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教授
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余四斌
发布时间:2017-02-21

                             

基本信息


姓名: 余四斌 出生年月: 1967.09

性别: 硕/博导: 博导

民族: 开设课程:

种子科学导论,遗传学与基因组学研究进展,种子科学研究进展


职称: 教授 研究方向:

种质资源创新与利用


学位: 农学博士


联系方式
办公电话:87281803

电子邮件:ysb@mail.hzau.edu.cn

办公地址:作物遗传改良国家重点实验室A515


个人简介
余四斌,男,1967年9月出生,教授,博士生导师。主要从事水稻遗传育种和分子生物学研究以及教学工作,讲授数量遗传学、种子生理工艺学和遗传学进展等课程。1998-2000年在国际水稻研究所(IRRI)进行合作研究。目前研究方向主要包括水稻新种质创建、基因多样性分析与优异基因发掘、分子育种、种子质量控制等。


科研项目

1. 科技部,国家自然科学基金项目,水稻种子耐贮性基因SS1的鉴定与功能分析. 课题编号:31971864, 项目年限:2020-2023

2. 科技部,国家自然科学基金项目,水稻冠根形成基因的克隆与功能分析. 课题编号:31671656, 项目年限:2017-2020

3. 科技部,国家高技术研究发展计划,绿色超级稻新品种选育,课题编号:2014AA10A604,项目年限:2014-2018

4. 湖北。北省科技重大专项,主要粮食作物重大新品种选育,课题编号:2020ABA016,项目年限:2021-2023(子课题)

5. 湖北。北省技术创新专项,适合“双水双绿”模式的特色优质水稻新品种选育,课题编号:2019ABA104,项目年限:2019-2021(子课题)

6. 湖北。湖北省产业体系专项,“双水双绿”关键技术创新与集成应用,课题编号:46141900205,项目年限:2018-2021(课题)

教学研究与教学改革

1. 2016-1017年校级教改项目:《种子学综合实验》精品实践课程建设


发明专利及获奖情况

发明专利:

1. 余四斌,孙文强,高大伟,王重荣。一种水稻基因OsAP2-6及制备方法和应用。专利号, ZL201310731026.9 (授权公告日2018.4.10)

2. 余四斌,邱先进,王记林,孙文强。一种水稻粒型基因qSS7及制备方法和应用。专利号, ZL20131070753447.1(授权公告日2018.4.20)

3. 余四斌,熊银,肖雄峰,袁志阳,张超普。水稻基因OsEIN2L及其应用。专利号 ZL201610292521.8 (授权公告日2019.9.10)

4. 余四斌,袁志阳,孙文强,熊银,龚蓉,张佳宁。基于KASP技术用于水稻产量基因分型的引物组 合及其应用。专利号 ZL201710297282.X (授权公告日2019.7.19)

5. 余四斌,袁志阳,孙文强,凡凯,夏雨。基于KASP技术用于水稻特殊营养物质基因分型的引物及 应用。ZL201710751904.1(授权公告日20200424)

6. 余四斌,孙文强,夏雨,张丽婷,袁志阳。用于鉴别稻米脂肪酸品质的DNA分子标记及其应用。 ZL201710751127.0(授权公告日20200609)

7. 王记林,余四斌,袁志阳,邱先进。一组用于改良稻米品质的分子标记及水稻改良方法和应用。 ZL201710355389.5(授权公告日20200508)

8. 余四斌,袁志阳,蔡星星,凡凯,田莉,邱先进。一种水稻温敏核不育基因tms3突变体及其分子 标记与应用。ZL201910501858.9 (授权公告日20200901)

9. 余四斌,高大伟,孙文强,王电文。一种水稻基因OsPGSIP1及其应用。ZL2018.10945403.1(授权 公告日20200901)

10. 余四斌,袁志阳,凡凯,田莉,熊银。一种水稻种子耐贮藏基因OsGH3-2及其分子标记的应用。 ZL201910554967.7(授权公告日20201002)

