41
7.傅廷栋,杨光圣.油菜细胞质雄性不育系杂种.见:傅廷栋主编,杂交油菜的育种与利用.武汉:湖北科学技术出版社,2000,56-58
8.傅廷栋.杂交油菜的育种与利用.武汉:湖北科学技术出版社,2000
9.方智远,孙培田,刘玉梅等.几种类型甘蓝雄性不育的研究与显性不育系的利用.中国蔬菜,2001,(1):6-10
10.胡琼,李云昌,梅德圣,方小平,Hansen L N,Andersen S B.属间体细胞杂交创建甘蓝型油菜细胞质雄性不育系及其鉴定.中国农业科学,2004.37(3):333-338;
11.黄帮全,李薇,居超民.Ogura雄性不育细胞质导入紫菜薹及杂种优势利用初报.种子,1999,(3):57.
12.康健,陈凡,吴乃虎.光敏核不育水稻育性相关基因cDNA片断的分离.科学通报,1998,43(19):2078-2082
13.柯桂兰,赵稚雅,宋胭脂.大白菜异源胞质雄性不育系CMS3411-7的选育及应用.园艺学报,1992,19(4):333-340.
14.李殿荣.甘蓝型油菜三系选育初报.陕西农业科学,1980,1:26-29
15.李树林,钱玉秀,吴志华.甘蓝型油菜细胞核雄性不育性的遗传规律探讨及其应用.上海农业学报,1985,1(2):1-12
16.李树林,钱玉秀,吴志华.甘蓝型油菜细胞核雄性不育性的遗传验证.上海农业学报,1986,2(2):1-8
17.李树林,钱玉秀,周熙荣.显性核不育油菜的遗传性.上海农业学报,1987,3(2):1-8
18.李树林,周熙荣,周志疆,钱玉秀.显性核不育油菜的遗传与利用.作物研究,1990.4(3): 27-32
19.李云昌,郑元本,龚仁才等.甘蓝型油菜萝匍质不育系的研究极其恢保关系测定.中国油料,1993,(3):8-11
20.凌杏元.周培疆,朱英国.一种新的适于线粒体DNA差异展示的方法.科学通报,1999a,44(7):747-749
21.凌杏元,关和新,周培疆,朱英国.AFLP在水稻线粒体DNA研究中的应用.武汉大学学报,1999b,45(4):477-479
22.凌杏元,周培疆,朱英国.植物细胞质雄性不育分子机理研究进展.植物学通报,2000,17(4):319-332
23.刘尊文.甘蓝型油菜双低“三系”选育简报.江西农业科技.1988,9:11-12
24.刘尊文,彭芝兰.周小平.李海龙,周贱根,吴平.甘蓝型油菜光温敏雄性不育两用系501-8S的选育.中国油料作物学报,1998,20(1):13-16
25.刘忠松。不育花药的生理生化研究进展与展望。植物生理学通讯,1987,2:12-21
26.刘忠松,官春云,陈社员(编著).植物雄性不育机理的研究及应用.北京:中国农业出版社,2001,78-80
27.娄子,王小武,Guusje.Bonnema,方智远.利用DNA-AFLP技术鉴定甘蓝显性核不育基因相关表达序列.园艺学报,2003,30(6):668-672
28.孟金陵主编.植物生殖遗传学(第一版).北京:科学出版社,1995,147-213
29.裴得胜,向跃武,李名扬,蔡平钟,张志雄,阎文昭,侯磊,裴炎.核质互作型水稻线粒体不育基因的RAPD分析.遗传学报,2003,30(4):357-363
30.萨姆布鲁克J,拉塞尔DW著.黄培堂等译:分子克隆实验指南(第三版).北京:科学出版社,2002
31.史华清,龚瑞芳,壮丽连.芥菜型油菜杂种优势利用.作物学报,1991,17(1):32-41
32.田志宏.郑用琏,孟金陵.几个甘蓝型油菜细胞质雄性不育系线粒体DNA的RFLP分析.遗传,1998,20(增刊):22-26
33.王俊霞,杨光圣,傅廷栋,孟金陵.甘蓝型油菜pol CMS育性恢复基因德RAPD标记.作物学报,2000a,26(5):575-578
34.王俊霞,杨光圣,傅廷栋,孟金陵.甘蓝型油菜pol CMS育性恢复基因的基于PCR的分子标记研究.遗传学报,2000b,27(11):1012-1017
35.王永勤,余小林,曹家树.白菜小抱子发育相关基因BcMF3的分离及序列分析.遗传学报,2004,31(11):1302-1308
36.王永飞,马三梅,张鲁刚,王鸣,郑学勤.与细胞质雄性不育相关的orf224基因的克隆和表达载体构建.西北农林科技大学学报(自然科学版),2002,30:9-12
37.王保仁,常桂菊.湘矮A油菜雄性不育系及其杂交组合的细胞学观察和同工酶的研究研究.湖 南师范大学自然科学学报,1986,9(1):83-93
38.王国槐,陈社员,官春云.甘蓝型油菜细胞质雄性不育系681A的选育研究.作物研究,2000
39.魏宝琴,魏毓棠.Ogura不育源结球白菜雄性不育系的选育.中国蔬菜,1995,(5):18-21.
40.许仁林,谢东,师素云,陆维忠,国伟,汪训明.水稻线粒体DNA雄性不育有关特异片段的克隆及序列分析.植物学报,1995,37(7):501-506
41.谢建坤,庄杰云,樊叶杨,涂国庆,夏英武,郑康乐.水稻CMS-WA育性恢复基因定位及其互作分析.遗传学报,2002,22(4):616-627
42.杨光圣,傅廷栋.环境条件对油菜细胞质雄性不育性的影响.中国油料,1987,3:15-19
43.杨光圣.甘蓝型油菜细胞质雄性不育的研究.遗传,1988,10(5):8-11
44.杨光圣,傅廷栋,陈永德.甘蓝型油菜陕2A细胞质雄性不育的研究.华中农业大学学报.1990,9(2):141-147
45.杨光圣,傅廷栋.油菜细胞质雄性不育恢保关系的初步研究.作物学报,1991.17(2):151-156
46.杨光圣,傅廷栋,杨小牛,马朝芝.甘蓝型油菜生态雄性不育两用系的研究Ⅰ.雄性不育两用系的遗传.作物学报,1995,21(2):129-135
47.杨光圣,傅廷栋,杨小牛,马朝芝.油菜波里马细胞质雄性不育恢复基因的筛选与遗传.中国农业科学,1996,29(4):17-22
48.杨光圣,傅廷栋,Brown G G.甘蓝型油菜细胞质雄性不育的遗传分类研究.中国农业科学.1998,31(1):27-31
49.杨光圣,瞿波,傅廷栋.三个甘蓝型油菜隐性细胞核雄性不育系小孢子发生的细胞学研究.华中农业大学学报,1999b,18(6):520-523
50.杨光圣,瞿波,王淑新,傅廷栋.一个甘蓝型油菜DGCMS雄性不育系的花器形态及细胞学研究.中国油料作物学报,2000,22(3):16-21
51.杨剑波,汪秀峰,赵成松,向太和,李莉.水稻线粒体DNA中与雄性不育有关特异片段的克隆及序列分析.遗传学报.2002,29(9):808-813
52.杨剑波,汪秀峰,赵成松,向太和,李莉.野败型水稻保持系线粒体特异DNA片段的克隆及序列分析.植物生理与分子生物学报,2003,29(3):199-205
53.余凤群,傅廷栋.甘蓝型油菜几个品种花药发育的细胞学研究.中国油料,1988,4:23-25
54.余凤群,傅廷栋.甘蓝型油菜几个雄性不育系花药发育的细胞形态学研究.武汉植物学研究,1990,8(3):209-216
55.袁美,杨光圣,傅廷栋,李云.甘蓝型油菜po1CMS育性恢复基因对orf24/atp6的转录调控.遗传学报,2003.30(5):469-473
56.袁隆平.杂交水稻学,北京:中国农业出版社,2002
57.易平,汪莉,孙清萍,朱英国.红莲型细胞质雄性不育水稻线粒体相关嵌合基因的发现.科学通报,2002,47:130-133.
58.庄杰云,樊叶杨,吴建利,饶志明,夏英武,郑康乐.水稻CMS-WA育性恢复基因的定位.遗传学报,2001,28(2):129-34
59.朱英国.水稻雄性不育生物学,武汉:武汉大学出版社,2000
60.周永明,傅廷栋.中国油菜品种的遗传改良.(英文)第十二界国际油菜大会论文集,2007
61.Ashutosh,Kumar P,Kumar V D,Prakash C S,Prakash S,Bhat S R.A Novel orf108Co-Transcribed with the atpA Gone is Associated with Cytoplasmic Male Sterility in Brassica juncea Carrying Moricandia arvensis Cytoplasm.Plant Cell Physiol,2008,49(2):284-289
62.Abdelnoor R V,Yule R,Elo A,Christensen A C,Meyer-Gauen G,Mickenzie S A.Substoichiometric shifting in the plant mitochodrial genome is inflenced by a gone homologous to MutS.Proc Natl Acad Sci USA,2003,100(10):5968-5973
63.Ahmed T A,Tsujimoto H and Sasakuma T.QTL analysis of fertility-restoration against cytoplasmic male sterility in wheat.Genes Goner Syst,2001,76:33-38
64.Akagi H,Nakamura A,Sawada R,Oka M,Fujimura T.Genetic diagnosis of cytoplasmic male cybrid plants of rice.Theor Appl Genet,1995,90:948-950.
