密度、N肥力对春小麦不同基因型主要品质和农艺性状影响的研究
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摘要
本试验使用裂裂区设计,对不同密度、N肥下的14个稳定的春小麦品种(系)的5个品质性状(GMP、伯尔辛克值、沉降值、粗蛋白含量、湿面筋含量)和5个农艺性状(株高、有效分蘖、千粒重、单株粒重、穗长)使用多种统计方法,来综合分析春小麦品质、农艺性状。结果如下:
1.所测的14个品种(系)的5个品质性状(GMP、伯尔辛克值、沉降值、粗蛋白含量、湿面筋含量)品种间差异极显著,各品质性状对氮肥、密度的敏感性与大到小依次为伯尔辛克值、GMP、湿面筋含量、沉降值、蛋白质;5个品质性状对对氮肥的敏感性与大到小依次为GMP、粗蛋白含量、湿面筋含量、沉降值、伯尔辛克值。
2.各个农艺性状品种间差异极显著,不同密度间差异显著,不同肥料水平间差异极显著。各农艺性状对氮肥、密度的敏感性从大到小依次为株高、千粒重、穗长、有效分蘖、单株粒重。
3.蛋白质、GMP、湿面筋、伯尔辛克值、沉降值在不同的N肥水平之间呈显著的正相关关系,累计贡献率超过85%,基本可以决定春小麦不同品质类型的变化。
4.以株高、穗长、有效分蘖、千粒重为自变量,以单株粒重为因变量进行逐步回归,的最终的回归方程如下Y=-6.62764439-0.01604955971X_1+0.797712236X_3+0.2230949155X_4。此方程所的结果与各个农艺性状间的简单相关分析结果相同,证明逐步回归所选的最优方程合理,此外此方程可以作为单株粒重(即产量)的预测方程。
5.株高在61.529~110.14cm的范围内,与单株产量无必然联系,即高杆和矮杆与产量无因果关系
6.研究发现14个品种(系)的5个农艺性状(株高、穗长、有效分蘖、千粒重、单株粒重)的最适N肥和密度组合为20万株/亩×30kg/亩,品质性状的最适N肥密度组合不尽相同,可分为4类即高密高肥、低密高肥、中密高肥和特殊的Q16,可以将不同的基因型的春小麦分开。
7.分析表明依靠不同N肥水平和密度组合中品质性状的最适表现分类结果与品质聚类结果相似,证明了以靠不同N肥水平和密度组合中品质性状的最适表现分类不同基因型小麦的正确性,也说明了品质聚类是进行春小麦品种分类的较好的方法。
8.不同基因型的春小麦对环境反应不同,可以从中筛选出对环境反应最不敏感的品种即东6501,从而实现高产优质并重。
The 10 quality and agricultural characters of the 14 varieties of spring wheat in the different the grads of density and fertility have been comprehensively analyzed by several statistical means .The conclusion was showed as follows:
1. The 5 quality indexes (wet gluten content, GMP, pelshenke velum ,sedimentation, crude protein content) are analyzed, Variances of GMP, wet gluten content ,pelshenke velum, sedimentation are terribly significant; The sensitivity of pelshenke velum is higher than that of other quality characters. The sequence of the sensitivity of the quality characters is pelshenke velum, GMP, wet gluten content, sedimentation, crude protein content.
2. The variance of agricultural characters are terribly significant and the variance of different density is terribly significant, the variance of different fertilizer is terribly significant The The sequence of the sensitivity of the quality characters is plant height, thousand kernel weigh, ear length, available tiller, single plant grain weight
3. Tthe correlativities of wet gluten content, GMP, pelshenke velum ,sedimentation ,crude protein content are terribly significant, and cumulative contribution rate is above 85%.So wet gluten content, GMP, pelshenke velum ,sedimentation ,crude protein content can decide the change of the different quality types of spring wheat.
4. plant height, available tiller, thousand kernel weight, ear length are used to be independent variable and single plant grain weight is Y in order to do step- regress, the equation is :
the equation has been proved by simple correlation on agricultural characters and can be used to prognosticate single plant grain weight.
5. There are not necessary contact between plant length(61.529-110.14cm) and single plant grain weight.
6. Investigation in agricultural and quality characters find that the properest combination of 5 agricultural characters is 200000/mu+30kg/mu.The properest combination of 5 quality characters is different each other .moreover it can detach the different genotypes of spring wheat.
7. Clustering of quality prove that the properest combination of 5 quality characters is validity and Clustering of quality is a good way to sort spring wheat.
8. The reaction of different genotype spring wheat to environment is different, so the most blunt variety can been elected ,ie ,6501 in order to gain high yield and quality at the same time.