主要奖励:

1. 2016年度,国家自然科学奖(二等奖)(序4

2. 2015年度,湖北省自然科学奖(一等奖)4)

3. 2009年度,国家科技进步奖(二等奖)(参加)

4. 2007年度,上海市科技进步奖(一等奖)(序5)

5. 2004年度,中国农学会青年科技奖

6. 2000年度,湖北省科技进步奖(三等奖)(序2)

7. 1993年度,国家教委科技进步奖(三等奖)(序3)


发表的论文及著作

学术论文

1. Zhang CP, Wang DW, Wang J, Sun Q, Tian L, Tang X, Yuan Z, He H*, Yu S*. Genetic dissection and validation of chromosomal regions for transmission ratio distortion in intersubspecific crosses of rice. Front Plant Sci (2020) 11:563548. Doi: 10.3389/fpls.2020.563548

2. Yu S#, Ali J#, Zhang CP, Li ZK*, Zhang Q*. Genomic breeding of green super rice varieties and their deployment in Asia and Africa. Theor Appl Genet (2020) 133:1427–1442

3. Zhang CP, Yuan ZY, Wang YT, Sun WQ, Tang X, Sun YJ , Yu S*. Genetic dissection of seed dormancy in rice (Oryza sativa L.) by using two mapping populations derived from common parents. Rice (2020) 13: 52

4. Yuan S, Wang YT, Zhang CP, He H*, Yu S*. Genetic dissection of seed dormancy using chromosome segment substitution lines in rice (Oryza sativa L.). Int J Mol Sci (2020) 21: 1344

5. Gao DW, Sun WQ, Wang DW, Dong HL, Zhang R, Yu S*. A xylan glucuronosyltransferase gene exhibits pleiotropic efects on cellular composition and leaf development in rice. Sci Reports (2020) 10: 3726

6. Wang P#, Xiong Y#, Gong R, Yang Y, Fan Kai, Yu S*. A key variant in the cis-regulatory element of flowering gene Ghd8 associated with cold tolerance in rice. Sci Reports (2019) 9:9603

7. Wang P, Gong R, Yang Y, Yu S*. Ghd8 controls rice photoperiod sensitivity by forming a complex that interacts with Ghd7. BMC Plant Biology (2019) 19:462

8. Yuan Z, Fan K, Xia L, Ding X, Tian L, Sun W, He H, Yu S*. Genetic dissection of seed storability and validation of candidate gene associated with antioxidant capability in rice (Oryza sativa L.). Int J Mol Sci (2019) 20: 4442

9. Tang X, Gong R, Sun W, Zhang C, Yu S*. Genetic dissection and validation of candidate genes for flag leaf size in rice (Oryza sativa L.). Theor Appl Genet (2018) 131: 801-815

10. Gong R, Cao HS, Zhang J, Xie K, Wang DW, Yu S*. Divergent functions of the GAGA-binding transcription factor family in rice. The Plant J (2018) 94: 32-47

11. Chen J#, Wang JL#, Chen W, Sun WQ, Peng M, Yuan ZY, Shen SQ, Xie K, Jin C, Sun YY, Liu XQ, Fernie AR, Yu S*, Luo J*. Metabolome analysis of multi-connected biparental chromosome segment substitution line populations. Plant Physiology (2018) 178:612-625

12. Gong R, Cao HS, Zhang J, Xie K, Wang DW, Yu S*. Divergent functions of the GAGA-binding transcription factor family in rice. The Plant J (2018) 94: 32–47

13. Chen J, Wang JL, Chen W, Sun WQ, Peng M, Yuan ZY, Shen SQ, Xie K, Jin C, Sun YY, Liu XQ, Fernie AR, Yu S*, Luo J*. Metabolome analysis of multi-connected biparental chromosome segment substitution line populations. Plant Physiology (2018) 178:612–625