65.Akagi H,Nakamura A,Yokozeki-Misono Y,Inagaki A,Takahashi H,Mori K,Fujimura T.Positional cloning of the rice Rf-1 gene,a restorer of BT type cytoplasmic male sterility that encodes a mitochondria-targeting PPR protein.Theor Appl Genet,2004,108(8):1449-1457.
66.Bangs S S,Banga S K and Sandha G S.Development and characterization ofB.tournefortii CMS system in Brassiea napus L.Proc 9th Int Rapeseed Cong.,1995,1:55-57
67.Bannerot H,Boudidard L,Chupeau Y.Unexpected difficulties met with the radish cytoplasm in B oleracea.Eucarpia Cruciferae Newsl,1977,2:16
68.Bellaoui M,Pelletier q,Budar A.The steady-state level of mRNA from the ogura cytoplasmic male sterility locus in Brassica cybrids is determined post-transcriptionally by its 3'region.EMBO,1997,16(16):5057-5068
69.Beckett J B.ClassiWcation of male-sterile cytoplasms in maize(Zea mays).Crop Sci,1971,11:724-727
70.Bellaoui M,Grelon M,Pelletier q,Budar R.The restorer Rfo gone acts post- translationally on the stability of the ORF138 ogura CMS-associated protein in reproductive tissues of rapeseed cybrids.Plant Mol Biol,1999,40:893-902.
71.Bentolila S,Alfonso A A,Hanson M R.A pentatricopoptide repeat-containing gone restores fertility to cytoplasmic male-sterile plants.Proc Nail Acad Sci USA,2002,99(16):10887-10892
72.Bhat S R,Vijayan P,Ashutosh,Dwivedi K K,Prakash S.Diplotaxis erucoides-induced cytoplasmic male sterility in Brassica juncea is rescued by the Moricandia arvensis restorer: genetic and molecular analyses.Plant Breed.,2006,125:150-155
73.Bhat SR,Kumar P,Prakash S.An improved cytoplasmic male sterile(Diplotaxis berthautii)Brassica juncea:identification of restorer and molecular characterization.Euphytica,2008,159:145-152
74.Boden L and Brown G G.Genetic plasticity and its consequences:perspectives on gene organization and expression in plant mitochondria.Can.J.Bot,1993,71:645-660
75.Bonhome S,Budar F,Ferault M.A 2.5kb NcoI fragment of ogura radish mitochondrial DNA is correlated with cytoplasmic male sterility in Brassie cybrids.Curr genet,1991,19:121-127
76.Brown G G,Formanova N,Jin H,Wargachuk R,Dendy C,Patll P,Laforest M,Zhang J F,Cheung W Y,Landry B S.The radish Rfo restorer gene of Ogura cytoplasmicmale sterility encodes a protein with multiple pentatrico peptide repeats.Plant J,2003,35:262-272
77.Bonhomme S,Budar F,Lancelin D,Small I,Defiance M C,Pelletier Cz Sequence and transcript analysis of the Nco2.5 ogura-specific fragment correlated with cytoplasmic male sterility in Brassica cybrid.Mol Gen Genet,1992,235:340-348.
78.Bonnet A.Breeding in France of a radish Fl hybrid obtained by use of cytoplasmic male sterility Eucarpia cruciferae newsl,1977,2:5
79.Brown GG.Unique aspects of cytoplasm male sterility and fertility restoration in Brassica napus.J Here,1999,90:351-356
80.Braun C J,Levings C S Ⅲ.Nueleotide sequence of the F_1-ATPase a subunit gene from maize mitochondria.Plant Physiol,1985,79:571-577
81.Bonen L,Boer P H,Mclntosh J E,Gray M W.Nucleotide sequence of the wheat mitochondrial gene for subunit I of cytochrome oxidase.Nucl Acids Res,1987,15:6734
82.Cui X Q,Wise R P,Schnable P S.The rf2 nuclear restorer gene of male-sterile T-cytoplasm maize.Science,1996,272:1334-1336.
83.Delourme R,Eber F.Linkage between an isoenzyme marker and a restorer gene in radish cytoplasmic male sterility of rapeseed(B.napus).Theor Appl Genet,1992,85:222-228
84.Delorme V,Keen C L,Rai K N,Leaver C J.Cytoplasmic-nuclear male sterility in pearl millet:comparative RFLP and transcript analyses of isonuclear male-sterile lines.Theor Appl Genet,1997,95:96 1-968
85.Delourme R,Bouchereau A,Hubert N,Renard M,Landry B S.Identification of RAPD markers linked to fertileity restorer gene for ogura radish cytoplasmic male sterility of rapeseed(Brassica napus L.).TheorAppl Genet,1994,88:741-748
86.Delourme R,Eber F,Renard M.Breeding double low restorer lines in radish cytoplasmic male sterility of rapeseed(Brassica napus L.).Proc 9th Intl Rapeseed Cong.,1995,1:6-8
87.Delourme R,Foisset N,Horvais R,Barret P,Champagne q Cheung WY,Landry B S,Renard M.Characterisation of the radish introgression carrying the Rfo restorer gene for the Ogu-INRA cytoplasmic male sterility in rapeseed(Brassica napus L.).Theor Appl Genet,1998,97:129-134.
88.Delourme R,Horvais R,Uall P,Renard M.Double low restored Fl hybrids can be produced with the Ogu-INRA CMS rapeseed.Proc 10th Intl Rapeseed Cong,1999,1:71
89.Dewey R E,Levings Ⅲ C S,Timothy D H.Novel recombination in the maize mitochondrial genome produces a unique transcription unit in the Texas male-sterile cytoplasms.Cell,1986,44:439- 449.
90.Dewey R E,Levings C S Ⅲ,Timothy D H Nucleotide sequence of ATPase subunit 6 gene of maize mitochondria.Plant Physiol,1985a,79:914-919
91.Dewey R E,Schuster A M,Levings C S Ⅲ,Timothy D H.Nucleotide sequence of F_0-ATPase proteolipid(subunit9) gene of maize mitochondria.Proc Natl Acad Sci USA,1985b,82:1015-1019
92.Dill C L,Wise R P,Schnable P S.Rf8 and Rf* mediate unique T-urf13-transcript accumulation,revealing a conserved motif associated with RNA processing and restoration of pollen fertility in T cytoplasm maize.Genetics,1997,147:1367-1379.
93.Dieterich J H,Braun H P,Schmitz U K.Alloplasmic male sterility in Brassica napus (CMS"Tournefortii-Stiewe") is associated with a special gene arrangement around a novel atp9 gene.Mol Gen Genet.2003,269:723-73 1
94.Dombrowski S D,Brennicke A,Binder S.3′-inverted repeats in plant mitochondrial mRNAs are processing signals rather than transcription terminators.EMBO J,1997,16(16):5069-5076
95.Donson J,Fang Y W,Espiritu-Santo q Xing W M,Salazar A,Miyamoto S,Armendarez V Volkmuth W.Comprehensive gene expression analysis by transcript profiling.Plant Mol Biol.,2002,48:75-97
96.Doyle J J,Doyle J L.Isolation of plant DNA from fresh tissue.Focus,1990,12:13-15
97.Erickon L,Grant I,Beversdof W.Cytoplasmic male sterility in rapeseed(B.napus).Ⅰ.Restriction patterns of chloroplast and mitochondrial DNA.Theor,4ppl Genet,1986,72:145-150
98.Fan Z,Stefansson B R.Influence of temperature on sterility of two cytoplasmic male sterility in rape(B.napus L.).Can J Plant Sci,1986,66:221-227
99.Fu T D.Production and research of rapeseed in the People's Republic of China.Eucarpia Cruciferae Newsl,1981,6:6-7
100.Grant I,Beversdorf,W D,Peterson R L.A comparative light and electron microscopic study of microspore and tapetal development in male fertile and cytoplasmic male sterile oilseed rape (Brassica napus).Can J Bot,1986,64(5):1055-1068.
101.Gray M W,Hanic-Joyce P J,Covello P S.Transcription,processing and editing in plant mitochondria.Anne Rev Plant Physiol,1994,43:145-175.
102.Gray M W.Origion and evolution of mitochondrial DNA.Anne Rev Cell Bio,1989,5:25-50
103.Handa H and Nakajima K.Different organization and altered t ranscription of the mitochondria atp6 gene in the male-sterile cytoplasm of rapeseed(Brassica napus L.).Curr Genet,1992a 21:153-159
104.Hanson M R,Folkerts O.Structure and function of the higher plant mitochondrial genomes.In Rev Cytol,1992,141:129-172
105.Handa H and Nakajima K.RNA editing of atp6 transcripts from male-sterile and norma cytoplasm of rapeseed(Brassica napus L.).FEBS,1992b,310(2):111-114
106.Handa H,Gualberto J M,Grienenberger J M.Characterization of the Handa H.The complete nucleotide sequence and RNA editing content of the mitochondrial genome of rapeseed(Brassica napus L.):comparative analysis of the mitochondria) genome of rapeseed and Arabidopsis thaliana.Nucleic Acids Res,2003,31(20):5907-5916.
