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作物学报 ›› 2022, Vol. 48 ›› Issue (5): 1141-1151.doi: 10.3724/SP.J.1006.2022.12024

• 作物遗传育种·种质资源·分子遗传学 • 上一篇    下一篇

基于染色体片段置换系群体检测水稻株型性状QTL

王小雷(), 李炜星, 欧阳林娟, 徐杰, 陈小荣, 边建民, 胡丽芳, 彭小松, 贺晓鹏, 傅军如, 周大虎, 贺浩华, 孙晓棠*(), 朱昌兰*()   

  1. 江西农业大学 / 作物生理生态与遗传育种教育部重点实验室 / 江西省超级稻工程技术研究中心, 江西南昌 330045
  • 收稿日期:2021-04-07 接受日期:2021-09-09 出版日期:2022-05-12 网络出版日期:2021-10-15
  • 通讯作者: 孙晓棠,朱昌兰
  • 作者简介:E-mail: wxl0vip@163.com
  • 基金资助:
    国家自然科学基金项目(31860373);江西省“5511”优势科技创新团队项目资助(20165BCB19005)

QTL mapping for plant architecture in rice based on chromosome segment substitution lines

WANG Xiao-Lei(), LI Wei-Xing, OU-YANG Lin-Juan, XU Jie, CHEN Xiao-Rong, BIAN Jian-Min, HU Li-Fang, PENG Xiao-Song, HE Xiao-Peng, FU Jun-Ru, ZHOU Da-Hu, HE Hao-Hua, SUN Xiao-Tang*(), ZHU Chang-Lan*()   

  1. Key Laboratory of Crop Physiology, Ecology and Genetic Breeding, Ministry of Education / College of Agronomy, Jiangxi Agricultural University / Research Center of Super Rice, Engineering and Technology, Nanchang 330045, Jiangxi, China
  • Received:2021-04-07 Accepted:2021-09-09 Published:2022-05-12 Published online:2021-10-15
  • Contact: SUN Xiao-Tang,ZHU Chang-Lan
  • Supported by:
    National Natural Science Foundation of China(31860373);“5511” Superior Science and Technology Innovation Team Project of Jiangxi Province, China(20165BCB19005)

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摘要:

株型是由多个形态和生理性状集成的复合性状, 它与水稻产量密切相关。挖掘优异株型等位基因或QTL, 对水稻超高产育种具有重要意义。本研究利用籼稻昌恢121和粳稻Koshihikari构建的208个染色体片段置换系(chromosome segment substitution lines, CSSLs), 在3个环境下, 对控制株高、剑叶形态和分蘖数的QTL进行检测, 共鉴定到35个株型性状QTL, 分布于11条染色体上(除9号染色体以外), 解释表型变异2.00%~22.86%。值得关注的是qPH-1-1qFLW-6qFLA-3均能在3个环境下被检测到, 其中qFLW-6为1个新鉴定到的剑叶宽QTL。对qPH-1-1qFLA-3位点进行鉴定, 验证了这2个位点等位基因的加性效应和环境稳定性。本研究为株型性状QTL的进一步精细定位、克隆及分子辅助聚合育种奠定了基础。

关键词: 水稻, 染色体片段置换系, 株型, 数量性状基因座位

Abstract:

Plant architecture is a compound trait integrated with multiple morphological and physiological traits, and it is closely related to rice yield. Deciphering excellent plant architecture alleles or QTLs is of great significance for high-yield rice breeding. In this study, we constructed a set of Changhui 121/Koshihikari chromosome segment substitution lines (CSSLs) with the size of 208 in our laboratory. QTLs controlling plant height, flag leaf morphology, and tiller numbers were detected under three environments. A total of 35 QTLs for rice architecture were identified on 11 chromosomes except chromosome 9, and the range of the phenotypic variation explaining was 2.00%-22.86%. It was worth noting that qPH-1-1, qFLW-6, and qFLA-3 could be detected in three environments, among which qFLW-6 was a newly identified QTL of the flag leaf width. Phenotypic identification verified that the additive effects and environmental stability of the two locus alleles by the replacement lines carrying qPH-1-1 and sites. The results of this study laid the foundation for further fine mapping and cloning of QTLs for rice plant architecture and the molecular marker-assisted selection (MAS) in rice breeding.

