摘要
质核互作雄性不育性在农作物杂种优势利用中起着重要作用,揭示质核互作雄性不育性的机理具有重要的理论和实际意义,关于植物雄性不育的蛋白质组学研究的报道不多,尤其在大豆上尚未见到相关报道。本文对大豆质核互作雄性不育系NJCMS1A和NJCMS2A与其对应保持系NJCMS1B和NJCMS2B的不同器官的蛋白质组差异进行比较研究,获得如下结果:
1.利用蛋白质组技术分析大豆质核互作雄性不育系NJCMS1A和NJCMS2A与其对应保持系NJCMS1B和NJCMS2B的不同器官的蛋白质组差异,结果发现不育系与保持系的花药间差异表达蛋白较多,种子间仅有少量的差异表达蛋白,而叶片间2-DE图谱基本一致,几乎没有差异,说明蛋白表达具有时空性。
2.运用MALDI-TOF-MS质谱技术鉴定不育系NJCMS1A与其保持系NJCMS1B的花药中差异表达蛋白,单核小孢子期花药中鉴定出7个差异表达蛋白,二胞花粉期花药中鉴定出16个差异表达蛋白,对主要差异蛋白包括ACC氧化酶、ACC合成酶、半胱氨酸蛋白酶、V型H~+-ATP酶A亚基、MADS盒蛋白、淀粉分枝酶和UDP-葡萄糖焦磷酸化酶等进行功能分析,推测不育系NJCMS1A雄性不育性可能与能量代谢紊乱、细胞程序化死亡(PCD)、乙烯过度产生、淀粉合成受抑制和花器官发育调节基因作用失控等有关。
3.运用MALDI-TOF-MS质谱技术分析不育系NJCMS2A与其保持系NJCMS2B的花药中差异表达蛋白,单核小孢子期花药中鉴定出4个差异表达蛋白,二胞花粉期花药中鉴定出14个差异表达蛋白,对主要差异蛋白如热激蛋白22 kD、半胱氨酸蛋白酶、V型H~+-ATP酶A亚基、MADS盒蛋白和淀粉分枝酶等进行功能分析,推测不育系NJCMS2A雄性不育性可能与能量代谢紊乱、细胞程序化死亡(PCD)、淀粉合成受抑制和花器官发育调节基因作用失控等有关。
4.分析发现在不育系NJCMS1A和NJCMS2A的单核小孢子期和二胞花粉期花药中均缺失而在保持系NJCMS1B和NJCMS2B中均出现的蛋白有MADS盒蛋白和淀粉分枝酶;在不育系NJCMS1A和NJCMS2A的二胞花粉期花药中均出现而在保持系NJCMS1B和NJCMS2B中均缺失的蛋白有半胱胺酸蛋白酶、V型H~+-ATP酶A亚基、腺苷酸脱氨酶、拟南芥1号染色体基因组编码蛋白、寡尿苷酸结合酶、Cullin、β-香树素合成酶和Hypothetical protein MtrDRAFT_AC146570g8v1。这些蛋白可能对育性的影响比较稳定,建议在以后的研究中,选择上述蛋白进行基因克隆,以进一步确定其功能。
Cytoplasmic-nuclear male sterility is a mojor tool in the hybrid seed production for utilization of heterosis in crops. The knowledge of the mechanism of the cytoplasmic-nuclear male-sterility is essential to hybrid seed production. Few studies have been done on the proteomics of the male sterility in crops, especially no relevant paper has been reported in soybean so far. The soybean cytoplasmic-nuclear male-sterile lines NJCMS1A and NJCMS2A were developed through consecutive backcross procedures in the National Center for Soybean Improvement, Nanjing Agricultural University. The present paper was aimed at the differential proteomic studies of the different organs between NJCMS1A, NJCMS2A and their maintainers NJCMSIB, NJCMS2B respectively. The results were as follows:
1.The proteomic approach was used to detect the differentially expressed proteins of the different organs between the male-sterile lines NJCMS 1 A, NJCMS2A and their maintainers NJCMS IB, NJCMS2B respectively. The results showed that the differences were investigated on the 2-DE maps of anthers and seeds, but not found on those of leaves between NJCMS1A, NJCMS2A and NJCMS1B, NJCMS2B respectively. The above results showed that the expression of the proteins related to the male sterility were spacially and periodly.