Ma Tingchen Crop hybrid breeding Prof. Li Zhuofu
1.所测的14个品种(系)的5个品质性状(GMP、伯尔辛克值、沉降值、粗蛋白含量、湿面筋含量)品种间差异极显著,各品质性状对氮肥、密度的敏感性与大到小依次为伯尔辛克值、GMP、湿面筋含量、沉降值、蛋白质;5个品质性状对对氮肥的敏感性与大到小依次为GMP、粗蛋白含量、湿面筋含量、沉降值、伯尔辛克值。
2.各个农艺性状品种间差异极显著,不同密度间差异显著,不同肥料水平间差异极显著。各农艺性状对氮肥、密度的敏感性从大到小依次为株高、千粒重、穗长、有效分蘖、单株粒重。
3.蛋白质、GMP、湿面筋、伯尔辛克值、沉降值在不同的N肥水平之间呈显著的正相关关系,累计贡献率超过85%,基本可以决定春小麦不同品质类型的变化。
4.以株高、穗长、有效分蘖、千粒重为自变量,以单株粒重为因变量进行逐步回归,的最终的回归方程如下Y=-6.62764439-0.01604955971X_1+0.797712236X_3+0.2230949155X_4。此方程所的结果与各个农艺性状间的简单相关分析结果相同,证明逐步回归所选的最优方程合理,此外此方程可以作为单株粒重(即产量)的预测方程。
5.株高在61.529~110.14cm的范围内,与单株产量无必然联系,即高杆和矮杆与产量无因果关系
6.研究发现14个品种(系)的5个农艺性状(株高、穗长、有效分蘖、千粒重、单株粒重)的最适N肥和密度组合为20万株/亩×30kg/亩,品质性状的最适N肥密度组合不尽相同,可分为4类即高密高肥、低密高肥、中密高肥和特殊的Q16,可以将不同的基因型的春小麦分开。
7.分析表明依靠不同N肥水平和密度组合中品质性状的最适表现分类结果与品质聚类结果相似,证明了以靠不同N肥水平和密度组合中品质性状的最适表现分类不同基因型小麦的正确性,也说明了品质聚类是进行春小麦品种分类的较好的方法。
8.不同基因型的春小麦对环境反应不同,可以从中筛选出对环境反应最不敏感的品种即东6501,从而实现高产优质并重。
The 10 quality and agricultural characters of the 14 varieties of spring wheat in the different the grads of density and fertility have been comprehensively analyzed by several statistical means .The conclusion was showed as follows:
1. The 5 quality indexes (wet gluten content, GMP, pelshenke velum ,sedimentation, crude protein content) are analyzed, Variances of GMP, wet gluten content ,pelshenke velum, sedimentation are terribly significant; The sensitivity of pelshenke velum is higher than that of other quality characters. The sequence of the sensitivity of the quality characters is pelshenke velum, GMP, wet gluten content, sedimentation, crude protein content.
2. The variance of agricultural characters are terribly significant and the variance of different density is terribly significant, the variance of different fertilizer is terribly significant The The sequence of the sensitivity of the quality characters is plant height, thousand kernel weigh, ear length, available tiller, single plant grain weight
3. Tthe correlativities of wet gluten content, GMP, pelshenke velum ,sedimentation ,crude protein content are terribly significant, and cumulative contribution rate is above 85%.So wet gluten content, GMP, pelshenke velum ,sedimentation ,crude protein content can decide the change of the different quality types of spring wheat.
4. plant height, available tiller, thousand kernel weight, ear length are used to be independent variable and single plant grain weight is Y in order to do step- regress, the equation is :
the equation has been proved by simple correlation on agricultural characters and can be used to prognosticate single plant grain weight.
5. There are not necessary contact between plant length(61.529-110.14cm) and single plant grain weight.
6. Investigation in agricultural and quality characters find that the properest combination of 5 agricultural characters is 200000/mu+30kg/mu.The properest combination of 5 quality characters is different each other .moreover it can detach the different genotypes of spring wheat.
7. Clustering of quality prove that the properest combination of 5 quality characters is validity and Clustering of quality is a good way to sort spring wheat.
8. The reaction of different genotype spring wheat to environment is different, so the most blunt variety can been elected ,ie ,6501 in order to gain high yield and quality at the same time.
Ma Tingchen Crop hybrid breeding Prof. Li Zhuofu
引文
1.《中国农业年鉴》编辑委员会.中国农业年鉴,北京,中国农业出版社,1998
2.巴甫洛夫·A·H·禾谷类作物籽粒产量与蛋白质含量的关系,国外农业科技,1980,(12)
3.柏新付.高肥条件下种植密度对小麦产量及其构成因素的影响,烟台师范学院学报(自然科学版) 1997,3:33~16
4.边宽江,姚立会,廖祥儒.小麦品种产量与产量因素通径分析,西北农业学报 1999,8(2):20~21
5.蔡大同、茆泽圣、杨桂芳等.氮肥不同时期施用对优质小麦产量和加工品质的影响,土壤肥料,1994(2):19~21
6.陈得钊.多元数据处理,北京,化学工业出版社,1998
7.成思危.复杂性科学探索,北京,民族与建设出版社,1999
8.程爱华,兰静,王乐凯等.SDS和Zeleny沉降值实验与小麦品质关系,黑龙江农业科学,1997,(3):37~39
9.程国旺,王浩波,戚艺军.氮肥用量对面包小麦品种产量和品质的影响,安徽农业科学,2002.3:31~35
10.程国旺、马传喜.小麦品质性状与我国小麦品质的改良途径,粮油食品科学,1999,7(5):35~38
11.邓天存,贵红,杨光宇.建国五十年来河南省小麦品种农艺性状演变规律及二十一世纪遗传改良方向探讨,麦类作物学报,2001,21(5):51~55
12.杜联盟,李硕碧,肖守胡.小麦品种选育早期品质选择指标的评价,麦类作物,1998,18(6):24~27
13.范濂,崔党群,王福亭等.普通小麦子粒品质性状的遗传分析,河南农业大学学报,1993,27(2):115~119
14.高产小麦吸肥规律研究.Ⅳ 高效施肥期分析,江苏农学院学报,1995(专):125~130
15.郭瑞林,杨春玲,关立等.小麦品种区域试验的同异分析方法研究,麦类作物学报,2001,21(3):60~63
16.郭瑞林.作物灰色育种学,北京,中国农业出版社,
17.何文寿,陈素生,康建宏.不同基因型春小麦氮磷钾养分效率与其农艺性状的相关性研究,干旱地区农业研究,2000,18(3):37~39
18.何中虎,林作楫,王龙俊等.中国小麦品质区划的研究,中国农业科学 2002,35(4):359~364
19.黄婷,马传喜,徐风等.面包小麦高产优质新组合选配的研究,安徽农业科学,2001(3):12~15
20.贾振华.施氮量对产量与蛋白质同步形成的影响.河南职技师院学报,1990,18(3~4):110~116
21.蒋纪云.优质小麦栽培理论与实践.西安:世界图书出版社西安公司,1995.