Key words: rice, chromosome segment substitution lines, plant architecture, quantitative trait locus

表1

昌恢121、Koshihikari和208个CSSLs的种植环境"

环境Environment 重复数Replication 种植地点Crop location 种植季节Crop season
E1 3 江西南昌(北纬28.45°, 东经115.50°)
Nanchang, Jiangxi (28.45°N, 115.50°E)		 2015年5月-10月
May to October in 2015
E2 3 三亚海南(北纬18.14°, 东经109.31°)
Sanya, Hainan (18.14°N, 109.31°E)		 2015年12月-2016年5月
December 2015 to May 2016
E3 3 江西南昌(北纬28.45°, 东经115.50° )
Nanchang, Jiangxi (28.45°N, 115.50°E)		 2016年5月-10月
May to October in 2016

表2

株型性状的测量方法"

性状Trait 考察记录方法 Investigation method
株高Plant height (cm) 穗颖尖到地面的高度
Height of spike tip to ground
剑叶长Flag leaf length (cm) 剑叶基部到顶端的长度
The length of the flag leaf from base to tip
剑叶宽Flag leaf width (cm) 剑叶最宽处的长度
The length of the widest point of the flag leaf
剑叶夹角Flag leaf angel (o) 剑叶与叶枕的连线与主茎延长线所成角度
The angle between the flag leaf and the main stem
分蘖数Tiller numbers (tillers per plant) 成熟期能抽穗且能结实10粒以上的分蘖数
Tillers that can produce more than 10 grains at maturity are called effective tillers

图1

昌恢121和Koshihikari的株型性状"

表3

昌恢121、Koshihikari和208个CSSLs的株型性状"

性状
Trait		 环境
Environment		 亲本Parents 208个染色体片段置换系 208 CSSLs
昌恢121
Changhui 121
(mean ± SD)		 Koshihikari
(mean ± SD)		 Mean ± SD 范围
Range		 峰度
Kurtosis		 偏度
Skewness		 遗传率
hB2
株高
Plant height (cm)		 E1 128.20 ± 2.12** 107.20 ± 2.30 128.40 ± 0.42 76.00-174.30 1.40 0.89 0.98
E2 97.20 ± 0.41** 86.00 ± 0.76 92.70 ± 0.28 72.30-128.00 0.25 0.77 0.99
E3 124.00 ± 2.28** 97.70 ± 5.17 121.00 ± 11.80 91.00-155.00 0.14 0.77 0.75
剑叶长
Flag leaf length (cm)		 E1 29.90 ± 2.15 31.70 ±1.86 31.60 ± 0.29 18.30-43.10 1.53 0.71 0.89
E2 25.40 ± 1.63 24.72 ± 1.22 22.93 ± 0.12 16.60-51.30 1.90 0.69 0.97
E3 37.00 ± 0.14* 30.70 ± 0.17 33.80 ± 3.72 25.20-51.80 2.02 0.46 0.83
剑叶宽
Flag leaf width (cm)		 E1 1.80 ± 0.58** 1.30 ± 0.58 1.80 ± 0.58 1.00-2.20 0.80 0.69 0.97
E2 1.80 ± 0.08** 1.24 ± 0.06 1.41 ± 0.00 1.00-2.00 1.89 0.41 0.99
E3 2.00 ± 0.01** 1.20 ± 1.00 1.60 ± 0.14 1.00-2.20 1.21 0.12 0.78
剑叶夹角
Flag leaf angle (o)		 E1 13.00 ± 1.53 40.00 ± 14.71** 11.00 ± 0.00 4.00-51.00 0.88 1.49 0.52
E2 13.78 ± 1.40 35.22 ± 1.64** 15.14 ± 0.20 4.00-51.30 1.79 0.97 0.89
E3 9.00 ± 1.00 30.30 ± 1.33** 15.00 ± 5.52 4.00-38.00 1.42 0.85 0.92
分蘖数
Tiller numbers		 E1 9.00 ± 2.08 11.00 ± 2.00 8.00 ± 0.00 5.00-14.00 0.15 0.96 0.97
E2 10.00 ± 0.47 14.00 ± 0.63* 8.00 ± 0.23 4.00-15.00 1.17 0.45 0.99
E3 10.00 ± 1.13 12.00 ± 1.34 8.00 ± 1.61 5.00-13.00 1.66 1.14 0.97