107.Hanson M R.Plant mitochondrial mutations and male sterility.Anne Rev Genet,1991,25:461-486.
108.He S,Yu Z H,Vallejos C E,Mackenzie S A.Pollen fertility restoration by nuclear gene Fr in CMS common bean:an Fr linkage map and the mode of Fr action.Theor Appl Genet.1995,90:1056-1062..
109.Heyn F W.Introgression of restorers genes from Raphanus sativus into cytoplasmic male sterile Brassica napus and the genetics of fertility restoration.Proc.Sth Inter rapeseed Cong,1978,1:82-83
110.Hinata K and Konno N.Studies on a male sterile strain having the Brassica campestris nucleus and the Diplotaxis muralis cytoplasm I.On the breeding procedure and some charateristics of the male sterile strain.Jpn J Breed,1979,29:305-311
111.Horn R,Friedt W.CMS Sources in sunflower:different origin but same mechanism? Theor Appl Genet,1999,98:195-201
112.Horn R,Kohler R H,Zetsche K A.mitochondrial 16 kDa protein is associated with cytoplasmic male sterility in sunflower.Plant Mol Biol,1991,17:29-36.
113.Hu Q,Andersen S B,Dixelius C,et al.Production of fertile intergeneric somatic hybrids between Brassica napus and Sinapis arvensis for the enrichment of the rapeseed gene pool.Plant Cell Rep,2002,21:147-152
114.Iwabuchi M,Kyozuka J and Shimamoto K.Processing followed by complete editing of an altered mitochondrial atp6 RNA restores fertility of cytoplasmic male-sterile rice.EMBO J,1993,12:1437-1446
115.Iwabuchi M,Koizuka N,Fujimoto H,Sakai T,Imamura J.Identification and expression of the kosena radish(Raphanus sativus cv.Kosena) homologue of the ogura radish CMS-associated gene,orf138.Plant Mol Biol,1999,39:183-188.
116.Janska H,Sarria R,Woloszynska M,Arrieta-Montiel M,Mackenzie S A.Stoichiometric shifts in the common bean mitochondrial genome leading to male sterility and spontaneous reversion to fertility.Plant Cell,1998,10:1163-1180.
117.Jean M,Brown G G Landry B S.Genetic mapping of nuclear fertility restorer genes for the 'Polima' cytoplasmic male sterility in canola(Brassica napus L.) using DNA markers.Theor Appl Genet,1997,95:321-328.
118.Kang B C,Nahm S H,Huh J H,Yoo H S,Yu J W,Lee M H,Kim B D.An interspecific (Capsicum annuum x C.chinese) F_2 linkage map in pepper using RFLP and AFLP markers.Theor Appl Genet,2001,102:531-539
119.Kaul M L H Male Sterility in Higher Plants.Springer-Verlag,1988,Berlin
120.Kadowaki K,Suzuki T,Kazama S.A chimeric gene containing the 5' portion of atp6 is associated with cytoplasmic male-sterility of rice.Mol Gen Genet,1990,224(1):10-16.
121.Kemble R J,Gunn R E,Flavell R B.Classification of normal and male sterile cytoplasms in maize.Ⅱ.Electrophoretic analysis of DNA species in mitochondria.Genetics,1980,95:451-458
122.Kadowaki K,Osumi T,Nemoto H,Harada K,Shinjyo C.Mitochondrial DNA polymorphism in male-sterile cytoplasm of rice.Theor Appl Genet,1988,75:234-236
123.Kennell J C,Pring D R Initiation and processing of atp6,T-urf13 and orf221 transcripts from mitochondria of T cytoplasm maize.Mol Gen Genet,1989,216:16-24.
124.Kohler RH,Horn R,Lossl A,Zetsche K.Cytoplasmic male sterility in sunflower is correlated with the co-transcription of a new open reading frame with the atpA gene.Mol Gen Genet,1991,227:369-376.
125.Koizuka N,Imai R,Iwabuchi M,Sakai T,Imamura J.Genetic analysis of fertility restoration and accumulation of ORF125 mitochondrial protein in the kosena radish(Raphanus sativus cv.Kosena)and a Brassica napus restorer line.Theor Appl Genet,2000,100:949-955
126.Koizuka N,Imai R,Fujimoto H,Hayakawa T,Kimura Y,Kohno-Murase J,Sakai T,Kawasaki S,Imamura J.Genetic characterization of a pentatricopeptide repeat protein gene,orf687,that restores fertility in the cytoplasmic male-sterile Kosena radish.Plant J,2003,34(4):407-415.
127.Kojima T,Tsujimoto H,Ogihara Y,High-resolution RFLP mapping of the fertility restoration (Rf3) gene against Triticum timophevel cytoplasm located on chromosome 1BS of common wheat.Genes Genetics Systems,1997,72(6):353-359.
128.Komori T,Ohta S,Murai N,Takakura Y,Kuraya Y,Suzuki S,Hiei Y,Imaseki H,Nitta N.Map-based cloning of a fertility restorer gene Rf-1,in rice(Oryza sativa L.).Plant J,2004,37: 315-325.
129. Krishnasamy S and Makaroff C A. Characterization of the radish mitochondrial orfB locus:possible relationship with male-sterility in ogura radish. Curr Genet, 1993, 24: 156-163
130. Krishnasamy S, Makaroff C A. Organ-specific reduction in the abundance of a mitochondrial protein accompanies fertility restoration in cytoplasmic male-sterile radish. Plant Mol Biol, 1994, 26:935-946.
131. Kubo T, Nishizawa S, Sugawara A, Itchoda N, Estiati A, Mikami T. The complete nucleotide sequence of the mitochondrial genome of sugar beet (Beta Vulgaris L.) reveals a novel gene for Trna Cys(GCA). Nucl Acids Res, 2000, 28: 2571-2576.
132. L'Homme Y, Brown G G. Organization differences between cytoplasmic male sterile and fertile Brassica mitochondrial genomes are confined to a single transposed locus. Nucl Acids Res, 1993, 21:1903-1909
133. L'Homme Y, Stahl R J, Li X Q, Hameed A, Brown G G. Brassica nap cytoplasmic male sterility is associated with expression of a mtDNA region containing a chimeric gene similar to the pol CMS-associated orf224 gene. Curr Genet, 1997, 31: 325-335
134. Landgren M, Zetterstrand M, Sundberg E, Glimelius K. Alloplasmic male-sterie Brassica lines containing B.tournefortii mitochondria express an ORF 3' of the atp6 gene and a 32 kDa protein. Plant Mol Biol, 1996,32:879-890
135. Laser R D and Lersten N R. Anatomy and cytology of microsporogenesis in cytoplasmic male sterile angiosperms. Bot Rev,1972, 38: 425-454.
136. Laver H K, Reynolds S J, Monegar F and Leaver C J. Mitochondrial genome organization and expression associated with cytoplasmic male sterility in sunflower(helianthus annuus). Plant, 1991, 1:185-193.
137. Leaver CJ. Mitochondrial genome organization and expression in higher plants. Annu Rev Plant Physiol,1982,33:373-402.
138. Levings III CS, Pring D R. Restriction emdonuclease analysis of mitochondrial DNA from normal and Taxas cytoplasmic male-sterile maize. Science, 1976,193: 158-169
139. Li XQ, Jean M, Landry B S, Brown G G. Restorer genes for different forms of Brassica cytoplasmic male sterility map to a single nuclear locus that modifies transcripts of several mitochondrial genes. Proc Natl Acad Sci USA, 1998, 95(17): 10032-10037..
140. Liu Z, Guan C, Zhao F, Chen S. Inheritance and mapping of a restorer gene for the rapeseed cytoplasmic male sterile line 681A. Plant Breed, 2005, 124:5-8
141. Makaroff C A, Pahner J D. Mitochondrial DNA rearrangements and transcriptional alternations in the male-sterile cytoplasm of ogura radish. Mol Cell Bio, 1988, 8:1474-1480.
142. Mathias R. transfer of cytoplasmic male sterility from brown mustard (B juncea L.Coss) into rapeseed (B.napus L.). Z.Pfanzenzuchtg, 1985, 95:371-374
143. Maureen R. Hanson and Stephane Bentolila Interactions of Mitochondrial and Nuclear Genes That Affect Male Gametophyte Development. Plant Cell, 2004,Vol. 16, S154-S169, Supplement
144. Menassa R, L'Homme Y and Brown G G.Post-transcriptional and developmental regulation of a CMS-associated mitochondrial gene region by a nuclear restorer gene. Plant, 1999,17(5): 491-499
145. Moneger F, Smart C J, Leaver C J. Nuclear restoration of cytoplasmic male sterility in sunflower is associated with the tissue-specific regulation of a novel mitochondrial gene. EMBO 7,1994,13(1):8-17.
146. Murayama S, Yamagishi H, Terachi T. Identification of RAPD and SCAR markers linked to a restorer gene for ogura cytoplasmic male sterility in radish (Raphanus sativus L.) by bulked segregation analysis. Breed Sci, 1999,49:115-121.