22.金善宝.中国小麦学,北京,中国农业出版社,1996
23.莱利.J.小麦育种的理论和实践,北京,北京农业出版社,1982
24.李岗,王虎全,谢惠民等.渭北旱地小麦不同产量形态生理指标及调控技术研究.干旱地区农业研究,1997,15(2):15~19.3
25.李金才.品种和播种密度对小麦灌浆特性及产量影响的研究,安徽农业大学学报,1996,23(4):461-465
26.李志西,魏益民,张建国.小麦蛋白质与面团特性和烘焙品质的关系的研究,中国粮油学报,1998,13(3):1~5
27.李卓夫.春小麦性状变异非线形特征育种作用的研究,博士学位论文,2001
28.李宗智.冬小麦若干品质性状遗传及相关研究,作物学报,1990,16(1):1~4
29.李宗智.小麦品质改良进展,农牧情报研究,1988,(7):17~21
30.李宗智.小麦制面包性状的遗传,河北农业大学学报,1981,4(2):175~183
31.李宗智译.伯尔辛克值测定法,全国小麦品质改良研讨班资料选编,1986:125~128
32.林作楫.食品加工与小麦品质改良,北京,中国农业出版社,1994
33.林作楫,王光瑞.我国小麦品质概况和优质品种评选,麦类文摘,1996,16(5):9~10
34.林作楫.小麦育种工作40年回顾,河南农业科学,1999,(2):3~4
35.刘广田,李保云.小麦品质性状的遗传及其遗传改良。农业生物技术学报,2000,8(4):307~314
36.刘广田.我国北方几个主要冬小麦品种品质性状的研究,北京农业科学,1985,(1):13~16
37.刘海刚,贺双.优质小麦品种、密度、肥料三因素联合效应研究,现代化农业 2001,09:18~21
38.刘来福.作物数量遗传学,北京,农业出版社,1984
39.刘明钟,张洪源,周兴根.施肥对小麦籽粒营养品质和产量的影响,江苏农业学报,1987,3(3):31~37
40.卢少源.提高小麦品种高产潜力的早代选择指标研究,中国小麦育种研究进展,1995
41.马学飞,陈素生,刘生祥,等.宁夏引黄灌区春小麦主要性状的演变及高产育种的主攻方向,宁夏农林科技,1988,(6):1~5.
42.苗艳芳、常爱芳、张会民等.氮肥分配比例对小麦产量和群体质量的影响,麦类作物,1999(4);43~45
43.莫惠栋.农业试验设计,上海,上海科学出版社,1992
44.南京农业大学.田间试验与设计,北京,农业出版社,1992
45.秦武发、李宗智.氮素供应对小麦品质的影响Ⅱ供氮方式,河北农业大学学报,1989(4):21~27
46.商业部四川粮食贮藏科学研究所谷化室营养组.我国主要产麦区小麦品种的烘焙品质和蒸煮,1986
47.盛志廉,陈瑶生 北京 科技出版社 1999
48.宋建荣.山区小麦主要品质性状与产量性状早代选择效果研究,麦类作物学报,2001,21(5):68~73
49.宋哲民,李维平,闵东红,等.小麦性状的遗传参数与综合选择.西北农业大学学报,1996,24(1):23~27.
50.孙辉,李保云,刘广田.普通小麦谷蛋白亚基与烘烤品质的关系.中国农业大学学报,2000,5:18~24
51.孙辉,李保云,朱金宝等.小麦高低分子量谷蛋白亚基单向一步分离法新探.中国农业大学学报,1998,3(增刊):19~23
52.孙辉,姚大年,李保云等.普通小麦谷蛋白大聚合体含量与烘焙品质的相关关系,中国粮油学报,1998,13(6):13~16
53.孙辉,姚大年,李保云等.小麦谷蛋白大聚合体含量的影响因素,麦类作物学报,2000,20(2):23~27
54.孙辉.小麦谷蛋白亚基、GMP含量与小麦品质的关系及Glu-Dly位点的基因多态性研究,博士论文,1998
55.唐启义,冯明光.实用统计分析及计算机处理平台,北京,科学出版社,2002
56.田纪春.超级小麦及其育种方法,麦类作物学报,2002,22(1):87~90
57.万富世,王光瑞,李宗智.我国小麦品质的现状及改良目标初探,中国农业科学,1989,22(3):14~21
58.汪芝寿,曹承富,孔令聪.安徽省淮北地区优质小麦优质高产栽培技术,安徽农学通报,1999,5(4):16~18
59.王光瑞.小麦主要品质性状之间及其与产量知道关系的研究,中国农科院年报,1985:148~153
60.王金水.小麦谷蛋白与面包品质之间的关系,郑州粮食学院,1997,18(2):51~57
61.王娟玲,王玉平等.模糊聚类分析在小麦亲本材料分类上的应用,山西农业科学,1997,25(1):7~9
62.王龙俊,陈荣振,朱新开等.江苏省小麦品质区划研究初报,江苏农业科学,2002,2:15~18
63.王秋杰、寇长林、王兴仁等.冬小麦氮肥经济效益与施肥期结构的研究,干旱地区农业研究,1999,17(1):29~34
64.王绍忠,等.小麦品质生态及品质区划研究,河南农业科学,1995,(10):3~11
65.王旭清、王法宏.栽培措施和环境条件对小麦籽粒品质的影响,山东农业科学,1999(1):52~55
66.王燕,李宗智,张彩英等.全国小麦品质检测报告,河北农业大学学报,1995,18(1):1~9
67.王月福,于振文,李尚霞。施氮量对小麦籽粒蛋白质组分含量及加工品质的影响,中国农业科学,2002,35(9):1071-1078
68.王岳光,刘广田,等.杂交模式对小麦性状遗传和变异的影响.中国农业大学学报,1997,2(1):19~24
69.王岳光,刘广田,等.杂交模式对小麦性状遗传和变异的影响.中国农业大学学报,1997,2(3):1~4
70.魏益民,李志西,王天宏等.小麦子粒蛋白质组分与面包烘焙品质关系的研究,中国粮油学报,1999,14(1):1~5
71.魏益民.小麦品质与加工[M].西安:西安世界地图出版公司,1995.