图2

208个CSSLs的株型分布图 2015 JXNC: 2015江西南昌中稻季; 2016 HNSY: 2016海南三亚; 2016 JXNC: 2016江西南昌中稻季。FLW: 剑叶宽; FLL: 剑叶长; FLA: 剑叶夹角; PH: 株高; TN: 分蘖数。"

表4

株型性状之间的相关系数"

性状
Trait		 环境
Environment		 株高
Plant height		 剑叶长
Flag leaf length		 剑叶宽
Flag leaf width		 剑叶夹角
Flag leaf angle
剑叶长 Flag leaf length E1 0.305**
E2 0.177*
E3 0.207**
剑叶宽 Flag leaf width E1 0.115 0.308**
E2 0.135 0.401**
E3 0.156 0.243**
剑叶夹角 Flag leaf angle E1 0.238** 0.124 0.146
E2 0.209** 0.087 0.038
E3 0.315** 0.172 0.153
分蘖数 Tiller numbers E1 0.098 0.097 0.194 0.106
E2 0.009 0.117 0.078 0.056
E3 0.106 0.108 0.112 0.083

表5

昌恢121/Koshihikari 208个CSSLs群体检测到的株型性状QTL"

性状
Trait		 QTL 染色体Chr. 标记区间
Marker interval		 LOD值
LOD score		 表型贡献率
Phenotypic variation
explained (%)		 加性效应
Additive effects (Add)
E1 E2 E3 E1 E2 E3 E1 E2 E3
株高
Plant height		 qPH-1-1 1 RM5423-RM5302 6.60 6.04 4.10 9.27 7.17 3.44 18.58 11.92 15.42
qPH-1-2 1 RM5389-RM6696 9.59 11.51 13.93 14.53 13.97 10.42
qPH-2-1 2 RM5812-RM1211 3.69 4.27 5.04
qPH-2-2 2 RM7451-RM154 4.14 3.48 15.52
qPH-3 3 RM5891-RM5475 3.62 5.30 4.92 4.51 6.61 14.50
qPH-4 4 RM5503-RM5879 3.54 4.80 7.88
qPH-5 5 RM3345-RM7444 8.39 10.22 8.74
qPH-7 7 RM8262-RM7273 3.07 3.53 5.97
qPH-12 12 RM6288-RM19 4.25 4.94 4.42
剑叶长
Flag leaf length		 qFLL-5-1 5 RM3476-RM178 10.00 7.41 9.42
qFLL-5-2 5 RM3790-RM7423 19.15 15.80 9.74
qFLL-6 6 RM7641-RM3138 2.59 4.79 -2.49
qFLL-7 7 RM5711-RM8263 2.96 2.03 1.59
qFLL-12 12 RM6869-RM3331 6.86 13.97 6.97
剑叶宽
Flag leaf width		 qFLW-1 1 RM3530-RM8111 5.50 4.39 4.97 7.48 0.12 0.10
qFLW-3 3 RM1164-RM3646 4.03 3.59 0.09
qFLW-4 4 RM6089-RM5503 2.64 6.32 2.31 11.01 0.05 0.11
qFLW-5 5 RM3345-RM7444 21.11 6.13 22.86 10.64 0.16 0.09
qFLW-6 6 RM3628-RM5371 15.83 3.31 9.88 16.17 2.94 9.38 6.91 1.95 0.32
qFLW-7 7 RM3394-RM5752 3.58 3.16 0.06
qFLW-10 10 RM484-RM591 3.97 3.55 1.49
剑叶夹角
Flag leaf angle		 qFLA-1-1 1 RM6387-RM5389 5.67 5.16 2.78
qFLA-1-2 1 RM6296-RM5362 13.59 21.11 11.02
qFLA-2 2 RM1358-RM5812 9.74 9.76 7.03 8.42 5.09 7.78
qFLA-3 3 RM3513-RM2334 10.07 9.98 12.87 9.63 14.87 11.51 3.31 6.61 3.86
qFLA-4 4 RM5412-RM3471 6.97 5.82 2.68
qFLA-5 5 RM3328-RM2998 9.76 8.42 4.34
qFLA-6 6 RM3628-RM5371 15.83 16.17 6.91
qFLA-10 10 RM484-RM591 3.97 3.55 1.49
分蘖数
Tiller numbers		 qTN-1 1 RM259-RM5496 3.35 7.02 1.22
qTN-5-1 5 RM1237-RM305 5.11 10.93 1.69
qTN-5-2 5 RM3328-RM2998 7.42 2.89 1.38
qTN-6 6 RM6275-RM3628 2.70 4.02 5.06 7.64 0.97 2.89
qTN-8 8 RM4085-RM6838 2.80 7.90 5.83 2.00 0.73 1.58
qTN-11 11 RM3717-RM1812 2.60 4.87 0.95