147. Nahm S H, Lee H J, Lee S W, Joo G Y, Harn C H, Yang S G, Min B W Development of a molecular marker specific to a novel CMS line in radish (Raphanus sativus L.). Theor Appl Genet, 2005,111:1191-1200
148. Notsu T Masoood S, Nishikawa T, Kubo N, Akiduki q Nakazono M, Hirai A, Kadowaki K.The complete sequence of the rice (Oryza sativa L.) mitochondrial genome: frequent DNA sequence acquisition and loss during the evolution of flowering plants. Mol Gen Genet,2002, 268: 434-445.
149. Ogura H. Studies on the new male sterility in Japanese Radish, with special references to the utilization of this sterility towards the practical raising of hybrid seed. Mem Fac Agric Kagoshima Univ, 1968, 6(2): 39-78
150. Pathania A, Bhat S R.Kumar V D, Ashutosh, Kirti P B, Prakash S, Chopra V L. Cytoplasmic male sterility in alloplasmic Brassica juncea carrying Diplotaxis catholica cytoplasm: molecular characterization and genetics of fertility restoration. Theor Appl Genet, 2003, 107: 455- 461.
151. Pearson O H. Cytoplasmically inherility characters and flavor components from the speicies cross Brassica nigra (L) KochxB. oleracea L. J. Amer. Sco. Hort. Sci, 1972,97(3):397-402.
152. Pelletier q Primard C, Vedel F, Chetrit P, Remy R, Rousselle P, Renard M. Intergeneric cytoplasmic hybridization in Cruciferae by protoplast fusion. Mol Gen Genet, 1983, 191: 244-50.
153. Phillips P W B. Intellectual property rights, canola and public research in Canada. In:SamtanielloV,Evenson R E, Zilberman D, Carlson G A. eds. Agriculture and Intellectural Property Rights. CAB International, 2000,223-249.
154. Pruitt K D, Hanson M R. Transcription of the Petunia mitochondrial CMS-associated Pcf locus in male sterile and fertility-restored lines. Mol Gen Genet, 1991,227(3): 348-355.
155. Prakash S, Chopra V L Male sterility caused by cytoplasm of Brassica oxyrrhina in B. campestris and B.jnncea.Theor Appl Genet,1990,79:285-287
156.Prakash S,Kirti P B.,Bhat S R.,Gaikwad K,Dinesh Kumar V,Chopra V L.A Moricandia arvensis based cytoplasmic male sterility and fertility restoration system in Brassica juncea.Theor.Appl.Genet.,1998,97:488-492
157.Rawat D S,Anand I J.Male sterility in Indian mustard,Ind J Genet Plant Breed,1979,39:412-414.
158.Robbelen Cz Citation at the occasion of presenting the GCIRC Superior Scientist Award to FU Tingdong.Proc 8th Int Rapeseed Cong(Sasktoon Canada),1991,1:2-5
159.Rousselle P.Study of a cytoplasmic male sterility after interspecific crosses between Brassica napus and Raphanus sativus.Proc.of a EUCARPIA-conference on breeding of cruciferous.Wageningen,1979,100-101
160.Sakai T.and Imamura J.Intergeneric transfer of cytoplasmic male sterility between Raphanus sativus(CMS line) and Brassica napus though cytoplast-protoplast fusion.Theor Appl Genet,1990,80:421-427
161.Sakai T,Iwabuchi M.Kohno-Murase J.Transfer of radish CMS-restorer gene into Brassica napus by intergeneric protoplast fusion.Proc 9th Int Rapeseed Cong,Cambridge,1995,1:3-5
162.Sakai T,Imamura J Alteration of mitochondrial genomes containing atpA genes in the sexual progeny of cybrids between Raphanus sativus CMS line and Brassica napus cv.Westar.Theor Appl Genet,1992,84:923-929
163.Sarria R,Lyznik A,Vallejos C E,Mackenzie S A.A cytoplasmic male sterility-associated mitochondrial peptide in common bean is post-translationally regulated.Plant Cell,1998,10:1217-1228
164.Schnable P S and Wise R P.The molecular basis of cytoplasmic male sterility and fertility restoration.Trends Plant Sci,1998,3(5):175-180.
165.Shiga T and Baba S.Cytoplasmic male sterility in rape plants(Brassica napus L).Jpn J Breed,1971,21(2):16-17
166.Shiga T,Baba S.Cytoplasmic male sterility in oilseed rape(Brassica napus),and its utilization to breeding.Jpn J Breed,1973,23(4):187-197.
167.Shinjyo C(1969).Cytoplasmic genetic male sterility in cultivated rice.Oryza sativa L.Ⅱ.The inheritance of male sterility.Jpn J Genet,44:149-156.
168.Singh M,Brown G G.Suppression of cytoplasmic male sterility by nuclear genes alters expression of a novel mitochondrial gene region.Plant Cell,1991,3:1349-1362.
169.Singh M,Brown GG.Characterization of expression of a mitochondrial gene associated with the Brassica 'Polima' CMS:developmental influences.Curr Genet,1993,24:316-322
170. Singh M, Hamel N R, Li X Q, Young B, Jean M, Landry B S, Brown GG Nuclear genes associated with a single Brassica CMS restorer locus influence transcripts of three different mitochondria) gene regions.Genetics,1996,143:505-516.
171. Sodhi Y S, Chandra A, Verma J K, Arumugam N, Mukhopadhyay A, Gupta V, Pental D, Pradhan AK A new cytoplasmic male sterility system for hybrid seed production in Indian oilseed mustard Brassica juncea. Theor Appl Genet ,2006, 114:93-99
172.Stahl R, Sun S, L'Homme Y, Ketela T, Brown GG. RNA editing of transcripts of a chimeric mitochondrial gene associated with cytoplasmic male-sterility in Brassica.. Nucl Acids Res, 1994,22(11):2109-2113
173.Stiewe G, Witt U, Hansen S, Theis R, Abel W O, Robbelen G.Natural and experimental evolution of CMS for rapeseed breeding. Adv Plant Breed, 1995, 18: 59-76
174. Sugiyama Y, Watase Y, Nagase M, Makita N, Yagura S, Hirai A, Sugiura M. The complete nucleotide sequence and multipartite organization of the tobacco mitochondrial genome: comparative analysis of mitochondrial genome in higher plants. Mol Gen Genet,2005, 272(6):603-615
175. Tang H V,Pring D R, Shaw L C, Salazar R A, Muza F R, Yan B, Schertz K R Transcript processing internal to a mitochondrial open reading frame is correlated with fertility restoration in male-sterile sorghum. Plant J, 1996,10:123-133.
176. Thompson K R Cytoplasmic male sterility in oil-seed rape. Heredity, 1972, 29(2):253-257
177. Unseld M, Marienfeld J R, Brandt P, Brennicke A. The mitochondrial genome of Arabidopsis thaliana contains 57 genes in 366,924 nucleotides. Nature Genetics, 1991 , 15: 57-61
178. Wang H M, Ketela T, Keller W A, Gleddie S C, Brown G G. Genetic correlation of the orfl24/atp6 gene region with Polima CMS in Brassica somatic hybrids. Plant Mol Biol,1995,27(4):801-807
179. Wang Z, ZouY, Zhang Q, Li X, Chen L, Wu H, Su D, Guo J, Chen Y, Luo D, Long Y, Zhong Y, Liu YG. Cytoplasmic male mterility of rice with Boro II cytoplasm is caused by acytotoxic peptide and is restored by two related PPR motifgenes via distinct modes of mRNA silencing. Plant Cell, 2006,1 (8):676-687
180. Wise R P, Dill C L, Schnable P S.Mutator-induced mutations of the rfl nuclear fertility restorer of T-cytoplasm maize alter the accumulation of the T-urf13 mitochondrial transcripts. Genetics, 1996c, 143:1383-1394
181. Wise R P and Pring D R. Nuclear-mediated mitochondrial gene regulation and male fertility in higher plants: Light at the end of the tunnel? Proc Natl Acad Sci USA, 2002, 99:10240-10242.