2.The matrix-assisted laser-adsorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) technique was used to obtain the peptide mass fingerprinting of the differentially expressed proteins in anthers between NJCMS1A and NJCMS1B. In the anthers at uninucleate microspore stage, 7 differentially expressed protein spots were identified. In the anthers at binucleate pollen stage, 16 differentially expressed protein spots were identified. According to the literature, the functions, especially those related to the male sterility of the major differentially expressed proteins, including 1-aminocyclopropane-1-carboxylate oxidase (ACC oxidase), ACC synthase 2, cysteine proteinase, vacuolar H~+-ATPase A subunit, MADS box protein, starch branching enzyme, and UDP-glucose pyrophosphorylase etc. were reviewed and discussed. It was inferred that the male sterility of NJCMS1A might be related to energy metabolism turbulence, the programmed cell death (PCD), ethylene excessive synthesis, starch synthesis suffocation and the abnormal function of the flower developmental gene.
3.The matrix-assisted laser-adsorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) technique was used to obtain the peptide mass fingerprinting of the differentially expressed proteins in anthers between NJCMS2A and NJCMS2B. In the anthers at uninucleate microspore stage, 4 differentially expressed protein spots were identified. In the anthers at binucleate pollen stage, 14 differentially expressed protein spots were identified. According to the literature, the functions, especially those related to the male sterility of the major differentially expressed proteins, including Heat shock 22 kDa protein, cysteine proteinase, vacuolar H+-ATPase A subunit, MADS box protein, and starch branching enzyme were reviewed and discussed. It was inferred that the male sterility of NJCMS2A might be related to energy metabolism turbulence, the programmed cell death (PCD), starch synthesis suffocation and the abnormal function of the flower developmental gene.
4.To synthesize the results of NJCMS1A and NJCMS2A, it was found that the MADS box protein and starch branching enzyme didn't appear in the anthers at both uninucleate microspore and binucleate pollen stages of NJCMS1A and NJCMS2A, but appeared in those of NJCMS1B and NJCMS2B; cysteine proteinase, vacuolar H~+-ATPase A subunit, adenosine/AMP deaminase, AIG1-like protein, oligouridylate binding protein, cullin, beta-amyrin synthase and hypothetical protein MtrDRAFT_AC146570g8vl appeared in the anthers at binucleate pollen stages of NJCMS1A and NJCMS2A, but didn't appear in those of NJCMS1B and NJCMS2B. These proteins might be related to the male sterility of NJCMS1A and NJCMS2A stably. It was suggested to clone the genes of the above proteins and study their functions, especially those related to the male sterility.
引文
1. Abe T, Niiyama H, Sasahara T. Cloning of cDNA for UDP-glucose pyrophosphorylase and the expression of mRNA in rice endosperm. Theor Appl Genet, 2002, 105: 216— 221
2. Afjehi S L, Gruber O M, Felizardo M, et al. Expression of proteasomal proteins in ten different tumor cell lines. Amino Acids, 2004, 27: 129~140
3. Albertsen M C, Palmer R G. A comparative light and electron-microscopic study of microsporogenesis in male sterile(ms1) and male fertile soybean. American Journal Botany, 66 (3): 253-265
4. Andrea C, Gary J L. Motifs specific for the ADR1 NBS-LRR protein family in arabidopsis are conserved among NBS-LRR sequences from both dicotyledonous and monocotyledonous plants. Planta, 2005, 221: 597~601
5. Arturo O L, Mark A R. Characterization of the UDP-glucose pyrophosphorylase gene from the marine red alga Gracilaria gracilis. Journal of Applied Phycology, 1999, 10: 581-588
6. Athanasios T, Joseph R E, Curtis J P, et al. Sequence and analysis of chromosome 1 of the plant Arabidopsis thaliana. Macmillan Magazines Ltd, 2000, 816 - 820
7. Bai Y N, Gai J Y. Development of a new cytoplasmic-nuclear male-sterility line of soybean and inheritance of its male-fertility restorability. Plant Breeding, 2006, 125: 85-88
8. Bradford M M. A rapid and sensitive method for the quantification of microgram quantities of protein utilizing the principle of protein dye binding. Analytical Biochemisrty, 1976, 72: 248—254
9. Chopra J, Kaur N, Gupta A K. Role of enzymes of sucrose-starch conversion in seed sink strength in mung bean. Bilogia plantarum, 2005, 49 (4): 561—566
10. Daiji K, Takeshi I, Tetsu N S N. Pollen UDP-glucose pyrophosphorylase showing polymorphism well-correlated to the s genotype of Pyrus pyrifolia. Sex Plant Reprod, 2002, 14: 315—323
11. Dale G. Latner A L. Isoelectric focusing of serum proteins in acrylamide gels followed by electrophoresis. Clin Chim Acta, 1969, 24: 61—68
12. Danilo D F, Mark D L, John N O. Growth and development of conifer pollen tubes. Sex Plant Reprod, 2005, 18: 149-162
13. Davis W H. Route to hybrid soybean production. United States Patent no.4545146, 1985
14. Ding D R, Gai J Y, Cui Z L, et al. Development of a cytoplasmic-nuclear male-sterile line of soybean. Euphytica, 2002, 124: 85—91
15. Ding D R, Gai J Y, Yang J S. Comparative restriction patterns and RFLP analysis of mitochondria DNA between cytoplasmic-nuclear male sterile line NJCMS1A and its maintainer NJCMS1B of the soybean. WSRC VI Proceedings, Superior Printing, Champaign, Illinois, 1999, pp435.