图3

昌恢121/Koshihikari 208个CSSLs中检测到的株型性状QTL在染色体上的分布 PH: 株高; FLL: 剑叶长; FLW: 剑叶宽; FLA: 剑叶夹角; TN: 分蘖数。2015 JXNC: 2015年江西南昌中稻季; 2016 SYHN: 2016年海南三亚; 2016 JXNC: 2016年江西南昌中稻季。"

表6

2个亲本和目标置换系在3个环境中的株型性状"

QTL位点
QTL locus		 株系
Line		 标记Marker 剑叶角表型值 FLA of phenotypic value (o)
RM3646 RM3513 RM2334 RM5891 2015江西南昌中稻季
2015 JXNC		 2016海南三亚
2016 JXNC		 2016江西南昌中稻季
2016 JXNC
qFLA-3 CH121 A A A A 13.0 13.8 9.0
CSSL8 B B B B 51.2** 36.0** 17.7**
CSSL90 B B B A 19.3** 26.0** 13.8*
CSSL115 A B B B 21.6** 35.3** 25.9**
Koshihikari B B B B 40.0 35.2 30.3
QTL位点
QTL locus		 株系
Line		 标记Marker 株高表型值 PH of phenotypic value (cm)
RM3148 RM5423 RM5302 RM3530 2015江西南昌中稻季
2015 JXNC		 2016海南三亚
2016 JXNC		 2016江西南昌中稻季
2016 JXNC
PH-1-1 CH121 A A A A 128.2 97.2 124.0
CSSL21 A B B B 105.4** 78.7** 103.1**
CSSL49 B B B B 93.2** 74.3** 91.1**
CSSL161 B B B A 112.4** 77.0** 103.2**
Koshihikari B B B B 107.2 86.0 92.7

表7

QTL多效性区域分析"