14. Sun W, Gao D, Xiong Y, Tang X, Xiao X, Wang C, Yu S*. Hairy Leaf 6, an AP2/ERF transcription factor, interacts with OsWOX3B and regulates trichome formation in rice. Mol Plant (2017) 10: 1417–1433

15. Zhang J, Chen LL, Xing F, Kudrna DA, Yao W, Copetti D, Mu T, Li W, Song JM, Xie W, Lee S, Talag J, Shao L, An Y, Zhang CL, Ouyang Y, Sun S, Jiao WB, Lv F, Du B, Luo M, Maldonado CE, Goicoechea JL, Xiong L, Wu C, Xing Y, Zhou DX, Yu S, Zhao Y, Wang G, Yu Y, Luo Y, Zhou ZW, Hurtado BE, Danowitz A, Wing RA, Zhang Q*. Extensive sequence divergence between the reference genomes of two elite indica rice varieties Zhenshan 97 and Minghui 63. Proc Natl Acad Sci USA. (2016) 113(35): E5163–71

16. Zhang HW, Fan YY, Zhu YJ, Chen JY, Yu S, Zhuang J*. Dissection of the qTGW1.1 region into two tightly-linked minor QTLs having stable effects for grain weight in rice. BMC Genetics (2016)17: 98

17. Wang X, Li L, Yang Z, Zheng X, Yu S, Xu C, Hu Z. Predicting rice hybrid performance using univariate and multivariate GBLUP models based on North Carolina mating design II. Heredity (2016) 1–9

18. Sun W, Zhou Q, Yao Y, Qiu X, Xie K, Yu S*. Identification of genomic regions and the isoamylase gene for reduced grain chalkiness in rice. PLoS ONE (2015) 10: e0122013. doi:10.1371/journal.pone.0122013

19. Xie W, Wang G, Yuan M, Yao W, Lyu K, Zhao H, Yang M, Li P, Zhang X, Yuan J, Wang Q, Liu F, Dong H, Zhang L, Li X, Meng X, Zhang W, Xiong L, He Y, Wang S, Yu S, Xu C, Luo J, Li X, Xiao J, Lian X, Zhang Q*. Breeding signatures of rice improvement revealed by a genomic variation map from a large germplasm collection. Proc Natl Acad Sci USA (2015) 112(39): E5411–5419

20. Wang Q, Xie W, Xing H, Yan J, Meng X, Li X, Fu X, Xu J, Lian X, Yu S, Xing Y, Wang G*. Genetic architecture of natural variation in rice chlorophyll content revealed by a genome-wide association study. Mol Plant (2015) 8:946–57

21. Wu J, Feng F, Lian X, Teng X, Wei H, Yu H, Xie W, Yan M, Fan P, Li Y, Ma X, Liu H, Yu S, Wang G, Zhou F, Luo L, Mei H*. Genome-wide Association Study (GWAS) of mesocotyl elongation based on re-sequencing approach in rice. BMC Plant Biol (2015) 15:218

22. Chen W, Gao Y, Xie W, Gong L, Lu K, Wang W, Li Y, Liu X, Zhang H, Dong H, Zhang W, Zhang L, Yu S, Wang G, Lian X, Luo J*. Genome-wide association analyses provide genetic and biochemical insights into natural variation in rice metabolism. Nat Genet (2014) 46 (7): 714 –721

23. Gong L, Chen W, Gao Y, Liu X, Zhang H, Xu C, Yu S, Zhang Q, Luo J*. Genetic analysis of the metabolome exemplified using a rice population. Proc Natl Acad Sci (2013) 110(50):20320-20325

24. Lu L, Shao D, Qiu X, Sun L, Yan W, Zhou X, Yang L, He Y, Yu S, Xing Y. Natural variation and artificial selection in four genes determine grain shape in rice. New Phytol. (2013) 200:1269–1280