72.吴兆苏.小麦超高产育种展望,作物学报 1990
73.吴兆苏.小麦育种学,北京,农业出版社,1990
74.西北农学院.作物育种学,北京,农业出版社,1981
75.邢先贵、朱旭彤.优质小麦品种在不同栽培条件下的产量和品质表现,华中农业大学学报,1996,15(2):117~122
76.徐兆飞,张惠叶,张定一.小麦品质及其改良,气象出版社,2000
77.徐自成,赵友梅.小麦粉面包烘烤品质指标典型相关分析,华北农学报,1991,6(2):118~121
78.扬足君,舒焕麟,李光蓉.向小麦中到入优良谷蛋白亚基的研究,西南农业学报,2001,21(1):10~18
79.杨学举,张树华,常文镇.中国麦制的食品食用需求趋势及相应对策,麦类作物,1999,19(5):10~12
80.杨学举,周进宝,万永红.优质小麦品质性状的环境变异研究,麦类作物学报,2000,20(3):21~24
81.于秀林,任雪松.多元统计分析,北京,中国统计出版社,1999
82.袁志发,孟德顺编著.多元统计分析.陕西杨陵:天则出版社,1991.3
83.张保军,等.小麦籽粒品质及其影响因素分析[J].国外农学-麦类作物,1995,(4):29~31.
84.张彩英,常文锁,谢令琴等.小麦高代新品系的聚类分析,麦类作物学报,2001,21(5):31~34
85.张国泰,等.小麦籽粒蛋白质含量的变异.中国小麦生态[M].北京:科学出版社,1991.
86.张鸿程.我国小麦优质生产与加工转化之路,江苏农业科学,2000(5):2~7
87.张亚军,许宏军,常秋红等。氮钾配比对小麦氮素利用率及品质的影响,安徽农业科学,2002.5:24~27
88.张忠军,张树楱.对小麦形态性状之间多元关系的分析,北京农业大学学报,1986,12)(4):379~384
89.赵广才,刘利华,杨玉双.高产小麦不同密度及肥料运筹的综合效应,北京农业科学,1997,2:25~29
90.赵广才.不同肥料运筹对冬小麦产量和品质的影响[J].北京农业科学,1991,(9):24~29,27.
91.赵会贤,胡胜武,吉万全等.麦谷蛋白GLU-1和GLU-3位点基因等位变异对小麦籽粒聚合体蛋白粒度分布的影响,中国农业科学 1998,31(1):13~16
92.赵振东,董进英,刘建军.沉降试验在小麦品质育种中的应用,山东农业科学,1995,(2):13~16
93.周青文,万平.麦胚乳贮藏白组分遗传研究进展,麦类作物学报,2000,20(2):78~83
94.朱金宝,刘广田,等.基因型和环境对小麦烘烤品质的影响.中国农业科学,1995,21(6):679~684
95.朱金宝,刘广田,张树榛.小麦子粒高低分子量谷蛋白亚基及其与品质关系的研究,中国农业科学,1996,29(1):34~39
96.朱金宝。普通小麦品质性状遗传、环境互作及其与高低分子量谷蛋白亚基的关系:[博士学位论文].北京农业大学,1993
97.庄巧生,杜振华等.中国小麦遗传育种进展,北京,中国农业出版社,1996,135~140
98.左联中,任杰成,杨文龙等.模糊聚类分析在小麦品种鉴定中的应用,山西农业科学,1998,26(4):12~15
99. Anderson OD, Lilts JC, Greene FC. The~gliadin gene family. 1. Characterization of ten new ~gliadin genomic clones, evidence for limited sequence conservation of flanking DNA, and Southern analysis of the gene family. Theor Appl Gene, 1997, 95:50~58
100. Axford D W E, McDermott E E, Redman D G. Note on the sodium dodecyl sulfate test of bread~making quality: comparison with Pelschenke and Zeleny tests. Cereal Chem, 1979, 56: 582~584
101. Buonocour F, Hickman DR, Caporale C, et al. Characterisation of a noval high Mr glutenin subunit encoded by chromosome 1D of bread wheat. J Cereal Sci, 1996, 23: 55~60
102. BenzianB, etal. Proteinconcentrationofgraininrelationtosomeweatherandsoil factorsduring17yearsofEnglishwinter-wheatexperiment. J. Sci. FoodAgric, 1986(37): 435-444.