染色体
Chr.		 标记区间
Marker interval		 性状
Trait		 多效性QTL
Pleiotropic QTLs		 已克隆的基因
Cloning gene		 参考文献
Reference
5 RM3345-RM7444 PH, FLW qPH-5, qFLW-5 EUI1[31]
5 RM3328-RM2998 FLA, TN qFLA-5, qTN-5-2 Yang and Xing[32]
6 RM3628-RM5371 FLW, FLA qFLW-6, qFLA-6 OsSPX1[33], LC3[34] Hong et al.[35], Mei and Luo[36]
10 RM484-RM591 FLW, FLA qFLW-10, qFLA-10 Mei and Li[37]
[1] 马梦影, 巩文靓, 康雪蒙, 段海燕. 水稻理想株型改良的研究进展. 中国农学通报, 2020, 36(29):1-6.
Ma M Y, Gong W L, Kang X M, Duan H Y. The improvement of ideal plant type of rice: a review. Chin Agric Sci Bull, 2020, 36(29):1-6 (in Chinese with English abstract).
[2] 陈温福, 徐正进, 张龙步. 水稻超高产育种——从理论到实践. 沈阳农业大学学报, 2003, 34:324-327.
Chen W F, Xu Z J, Zhang L B. Rice breeding for super high yield—from theories to practices. J Shenyang Agric Univ, 2003, 34:324-327 (in Chinese with English abstract).
[3] 程式华, 曹立勇, 庄杰云, 吴伟明. 关于超级稻品种培育的资源和基因利用问题. 中国水稻科学, 2009, 23:223-228.
Cheng S H, Cao L Y, Zhuang J Y, Wu W M. Discussion on germplasm and gene utilization in breeding of super rice. Chin J Rice Sci, 2009, 23:223-228 (in Chinese with English abstract).
[4] 刘化龙, 杨洛淼, 徐善斌, 刘华东, 邹德堂. 多环境下水稻株型相关性状QTL解析. 东北农业大学学报, 2020, 51:1-9.
Liu H L, Yang L M, Xu S B, Liu H D, Zou D T. QTL analysis on plant type related traits of rice under multi-environment. J Northeast Agric Univ, 2020, 51:1-9 (in Chinese with English abstract).
[5] 周丽慧, 赵春芳, 赵凌, 张亚东, 朱镇, 陈涛, 赵庆勇, 姚姝, 于新, 王才林. 利用染色体片段置换系群体检测水稻叶片形态QTL. 中国水稻科学, 2013, 27:26-34.
Zhou L H, Zhao C F, Zhao L, Zhang Y D, Zhu Z, Chen T, Zhao Q Y, Yao S, Yu X, Wang C L. QTL detection for leaf morphology of rice using chromosome segment substitution lines. Chin J Rice Sci, 2013, 27:26-34 (in Chinese with English abstract).
[6] 李红, 何炜, 连玲, 魏毅东, 蔡秋华, 王颖姮, 谢华安, 张建福. 水稻株型的研究进展. 福建稻麦科技, 2020, 38:61-66.
Li H, He W, Lian L, Wei Y D, Cai Q H, Wang Y H, Xie H A, Zhang J F. Research advances on plant type of rice. Fujian Sci Technol Rice Wheat, 2020, 38:61-66 (in Chinese with English abstract).
[7] Sasaki A, Ashikari M, Ueguchi-Tanaka M, Itoh H, Nishimura A, Swapan D, Ishiyama K, Saito T, Kobayashi M, Khush G S, Kitano H, Matsuoka M. Green revolution: a mutant gibberellin-synthesis gene in rice. Nature, 2002, 416:701-702.
doi: 10.1038/416701a
[8] Tan L B, Li X R, Liu F X, Sun X Y, Li C G, Zhu Z F, Fu Y C, Cai H W, Wang X K, Xie D X, Sun C Q. Control of a key transition from prostrate to erect growth in rice domestication. Nat Genet, 2008, 40:1360-1364.
doi: 10.1038/ng.197
[9] Zhang L, Yu H, Ma B, Liu G F, Wang J J, Wang J M, Gao R C, Li J J, Liu J Y, Xu J, Zhang Y Y, Li Q, Huang X H, Xu J L, Li J M, Qian Q, Han B, He Z H, Li J Y. A natural tandem array alleviates epigenetic repression of IPA1 and leads to superior yielding rice. Nat Commun, 2017, 8:14789.
doi: 10.1038/ncomms14789 pmid: 28317902