16. Friedman H, Hagiladi A, Resnick N, et al. Ethylene-insensitive related phenotypes exist naturally in a genetically variable population of Dianthus barbatus. Theor Appl Genet, 2001, 103: 282—287
17. Gallardo K, Job C, Groot SPC,et al . Proteomic analysis of Arabidopsis seed germination and priming. Plant Physiology, 2001, 126: 835—848
18. Getu B, Christine H F, Karl J K. Two new cysteine proteinases with specific expression patterns in mature and senescent tobacco (Nicotiana tabacum L.) leaves. Journal of Experimental Botany, 2006, 57(6): 1431 — 1443
19. Guillermo D R, Leonardo MC, Mercedes E M, et al. Multiple phosphorylation sites in the b subunit ofthylakoid ATP synthase. Photosynth Res, 2006, 89: 11 — 18
20. Hironaka K, Ishbashi K, Hakamada K. Effect of static loading on sugar contents and activities of invertase, UDP-glucose pyrophosphorylase and sucrose 6-phosphate synthase in potatoes during storage. Potato Research, 2001, 44: 33~39
21. Imin N, Kerim T, Rolfe G B, et al. Effect of early cold stress on the maturation of rice anthers. Proteomics, 2004, 4 (7): 1873-1882
22. Inaki Iturbe-Ormaetxe, Kosmas Haralampidis, Kalliopi Papadopoulou, et al. Molecular cloning and characterization of triterpene synthases from Medicago truncatula and Lotus japonicus. Plant Molecular Biology, 2003, 51: 731—743
23. Joo-Ho Shin. Talin Gulesserian, Rachel Weitzdoerfer, et al. Derangement of hypothetical proteins in fetal down's syndrome brain. Neurochemical Research, 2004, 29(6): 1307— 1316
24. Kaul M L. Male sterility in higher plants. Monograph on Theor, Appl.Geenet, Vol.10. Springer-verlag Berlin, 1988
25. KuniedaT, FujiwaraT, Amano T, et al. Molecular cloning and characterization of a senescence-induced tau-class Glutathione-S-transferase from barley leaves. Plant Cell Physiol, 2005, 46(9): 1540-1544
26. Lilac P, Dana H, Limor B, et al. The TM5 MADS Box gene mediates organ differentiation in the three inner whorls of tomato flowers. Plant Cell, 1994, 6: 175— 186
27. Link A J, Eng J, Schieltz D M, et al. Diect analyses of protein complexes using mass spectrometry. Nat Biotech, 1999, 17: 676—682
28. Margolis J, Kenrick K G. Two-dimensional resolution of plasma proteins by combination of polyacrylamide disc and gradient gel electrophoresis. Nature, 1969, 221: 1056— 1057
