黄淮南片麦区新育成品种（系）中3个矮秆基因分子标记检测及其与农艺性状的关系

doi:10.16035/j.issn.1001-7283.2019.06.003

摘要/Abstract

摘要：

利用矮秆基因RhtB1-b、RhtD1-b和Rht8特异分子标记对郑麦583和2015-2016年度参加河南省区域试验、河南省品种比较试验、国家黄淮南片区域试验及国家黄淮麦区品种比较试验的共630份小麦材料的基因型进行检测。结果表明,供试材料中检测到549份材料含有RhtB1-b基因;592份材料含有RhtD1-b基因;513份材料含有Rht8基因;422份材料同时含有3个矮秆基因,169份材料仅含有2个矮秆基因,说明3个主要的矮秆基因在河南小麦育种过程中被聚合使用。此外,分析发现,矮秆基因Rht8与株高和每公顷穗数,以及千粒重具有显著相关性。郑麦583等小麦品种聚合了这3个矮秆基因,具有优良的丰产性,通过选择和利用矮秆基因对于培育具有丰产性优点的小麦品种具有一定价值。

关键词: 小麦, 株高, 矮秆基因, 农艺性状

Abstract:

In this study, Zhengmai 583 and 630 materials derived from variety comparison test and regional trials of Yellow-Huai wheat area and Henan Province at 2015-2016 were screened by specific molecular marker of wheat dwarf genes RhtB1-b, RhtD1-b and Rht8. The results showed that 549 wheat materials carried RhtB1-b gene; 592 wheat materials carried RhtD1-b gene; 513 wheat materials carried Rht8 gene; 422 materials carried all 3 dwarfing genes, and additional 169 lines carried 2 dwarfing genes which indicated that the 3 dwarf genes had been fixed in Henan wheat breeding progress. Moreover, Rht8 showed significantly correlation with reducing plant height, spike number per hectare and increasing 1000-kernel weight. Zhengmai 583 carried 3 dwarf genes, showed excellent fertility. The selection and utilization of dwarf genes are of certain value for the cultivation of wheat varieties with high yield.

Key words: Wheat, Plant height, Dwarfing gene, Agronomic traits

曹廷杰,张玉娥,胡卫国,杨剑,赵虹,王西成,周艳杰,赵群友,李会群. 黄淮南片麦区新育成品种（系）中3个矮秆基因分子标记检测及其与农艺性状的关系[J]. 作物杂志, 2019 (6): 14–19

Cao Tingjie,Zhang Yu’e,Hu Weiguo,Yang Jian,Zhao Hong,Wang Xicheng,Zhou Yanjie,Zhao Qunyou,Li Huiqun. Detection of Three Dwarfing Genes in the New Wheat Cultivars (Lines) Developed in South Huang-Huai Valley and Its Association with Agronomic Traits[J]. Crops, 2019(6): 14–19

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检测基因名称 ID of detection gene	正向引物序列(5′-3′) Sequence of forward primer (5′-3′)	反向引物序列(5′-3′) Sequence of reverse primer (5′-3′)	退火温度(℃) Annealing temperature
RhtB1-b	TCTCCTCCCTCCCCACCCAAC	CATCCCCATGGCCATCTCGAGCTA	63
RhtD1-b	CGCGCAATTATTGGCCAGAGATAG	CCCCATGGCCATCTCGAGCTGCTA	63
Rht8	CTCCCTGTACGCCTAAGGC	CTCGCGCTACTAGCCATTG	55

性状Trait	最小值 Minimum	最大值 Maximum	平均值 Mean	标准差 Standard deviation	变异系数(%) Coefficient of variation
株高Plant height (cm)	59.30	91.00	76.99	4.51	0.06
每公顷穗数Spike number per hectare (×10⁶)	3.80	6.63	5.57	0.45	0.08
千粒重1000-kernel weight(g)	37.00	53.40	45.00	2.71	0.06
穗粒数Kernel number per spike	29.10	43.80	34.80	2.19	0.06

性状 Trait	位点 Locus	样本容量 Sample size	平均数 Mean	标准差 Standard error	最小值 Minimum	最大值 Maximum	F	显著性 Significance
株高Plant height (cm)	Rht8(+)	513	76.70	4.44	59.30	89.00	11.53	0.001^**
	Rht8(-)	117	78.26	4.61	63.90	91.00
每公顷穗数Spike number per hectare (×10⁶)	Rht8(+)	513	5.54	0.36	3.80	6.63	10.12	0.002^**
	Rht8(-)	117	5.66	0.48	4.40	6.63
千粒重1000-kernel weight (g)	Rht8(+)	513	45.10	2.66	37.80	53.40	4.08	0.044^*
	Rht8(-)	117	44.54	2.90	37.00	50.90
穗粒数Kernel number per spike	Rht8(+)	513	34.93	2.58	29.10	43.80	15.19	0.000^**
	Rht8(-)	117	34.06	2.41	29.40	40.61