103. Forde J, Malpica JM, Halford NG, et al. The nucleotide sequence of a HMW glutenin subunit gene located on chromo some 1A of wheat(Triticum aestivum L). Nucleic Acids Res, 1985, 13:6817~6832
104. Halford N G, Field J M, Blair H, et al. Analysis of HMW glutenin subunitsen coded by chromosome 1A of bread wheat(Triticum aestivum L. ) indicates quantitative effects on grain quality. Thero Appl Genet, 1992, 83:373~378
105. Huang D Y, Khan K. Quantitative determination of high molecular weight glutenin subunit of hard red spring wheat by SDS~PAGE: Ⅱ. Quantitative effects of toral amounts on bread making quality characteristics. Cereal Chem, 1997, 76:781~785
106. Jackson E A, Holt L M, Payne P E. Characterization of high molecular weight gliadin and low~molecular~weight glutenin subunits of wheat endosperm by two~ dimensional electrophoresis and the chromosomal location of their controlling genes. Theor Appl Genet, 1983,66:29~37
107. Lawrence G J, MacRitchie F, Wrigly C W. Dough and baking quality of wheat lines deficient in glutenin subunits controlled by the Glu~A1, Glu~B1 and Glu~D1 loci. J Cereal Sci, 1988, 7:109~112
108. Lawrence G J, Payne P I. Detection by gel electrophoresis of oligomers formed by the association of high~molecular~weight glutenin protein subunits of wheat endosperm. J Experimental Botany, 1983 , 34:254~267
109. Lorenzo A, Kronstad W E, Vieira L G E. Relationships between high mol ecular weight glutenin subunits and loaf volume in wheat as measured by the sodium dode cyl sulfate sedimentation test. Crop Sci, 1987,27:253~257
110. Lorenzo A, Kronstad WE and Vieira LGE. Relationship between high molecular weight glutenin subunits and loaf volume in wheat as measured by the sodium Dodecy Sulphate Sedimentation Test. Crop Sci, 1987, 27:253~257
111. McCormick KM, PanozzoJF, et al. A swelling power test for selecting potential noodle quality wheat. Australia, J Agric Res, 1994, 42:317~323
112. Payne P I, Law C N, Mudd E E. Control by homologous group 1 chromosomes of the high~molecular~weight subunits of glutenin, a major protein of wheat endospe rm. Theor Appl Genet, 1980,58:113~120
113. Payne P I. Genetics of wheat storage protein and the effect of allelic variation in bread making quality. Ann Rev Plant Physiol, 1987,38:141~153
114. Payne PI, Corfield KG. Subunit composition of wheat glutenin proteins isolated by gel filtration in a dissociating medium. Planta, 1979, 145:83~88
115. Payne PI, Holt LM, Krattiger AF, et al. Relationships between seed quality and HMW glutenin subunit composition determined using wheats grown in Spain. J Cereal Sci, 1988, 7:229~235
116. Popineu Y, cornec M Lefebvre J, et al. Influence of high glutenin subunits on glutenin polymers and rheological properties of near~isogenic lines of wheat sicco. Cereal Sci, 1994, 19:231~241
117. Rogers WJ, Payne PI, Harindes K. The HMW glutenin subunit and gliandin composition of German~grown wheat varieties and their relationship with bread~making quality. Plant Breeding, 1989, 103:89~100
118. Shewry PR, Tatham AS. Disulphide bonds in wheat gluten proteins. J Cereal Sci, 1997, 25:207~227
119. Weegels P L, Hamer R J, Schofield J D. Functional properties of wheat glutenin. J Cereal Sci, 1996,23:1~18
120. Yamamori M, Nakamura T, Kuroda A. Variations in the content of starch~guanule bound protein among several Japanese cultivars of common wheat(Triticum aestivum L.).Euphytica, 1992, 643:215~219
121. Shewry, Peter R, Tatham Arthur S, and Lazzeri Paul, Biothechnology of Wheat quality. J. Sci. Food. Agric. 1997(73):397-406
122. Kota A, Matsuda T, Matsudomi M, and Kobayashi K, 1984, Determination of protein hydrophobicity using a sodium dodecyl sulfate binding method. J. Agr. Food Chem. 32:284
123. Gianibelli, M.C.,Larroque, O. R.,Macritchie, F.,and Wrigley, C.W.,2001, Biochemical, Genetic, and Molecular Characterization of Wheat Glutenin and Its Component Subunits, Cereal Chem. 78 (6): 635~646
124. Khatkar, B.S., Fido, R.J., Tatham, A.S.,and Schofield, J.D., Functional properties of wheat gliadins. ⅡEffects on dynamic rheological properties of wheat gluten. Journal of cereal science 2002(35): 307~313
125. Amin C. Kapoor and Robert E. Heiner, Biochemical changes in developing wheat grains, changes in nitrogen fractions, amino acids and nutritional quality. J. Sci Food Agric. 1982, 33,35~40
126. Kàroly Kobrehel and Rémi Alary, The role of a low molecular weight glutenin fraction in the cooking quality of durum wheat pasta. J. Sci Food Agric. 1989, 47, 487~500
127. Singh, H, and Macritchie, F., Application of polymer science to properties of gluten. Journal of cereal science 2001 (33): 231~343
128. Gianibelli, M.C., Masci, S., Larroque, O.R., Lafiandra, D.,and Macritchie, F., 2002, Biochemical characterization of a novel polymeric protein subunit from bread wheat. Journal oF cereal science 35:265~276
129. Carceller, J. L. and T. Aussenac, 2001, Size characterization of glutenin polymers by HPSEC-MALLS. Journal oF cereal science 33:131~142
130. Bean, S. R., Lyne, R. K, K.A. Tilley, O.K. Chung, and G. L. Laookhart, 1998, A rapid method for quantitation of insoluble polymeric proteins in flour. Cereal chem. 75(3): 374~379
2.巴甫洛夫·A·H·禾谷类作物籽粒产量与蛋白质含量的关系,国外农业科技,1980,(12)
3.柏新付.高肥条件下种植密度对小麦产量及其构成因素的影响,烟台师范学院学报(自然科学版) 1997,3:33~16
4.边宽江,姚立会,廖祥儒.小麦品种产量与产量因素通径分析,西北农业学报 1999,8(2):20~21
5.蔡大同、茆泽圣、杨桂芳等.氮肥不同时期施用对优质小麦产量和加工品质的影响,土壤肥料,1994(2):19~21
6.陈得钊.多元数据处理,北京,化学工业出版社,1998
7.成思危.复杂性科学探索,北京,民族与建设出版社,1999
8.程爱华,兰静,王乐凯等.SDS和Zeleny沉降值实验与小麦品质关系,黑龙江农业科学,1997,(3):37~39
9.程国旺,王浩波,戚艺军.氮肥用量对面包小麦品种产量和品质的影响,安徽农业科学,2002.3:31~35
10.程国旺、马传喜.小麦品质性状与我国小麦品质的改良途径,粮油食品科学,1999,7(5):35~38
11.邓天存,贵红,杨光宇.建国五十年来河南省小麦品种农艺性状演变规律及二十一世纪遗传改良方向探讨,麦类作物学报,2001,21(5):51~55
12.杜联盟,李硕碧,肖守胡.小麦品种选育早期品质选择指标的评价,麦类作物,1998,18(6):24~27
13.范濂,崔党群,王福亭等.普通小麦子粒品质性状的遗传分析,河南农业大学学报,1993,27(2):115~119
14.高产小麦吸肥规律研究.Ⅳ 高效施肥期分析,江苏农学院学报,1995(专):125~130
15.郭瑞林,杨春玲,关立等.小麦品种区域试验的同异分析方法研究,麦类作物学报,2001,21(3):60~63
16.郭瑞林.作物灰色育种学,北京,中国农业出版社,
17.何文寿,陈素生,康建宏.不同基因型春小麦氮磷钾养分效率与其农艺性状的相关性研究,干旱地区农业研究,2000,18(3):37~39
18.何中虎,林作楫,王龙俊等.中国小麦品质区划的研究,中国农业科学 2002,35(4):359~364
19.黄婷,马传喜,徐风等.面包小麦高产优质新组合选配的研究,安徽农业科学,2001(3):12~15
20.贾振华.施氮量对产量与蛋白质同步形成的影响.河南职技师院学报,1990,18(3~4):110~116
21.蒋纪云.优质小麦栽培理论与实践.西安:世界图书出版社西安公司,1995.