29. Man'a M Lo'pez, Edson Bertolini Antonio Olmos, Paola Caruso Man'a Teresa Gorris, et al. Innovative tools for detection of plant pathogenic viruses and bacteria. Int Microbiol, 2003, 6: 233-243
30. Martin Hajduch, Ashwin Ganapathy, Joel W Stein, et al. A systematic proteomic study of seed filling in soybean, establishment of high-resolution two-dimensional reference maps, expression profiles, and an interactive proteome database. Plant Physiology, 2005, 137: 1397-1419
31. Matt Geisler, Malgorzata Wilczynska, Stanislaw Karpinski, et al. Toward a blueprint for UDP-glucose pyrophosphorylase structure/function properties: homology-modeling analyses. Plant Molecular Biology, 2004, 56: 783—794
32. Madsen L H, Collins N C, Rakwalska M, et al. Barley disease resistance gene analogs of the NBS-LRR class: identification and mapping. Mol Gen Genomics, 2003, 269: 150—161
33. Mazal Solomon, Beatrice Belenghi, Massimo Delledonne, et al. The involvement of cysteine proteases and potease inhibitor genes in the regulation of programmed cell death in plants. Plant Cell, 1999, 11: 431-443
34. Monowar Md, Karim Khan, Asad Jan, et al. Identification of phosphoproteins regulated by gibberellin in rice leaf sheath. Plant Molecular Biology, 2005, 58: 27—40
35. Michel Zivy. Proteomics: a link between genomics, genetics and physiology. Plant Molecular Biology, 2002, 44: 575—580
36. Nijat I. Tursun K. Barry G R, et al. Effect of early cold stress on the maturation of rice anthers. Proteomics, 2004, 4: 1873—1882
37. O'Farrell P H. High resolution two-dimensional electrophoresis of proteins. J Bio Chem, 1975, 250: 4007-4021
38. Pandey A. Proteomics to study genes and genomes. Nature, 2000, 405 (6788): 837
39. Peng Y H, Yang G B, Yuan J Z. Genetic analysis of a new type of male sterile soybean. World Soybean Research Conference V Abstract. Funny Publishing Limited Partnership, Bangkok, Thailand, 1994, pp90
40. Pinto D M, Ning Y, Figeys D. An enhanced microfluidic chip coupled to an electrospray qstar mass spectrometer for protein identification. Eletrophoresis, 2000, 21:181-190