25. Yan W, Liu H, Zhou X, Li Q, Zhang J, Lu L, Liu T, Liu H, Zhang C, Zhang Z, Shen G, Yao W, Chen H, Yu S, Xie W, Xing Y*. Natural variation in Ghd7.1 plays an important role in grain yield and adaptation in rice. Cell Res (2013) 23(7):969–71

26. Zhang F, Jiang YZ, Yu S, Ali J, Paterson AH, Khush GS, Xu JL, Gao YM, Fu BY, Lafitte R, Li ZK*. Three genetic systems controlling growth, development and productivity of rice (Oryza sativa L.): a reevaluation of the ‘Green Revolution’. Theor Appl Genet (2013) 126:1011–1024

27. Wang P, Zhou GL, Cui KH, Li ZK, Yu S*. Clustered QTL for source leaf size and yield traits in rice (Oryza sativa L.) Mol Breeding  (2012) 29: 99–113

28. Qiu XJ, Gong R, Tan YB, Yu S*. Mapping and characterization of the major quantitative trait locus qSS7 associated with increased length and decreased width of rice seeds. Theor Appl Genet (2012) 125: 1717–1726

29. Qu Z, Li L, Luo J, Wang P, Yu S, Mou T, Zheng X, Hu Z. QTL mapping of combining ability and heterosis of agronomic traits in rice backcross recombinant inbred Lines and hybrid crosses. PLoS ONE (2012) 7(1): e28463

30. Wang P, Xing YZ, Li ZK, Yu S*. Improving rice yield and quality by QTL pyramiding. Mol Breeding (2012) 29:903–913

31. Wang P, Zhou G, Yu H, Yu S. Fine mapping a major QTL for flag leaf size and yield-related traits in rice. Theor Appl Genet (2011) 123:1319–1330

32. Li M, Sun P, Zhou H, Chen S, Yu S*. Identification of quantitative trait loci associated with germination using chromosome segment substitution lines of rice (Oryza sativa L.). Theor Appl Genet (2011) 123:411–420

33. Ding ZH, Wang CR, Chen S, Yu S*. Diversity and selective sweep in the OsAMT1;1 genomic region of rice. BMC Evol Biology (2011) 11: 61. http://www.biomedcentral.com /1471-2148/11/61

34. Kovi MR, Zhang Y, Yu S, Yang G, Yan W, Xing Y*. Candidacy of a chitin-inducible gibberellin-responsive gene for a major locus affecting plant height in rice that is closely linked to Green Revolution gene sd1. Theor Appl Genet (2011) 123:705–714.

35. Wang CR, Chen S, Yu S*. Functional markers developed from multiple loci in GS3 for fine marker-assisted selection of grain length in rice. Theor Appl Genet (2011) 122: 905–913

36. Yan WH#, Wang P#, Chen HX, Zhou HJ, Li QP, Wang CR, Ding ZH, Zhang Y, Yu S*, Xing YZ*, Zhang Q. A Major QTL, Ghd8, plays pleiotropic roles in regulating grain productivity, plant height, and heading date in rice. Mol Plant (2011) 4: 319–330

37. Tan CJ, Sun YJ, Xu HS, Yu S*. Identification of quantitative trait locus and epistatic interaction for degenerated spikelets on the top of panicle in rice. Plant Breeding (2011) 130: 177–184

38. Ali ML, Sanchez PL, Yu S, Lorieux M, Eizenga GC*. Chromosome segment substitution lines: A powerful tool for the introgression of valuable genes from oryza wild species into cultivated rice (O. sativa). Rice (2010) 3: 218–234

39. Wang J, Yu HH, Xie WB, Xing YZ, Yu S, Xu CG, Li XH, Xiao JH, Zhang Q*. A global analysis of QTLs for expression variations in rice shoots at the early seedling stage. The Plant J (2010) 63: 1063–1074

40. Xie W, Feng Q, Yu H, Huang X, Zhao Q, Xing Y, Yu S, Han B, Zhang Q*. Parent-independent genotyping for constructing an ultrahigh-density linkage map based on population sequencing. Proc Natl Acad Sci USA (2010) 107: 10578–10583