182. Witt U, Hansen S, Albaum M, Abel W O. Molecular analyses of the CMS-inducing Polima'cytoplasm of Brassica napus L. Curr Genet, 1991, 19:323-329
183. Xiao H,Zhang F, zheng Y. The 5' stem-loop and its role in mRNA stability in maize S cytoplasmic male sterility, plant J, 2006, 47 : 864-872
184.Zabala G Gabay-Laughnan S, Laughnan J R. The nuclear gene Rf3 affects the expression of the mitochondrial chimeric sequence R implicated in S-type male sterility in maize. Genetics, 1997, 147:847-860
2.陈凤祥,胡宝成,李成,李强生,陈维生,张曼琳.甘蓝型油菜细胞核雄性不育的遗传研究.Ⅰ.隐性核不育系9012A的遗传.作物学报,1998,24(4):22-26
3.陈凤祥,胡宝成,李强生.细胞核不育材料9012A的发现与初步遗传.见:全国植物雄性不育及杂种优势利用青年学术讨论会论文集.北京农业大学学报(增刊),1993,2:20-25
4.傅寿仲,戚存扣,唐继红.甘蓝型油菜细胞质雄性不育系MI CMS的选育.作物学报,1989,15(4):305-309
5.傅廷栋,杨小牛,杨光圣.甘蓝型油菜波里马雄性不育的选育与研究.华中农业大学学报,1989,3:201-207
6.傅廷栋,杨光圣.国内外油菜杂种优势的研究与利用概况.华中农业大学一九九四年油菜研究年报,1995,39-41
7.傅廷栋,杨光圣.油菜细胞质雄性不育系杂种.见:傅廷栋主编,杂交油菜的育种与利用.武汉:湖北科学技术出版社,2000,56-58
8.傅廷栋.杂交油菜的育种与利用.武汉:湖北科学技术出版社,2000
9.方智远,孙培田,刘玉梅等.几种类型甘蓝雄性不育的研究与显性不育系的利用.中国蔬菜,2001,(1):6-10
10.胡琼,李云昌,梅德圣,方小平,Hansen L N,Andersen S B.属间体细胞杂交创建甘蓝型油菜细胞质雄性不育系及其鉴定.中国农业科学,2004.37(3):333-338;
11.黄帮全,李薇,居超民.Ogura雄性不育细胞质导入紫菜薹及杂种优势利用初报.种子,1999,(3):57.
12.康健,陈凡,吴乃虎.光敏核不育水稻育性相关基因cDNA片断的分离.科学通报,1998,43(19):2078-2082
13.柯桂兰,赵稚雅,宋胭脂.大白菜异源胞质雄性不育系CMS3411-7的选育及应用.园艺学报,1992,19(4):333-340.
14.李殿荣.甘蓝型油菜三系选育初报.陕西农业科学,1980,1:26-29
15.李树林,钱玉秀,吴志华.甘蓝型油菜细胞核雄性不育性的遗传规律探讨及其应用.上海农业学报,1985,1(2):1-12
16.李树林,钱玉秀,吴志华.甘蓝型油菜细胞核雄性不育性的遗传验证.上海农业学报,1986,2(2):1-8
17.李树林,钱玉秀,周熙荣.显性核不育油菜的遗传性.上海农业学报,1987,3(2):1-8
18.李树林,周熙荣,周志疆,钱玉秀.显性核不育油菜的遗传与利用.作物研究,1990.4(3): 27-32
19.李云昌,郑元本,龚仁才等.甘蓝型油菜萝匍质不育系的研究极其恢保关系测定.中国油料,1993,(3):8-11
20.凌杏元.周培疆,朱英国.一种新的适于线粒体DNA差异展示的方法.科学通报,1999a,44(7):747-749
21.凌杏元,关和新,周培疆,朱英国.AFLP在水稻线粒体DNA研究中的应用.武汉大学学报,1999b,45(4):477-479
22.凌杏元,周培疆,朱英国.植物细胞质雄性不育分子机理研究进展.植物学通报,2000,17(4):319-332
23.刘尊文.甘蓝型油菜双低“三系”选育简报.江西农业科技.1988,9:11-12
24.刘尊文,彭芝兰.周小平.李海龙,周贱根,吴平.甘蓝型油菜光温敏雄性不育两用系501-8S的选育.中国油料作物学报,1998,20(1):13-16
25.刘忠松。不育花药的生理生化研究进展与展望。植物生理学通讯,1987,2:12-21
26.刘忠松,官春云,陈社员(编著).植物雄性不育机理的研究及应用.北京:中国农业出版社,2001,78-80
27.娄子,王小武,Guusje.Bonnema,方智远.利用DNA-AFLP技术鉴定甘蓝显性核不育基因相关表达序列.园艺学报,2003,30(6):668-672
28.孟金陵主编.植物生殖遗传学(第一版).北京:科学出版社,1995,147-213
29.裴得胜,向跃武,李名扬,蔡平钟,张志雄,阎文昭,侯磊,裴炎.核质互作型水稻线粒体不育基因的RAPD分析.遗传学报,2003,30(4):357-363
30.萨姆布鲁克J,拉塞尔DW著.黄培堂等译:分子克隆实验指南(第三版).北京:科学出版社,2002
31.史华清,龚瑞芳,壮丽连.芥菜型油菜杂种优势利用.作物学报,1991,17(1):32-41
32.田志宏.郑用琏,孟金陵.几个甘蓝型油菜细胞质雄性不育系线粒体DNA的RFLP分析.遗传,1998,20(增刊):22-26
33.王俊霞,杨光圣,傅廷栋,孟金陵.甘蓝型油菜pol CMS育性恢复基因德RAPD标记.作物学报,2000a,26(5):575-578
34.王俊霞,杨光圣,傅廷栋,孟金陵.甘蓝型油菜pol CMS育性恢复基因的基于PCR的分子标记研究.遗传学报,2000b,27(11):1012-1017
35.王永勤,余小林,曹家树.白菜小抱子发育相关基因BcMF3的分离及序列分析.遗传学报,2004,31(11):1302-1308
36.王永飞,马三梅,张鲁刚,王鸣,郑学勤.与细胞质雄性不育相关的orf224基因的克隆和表达载体构建.西北农林科技大学学报(自然科学版),2002,30:9-12
37.王保仁,常桂菊.湘矮A油菜雄性不育系及其杂交组合的细胞学观察和同工酶的研究研究.湖 南师范大学自然科学学报,1986,9(1):83-93
38.王国槐,陈社员,官春云.甘蓝型油菜细胞质雄性不育系681A的选育研究.作物研究,2000
39.魏宝琴,魏毓棠.Ogura不育源结球白菜雄性不育系的选育.中国蔬菜,1995,(5):18-21.
40.许仁林,谢东,师素云,陆维忠,国伟,汪训明.水稻线粒体DNA雄性不育有关特异片段的克隆及序列分析.植物学报,1995,37(7):501-506
41.谢建坤,庄杰云,樊叶杨,涂国庆,夏英武,郑康乐.水稻CMS-WA育性恢复基因定位及其互作分析.遗传学报,2002,22(4):616-627
42.杨光圣,傅廷栋.环境条件对油菜细胞质雄性不育性的影响.中国油料,1987,3:15-19
43.杨光圣.甘蓝型油菜细胞质雄性不育的研究.遗传,1988,10(5):8-11
44.杨光圣,傅廷栋,陈永德.甘蓝型油菜陕2A细胞质雄性不育的研究.华中农业大学学报.1990,9(2):141-147
45.杨光圣,傅廷栋.油菜细胞质雄性不育恢保关系的初步研究.作物学报,1991.17(2):151-156
46.杨光圣,傅廷栋,杨小牛,马朝芝.甘蓝型油菜生态雄性不育两用系的研究Ⅰ.雄性不育两用系的遗传.作物学报,1995,21(2):129-135
47.杨光圣,傅廷栋,杨小牛,马朝芝.油菜波里马细胞质雄性不育恢复基因的筛选与遗传.中国农业科学,1996,29(4):17-22
48.杨光圣,傅廷栋,Brown G G.甘蓝型油菜细胞质雄性不育的遗传分类研究.中国农业科学.1998,31(1):27-31
49.杨光圣,瞿波,傅廷栋.三个甘蓝型油菜隐性细胞核雄性不育系小孢子发生的细胞学研究.华中农业大学学报,1999b,18(6):520-523
50.杨光圣,瞿波,王淑新,傅廷栋.一个甘蓝型油菜DGCMS雄性不育系的花器形态及细胞学研究.中国油料作物学报,2000,22(3):16-21
51.杨剑波,汪秀峰,赵成松,向太和,李莉.水稻线粒体DNA中与雄性不育有关特异片段的克隆及序列分析.遗传学报.2002,29(9):808-813
52.杨剑波,汪秀峰,赵成松,向太和,李莉.野败型水稻保持系线粒体特异DNA片段的克隆及序列分析.植物生理与分子生物学报,2003,29(3):199-205
53.余凤群,傅廷栋.甘蓝型油菜几个品种花药发育的细胞学研究.中国油料,1988,4:23-25
54.余凤群,傅廷栋.甘蓝型油菜几个雄性不育系花药发育的细胞形态学研究.武汉植物学研究,1990,8(3):209-216
55.袁美,杨光圣,傅廷栋,李云.甘蓝型油菜po1CMS育性恢复基因对orf24/atp6的转录调控.遗传学报,2003.30(5):469-473
56.袁隆平.杂交水稻学,北京:中国农业出版社,2002
57.易平,汪莉,孙清萍,朱英国.红莲型细胞质雄性不育水稻线粒体相关嵌合基因的发现.科学通报,2002,47:130-133.