41. Rashmi M, Mohapatra P K. Ethylene control of seed coat development in low and high sterile semidwarfindica rice cultivars. Plant Growth Regul, 2006, 50:47-55
42. Sung H C, Quoc T H, Yoon Y K, et al. Proteome analysis of gametophores identified a metallothionein involved in various abiotic stress responses in Physcomitrella patens. Plant CellRep, 2006, 25:475-488
43. Tang W, Harrata A K, Lee C S. Two-dimensional analysis of recombinant E. coli proteins using capillary isoelectric focusing electrospray ionization mass spectrometry. Anal Chem, 1997, 69:177-3182
44. Tursun K, Nijat I, Jeremy J W, et al. Proteome analysis of male gametophyte development inriceanthers. Proteomics, 2003, 3, 738-751
45. Veselova T D, Il'ina G M, Levinskikh M A, et al. Ethylene is responsible for a disturbed development of plant reproductive system under conditions of space flight. Russian Journal of Plant Physiology, 2003, 50:339-354
46. Vierling E. The role of heat shock protein in plants. Annu Rev Plant Physiol Plant Mol Biol, 1991, 42:579-620
47. Wan C, Lal Y, Zhu H, et al. Abnormal changes of plasma acute phase proteins in schizophreniaand the relation between schizophrenia and haptoglobin (Hp) gene. Amino Acids, 2007, 32:101-108
48. Wu W G, Tang X M, Wei H, et al. Identification and validation of metastasis-associated proteins in head and neck cancer cell lines by two-dimensional electrophoresis and mass spectrometry. Clinical & Experimental Metastasis, 2002, 19:319-326
49. Yang S P, Duan M P, Meng Q C, et al. Inheritance and gene tagging of male fertility restoration of cytoplasmic-nuclear male-sterile line NJCMS1A in soybean. Plant Breeding, 2007, 126 (in press)
50. Zhang J K, Zong X F, Yu G D, et al. Relationship between phytohormones and male sterility in thermo-photo-sensitive genie male sterile (TGMS) wheat. Euphytica, 2006, 150:241-248
51. Zhang S L, Danilo D F. Structural, histochemical, and protein analysis of male reproductive development in willow. Sex Plant Reprod, 2005, 18:37-46
52. 蔡小钿,王金发.植物MADS盒基因的功能和调节机理.植物生理学通讯,2000,36(3):277~281
53. 曹仪植.分子生物学.高等教育出版社,2002
54. 陈建南,傅鸿仪,路子显等.HSP70反义RNA对高粱花粉的正常形成的影响.科学通报,1997,42(18):1993~1997
55. 陈建南,傅鸿仪,路子显等.高粱细胞质雄性不育与HSC70mRNA关系.科学通报,1998,43(23):2323~2530