[10] Sakamoto T, Morinaka Y, Ohnishi T, Sunohara H, Fujioka S, Ueguchi-Tanaka M, Mizutani M, Sakata K, Takatsuto S, Yoshida S, Tanaka H, Kitano H, Matsuoka M. Erect leaves caused by brassinosteroid deficiency increase biomass production and grain yield in rice. Nat Biotechnol, 2006, 24:105-109.
pmid: 16369540
[11] Jin J, Huang W, Gao J P, Yang J, Shi M, Zhu M Z, Luo D, Lin H X. Genetic control of rice plant architecture under domestication. Nat Genet, 2008, 40:1365-1369.
doi: 10.1038/ng.247
[12] Wang Y H, Li J Y. Rice, rising. Nat Genet, 2008, 40:1273-1275.
doi: 10.1038/ng1108-1273
[13] Jiao Y Q, Wang Y H, Xue D W, Wang J, Yan M X, Liu G F, Dong G J, Zeng D L, Lu Z F, Zhu X D, Qian Q, Li J Y. Regulation of OsSPL14 by OsmiR156 defines ideal plant architecture in rice. Nat Genet, 2010, 42:541-544.
doi: 10.1038/ng.591
[14] Liu M M, Shi Z Y, Zhang X H, Wang M X, Zhang L, Zheng K Z, Liu J Y, Hu X M, Di C R, Qian Q, He Z H, Yang D L. Inducible overexpression of ideal plant architecture1 improves both yield and disease resistance in rice. Nat Plants, 2019, 5:389-400.
doi: 10.1038/s41477-019-0383-2
[15] Wang F, Han T W, Song Q X, Ye W X, Song X G, Chu J F, Li J Y, Chen Z J. The rice circadian clock regulates tiller growth and panicle development through strigolactone signaling and sugar sensing. Plant Cell, 2020, 32:3124-3138.
doi: 10.1105/tpc.20.00289
[16] Wang J, Zhou L, Shi H, Chern M S, Yu H, Yi H, He M, Yin J J, Zhu X B, Li Y, Li W T, Liu J L, Wang J C, Chen X Q, Qing H, Wang Y P, Liu G F, Wang W M, Li P, Wu X J, Zhu L H, Zhou J M, Ronald P C, Li S G, Li J Y, Chen X W. A single transcription factor promotes both yield and immunity in rice. Science, 2018, 361:1026-1028.
doi: 10.1126/science.aat7675
[17] 王小雷, 李炜星, 曾博虹, 孙晓棠, 欧阳林娟, 陈小荣, 贺浩华, 朱昌兰. 基于染色体片段置换系对水稻粒形及千粒重QTL检测与稳定性分析. 作物学报, 2020, 46:1517-1525.
doi: 10.3724/SP.J.1006.2020.02008
Wang X L, Li W X, Zeng B H, Sun X T, Ou-Yang L J, Chen X R, He H H, Zhu C L. QTL detection and stability analysis of rice grain shape and thousand-grain weight based on chromosome segment substitution lines. Acta Agron Sin, 2020, 46:1517-1525 (in Chinese with English abstract).
[18] 孙永建, 周济, 徐华山, 余四斌. 利用代换系分析水稻株高QTL及其互作效应. 分子植物育种, 2010, 8:1068-1073.
Sun Y J, Zhou J, Xu H S, Yu S B. QTL and their interactions for plant height in rice chromosomal substitution segment lines. Mol Plant Breed, 2010, 8:1068-1073 (in Chinese with English abstract).
[19] 杨梯丰, 曾瑞珍, 朱海涛, 陈岚, 张泽民, 丁效华, 李文涛, 张桂权. 水稻粒长基因GS3在聚合育种中的效应. 分子植物育种, 2010, 8:59-66.
Yang T F, Zeng R Z, Zhu H T, Chen L, Zhang Z M, Ding X H, Li W T, Zhang G Q. Effect of grain length geneGS3 in pyramiding breeding of rice. Mol Plant Breed, 2010, 8:59-66 (in Chinese with English abstract).
[20] Hu Z J, Lu S J, Wang M J, He H H, Sun L, Wang H R, Liu X H, Jiang L, Sun J L, Xin X Y, Kong W, Chu C C, Xue H W, Yang J S, Luo X J, Liu J X. A novel QTL qTGW3 encodes the GSK3/SHAGGY-Like kinase OsGSK5/OsSK41 that interacts with OsARF4 to negatively regulate grain size and weight in rice. Mol Plant, 2018, 11:736-749.