58.庄杰云,樊叶杨,吴建利,饶志明,夏英武,郑康乐.水稻CMS-WA育性恢复基因的定位.遗传学报,2001,28(2):129-34
59.朱英国.水稻雄性不育生物学,武汉:武汉大学出版社,2000
60.周永明,傅廷栋.中国油菜品种的遗传改良.(英文)第十二界国际油菜大会论文集,2007
61.Ashutosh,Kumar P,Kumar V D,Prakash C S,Prakash S,Bhat S R.A Novel orf108Co-Transcribed with the atpA Gone is Associated with Cytoplasmic Male Sterility in Brassica juncea Carrying Moricandia arvensis Cytoplasm.Plant Cell Physiol,2008,49(2):284-289
62.Abdelnoor R V,Yule R,Elo A,Christensen A C,Meyer-Gauen G,Mickenzie S A.Substoichiometric shifting in the plant mitochodrial genome is inflenced by a gone homologous to MutS.Proc Natl Acad Sci USA,2003,100(10):5968-5973
63.Ahmed T A,Tsujimoto H and Sasakuma T.QTL analysis of fertility-restoration against cytoplasmic male sterility in wheat.Genes Goner Syst,2001,76:33-38
64.Akagi H,Nakamura A,Sawada R,Oka M,Fujimura T.Genetic diagnosis of cytoplasmic male cybrid plants of rice.Theor Appl Genet,1995,90:948-950.
65.Akagi H,Nakamura A,Yokozeki-Misono Y,Inagaki A,Takahashi H,Mori K,Fujimura T.Positional cloning of the rice Rf-1 gene,a restorer of BT type cytoplasmic male sterility that encodes a mitochondria-targeting PPR protein.Theor Appl Genet,2004,108(8):1449-1457.
66.Bangs S S,Banga S K and Sandha G S.Development and characterization ofB.tournefortii CMS system in Brassiea napus L.Proc 9th Int Rapeseed Cong.,1995,1:55-57
67.Bannerot H,Boudidard L,Chupeau Y.Unexpected difficulties met with the radish cytoplasm in B oleracea.Eucarpia Cruciferae Newsl,1977,2:16
68.Bellaoui M,Pelletier q,Budar A.The steady-state level of mRNA from the ogura cytoplasmic male sterility locus in Brassica cybrids is determined post-transcriptionally by its 3'region.EMBO,1997,16(16):5057-5068
69.Beckett J B.ClassiWcation of male-sterile cytoplasms in maize(Zea mays).Crop Sci,1971,11:724-727
70.Bellaoui M,Grelon M,Pelletier q,Budar R.The restorer Rfo gone acts post- translationally on the stability of the ORF138 ogura CMS-associated protein in reproductive tissues of rapeseed cybrids.Plant Mol Biol,1999,40:893-902.
71.Bentolila S,Alfonso A A,Hanson M R.A pentatricopoptide repeat-containing gone restores fertility to cytoplasmic male-sterile plants.Proc Nail Acad Sci USA,2002,99(16):10887-10892
72.Bhat S R,Vijayan P,Ashutosh,Dwivedi K K,Prakash S.Diplotaxis erucoides-induced cytoplasmic male sterility in Brassica juncea is rescued by the Moricandia arvensis restorer: genetic and molecular analyses.Plant Breed.,2006,125:150-155
73.Bhat SR,Kumar P,Prakash S.An improved cytoplasmic male sterile(Diplotaxis berthautii)Brassica juncea:identification of restorer and molecular characterization.Euphytica,2008,159:145-152
74.Boden L and Brown G G.Genetic plasticity and its consequences:perspectives on gene organization and expression in plant mitochondria.Can.J.Bot,1993,71:645-660
75.Bonhome S,Budar F,Ferault M.A 2.5kb NcoI fragment of ogura radish mitochondrial DNA is correlated with cytoplasmic male sterility in Brassie cybrids.Curr genet,1991,19:121-127
76.Brown G G,Formanova N,Jin H,Wargachuk R,Dendy C,Patll P,Laforest M,Zhang J F,Cheung W Y,Landry B S.The radish Rfo restorer gene of Ogura cytoplasmicmale sterility encodes a protein with multiple pentatrico peptide repeats.Plant J,2003,35:262-272
77.Bonhomme S,Budar F,Lancelin D,Small I,Defiance M C,Pelletier Cz Sequence and transcript analysis of the Nco2.5 ogura-specific fragment correlated with cytoplasmic male sterility in Brassica cybrid.Mol Gen Genet,1992,235:340-348.
78.Bonnet A.Breeding in France of a radish Fl hybrid obtained by use of cytoplasmic male sterility Eucarpia cruciferae newsl,1977,2:5
79.Brown GG.Unique aspects of cytoplasm male sterility and fertility restoration in Brassica napus.J Here,1999,90:351-356
80.Braun C J,Levings C S Ⅲ.Nueleotide sequence of the F_1-ATPase a subunit gene from maize mitochondria.Plant Physiol,1985,79:571-577
81.Bonen L,Boer P H,Mclntosh J E,Gray M W.Nucleotide sequence of the wheat mitochondrial gene for subunit I of cytochrome oxidase.Nucl Acids Res,1987,15:6734
82.Cui X Q,Wise R P,Schnable P S.The rf2 nuclear restorer gene of male-sterile T-cytoplasm maize.Science,1996,272:1334-1336.
83.Delourme R,Eber F.Linkage between an isoenzyme marker and a restorer gene in radish cytoplasmic male sterility of rapeseed(B.napus).Theor Appl Genet,1992,85:222-228
84.Delorme V,Keen C L,Rai K N,Leaver C J.Cytoplasmic-nuclear male sterility in pearl millet:comparative RFLP and transcript analyses of isonuclear male-sterile lines.Theor Appl Genet,1997,95:96 1-968
85.Delourme R,Bouchereau A,Hubert N,Renard M,Landry B S.Identification of RAPD markers linked to fertileity restorer gene for ogura radish cytoplasmic male sterility of rapeseed(Brassica napus L.).TheorAppl Genet,1994,88:741-748
86.Delourme R,Eber F,Renard M.Breeding double low restorer lines in radish cytoplasmic male sterility of rapeseed(Brassica napus L.).Proc 9th Intl Rapeseed Cong.,1995,1:6-8
87.Delourme R,Foisset N,Horvais R,Barret P,Champagne q Cheung WY,Landry B S,Renard M.Characterisation of the radish introgression carrying the Rfo restorer gene for the Ogu-INRA cytoplasmic male sterility in rapeseed(Brassica napus L.).Theor Appl Genet,1998,97:129-134.
88.Delourme R,Horvais R,Uall P,Renard M.Double low restored Fl hybrids can be produced with the Ogu-INRA CMS rapeseed.Proc 10th Intl Rapeseed Cong,1999,1:71
89.Dewey R E,Levings Ⅲ C S,Timothy D H.Novel recombination in the maize mitochondrial genome produces a unique transcription unit in the Texas male-sterile cytoplasms.Cell,1986,44:439- 449.
90.Dewey R E,Levings C S Ⅲ,Timothy D H Nucleotide sequence of ATPase subunit 6 gene of maize mitochondria.Plant Physiol,1985a,79:914-919
91.Dewey R E,Schuster A M,Levings C S Ⅲ,Timothy D H.Nucleotide sequence of F_0-ATPase proteolipid(subunit9) gene of maize mitochondria.Proc Natl Acad Sci USA,1985b,82:1015-1019
92.Dill C L,Wise R P,Schnable P S.Rf8 and Rf* mediate unique T-urf13-transcript accumulation,revealing a conserved motif associated with RNA processing and restoration of pollen fertility in T cytoplasm maize.Genetics,1997,147:1367-1379.
93.Dieterich J H,Braun H P,Schmitz U K.Alloplasmic male sterility in Brassica napus (CMS"Tournefortii-Stiewe") is associated with a special gene arrangement around a novel atp9 gene.Mol Gen Genet.2003,269:723-73 1
94.Dombrowski S D,Brennicke A,Binder S.3′-inverted repeats in plant mitochondrial mRNAs are processing signals rather than transcription terminators.EMBO J,1997,16(16):5069-5076
95.Donson J,Fang Y W,Espiritu-Santo q Xing W M,Salazar A,Miyamoto S,Armendarez V Volkmuth W.Comprehensive gene expression analysis by transcript profiling.Plant Mol Biol.,2002,48:75-97
96.Doyle J J,Doyle J L.Isolation of plant DNA from fresh tissue.Focus,1990,12:13-15
97.Erickon L,Grant I,Beversdof W.Cytoplasmic male sterility in rapeseed(B.napus).Ⅰ.Restriction patterns of chloroplast and mitochondrial DNA.Theor,4ppl Genet,1986,72:145-150
98.Fan Z,Stefansson B R.Influence of temperature on sterility of two cytoplasmic male sterility in rape(B.napus L.).Can J Plant Sci,1986,66:221-227
99.Fu T D.Production and research of rapeseed in the People's Republic of China.Eucarpia Cruciferae Newsl,1981,6:6-7
100.Grant I,Beversdorf,W D,Peterson R L.A comparative light and electron microscopic study of microspore and tapetal development in male fertile and cytoplasmic male sterile oilseed rape (Brassica napus).Can J Bot,1986,64(5):1055-1068.
101.Gray M W,Hanic-Joyce P J,Covello P S.Transcription,processing and editing in plant mitochondria.Anne Rev Plant Physiol,1994,43:145-175.