56. 褚福亮,王福生.蛋白质谱分析方法特点及其在蛋白组学研究领域中的应用.世界华人消化杂志,2002,10(12):1431~1435
57. 崔永兰,张露,黄敏仁.植物MADS盒基因研究进展.中国生物工程杂志,2003,23(9):50~54
58. 邓家术,段彬江,刘中来.植物热激蛋白的研究进展及其应用.生命的化学,2003,23(3):226~228
59. 邓琳.蛋白质组学研究进展与趋势.中国科技信息,2005,13:36~37
60. 丁自立,杨国正,吴金平.作物热激蛋白研究进展及应用.湖北农业科学,2006,45(4):519~521
61. 董彩华,王志强,王延枝.大豆液泡膜H~+—ATPase功能与构象关系的初步研究.生物化学与生物物理进展,2000,27(6):424~628
62. 董发才,宋纯鹏.植物细胞中的泛素及其生理功能.植物生理学通讯,1999,35(1): 54~59
63. 凡军民.大豆质核互作雄性不育系的细胞形态学和细胞化学特征的研究,南京农业大学,2003
64. 范宝莉,王振英,陈宏等.小麦T型细胞质雄性不育系、保持系蛋白质双向电泳比较研究.实验生物学报,2004,37(1):45~49
65. 范海延,陈捷,曲波等.蛋白质组学及其在植物科学研究中的应用.生物学通报,2006,41(1):6~8
66. 冯德芹,郭尧君.双向电泳在农业和林业中的最新应用.现代科学仪器,2006,5:37~43
67. 冯兰东,丁同楼,王宝山.植物液泡膜H~+-ATPase及其在胁迫中的响应.湛江师范学院学报,2005,6(6):71~76
68. 付琼.蛋白质组学研究进展与应用.江西农业大学学报,2004,26(5):818~823
69. 郭旭,杨云生.双向电泳技术在蛋白质组研究中的应用进展.中国卫生检验杂志,2006,16(5):638~640
70. 胡滨,陈观平,施农农等.植物细胞质雄性不育及其在育种中的应用.浙江林学院学报,2006,23(6):689~693
71. 胡向阳,方建颖,蔡伟明等.丝裂原活化蛋白激酶介导脱乙酰几丁质诱导的人参细胞氧进发与皂苷合成.中国科学C辑生命科学,2004,34(1):31~40
72. 季芝娟,薛庆中.植物蛋白质组学研究进展.生命科学,2004,16(4):242~248
73. 金志强,李瑞珍,徐碧玉等.香蕉果实特异性ACC合成酶基因的克隆及反义载体的构建.农业生物技术学报,2002,10(3):305~306
74. 李存玺,王永潮.泛素—蛋白水解酶复合体通路.科学通报,1998,43(18):1905~1911
75. 李赫,邹黎明.双向电泳图谱的图像分析技术进展.沈阳医学院学报,2006,8(1):74~79
76. 李丽莉,温博海,王恒睴.蛋白质组技术进展.生物技术通讯,2006,17(4):662~664
77. 李木英,石庆华,潘晓华等.影响两系杂交稻结实期茎鞘贮藏碳水化合物转运的生理因素研究.江西农业大学学报,1999,21(3):329~332
78. 李宁,许红韬.蛋白质组研究的现状与展望.生物技术通讯,2000,11(4):218~222
79. 李蓉,梁恒.生物质谱-蛋白质组研究的关键技术.化学通报,2002,11:748~752
80. 梁宇,荆玉祥,沈世华.植物蛋白质组学研究进展.植物生态学报,2004,28(1):114~125
81. 廖翔,应天翼,黄留玉等.蛋白质组学研究中的双向电泳技术.生物技术通讯,2003,14(6):522~524
82. 刘鹏,胡昌浩,董树亭等.甜质型与普通型玉米籽粒发育过程中糖代谢相关酶活性的比较.中国农业科学,2005,38(1):52~58
83. 刘军,黄上志,付家瑞.不同活力玉米种子胚萌发期间热激蛋白的合成.植物学报,2000,42(3):253~257
84. 刘军昌,段作营,毛忠贵.AMP脱氨酶活性测定的一种改进方法.食品与发酵工业,2001,27(7):30~33
85. 刘乐承,张弢,曹家树.植物花粉发育的分子生物学研究进展.长江大学学报(自科版),2006,3(3):174~179
86. 刘忠松,官春云,陈社员.植物雄性不育机理的研究及应用.北京:中国农业出版社,2001
87. 柳展基,杨小红,毕玉平.蛋白质组学在农业中的应用.分子植物育种,2006,4(3):106~110
88. 罗玉.植物中的糖代谢及其相关酶.文山师范高等专科学校学报,2004,17(2):155~159
89. 马彦军,王蒂.马铃薯腺苷二磷酸葡萄糖焦磷酸化酶的调控.中国马铃薯,2002, 16(6):353~355
90. 马媛媛,甘睿,王宁宁.植物富含亮氨酸重复序列型类受体蛋白激酶的生物学功能.植物生理与分子生物学学报,2005,31(4):331~339
91. 门淑珍,刘博林.小麦显性雄性核不育材料后代不育株与可育株不同器官的蛋白质比较研究.作物学报,2001,27(1):117~122
92. 孟慧,段翠芳,曾日中.植物蛋白质组学研究概况.热带农业科学,2006,26(2):60~65
93. 孟令波,霍宏图.蛋白质组学的研究及其发展趋势.哈尔滨学院学报,2005,26(10):125,~126
94. 穆蕊,张祖新,张方东等.玉米CMS-S小孢子败育过程中的细胞程序性死亡.作物学报,2006,32(5):666~670