22.金善宝.中国小麦学,北京,中国农业出版社,1996
23.莱利.J.小麦育种的理论和实践,北京,北京农业出版社,1982
24.李岗,王虎全,谢惠民等.渭北旱地小麦不同产量形态生理指标及调控技术研究.干旱地区农业研究,1997,15(2):15~19.3
25.李金才.品种和播种密度对小麦灌浆特性及产量影响的研究,安徽农业大学学报,1996,23(4):461-465
26.李志西,魏益民,张建国.小麦蛋白质与面团特性和烘焙品质的关系的研究,中国粮油学报,1998,13(3):1~5
27.李卓夫.春小麦性状变异非线形特征育种作用的研究,博士学位论文,2001
28.李宗智.冬小麦若干品质性状遗传及相关研究,作物学报,1990,16(1):1~4
29.李宗智.小麦品质改良进展,农牧情报研究,1988,(7):17~21
30.李宗智.小麦制面包性状的遗传,河北农业大学学报,1981,4(2):175~183
31.李宗智译.伯尔辛克值测定法,全国小麦品质改良研讨班资料选编,1986:125~128
32.林作楫.食品加工与小麦品质改良,北京,中国农业出版社,1994
33.林作楫,王光瑞.我国小麦品质概况和优质品种评选,麦类文摘,1996,16(5):9~10
34.林作楫.小麦育种工作40年回顾,河南农业科学,1999,(2):3~4
35.刘广田,李保云.小麦品质性状的遗传及其遗传改良。农业生物技术学报,2000,8(4):307~314
36.刘广田.我国北方几个主要冬小麦品种品质性状的研究,北京农业科学,1985,(1):13~16
37.刘海刚,贺双.优质小麦品种、密度、肥料三因素联合效应研究,现代化农业 2001,09:18~21
38.刘来福.作物数量遗传学,北京,农业出版社,1984
39.刘明钟,张洪源,周兴根.施肥对小麦籽粒营养品质和产量的影响,江苏农业学报,1987,3(3):31~37
40.卢少源.提高小麦品种高产潜力的早代选择指标研究,中国小麦育种研究进展,1995
41.马学飞,陈素生,刘生祥,等.宁夏引黄灌区春小麦主要性状的演变及高产育种的主攻方向,宁夏农林科技,1988,(6):1~5.
42.苗艳芳、常爱芳、张会民等.氮肥分配比例对小麦产量和群体质量的影响,麦类作物,1999(4);43~45
43.莫惠栋.农业试验设计,上海,上海科学出版社,1992
44.南京农业大学.田间试验与设计,北京,农业出版社,1992
45.秦武发、李宗智.氮素供应对小麦品质的影响Ⅱ供氮方式,河北农业大学学报,1989(4):21~27
46.商业部四川粮食贮藏科学研究所谷化室营养组.我国主要产麦区小麦品种的烘焙品质和蒸煮,1986
47.盛志廉,陈瑶生 北京 科技出版社 1999
48.宋建荣.山区小麦主要品质性状与产量性状早代选择效果研究,麦类作物学报,2001,21(5):68~73
49.宋哲民,李维平,闵东红,等.小麦性状的遗传参数与综合选择.西北农业大学学报,1996,24(1):23~27.
