[1] Salas F M G, Becraft P W, Yin Y, Lübberstedt T. From dwarves to giants? Plant height manipulation for biomass yield. Trends in Plant Science, 2009, 14(8): 454-461.
[2] Mock J J, Pearce R B. An ideotype of maize. Euphytiea, 1975, 24(3): 613-632.
[3] Park K Y, Kang Y K, Park S U, Hyeon G. Effects of planting density and tiller removal on growth and yield of sweet corn hybrids. Korean Journal of Crop Science, 1989, 34(2): 192-197.
[4] Khush G S. Green revolution: Preparing for 21st century, Genome, 1999, 42: 646-655.
[5] Begna S H, Hamilton R I, Dwyer L M, Stewart D W, Smith D L. Variability among maize hybrids differing in canopy architecture for above-ground dry matter and grain yield. Maydica, 2000, 45: 135-141.
[6] 兰进好, 褚栋. 玉米株高和穗位高遗传基础的QTL剖析. 遗传, 2005, 27(6): 69-78.
Lan J H, Zhu D. Study on the genetic basis of plant height and ear height in maize (Zea mays L.) by QTL dissection. Hereditas, 2005, 27(6): 69-78. (in Chinese)
[7] 李清超, 李永祥, 杨钊钊, 刘成, 刘志斋, 李春辉, 彭勃, 张岩, 王迪, 谭巍巍, 孙宝成, 石云素, 宋燕春, 张志明, 潘光堂, 黎裕, 王天宇. 基于多重相关RIL群体的玉米株高和穗位高QTL定位. 作物学报, 2013, 39(9): 1521-1529.
Li Q C, Li Y X, Yang Z Z, Liu C, Liu Z Z, Li C H, Peng B, Zhang Y, Wang D, Tan W W, Sun B C, Shi Y S, Song Y C, Zhang Z M, Pan G T, Li Y, Wang T Y. QTL mapping for plant height and ear height by using multiple related RIL populations in maize. Acta Agronomic Sinica, 2013, 39(9): 1521-1529. (in Chinese)
[8] Beavis W D, Grant D, Albertsen M, Fincher R. Quantitative trait loci for plant height in four maize populations and their associations with qualitative genetic. Theoretical and Applied Genetics, 1991, 83(2): 141-145.
[9] 杨晓军, 路明, 张世煌, 周芳, 曲延英, 谢传晓. 玉米株高和穗位高的QTL定位. 遗传, 2008, 30(11): 1477-1486.
Yang X J, Lu M, Zhang S H, Zhou F, Qu Y Y, Xie C X. QTL mapping of plant height and ear position in maize (Zea mays L.). Hereditas, 2008, 30(11): 1477-1486. (in Chinese)
[10] Zhang Y, Li Y X, Yang W, Liu Z Z, Cheng L, Bo P, Song Y C. Stability of QTL Across environments and QTL-by-environment interactions for plant and ear height in maize. Agricultural Sciences in China, 2010, 9(10): 1400-1412.
[11] Peiffer J A, Romay M C, Gore M A, Flint-Garcia S A, Zhang Z, Millard M J, Buckler E S. The genetic architecture of maize height. Genetics, 2014, 196(4): 1337-1356.
[12] Winkler R G, Helentjaris T. The maize Dwarf3 gene encodes a cytochrome P450-mediated early step in gibberellin biosynthesis. The Plant Cell, 1995, 7(8): 1307-1317.
[13] Thornsberry J M, Goodman M M, Doebley J, Kresovich S, Nielsen D, Buckler E S. Dwarf8 polymorphisms associate with variation in flowering time. Nature Genetics, 2001, 28(3): 286-289.
[14] Multani D S, Briggs S P, Chamberlin M A, Blakeslee J J, Murphy A S, Johal G S. Loss of an MDR transporter in compact stalks of maize br2 and sorghum dw3 mutants. Science, 2003, 302(5642): 81-84.
[15] Teng F, Zhai L, Liu R, Bai W, Wang L, Huo D, Zhang Z. ZmGA3ox2, a candidate gene for a major QTL, qPH3.1, for plant height in maize. The Plant Journal, 2013, 73(3): 405-416.
[16] 邢安琪. 玉米株高主效QTL-qph1及ys基因及其修饰因子ys-modifier的克隆、功能验证及机理研究[D]. 北京: 中国农业大学, 2014.
Xing A Q. Positional cloning and dissection of a major plant height QTL-qph1 and the ys mutant gene and its modifier in maize [D]. Beijing: China Agricultural University, 2014. (in Chinese)
[17] Nyquist W E, Baker R J. Estimation of heritability and prediction of selection response in plant populations. Critical Reviews in Plant Sciences, 1991, 10(3): 235-322.
[18] Henderson C R. General flexibility of linear model techniques for sire evaluation. Journal of Dairy Science, 1974, 57(8): 963-972.
[19] Zhu J. Analysis of conditional genetic effects and variance components in developmental genetics. Genetics, 1995, 141(4): 1633-1639.