doi: 10.1016/j.molp.2018.03.005
[21] Zhang T, Wang S M, Sun S F, Zhang Y, Li J, You J, Su T, Chen W B, Ling Y H, He G H, Zhao F M. Analysis of QTL for grain size in a rice chromosome segment substitution line Z1392 with long grains and fine mapping of qGL-6. Rice, 2020, 13:40.
doi: 10.1186/s12284-020-00399-z pmid: 32529315
[22] 贺浩华, 傅军如, 朱昌兰, 贺晓鹏, 彭小松, 陈小荣, 刘宜柏. 香型超级杂交稻新组合淦鑫688. 杂交水稻, 2008, 23(3):80-82.
He H H, Fu J R, Zhu C L, He X P, Peng X S, Chen X R, Liu Y B. Ganxin 688, a new combination of fragrant super hybrid rice. Hybrid Rice, 2008, 23(3):80-82 (in Chinese with English abstract).
[23] 王小雷, 刘杨, 孙晓棠, 欧阳林娟, 潘锦龙, 彭小松, 陈小荣, 贺晓鹏, 傅军如, 边建民, 胡丽芳, 徐杰, 贺浩华, 朱昌兰. 不同环境下稻米品质性状QTL的检测及稳定性分析. 中国水稻科学, 2020, 34:17-27.
Wang X L, Liu Y, Sun X T, Ou-Yang L J, Pan J L, Peng X S, He X P, Ru J R, Bian J M, Hu L F, Xu J, He H H, Zhu C L. Identification and stability analysis of QTL for grain quality traits under multiple environments in rice. Chin J Rice Sci, 2020, 34:17-27 (in Chinese with English abstract).
[24] Wang J K, Wan X Y, Crossa J, Crouch J, Weng J F, Zhai H Q, Wan J M. QTL mapping of grain length in rice (Oryza sativa L.) using chromosome segment substitution lines. Genet Res, 2006, 88:93-104.
doi: 10.1017/S0016672306008408
[25] Meng L, Li H H, Zhang L Y, Wang J K. QTL IciMapping: integrated software for genetic linkage map construction and quantitative trait locus mapping in biparental populations. Crop J, 2015, 3:269-283.
doi: 10.1016/j.cj.2015.01.001
[26] Voorrips R E. MapChart: software for the graphical presentation of linkage maps and QTLs. J Hered, 2002, 93:77-78.
pmid: 12011185
[27] 邹德堂, 王晋, 王敬国, 刘化龙, 刘宇强, 贾琰. 水稻剑叶形态与单株产量的基因定位分析. 东北农业大学学报, 2014, 45:23-28.
Zou D T, Wang J, Wang J G, Liu H L, Liu Y Q, Jia Y. QTL analysis of flag leaf characteristics and ears weight in rice. J Northeast Agric Univ, 2014, 45:23-28 (in Chinese with English abstract).
[28] 张习春, 张应洲, 圣忠华, 龙武华, 吴健强, 朱速松, 魏祥进. 水稻株型相关性状QTL定位研究. 江苏农业科学, 2019, 47:102-108.
Zhang X C, Zhang Y Z, Sheng Z H, Long W H, Wu J Q, Zhu S S, Wei X J. Study on QTL mapping for plant type traits in rice (Oryza sativa). Jiangsu Agric Sci, 2019, 47:102-108 (in Chinese with English abstract).
[29] 张玲, 李晓楠, 王伟, 杨生龙, 李清, 王嘉宇. 水稻株型相关性状的QTL分析. 作物学报, 2014, 40:2128-2135.
doi: 10.3724/SP.J.1006.2014.02128
Zhang L, Li X N, Wang W, Yang S L, Li Q, Wang J Y. Analysis of QTLs for plant type traits in rice (Oryza sativa). Acta Agron Sin, 2014, 40:2128-2135 (in Chinese with English abstract).
[30] 彭伟业, 孙平勇, 潘素君, 李魏, 戴良英. 水稻品种魔王谷粒形、剑叶性状和株高QTL定位. 作物学报, 2018, 44:1673-1680.
Peng W Y, Sun P Y, Pan S J, Li W, Dai L Y. Mapping QTLs for grain shape, flag leaf traits, and plant height in rice variety Mowanggu. Acta Agron Sin, 2018, 44:1673-1680 (in Chinese with English abstract).