50.孙辉,李保云,刘广田.普通小麦谷蛋白亚基与烘烤品质的关系.中国农业大学学报,2000,5:18~24
51.孙辉,李保云,朱金宝等.小麦高低分子量谷蛋白亚基单向一步分离法新探.中国农业大学学报,1998,3(增刊):19~23
52.孙辉,姚大年,李保云等.普通小麦谷蛋白大聚合体含量与烘焙品质的相关关系,中国粮油学报,1998,13(6):13~16
53.孙辉,姚大年,李保云等.小麦谷蛋白大聚合体含量的影响因素,麦类作物学报,2000,20(2):23~27
54.孙辉.小麦谷蛋白亚基、GMP含量与小麦品质的关系及Glu-Dly位点的基因多态性研究,博士论文,1998
55.唐启义,冯明光.实用统计分析及计算机处理平台,北京,科学出版社,2002
56.田纪春.超级小麦及其育种方法,麦类作物学报,2002,22(1):87~90
57.万富世,王光瑞,李宗智.我国小麦品质的现状及改良目标初探,中国农业科学,1989,22(3):14~21
58.汪芝寿,曹承富,孔令聪.安徽省淮北地区优质小麦优质高产栽培技术,安徽农学通报,1999,5(4):16~18
59.王光瑞.小麦主要品质性状之间及其与产量知道关系的研究,中国农科院年报,1985:148~153
60.王金水.小麦谷蛋白与面包品质之间的关系,郑州粮食学院,1997,18(2):51~57
61.王娟玲,王玉平等.模糊聚类分析在小麦亲本材料分类上的应用,山西农业科学,1997,25(1):7~9
62.王龙俊,陈荣振,朱新开等.江苏省小麦品质区划研究初报,江苏农业科学,2002,2:15~18
63.王秋杰、寇长林、王兴仁等.冬小麦氮肥经济效益与施肥期结构的研究,干旱地区农业研究,1999,17(1):29~34
64.王绍忠,等.小麦品质生态及品质区划研究,河南农业科学,1995,(10):3~11
65.王旭清、王法宏.栽培措施和环境条件对小麦籽粒品质的影响,山东农业科学,1999(1):52~55
66.王燕,李宗智,张彩英等.全国小麦品质检测报告,河北农业大学学报,1995,18(1):1~9
67.王月福,于振文,李尚霞。施氮量对小麦籽粒蛋白质组分含量及加工品质的影响,中国农业科学,2002,35(9):1071-1078
68.王岳光,刘广田,等.杂交模式对小麦性状遗传和变异的影响.中国农业大学学报,1997,2(1):19~24
69.王岳光,刘广田,等.杂交模式对小麦性状遗传和变异的影响.中国农业大学学报,1997,2(3):1~4
70.魏益民,李志西,王天宏等.小麦子粒蛋白质组分与面包烘焙品质关系的研究,中国粮油学报,1999,14(1):1~5
71.魏益民.小麦品质与加工[M].西安:西安世界地图出版公司,1995.
72.吴兆苏.小麦超高产育种展望,作物学报 1990
73.吴兆苏.小麦育种学,北京,农业出版社,1990
74.西北农学院.作物育种学,北京,农业出版社,1981
75.邢先贵、朱旭彤.优质小麦品种在不同栽培条件下的产量和品质表现,华中农业大学学报,1996,15(2):117~122
76.徐兆飞,张惠叶,张定一.小麦品质及其改良,气象出版社,2000
77.徐自成,赵友梅.小麦粉面包烘烤品质指标典型相关分析,华北农学报,1991,6(2):118~121
78.扬足君,舒焕麟,李光蓉.向小麦中到入优良谷蛋白亚基的研究,西南农业学报,2001,21(1):10~18
79.杨学举,张树华,常文镇.中国麦制的食品食用需求趋势及相应对策,麦类作物,1999,19(5):10~12
80.杨学举,周进宝,万永红.优质小麦品质性状的环境变异研究,麦类作物学报,2000,20(3):21~24
81.于秀林,任雪松.多元统计分析,北京,中国统计出版社,1999
82.袁志发,孟德顺编著.多元统计分析.陕西杨陵:天则出版社,1991.3
83.张保军,等.小麦籽粒品质及其影响因素分析[J].国外农学-麦类作物,1995,(4):29~31.
84.张彩英,常文锁,谢令琴等.小麦高代新品系的聚类分析,麦类作物学报,2001,21(5):31~34
85.张国泰,等.小麦籽粒蛋白质含量的变异.中国小麦生态[M].北京:科学出版社,1991.
86.张鸿程.我国小麦优质生产与加工转化之路,江苏农业科学,2000(5):2~7
87.张亚军,许宏军,常秋红等。氮钾配比对小麦氮素利用率及品质的影响,安徽农业科学,2002.5:24~27
88.张忠军,张树楱.对小麦形态性状之间多元关系的分析,北京农业大学学报,1986,12)(4):379~384
89.赵广才,刘利华,杨玉双.高产小麦不同密度及肥料运筹的综合效应,北京农业科学,1997,2:25~29
90.赵广才.不同肥料运筹对冬小麦产量和品质的影响[J].北京农业科学,1991,(9):24~29,27.
91.赵会贤,胡胜武,吉万全等.麦谷蛋白GLU-1和GLU-3位点基因等位变异对小麦籽粒聚合体蛋白粒度分布的影响,中国农业科学 1998,31(1):13~16
92.赵振东,董进英,刘建军.沉降试验在小麦品质育种中的应用,山东农业科学,1995,(2):13~16
93.周青文,万平.麦胚乳贮藏白组分遗传研究进展,麦类作物学报,2000,20(2):78~83
94.朱金宝,刘广田,等.基因型和环境对小麦烘烤品质的影响.中国农业科学,1995,21(6):679~684
95.朱金宝,刘广田,张树榛.小麦子粒高低分子量谷蛋白亚基及其与品质关系的研究,中国农业科学,1996,29(1):34~39
96.朱金宝。普通小麦品质性状遗传、环境互作及其与高低分子量谷蛋白亚基的关系:[博士学位论文].北京农业大学,1993
97.庄巧生,杜振华等.中国小麦遗传育种进展,北京,中国农业出版社,1996,135~140
98.左联中,任杰成,杨文龙等.模糊聚类分析在小麦品种鉴定中的应用,山西农业科学,1998,26(4):12~15
99. Anderson OD, Lilts JC, Greene FC. The~gliadin gene family. 1. Characterization of ten new ~gliadin genomic clones, evidence for limited sequence conservation of flanking DNA, and Southern analysis of the gene family. Theor Appl Gene, 1997, 95:50~58
100. Axford D W E, McDermott E E, Redman D G. Note on the sodium dodecyl sulfate test of bread~making quality: comparison with Pelschenke and Zeleny tests. Cereal Chem, 1979, 56: 582~584
101. Buonocour F, Hickman DR, Caporale C, et al. Characterisation of a noval high Mr glutenin subunit encoded by chromosome 1D of bread wheat. J Cereal Sci, 1996, 23: 55~60
102. BenzianB, etal. Proteinconcentrationofgraininrelationtosomeweatherandsoil factorsduring17yearsofEnglishwinter-wheatexperiment. J. Sci. FoodAgric, 1986(37): 435-444.