102.Gray M W.Origion and evolution of mitochondrial DNA.Anne Rev Cell Bio,1989,5:25-50
103.Handa H and Nakajima K.Different organization and altered t ranscription of the mitochondria atp6 gene in the male-sterile cytoplasm of rapeseed(Brassica napus L.).Curr Genet,1992a 21:153-159
104.Hanson M R,Folkerts O.Structure and function of the higher plant mitochondrial genomes.In Rev Cytol,1992,141:129-172
105.Handa H and Nakajima K.RNA editing of atp6 transcripts from male-sterile and norma cytoplasm of rapeseed(Brassica napus L.).FEBS,1992b,310(2):111-114
106.Handa H,Gualberto J M,Grienenberger J M.Characterization of the Handa H.The complete nucleotide sequence and RNA editing content of the mitochondrial genome of rapeseed(Brassica napus L.):comparative analysis of the mitochondria) genome of rapeseed and Arabidopsis thaliana.Nucleic Acids Res,2003,31(20):5907-5916.
107.Hanson M R.Plant mitochondrial mutations and male sterility.Anne Rev Genet,1991,25:461-486.
108.He S,Yu Z H,Vallejos C E,Mackenzie S A.Pollen fertility restoration by nuclear gene Fr in CMS common bean:an Fr linkage map and the mode of Fr action.Theor Appl Genet.1995,90:1056-1062..
109.Heyn F W.Introgression of restorers genes from Raphanus sativus into cytoplasmic male sterile Brassica napus and the genetics of fertility restoration.Proc.Sth Inter rapeseed Cong,1978,1:82-83
110.Hinata K and Konno N.Studies on a male sterile strain having the Brassica campestris nucleus and the Diplotaxis muralis cytoplasm I.On the breeding procedure and some charateristics of the male sterile strain.Jpn J Breed,1979,29:305-311
111.Horn R,Friedt W.CMS Sources in sunflower:different origin but same mechanism? Theor Appl Genet,1999,98:195-201
112.Horn R,Kohler R H,Zetsche K A.mitochondrial 16 kDa protein is associated with cytoplasmic male sterility in sunflower.Plant Mol Biol,1991,17:29-36.
113.Hu Q,Andersen S B,Dixelius C,et al.Production of fertile intergeneric somatic hybrids between Brassica napus and Sinapis arvensis for the enrichment of the rapeseed gene pool.Plant Cell Rep,2002,21:147-152
114.Iwabuchi M,Kyozuka J and Shimamoto K.Processing followed by complete editing of an altered mitochondrial atp6 RNA restores fertility of cytoplasmic male-sterile rice.EMBO J,1993,12:1437-1446
115.Iwabuchi M,Koizuka N,Fujimoto H,Sakai T,Imamura J.Identification and expression of the kosena radish(Raphanus sativus cv.Kosena) homologue of the ogura radish CMS-associated gene,orf138.Plant Mol Biol,1999,39:183-188.
116.Janska H,Sarria R,Woloszynska M,Arrieta-Montiel M,Mackenzie S A.Stoichiometric shifts in the common bean mitochondrial genome leading to male sterility and spontaneous reversion to fertility.Plant Cell,1998,10:1163-1180.
117.Jean M,Brown G G Landry B S.Genetic mapping of nuclear fertility restorer genes for the 'Polima' cytoplasmic male sterility in canola(Brassica napus L.) using DNA markers.Theor Appl Genet,1997,95:321-328.
118.Kang B C,Nahm S H,Huh J H,Yoo H S,Yu J W,Lee M H,Kim B D.An interspecific (Capsicum annuum x C.chinese) F_2 linkage map in pepper using RFLP and AFLP markers.Theor Appl Genet,2001,102:531-539
119.Kaul M L H Male Sterility in Higher Plants.Springer-Verlag,1988,Berlin
120.Kadowaki K,Suzuki T,Kazama S.A chimeric gene containing the 5' portion of atp6 is associated with cytoplasmic male-sterility of rice.Mol Gen Genet,1990,224(1):10-16.
121.Kemble R J,Gunn R E,Flavell R B.Classification of normal and male sterile cytoplasms in maize.Ⅱ.Electrophoretic analysis of DNA species in mitochondria.Genetics,1980,95:451-458
122.Kadowaki K,Osumi T,Nemoto H,Harada K,Shinjyo C.Mitochondrial DNA polymorphism in male-sterile cytoplasm of rice.Theor Appl Genet,1988,75:234-236
123.Kennell J C,Pring D R Initiation and processing of atp6,T-urf13 and orf221 transcripts from mitochondria of T cytoplasm maize.Mol Gen Genet,1989,216:16-24.
124.Kohler RH,Horn R,Lossl A,Zetsche K.Cytoplasmic male sterility in sunflower is correlated with the co-transcription of a new open reading frame with the atpA gene.Mol Gen Genet,1991,227:369-376.
125.Koizuka N,Imai R,Iwabuchi M,Sakai T,Imamura J.Genetic analysis of fertility restoration and accumulation of ORF125 mitochondrial protein in the kosena radish(Raphanus sativus cv.Kosena)and a Brassica napus restorer line.Theor Appl Genet,2000,100:949-955
126.Koizuka N,Imai R,Fujimoto H,Hayakawa T,Kimura Y,Kohno-Murase J,Sakai T,Kawasaki S,Imamura J.Genetic characterization of a pentatricopeptide repeat protein gene,orf687,that restores fertility in the cytoplasmic male-sterile Kosena radish.Plant J,2003,34(4):407-415.
127.Kojima T,Tsujimoto H,Ogihara Y,High-resolution RFLP mapping of the fertility restoration (Rf3) gene against Triticum timophevel cytoplasm located on chromosome 1BS of common wheat.Genes Genetics Systems,1997,72(6):353-359.
128.Komori T,Ohta S,Murai N,Takakura Y,Kuraya Y,Suzuki S,Hiei Y,Imaseki H,Nitta N.Map-based cloning of a fertility restorer gene Rf-1,in rice(Oryza sativa L.).Plant J,2004,37: 315-325.
129. Krishnasamy S and Makaroff C A. Characterization of the radish mitochondrial orfB locus:possible relationship with male-sterility in ogura radish. Curr Genet, 1993, 24: 156-163
130. Krishnasamy S, Makaroff C A. Organ-specific reduction in the abundance of a mitochondrial protein accompanies fertility restoration in cytoplasmic male-sterile radish. Plant Mol Biol, 1994, 26:935-946.
131. Kubo T, Nishizawa S, Sugawara A, Itchoda N, Estiati A, Mikami T. The complete nucleotide sequence of the mitochondrial genome of sugar beet (Beta Vulgaris L.) reveals a novel gene for Trna Cys(GCA). Nucl Acids Res, 2000, 28: 2571-2576.
132. L'Homme Y, Brown G G. Organization differences between cytoplasmic male sterile and fertile Brassica mitochondrial genomes are confined to a single transposed locus. Nucl Acids Res, 1993, 21:1903-1909
133. L'Homme Y, Stahl R J, Li X Q, Hameed A, Brown G G. Brassica nap cytoplasmic male sterility is associated with expression of a mtDNA region containing a chimeric gene similar to the pol CMS-associated orf224 gene. Curr Genet, 1997, 31: 325-335
134. Landgren M, Zetterstrand M, Sundberg E, Glimelius K. Alloplasmic male-sterie Brassica lines containing B.tournefortii mitochondria express an ORF 3' of the atp6 gene and a 32 kDa protein. Plant Mol Biol, 1996,32:879-890
135. Laser R D and Lersten N R. Anatomy and cytology of microsporogenesis in cytoplasmic male sterile angiosperms. Bot Rev,1972, 38: 425-454.
136. Laver H K, Reynolds S J, Monegar F and Leaver C J. Mitochondrial genome organization and expression associated with cytoplasmic male sterility in sunflower(helianthus annuus). Plant, 1991, 1:185-193.
137. Leaver CJ. Mitochondrial genome organization and expression in higher plants. Annu Rev Plant Physiol,1982,33:373-402.
138. Levings III CS, Pring D R. Restriction emdonuclease analysis of mitochondrial DNA from normal and Taxas cytoplasmic male-sterile maize. Science, 1976,193: 158-169
139. Li XQ, Jean M, Landry B S, Brown G G. Restorer genes for different forms of Brassica cytoplasmic male sterility map to a single nuclear locus that modifies transcripts of several mitochondrial genes. Proc Natl Acad Sci USA, 1998, 95(17): 10032-10037..
140. Liu Z, Guan C, Zhao F, Chen S. Inheritance and mapping of a restorer gene for the rapeseed cytoplasmic male sterile line 681A. Plant Breed, 2005, 124:5-8
141. Makaroff C A, Pahner J D. Mitochondrial DNA rearrangements and transcriptional alternations in the male-sterile cytoplasm of ogura radish. Mol Cell Bio, 1988, 8:1474-1480.
142. Mathias R. transfer of cytoplasmic male sterility from brown mustard (B juncea L.Coss) into rapeseed (B.napus L.). Z.Pfanzenzuchtg, 1985, 95:371-374
143. Maureen R. Hanson and Stephane Bentolila Interactions of Mitochondrial and Nuclear Genes That Affect Male Gametophyte Development. Plant Cell, 2004,Vol. 16, S154-S169, Supplement
144. Menassa R, L'Homme Y and Brown G G.Post-transcriptional and developmental regulation of a CMS-associated mitochondrial gene region by a nuclear restorer gene. Plant, 1999,17(5): 491-499
145. Moneger F, Smart C J, Leaver C J. Nuclear restoration of cytoplasmic male sterility in sunflower is associated with the tissue-specific regulation of a novel mitochondrial gene. EMBO 7,1994,13(1):8-17.