41. Mao HL, Sun SY, Yao JL, Wang CR, Yu S, Xu CG, Li XH, Zhang Q*. Linking differential domain functions of the GS3 protein to natural variation of grain size in rice. Proc Natl Acad Sci. USA (2010) 107: 19579–19584

42. Wen WW, Mei HW, Feng FJ, Yu S, Huang ZC, Wu JH, Chen, Xu XY, Luo L*. Population structure and association mapping on chromosome 7 using a diverse panel of Chinese germplasm of rice (Oryza sativa L.). Theor Appl Genet (2009) 119:459–470

43. Fan CC, Yu S, Wang CR, Xing Y*. A causal C–A mutation in the second exon of GS3 highly associated with rice grain length and validated as a functional marker. Theor Appl Genet (2009) 118:465–472

44. Zhao LN#, Zhou HJ#, Lu LX, Liu L, Li XH, Lin YJ*, Yu S*. Identification of quantitative trait loci controlling rice mature seed culturability using chromosomal segment substitution lines. Plant Cell Rep (2009) 28:247–256

45. Wang Y, Sun YJ, Chen DY and Yu S*. Analysis of quantitative trait loci in response to nitrogen and phosphorus deficiency in rice using chromosomal segment substitution lines. Acta Agron Sin (2009) 35(4): 580–587

46. Zeng B, Li Min, Yang ZY, Tan CJ, Dong HL and Yu S*. Mapping of a novel semisterile pollen QTL in rice. Acta Agron Sin (2009) 35(9): 1584–1589

47. Zhu LH, Zhong DB, Xu JL, Yu S, Li Z*. Differential expression of lodging resistance related QTLs in rice (Oryza sativa L.). Plant Sci (2008) 175: 898–905

48. Xue W, Xing Y, Weng X, Zhao Yu, Tang W, Wang Lei, Zhou H, Yu S, Xu C, Li X, Zhang Q*. Natural variation in Ghd7 is an important regulator of heading date and yield potential in rice. Nature Genet (2008) 40(6):761–767

49. Cui K, Huang J, Xing Y, Yu S, Xu C, Peng S*. Mapping QTLs for seedling characteristics under different water supply conditions in rice (Oryza sativa). Physiologia Plantarum  (2008) 132: 53–68

50. Li ZK, Arif M, Zhong DB, Fu BY, Xu JL, Domingo-Rey J, Ali J, Vijayakumar CHM, Yu S, Khush GS*. Complex genetic networks underlying the defensive system of rice (Oryza sativa L.) to Xanthomonas oryzae pv. Oryzae. Proc Natl Acad Sci. USA (2006) 103: 7994–7999

51. Ali AJ, Xu JL, Ismail AM, Fu BY, Vijaykumar CHM, Gao YM, Domingo J, Maghirang R, Yu S, Gregorio G, Yanaghihara S, Cohen M, Carmen B, Mackill D, Li Z*. Hidden diversity for abiotic and biotic stress tolerances in the primary gene pool of rice revealed by a large backcross breeding program. Field Crops Res (2006) 97: 66–76

52. Lafitte HR, Li ZK, Vijayakumar CHM, Gao YM, Shi Y, Xu JL, Fu BY, Yu S, Ali AJ, Domingo J, Maghirang R, Torres R, Mackill D. Improvement of rice drought tolerance through backcross breeding: Evaluation of donors and selection in drought nurseries. Field Crops Res (2006) 97:77–86

53. Zhang ZH, Yu S, Yu T, Huang Z, Zhu Y*. Mapping quantitative trait loci (QTLs) for seedling-vigor using recombinant inbred lines of rice. Field Crop Res (2005) 90:161-170

54. Xu JL, Yu S, Luo LJ, Zhong DB, Mei HW, Li Z*. Molecular dissection of the primary sink size and its related traits in rice. Plant Breeding (2004) 123:43–50