103. Forde J, Malpica JM, Halford NG, et al. The nucleotide sequence of a HMW glutenin subunit gene located on chromo some 1A of wheat(Triticum aestivum L). Nucleic Acids Res, 1985, 13:6817~6832
104. Halford N G, Field J M, Blair H, et al. Analysis of HMW glutenin subunitsen coded by chromosome 1A of bread wheat(Triticum aestivum L. ) indicates quantitative effects on grain quality. Thero Appl Genet, 1992, 83:373~378
105. Huang D Y, Khan K. Quantitative determination of high molecular weight glutenin subunit of hard red spring wheat by SDS~PAGE: Ⅱ. Quantitative effects of toral amounts on bread making quality characteristics. Cereal Chem, 1997, 76:781~785
106. Jackson E A, Holt L M, Payne P E. Characterization of high molecular weight gliadin and low~molecular~weight glutenin subunits of wheat endosperm by two~ dimensional electrophoresis and the chromosomal location of their controlling genes. Theor Appl Genet, 1983,66:29~37
107. Lawrence G J, MacRitchie F, Wrigly C W. Dough and baking quality of wheat lines deficient in glutenin subunits controlled by the Glu~A1, Glu~B1 and Glu~D1 loci. J Cereal Sci, 1988, 7:109~112
108. Lawrence G J, Payne P I. Detection by gel electrophoresis of oligomers formed by the association of high~molecular~weight glutenin protein subunits of wheat endosperm. J Experimental Botany, 1983 , 34:254~267
109. Lorenzo A, Kronstad W E, Vieira L G E. Relationships between high mol ecular weight glutenin subunits and loaf volume in wheat as measured by the sodium dode cyl sulfate sedimentation test. Crop Sci, 1987,27:253~257
110. Lorenzo A, Kronstad WE and Vieira LGE. Relationship between high molecular weight glutenin subunits and loaf volume in wheat as measured by the sodium Dodecy Sulphate Sedimentation Test. Crop Sci, 1987, 27:253~257
111. McCormick KM, PanozzoJF, et al. A swelling power test for selecting potential noodle quality wheat. Australia, J Agric Res, 1994, 42:317~323
112. Payne P I, Law C N, Mudd E E. Control by homologous group 1 chromosomes of the high~molecular~weight subunits of glutenin, a major protein of wheat endospe rm. Theor Appl Genet, 1980,58:113~120
113. Payne P I. Genetics of wheat storage protein and the effect of allelic variation in bread making quality. Ann Rev Plant Physiol, 1987,38:141~153
114. Payne PI, Corfield KG. Subunit composition of wheat glutenin proteins isolated by gel filtration in a dissociating medium. Planta, 1979, 145:83~88
115. Payne PI, Holt LM, Krattiger AF, et al. Relationships between seed quality and HMW glutenin subunit composition determined using wheats grown in Spain. J Cereal Sci, 1988, 7:229~235
116. Popineu Y, cornec M Lefebvre J, et al. Influence of high glutenin subunits on glutenin polymers and rheological properties of near~isogenic lines of wheat sicco. Cereal Sci, 1994, 19:231~241
117. Rogers WJ, Payne PI, Harindes K. The HMW glutenin subunit and gliandin composition of German~grown wheat varieties and their relationship with bread~making quality. Plant Breeding, 1989, 103:89~100
118. Shewry PR, Tatham AS. Disulphide bonds in wheat gluten proteins. J Cereal Sci, 1997, 25:207~227
119. Weegels P L, Hamer R J, Schofield J D. Functional properties of wheat glutenin. J Cereal Sci, 1996,23:1~18
120. Yamamori M, Nakamura T, Kuroda A. Variations in the content of starch~guanule bound protein among several Japanese cultivars of common wheat(Triticum aestivum L.).Euphytica, 1992, 643:215~219
121. Shewry, Peter R, Tatham Arthur S, and Lazzeri Paul, Biothechnology of Wheat quality. J. Sci. Food. Agric. 1997(73):397-406
122. Kota A, Matsuda T, Matsudomi M, and Kobayashi K, 1984, Determination of protein hydrophobicity using a sodium dodecyl sulfate binding method. J. Agr. Food Chem. 32:284
123. Gianibelli, M.C.,Larroque, O. R.,Macritchie, F.,and Wrigley, C.W.,2001, Biochemical, Genetic, and Molecular Characterization of Wheat Glutenin and Its Component Subunits, Cereal Chem. 78 (6): 635~646
124. Khatkar, B.S., Fido, R.J., Tatham, A.S.,and Schofield, J.D., Functional properties of wheat gliadins. ⅡEffects on dynamic rheological properties of wheat gluten. Journal of cereal science 2002(35): 307~313
125. Amin C. Kapoor and Robert E. Heiner, Biochemical changes in developing wheat grains, changes in nitrogen fractions, amino acids and nutritional quality. J. Sci Food Agric. 1982, 33,35~40
126. Kàroly Kobrehel and Rémi Alary, The role of a low molecular weight glutenin fraction in the cooking quality of durum wheat pasta. J. Sci Food Agric. 1989, 47, 487~500
127. Singh, H, and Macritchie, F., Application of polymer science to properties of gluten. Journal of cereal science 2001 (33): 231~343
128. Gianibelli, M.C., Masci, S., Larroque, O.R., Lafiandra, D.,and Macritchie, F., 2002, Biochemical characterization of a novel polymeric protein subunit from bread wheat. Journal oF cereal science 35:265~276
129. Carceller, J. L. and T. Aussenac, 2001, Size characterization of glutenin polymers by HPSEC-MALLS. Journal oF cereal science 33:131~142
130. Bean, S. R., Lyne, R. K, K.A. Tilley, O.K. Chung, and G. L. Laookhart, 1998, A rapid method for quantitation of insoluble polymeric proteins in flour. Cereal chem. 75(3): 374~379