146. Murayama S, Yamagishi H, Terachi T. Identification of RAPD and SCAR markers linked to a restorer gene for ogura cytoplasmic male sterility in radish (Raphanus sativus L.) by bulked segregation analysis. Breed Sci, 1999,49:115-121.
147. Nahm S H, Lee H J, Lee S W, Joo G Y, Harn C H, Yang S G, Min B W Development of a molecular marker specific to a novel CMS line in radish (Raphanus sativus L.). Theor Appl Genet, 2005,111:1191-1200
148. Notsu T Masoood S, Nishikawa T, Kubo N, Akiduki q Nakazono M, Hirai A, Kadowaki K.The complete sequence of the rice (Oryza sativa L.) mitochondrial genome: frequent DNA sequence acquisition and loss during the evolution of flowering plants. Mol Gen Genet,2002, 268: 434-445.
149. Ogura H. Studies on the new male sterility in Japanese Radish, with special references to the utilization of this sterility towards the practical raising of hybrid seed. Mem Fac Agric Kagoshima Univ, 1968, 6(2): 39-78
150. Pathania A, Bhat S R.Kumar V D, Ashutosh, Kirti P B, Prakash S, Chopra V L. Cytoplasmic male sterility in alloplasmic Brassica juncea carrying Diplotaxis catholica cytoplasm: molecular characterization and genetics of fertility restoration. Theor Appl Genet, 2003, 107: 455- 461.
151. Pearson O H. Cytoplasmically inherility characters and flavor components from the speicies cross Brassica nigra (L) KochxB. oleracea L. J. Amer. Sco. Hort. Sci, 1972,97(3):397-402.
152. Pelletier q Primard C, Vedel F, Chetrit P, Remy R, Rousselle P, Renard M. Intergeneric cytoplasmic hybridization in Cruciferae by protoplast fusion. Mol Gen Genet, 1983, 191: 244-50.
153. Phillips P W B. Intellectual property rights, canola and public research in Canada. In:SamtanielloV,Evenson R E, Zilberman D, Carlson G A. eds. Agriculture and Intellectural Property Rights. CAB International, 2000,223-249.
154. Pruitt K D, Hanson M R. Transcription of the Petunia mitochondrial CMS-associated Pcf locus in male sterile and fertility-restored lines. Mol Gen Genet, 1991,227(3): 348-355.
155. Prakash S, Chopra V L Male sterility caused by cytoplasm of Brassica oxyrrhina in B. campestris and B.jnncea.Theor Appl Genet,1990,79:285-287
156.Prakash S,Kirti P B.,Bhat S R.,Gaikwad K,Dinesh Kumar V,Chopra V L.A Moricandia arvensis based cytoplasmic male sterility and fertility restoration system in Brassica juncea.Theor.Appl.Genet.,1998,97:488-492
157.Rawat D S,Anand I J.Male sterility in Indian mustard,Ind J Genet Plant Breed,1979,39:412-414.
158.Robbelen Cz Citation at the occasion of presenting the GCIRC Superior Scientist Award to FU Tingdong.Proc 8th Int Rapeseed Cong(Sasktoon Canada),1991,1:2-5
159.Rousselle P.Study of a cytoplasmic male sterility after interspecific crosses between Brassica napus and Raphanus sativus.Proc.of a EUCARPIA-conference on breeding of cruciferous.Wageningen,1979,100-101
160.Sakai T.and Imamura J.Intergeneric transfer of cytoplasmic male sterility between Raphanus sativus(CMS line) and Brassica napus though cytoplast-protoplast fusion.Theor Appl Genet,1990,80:421-427
161.Sakai T,Iwabuchi M.Kohno-Murase J.Transfer of radish CMS-restorer gene into Brassica napus by intergeneric protoplast fusion.Proc 9th Int Rapeseed Cong,Cambridge,1995,1:3-5
162.Sakai T,Imamura J Alteration of mitochondrial genomes containing atpA genes in the sexual progeny of cybrids between Raphanus sativus CMS line and Brassica napus cv.Westar.Theor Appl Genet,1992,84:923-929
163.Sarria R,Lyznik A,Vallejos C E,Mackenzie S A.A cytoplasmic male sterility-associated mitochondrial peptide in common bean is post-translationally regulated.Plant Cell,1998,10:1217-1228
164.Schnable P S and Wise R P.The molecular basis of cytoplasmic male sterility and fertility restoration.Trends Plant Sci,1998,3(5):175-180.
165.Shiga T and Baba S.Cytoplasmic male sterility in rape plants(Brassica napus L).Jpn J Breed,1971,21(2):16-17
166.Shiga T,Baba S.Cytoplasmic male sterility in oilseed rape(Brassica napus),and its utilization to breeding.Jpn J Breed,1973,23(4):187-197.
167.Shinjyo C(1969).Cytoplasmic genetic male sterility in cultivated rice.Oryza sativa L.Ⅱ.The inheritance of male sterility.Jpn J Genet,44:149-156.
168.Singh M,Brown G G.Suppression of cytoplasmic male sterility by nuclear genes alters expression of a novel mitochondrial gene region.Plant Cell,1991,3:1349-1362.
169.Singh M,Brown GG.Characterization of expression of a mitochondrial gene associated with the Brassica 'Polima' CMS:developmental influences.Curr Genet,1993,24:316-322
170. Singh M, Hamel N R, Li X Q, Young B, Jean M, Landry B S, Brown GG Nuclear genes associated with a single Brassica CMS restorer locus influence transcripts of three different mitochondria) gene regions.Genetics,1996,143:505-516.
171. Sodhi Y S, Chandra A, Verma J K, Arumugam N, Mukhopadhyay A, Gupta V, Pental D, Pradhan AK A new cytoplasmic male sterility system for hybrid seed production in Indian oilseed mustard Brassica juncea. Theor Appl Genet ,2006, 114:93-99
172.Stahl R, Sun S, L'Homme Y, Ketela T, Brown GG. RNA editing of transcripts of a chimeric mitochondrial gene associated with cytoplasmic male-sterility in Brassica.. Nucl Acids Res, 1994,22(11):2109-2113
173.Stiewe G, Witt U, Hansen S, Theis R, Abel W O, Robbelen G.Natural and experimental evolution of CMS for rapeseed breeding. Adv Plant Breed, 1995, 18: 59-76
174. Sugiyama Y, Watase Y, Nagase M, Makita N, Yagura S, Hirai A, Sugiura M. The complete nucleotide sequence and multipartite organization of the tobacco mitochondrial genome: comparative analysis of mitochondrial genome in higher plants. Mol Gen Genet,2005, 272(6):603-615
175. Tang H V,Pring D R, Shaw L C, Salazar R A, Muza F R, Yan B, Schertz K R Transcript processing internal to a mitochondrial open reading frame is correlated with fertility restoration in male-sterile sorghum. Plant J, 1996,10:123-133.
176. Thompson K R Cytoplasmic male sterility in oil-seed rape. Heredity, 1972, 29(2):253-257
177. Unseld M, Marienfeld J R, Brandt P, Brennicke A. The mitochondrial genome of Arabidopsis thaliana contains 57 genes in 366,924 nucleotides. Nature Genetics, 1991 , 15: 57-61
178. Wang H M, Ketela T, Keller W A, Gleddie S C, Brown G G. Genetic correlation of the orfl24/atp6 gene region with Polima CMS in Brassica somatic hybrids. Plant Mol Biol,1995,27(4):801-807
179. Wang Z, ZouY, Zhang Q, Li X, Chen L, Wu H, Su D, Guo J, Chen Y, Luo D, Long Y, Zhong Y, Liu YG. Cytoplasmic male mterility of rice with Boro II cytoplasm is caused by acytotoxic peptide and is restored by two related PPR motifgenes via distinct modes of mRNA silencing. Plant Cell, 2006,1 (8):676-687
180. Wise R P, Dill C L, Schnable P S.Mutator-induced mutations of the rfl nuclear fertility restorer of T-cytoplasm maize alter the accumulation of the T-urf13 mitochondrial transcripts. Genetics, 1996c, 143:1383-1394
181. Wise R P and Pring D R. Nuclear-mediated mitochondrial gene regulation and male fertility in higher plants: Light at the end of the tunnel? Proc Natl Acad Sci USA, 2002, 99:10240-10242.
182. Witt U, Hansen S, Albaum M, Abel W O. Molecular analyses of the CMS-inducing Polima'cytoplasm of Brassica napus L. Curr Genet, 1991, 19:323-329
183. Xiao H,Zhang F, zheng Y. The 5' stem-loop and its role in mRNA stability in maize S cytoplasmic male sterility, plant J, 2006, 47 : 864-872
184.Zabala G Gabay-Laughnan S, Laughnan J R. The nuclear gene Rf3 affects the expression of the mitochondrial chimeric sequence R implicated in S-type male sterility in maize. Genetics, 1997, 147:847-860
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