55. Li ZK, Yu S, Lafitte HR, Huang N, Courtois B, Hittalmani S, Vijayakumar CHM, Liu GF,  Wang GC, Shashidhar HE, Zhuang JY, Zheng KL, Singh VP, Sidhu JS, Srivantaneeyakul S, Khush GS. QTL x environment interactions in rice. I. Heading date and plant height. Theor Appl Genet (2003) 108: 141–153

56. Yu S#, Xu WJ#, Vijayakumar CH, Ali J, Fu BY, Xu JL, Jiang YZ, Marghirang R, Domingo J, Aquino C, Virmani SS, Li Z*. Molecular diversity and multilocus organization of the parental lines used in the International Rice Molecular Breeding Program. Theor Appl Genet (2003) 108:131–-140

57. Cui KH, Peng SB, Xing YZ, Yu S, Xu CG, Zhang Q*. Molecular dissection of the genetic relationships of source, sink and transport tissue with yield traits in rice. Theor Appl Genet (2003) 106:649–-658

58. Hua JP, Xing YZ, Wu W, Xu CG, Sun X, Yu S, Zhang Q*. Single-locus heterotic effects and dominance by dominance interactions can adequately explain the genetic basis of heterosis in an elite rice hybrid. Proc Natl Acad Sci USA (2003) 100: 2574–2579

59. Cui KH, Peng SB, Xing YZ, Xu CG, Yu S, Zhang Q*. Molecular dissection of seedling-vigor and associated physiological traits in rice. Theor Appl Genet (2002) 105:745–753

60. Hua JP, Xing YZ, Xu CG, Sun XL, Yu S, Zhang Q*. Genetic dissection of an elite rice hybrid revealed that heterozygotes are not always advantageous for performance. Genetics  (2002) 162:1885–1895

61. Yu S, JX. Li, CG. Xu, YF. Tan, XH. Li, Zhang Q*. Identification of quantitative trait loci and epistatic interaction for plant height and heading date in rice. Theor Appl Genet (2002) 104: 619–625

62. Li JX, Yu S, Xu CG, Tan YF, Gao YJ, Li XH, Zhang Q*. Analyzing quantitative trait loci for yield using a vegetatively replicated F2 population from a cross between the parents of an elite rice hybrid. Theor Appl Genet (2000) 101: 248–254

63. Tan YF, Xing YZ, Li JX, Yu S, Xu CG, Zhang Q*. Genetic bases of appearance quality of rice grains in Shanyou 63, an elite rice hybrid. Theor Appl Genet (2000) 101:823–829

64. Tan YF, Li JX, Yu S, Xu CG, Zhang Q*. The three important traits for cooking and eating quality of rice grains are controlled by a single locus in an elite rice hybrid, Shanyou 63, Theor Appl Genet (1999) 99: 642–648

65. Yu S, Li JX, Xu CG, Tan YF, Gao YJ, Li XH, Zhang Q*. Epistasis plays an important role as the genetic basis of heterosis in rice. Science in China (series C) (1998) 41(3): 293–302

66. Yao FY, Xu CG, Yu S, Zhang Q*. Mapping and genetic analysis of two fertility restorer loci in the wild-abortive cytoplasmic male sterility system of rice (Oryza sativa L.) Euphytica  (1997) 98:183–187

67. Yu S, Li JX, Xu CG, Tan YF, Gao YJ, Li XH, Zhang Q* and Saghai Maroof MA Importance of epistasis as the genetic basis of heterosis in an elite rice hybrid. Proc Natl Acad Sci. USA  (1997) 94: 9226–9231