[31] Zhu Y Y, Nomura T, Xu Y H, Zhang Y Y, Peng Y, Mao B Z, Hanada A, Zhou H C, Wang R X, Li P J, Zhu X D, Mander L, Kamiya Y, Yamaguchi S, He Z H. ELONGATED UPPERMOST INTERNODE encodes a cytochrome P450 monooxygenase that epoxidizes gibberellins in a novel deactivation reaction in rice. Plant Cell, 2006, 18:442-456.
doi: 10.1105/tpc.105.038455
[32] Yang G H, Xing Y Z, Li S Q, Ding J Z, Yue B, Deng K, Li Y S, Zhu Y G. Molecular dissection of developmental behavior of tiller number and plant height and their relationship in rice (Oryza sativa L.). Hereditas, 2006, 143:236-245.
doi: 10.1111/j.2006.0018-0661.01959.x
[33] Ruan W Y, Guo M N, Xu L, Wang X Q, Zhao H Y, Wang J M, Yi K K. An SPX-RLI1 module regulates leaf inclination in response to phosphate availability in rice. Plant Cell, 2018, 30:853-870.
doi: 10.1105/tpc.17.00738
[34] Chen S H, Zhou L J, Xu P, Xue H W. SPOC domain-containing protein leaf inclination 3 interacts with LIP1 to regulate rice leaf inclination through auxin signaling. PLoS Genet, 2018, 14:e1007829.
[35] 洪凯, 张斌, 高阳, 阮班普, 彭友林, 马伯军, 钱前, 高振宇. 水稻剑叶夹角和单株产量的QTL分析. 分子植物育种, 2015, 13:761-768.
Hong K, Zhang B, Gao Y, Ruan B P, Peng Y L, Ma B J, Qian Q, Gao Z Y. Dissection of QTLs for flag leaf angel and yield per plant in rice. Mol Plant Breed, 2015, 13:761-768 (in Chinese with English abstract).
[36] Mei H W, Luo J L, Ying C S, Wang Y P, Yu X Q, Guo L B, Paterson A H, Li Z K. Gene actions of QTLs affecting several agronomic traits resolved in a recombinant inbred rice population and two testcross populations. Theor Appl Genet, 2003, 107:89-101.
pmid: 12721635
[37] Mei H W, Li Z K, Shu Q Y, Guo L B, Wang Y P, Yu X Q, Ying C S, Luo L J. Gene actions of QTLs affecting several agronomic traits resolved in a recombinant inbred rice population and two backcross populations. Theor Appl Genet, 2005, 110:649-659.
pmid: 15647921
[38] Marri P R, Sarla N, Reddy L V, Siddiq E A. Identification and mapping of yield and yield related QTLs from an Indian accession of Oryza rufipogon. BMC Genet, 2005, 6:33.
doi: 10.1186/1471-2156-6-33
[39] 张克勤, 戴伟民, 樊叶杨, 沈波, 郑康乐. 水稻剑叶角度与主穗产量的遗传剖析. 中国农学通报, 2008, 24(9):186-192.
Zhang K Q, Dai W M, Fan Y Y, Shen B, Zheng K L. Genetic dissection of flag leave angle and main panicle yield traits in rice. Chin Agric Sci Bull, 2008, 24(9):186-192 (in Chinese with English abstract).
[40] 周丽慧, 谢永楚, 陈涛, 张亚东, 朱镇, 赵庆勇, 姚姝, 于新, 赵凌, 王才林. 水稻剑叶形态与产量的关系及相关性状的QTL分析. 江苏农业学报, 2012, 28:1207-1211.
Zhou L H, Xie Y C, Chen T, Zhang Y D, Zhu Z, Zhao Q Y, Yao S, Yu X, Zhao L, Wang C L. Relations between flag leaf morphology and yield and QTL analysis of related traits. Jiangsu Agric Sci, 2012, 28:1207-1211 (in Chinese with English abstract).
[41] 孙佩, 才宏伟, 卫晓轶. 水稻最高分蘖数和有效分蘖数的QTL分析. 河南农业科学, 2014, 43:12-15.
Sun P, Cai H W, Wei X Y. QTL mapping of maximum tiller number and effective tiller number in rice (Oryza sativa L.). J Henan Agric Sci, 2014, 43:12-15 (in Chinese with English abstract).
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