95. 倪晓光,赵平.泛素-蛋白酶体途径的组成和功能.生理科学进展,2006,37(3):255-258
96. 潘晓华,李木英,曹黎明等.水稻发育胚乳中淀粉的积累及淀粉合成的酶活性变化.江西农业大学学报,1999,21(4):456~462
97. 潘运刚.蛋白质组学研究进展.赤峰学院学报(自然科学版),2005,21(6):48~49
98. 彭佶松,郑志仁,刘涤等.淀粉的生物合成及其关键酶.植物生理学通讯,1997,33(4):297~303
99. 秦慧,刘霆,柳斌等.几种双向凝胶电泳蛋白质检测方法的比较.中国实验血液学杂志,2006,14(1):168~172
100. 阮松林,马华升,王世恒等.植物蛋白质组学研究进展Ⅰ.蛋白质组关键技术.遗传,2006,28(11):1472~1486
101. 阮松林,童建新,赵杭苹.双向电泳技术研究进展.杭州农业科技,2006,5:2~5
102. 邵锦震,顾勇.水稻剑叶蛋白质的双向电泳分析.湖北师范学报(自然科学版),200.6,1:1~5
103. 史刚荣.植物细胞程序性死亡的研究进展.淮北煤师院学报,2002,23(3):39~45
104. 舒小丽,舒庆尧.作物淀粉生物合成与转基因修饰研究进展.生物技术通报,2004,4:19~26
105. 宋平,张竞男,胡珈瑞等.食蟹猴疟原虫(Plasmodium cynomolgi)中一个真核翻译起始因子4A(eIF一4A)同源蛋白的cDNA克隆、表达和ATP酶活性测定.中国生物化学与分子生物学报,2004,20(3):294~304
106. 宋素胜,谢道昕.泛素蛋白酶体途径及其对植物生长发育的调控.植物学通报,2006,23(5):564~577
107. 孙清萍,汪莉,易平等.红莲型水稻不育系统花粉发育不同时期MADS-box基因家族的表达分析.武汉植物学研究,2002,20(5):325~328
108. 孙薇,贺福初.差异蛋白质组学研究技术新进展.化学通报,2005,6:401~407
109. 孙学辉,路铁刚,贾士荣等.水稻中富含亮氨酸的重复序列和核苷酸结合位点(LRR-NBS)基因家族的生物信息学分析.中国农业科学,2004,37(1):1~7
110. 涂礼莉,张献龙,朱龙付等.海岛棉NBS类型抗病基因类似物的起源、多样性及进化.遗传学报,2003,30(11):1071~1077
111. 王芳,静广力.大豆不育系的鉴定及在育种上的应用,农业与技术,2004,24(2):97
112. 王彩琴,李燕,宋丽莉.热激蛋白的结构与功能.长治学院学报,2006,23(2):13~16
113. 王锋,郭尧君.蛋白质组学及其技术进展.现代科学仪器,2006,5:8~12
114. 王高鸿,黄久常.蛋白质的选择性降解.生命科学,1999,11:24~30
115. 王俐,章银梅,陈建南.基因工程创造新的植物雄性不育系研究的新进展.生命科学,2001,13(5):222~224
116. 王曼莹,杨玲,邹伟等.分子生物学.科学出版社,2006
117. 王世刚,王宇,唐咏等.辣椒CMS型雄性不育系与保持系花期叶片蛋白质组分析.中国蔬菜,2007,2:13~16
118. 王欣荣,刘锋,刘建华等.一种改进的双向电泳染色方法.中国生物工程杂志,2006,26(6):71~74
119. 王秀珍,滕晓月,阎龙飞等.玉米及高粱花药中三磷酸腺苷(ATP)含量与细胞质雄性不育.作物学报,1986,12(3):177~182
120. 王艳,张爱民.小麦核质互作长日光敏不育的遗传研究.云南大学学报,2002,21:65~66
121. 魏磊,丁毅,胡耀军等.紫稻细胞质雄性不育系叶片全蛋白双向电泳分析.遗传学报,2002,29(8):696~699
122. 文耕云,董燕麟.Ubiquitin及其功能的研究进展.生物化学与生物物理进展,1992,19(2):96~99
123. 文李,刘盖,万翠香等.水稻红莲型细胞质雄性不育系小孢子不同发育时期花药总蛋白质比较分析.武汉植物学研究,2006,24(4):346~350
124. 文李,刘盖,王坤等.水稻花药总蛋白质双向电泳方法的改良与优化.分子细胞生物学报,2006,39(5):473~476
125. 文李,刘盖,张再君等.红莲型水稻细胞质雄性不育花药蛋白质组学初步分析.遗传,2006,28(3):311~316
126. 吴蓓,吴建勇,蔡刘体等.生长素反应因子.植物生理学通讯,2005,41(3):273-279
127. 吴厚雄,肖辉海,李必湖.植物热激蛋白的研究进展.生物技术通报,2003,4:6~10
128. 吴世容,李志良,李根容等.生物质谱的研究及其应用.重庆大学学报,2004,27(1):123~128
129. 吴晓俊,刘涤,胡之璧.尿苷二磷酸葡萄糖焦磷酸化酶1.植物生理学通讯,2000,36(3):193~200
130. 夏快飞,陈良碧.光温敏两用核不育水稻特异蛋白质的研究进展.湖南师范大学自然科学学报,2001,24(4):81~84
131. 夏其昌,曾嵘.蛋白质化学与蛋白质组学.科学出版社,2002