68. 余四斌*,熊银,肖景华,罗利军,张启发 (2016). 杂交稻与绿色超级稻. 科学通报 61:1-7

69. 余四斌*,孙文强,王记林,黎志康 (2016). 水稻种质资源及其在功能基因组中的应用. 生命科学 28: 1121-1128

70. 余四斌*,汤欣欣,罗利军 (2016). 功能基因组与绿色超级稻培育的研究进展. 生命科学 28: 1287-1294

71. 余四斌 (2010) 水稻重要性状的等位基因研究进展. 分子植物育种 8(6): 1059–1067

72. 陈雅,包亮,王利凯,赵磊,余四斌,须健*(2012)水稻冠根数目多样性与生长素的关系. 中文字幕日产乱码2020芒果学报 31:410-413

73. 李雪梅,何宗顺,余四斌,陈国兴,吴昌银*(2012)水稻穗形态建成基因PMM 1的遗传分析与初步定位. 中文字幕日产乱码2020芒果学报 31:10-15

74. 孙永建, 周济, 徐华山, 余四斌*2010)利用代换系分析水稻株高QTL及其互作效应. 分子植物育种 8: 1068–1073

75. 吕海霞, 周广生, 丁泽红, 孙永建, 余四斌*2010)水稻染色体片段代换系对氮反应的QTL 分析. 分子植物育种 8: 1074–1081

76. 张晨昕, 邱先进,  董华林,  余四斌*( 2010) 野生稻染色体片段代换系构建及其效应分析. 分子植物育种 8: 1113–1119

77. 董华林, 张晨昕, 曾波, 孙文强, 余四斌* (2009) 利用野生稻高代回交群体分析水稻农艺性状QTL. 中文字幕日产乱码2020芒果学报28: 645-650

78. 陈庆全, 余四斌, 李春海, 牟同敏* (2008) 水稻抽穗开花期耐热性QTL的定位分析. 中国农业科学 41:315-321

79. 徐华山,孙永建,周红菊,余四斌*2007)构建水稻优良恢复系背景的重叠片段代换系及其效应分析. 作物学报33: 979–986

80. 陈庆全,穆俊祥,周红菊,余四斌* (2007) 利用基础导入系分析粳稻基因的遗传效应. 中国农业科学 40:2387–2394

81. 余四斌*, 穆俊祥, 赵胜杰, 周红菊, 谭友斌, 徐才国, 罗利军, 张启发(2005) 以珍汕97B和9311为背景的导入系构建及其筛选鉴定. 分子植物育种 3:629–636

82. 周红菊, 穆俊祥, 赵胜杰, 余四斌*(2005) 水稻高世代回交导入系耐盐性的遗传研究. 分子植物育种 3:716–720

83. 赵胜杰,重荣,余四斌* (2004) 转基因种子检测的二维取样分析方法. 农业生物技术学报 12:608-609

教材与著作

1. 作物种子学(第二版)副主编,2019,中国农业出版社

2. 作物功能基因组学》,参编,2019,科学出版社

3. 种子加工与贮藏(第版),参编,2019,中国农业出版社

4. 遗传学(第版),参编,2017,高等教育出版社

5. 资源节约型、环境友好型农业生产体系的理论与实践》,参编,2015,科学出版社

6. 种子检验学》,参编,2015,科学出版社

7. 绿色超级稻的构想与实践》,参编,2010,科学出版社

8. 《中国水稻遗传育种与品种系谱》,参编,2010,中国农业出版社

9. 《植物生物技术》,副主编,2004,科学出版社

     10.  Rice Breeding and Genetics: Research Priorities and Challenges (J.S Nanda, ed), Oxford & IBH Publish Co. (1999) PP. 241–270


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友情链接:

院系网站链接
动物科学技术学院,动物医学院 资源与环境学院 生命科学技术学院 园艺林学学院 水产学院 工学院 院庆网站
高校网站链接
中国农业科学院 中国科学院 西北农林科技大学 华中科技大学 南京农业大学 中国农业大学
教育网站链接
国家自然科学基金委员会 中华人民共和国农业农村部 中华人民共和国科学技术部 中华人民共和国教育部
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