[20] Maroof M A S, Biyashev R M, Yang G P, Zhang Q, Allard R W. Extraordinarily polymorphic microsatellite DNA in barley: Species diversity, chromosomal locations, and population dynamics. Proceedings of the National Academy of Sciences of the USA, 1994, 91(12): 5466-5470.
[21] Tanksley S D. Mapping polygenes. Annual Review of Genetics, 1993, 27(1): 205-233.
[22] 孙晓梅, 杨秀艳. 林木育种值预测方法的应用与分析. 北京林业大学学报, 2011, 33(2): 65-71.
Sun X M, Yang X Y. Applications and analysis of methods for breeding value prediction in forest trees. Journal of Beijing Forestry University, 2011, 33(2): 65-71. (in Chinese)
[23] 刘小刚. 玉米茎秆强度QTL定位研究[D]. 北京: 中国农业科学院, 2014.
Liu X G. Quantitative trait locus analysis of stalk strength in maize [D]. Beijing: Chinese Academy of Agricultural Sciences, 2014. (in Chinese)
[24] 郑德波, 杨小红, 李建生, 严建兵, 张士龙, 贺正华, 黄益勤. 基于SNP标记的玉米株高及穗位高QTL定位. 作物学报, 2013, 39(3): 549-556.
Zheng D B, Yang X H, Li J S, Yan J B, Zhang S L, He Z H, Huang Y Q. QTL identification for plant height and ear height based on SNP mapping in maize (Zea mays L.). Acta Agronomic Sinica, 2013, 39(3): 549-556. (in Chinese)
[25] 宋方威, 彭惠茹, 刘婷, 张义荣, 孙其信, 倪中福. 利用三重测交群体剖析玉米株高与穗位高杂种优势的遗传学基础. 作物学报, 2011, 37(7): 1186-1195.
Song F W, Peng H R, Liu T, Zhang Y R, Sun Q X, Ni Z F. Heterosis for plant height and ear position in maize revealed by quantitative trait loci analysis with triple testcross design. Acta Agronomic Sinica, 2011, 37(7): 1186-1195. (in Chinese)
[26] Liu G F, Yang J, Xu H M, Hayat Y, Zhu J. Genetic analysis of grain yield conditioned on its component traits in rice (Oryza sativa L.). Crop and Pasture Science, 2008, 59(2): 189-195.
[27] Zhao J Y, Becker H C, Zhang D Q, Zhang Y F, Ecke W. Conditional QTL mapping of oil content in rapeseed with respect to protein content and traits related to plant development and grain yield. Theoretical and Applied Genetics, 2006, 113(1): 33-38.
[28] 彭勃, 王阳, 李永祥, 刘成, 张岩, 刘志斋, 谭巍巍, 王迪, 孙宝成, 石云素, 宋艳春, 王天宇, 黎裕. 玉米籽粒产量与产量构成因子的关系及条件QTL分析. 作物学报, 2010, 36(10): 1624-1633.
Peng B, Wang Y, Li Y X, Liu C, Zhang Y, Liu Z Z, Tan W W, Wang D, Sun B C, Shi Y S, Song Y C, Wang T Y, Li Y. Correlation analysis and conditional QTL analysis of grain yield and yield components in maize. Acta Agronomica Sinica, 2010, 36(10): 1624-1633. (in Chinese)
[29] Kozumplik V, Pejic I, Senior L, Pavlina R, Graham G, Stuber C W. Use of molecular markers for QTL detection in segregating maize populations derived from exotic germplasm. Maydica, 1996, 41(3): 211-217.
[30] Melchinger A E, Utz H F, Schön C C. Quantitative trait locus (QTL) mapping using different testers and independent population samples in maize reveals low power of QTL detection and large bias in estimates of QTL effects. Genetics, 1998, 149(1): 383-403.
[31] Berke T G, Rocheford T R. Quantitative trait loci for flowering, plant and ear height, and kernel traits in maize. Crop Science, 1995, 35(6): 1542-1549.
[32] Beavis W D, Smith O S, Grant D, Fincher R. Identification of quantitative trait loci using a small sample of topcrossed and F4 progeny from maize. Crop Science, 1994, 34(4): 882-896.
[33] Schön C C, Melchinger A E. RFLP mapping in maize: Quantitative trait loci affecting testcross performance of elite European flint lines. Crop Science, 1994, 34(2): 378-389.
[34] Lübberstedt T, Melchinger A E, Schön C C, Utz H F, Klein D. QTL mapping in testcrosses of European flint lines of maize: I. Comparison of different testers for forage yield traits. Crop Science, 1997, 37(3): 921-931.
[35] Lawit S J, Wych H M, Xu D, Kundu S, Tomes D T. Maize DELLA proteins dwarf plant8 and dwarf plant9 as modulators of plant development. Plant & Cell Physiology, 2010, 51(11): 1854-1868.
[36] 张岩. 玉米株高和穗位高QTL定位与遗传基础研究[D]. 北京: 中国农业科学院, 2010.
Zhang Y. Mapping of quantitative trait loci (QTL) and genetic basis for plant height and ear height in maize [D]. Beijing: Chinese Academy of Agricultural Sciences, 2010. (in Chinese) |