132. 肖辉海,陈良碧.热激对温敏不育水稻花粉育性与花药蛋白质组分的影响.湘潭师范学院学报(自然科学版),2001,23(3):92~95
133. 谢锦云,李小兰,陈平等.温敏核不育水稻花药蛋白质组初步分析.中国生物化学与分子生物学报,2003,19(2):215~221
134. 徐晓燕,郑蕊,李春梅等.大豆种子萌发过程中的差异蛋白质组研究.生物化学与生物物理进展,2006,33(11):1106~1112
135. 许克新,王云川.双向电泳及质谱分析与蛋白组研究.第四军医大学学报,2002,23(22):2017~2022
136. 薛淑群,刘伟,匡友谊.蛋白质组学研究的技术体系及进展.水产学杂志,2004,17(1):77~81
137. 闫龙凤,杨青川,韩建国等.植物半胱氨酸蛋白酶研究进展.草业学报,2005,14(5):11~19
138. 杨正平,王聪.蛋白质组学研究的新进展.安阳师范学院学报,2006:147~148
139. 叶妙水,钟克亚,胡新文等.双向凝胶电泳的实验操作及进展.生物技术通报,2006,3:4~10
140. 易图永,谢丙炎,张宝玺等.植物抗病基因同源序列及其在抗病基因克隆与定位中的应用.生物技术通报,2002,2:16~20
141. 应万涛,焦丽燕,钱小红.生物质谱与蛋白质组学.生物技术通讯,2004,15(3):259-262
142. 于玲,王莱,牛吉山等,植物功能基因组研究进展.西北师范大学学报(自然科学版),2003,39(1):104~113
143. 于晓敏,蓝兴国,李玉花,泛素/26S蛋白酶体途径与显花植物自交不亲和反应.植物学通报,2006,23(2):197~206
144. 岳远彬,苗延平,张春庆.蛋白质组分析技术与进展.山东农业科学,2007,1:29~32
145. 郑彦,邵淑娟.比较蛋白质组研究方法学进展.生命科学仪器,2006,4:19~22
146. 曾嵘,夏其昌.蛋白质组学研究进展与趋势.中国科学院院刊,2002,3:166~169
147. 曾英,胡金勇,李志坚.植物MADS盒基因与花器官的进化发育.植物生理学通讯,2001,37(4):281~287
148. 张飚,李永清,高轩.谷胱甘肽-S-转移酶综述.吉林畜牧兽医,2006,11~13
149. 张孔湉,李京京.雄性不育高粱(3197A)的热激蛋白与育性的关系.遗传学报,1992,19(4):327~335
150. 张丽霞,张国强,陈瑞丽.蛋白质组学研究的新进展.安阳工学院学报,2006,3:8~10
151. 张群业,陈竺.差异表达蛋白质组学中的常用技术.国外医学遗传学分册,2004,27(2):64~68
152. 张田.蛋白质与蛋白质组学的研究进展.云南师范大学学报,2003,23(1):51~53
153. 张侠,尹海波,熊冬金等.植物热激蛋白70.植物生理学通讯,2004,40(4):500~504
154. 赵团结,盖钧镒.大豆2个雌雄不育突变体的发现与鉴定.大豆科学,2006,25(2):109~112
155. 赵团结,盖钧镒.大豆不育细胞质资源的发掘与鉴定.作物学报,2006,32(11):1604~1610
156. 赵团结,盖钧镒.大豆不育性自然变异的发现与鉴定.中国农业科学,2006,39(9):1756~1764
157. 赵团结,盖钧镒.大豆叶与花形态异常、雌性不育突变体NJS.10H的发现.大豆科学,2005,24(1):1~4
158. 赵团结,杨守萍,盖钧镒.大豆显性核雄性不育突变体N7241S的发现与遗传分析.中国农业科学,2005,38(1):22~26
159. 赵团结,杨守萍,盖钧镒.大豆育性突变体CT-2s的发现与遗传分析.中国油料作物学报,2005,27(2):5~9
160. 赵雅丽,韩冰,李淑芬等.液泡膜H~+-ATPase在植物的非生物胁迫响应和信号转导中的作用.植物生理学通讯,2006,42(5):812~816
161. 甄朱.蛋白质组学进展.生物工程学报,2001,17(5):491~493
162. 郑蕊,喻德跃.适于蛋白质组研究的大豆种子蛋白双向电泳技术的改进.大豆科学,2005,24(3):166~170
163. 郑蕊.大豆种子蛋白积累与调控的蛋白质组研究.南京农业大学,2005
164. 郑彦,邵淑娟.比较蛋白质组研究方法学进展.生命科学仪器,2006,4:19~22
165. 周建平,杨足君,冯娟等.小麦蛋白翻译起始因子5A基因eIF5A的克隆与分析.遗传,2006,28(5):571~577
166. 朱宏,马旭俊,马兴宏等.小麦叶片蛋白质的双向电泳分析.哈尔滨师范大学自然科学学报,2001,17(1):98~101
167. 朱宏,王继华,王同昌.小麦T型细胞质雄性不育系与可育系叶片蛋白质双向电泳分析.植物研究,2004,24(3):339~342
168. 朱英国.水稻雄性不育生物学.武汉大学出版社,2000
169. 朱玉贤,李毅.高等分子生物学.高等教育出版社,1997
170. 宗绪晓.木豆杂种优势利用研究进展.作物杂志,2006,37~40
171. 邹德洪,邹小云,贺浩华.水稻细胞质雄性不育分子生物学研究进展.种子,2006,25(10):32~37
