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《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2022年20

Page:

1-9

Research Field:

Publishing date:

Info

Title:

Detection of Six Disease Resistance Genes in Eighty-one Tomato Germplasm Resources

Author(s):

YANG Chaosha1; 2; WANG Shanshan1; YIN Weiping1; WANG Guohua1; ZHANG Liyong3; YIN Qingzhen1

(1.Institute of Cash Crops,Hebei Academy of Agriculture and Forestry Sciences,Shijiazhuang,Hebei 050051;2.Chengde Academy of Agriculture and Forestry Sciences，Chengde,Hebei 067055;3.Hebei Chemical and Pharmaceutical College,Shijiazhuang,Hebei 050026)

Keywords:

tomato; disease resistance genes; penta-primer amplification refractory mutation system（PARMS）; multiple genes pyramiding

PACS:

-

DOI:

10.11937/bfyy.20215153

Abstract:

Penta-primer amplification refractory mutation system （PARMS） were used to test for tomato yellow leaf curl virus disease resistant genes Ty-1、Ty-2、Ty-3/3a，root knot nematode resistant gene Mi-1.2，Fusarium crown and root rot resistance gene Frl，leaf mould resistant genes Cf-5、Cf-9，late blight resistant gene Ph-3 and gray leaf spot resistant gene Sm in 81 tomato inbred lines to clarify the types and distribution of multi-resistant genes in these materials,in order to provide reference for the screening of multi-resistant tomato germplasm resources.The results showed that there were 76，68，66 and 65 materials with the tomato yellow leaf curl virus disease resistant genes Ty-1 or Ty-2，leaf mould resistant genes Cf-5 or Cf-9，gray leaf spot resistant gene Sm，root knot nematode resistant gene Mi-1.2 respectively.A total of 31 materials containing four disease resistance genes at most.Combined with the field performance，three homozygous materials 463，heterozygous materials 398 and 354 with six disease resistance genes and materials 409，470，479 and 480 with five disease resistance genes were selected.The next step was to purify the selected materials，which would lay a foundation for breeding new tomato varieties with multi resistance and high quality.

References:

[1]郑金亮.日光温室早春茬番茄品种比较与综合评价[D].新乡:河南科技学院，2020.[2]谭海文,吴永琼,秦莉,等.我国番茄侵染性病害种类变迁及其发生概况[J].中国蔬菜,2019(1)：80-84.[3]朱晓林,魏小红,王宝强,等.番茄抗黄叶卷曲病相关基因Ty-6的克隆、序列分析及表达特性[J].生物技术通报,2020,36(7)：40-47.[4]李亚茹,王银磊,赵丽萍,等.不同抗病基因型番茄对番茄黄化曲叶病毒的抗病性鉴定[J].西南农业学报,2016,29(11)：2609-2614.[5]米国全,陈梦莹,史艳艳,等.番茄种质资源黄化曲叶病毒病抗性的鉴定与评价[J].河南农业科学,2017,46(5)：77-83.[6]杨超沙,王国华,吴志明,等.番茄黄化曲叶病毒及根结线虫抗性基因的检测[J].河北农业大学学报,2018,41(2)：73-76.[7]魏偲,史倩倩,茆振川,等.Mi基因家族番茄对南方根结线虫的抗性鉴定及评价[J].中国蔬菜,2016(6)：29-33.[8]高莹梅,胡靖康,赵婷婷,等.番茄抗根结线虫Mi-1基因研究进展[J].分子植物育种,2017,15(8)：3010-3015.[9]杨超沙,王国华,尹伟平,等.日光温室秋冬番茄多抗优良品种的筛选[J].西南大学学报（自然科学版）,2019,41(5)：8-14.[10]程琳,张生,李艳青,等.番茄颈腐根腐病病原菌鉴定与抗病种质材料的筛选[J].园艺学报,2016,43(4)：781-788.[11]李潇,李雪萍,漆永红,等.番茄颈腐根腐病病原鉴定及其品种抗性鉴定[J].甘肃农业大学学报,2019,54(5)：121-127.[12]刘蕾,王辉,李文丽,等.与番茄颈腐根腐病抗病基因Frl连锁的标记及应用[J].江苏农业科学,2018,46(16)：91-93.[13]孙亚林.番茄四个抗病基因的基因标记的创建与辅助选择[D].武汉:华中农业大学,2008.[14]于拴仓,柴敏,郑晓鹰,等.番茄叶霉病抗性基因Cf-5的CAPS 标记建立[J].分子植物育种,2005,3(1)：57-60.[15]张春芝.番茄抗晚疫病基因Ph-3的克隆及其效应子的筛选[D].北京:中国农业科学院2014.[16]REN Z,YOU Z,MUNIR S,et al.Development of a highly specific co-dominant marker for genotyping the Ph-3 (tomato late blight resistance) locus by comparing cultivated and wild ancestor species[J].Molecular Breeding,2019,39(3):45.[17]胡明瑜,白文钦,潘晓雪,等.番茄抗晚疫病基因Ph-3的分子标记开发及应用[J].植物病理学报,2018,48(4)：560-566.[18]苏晓梅.番茄抗灰叶斑病基因Sm的精细定位与克隆[D].北京:中国农业大学,2018.[19]王艺蓉.分子标记辅助樱桃番茄优良自交系及杂交组合的选育[D].北京:华中农业大学,2016.[20]陈宝玲,甘桂云,王先裕,等.126份番茄材料的抗性基因分子标记检测[J].中国蔬菜,2016(6)：34-41.

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Last Update: 2022-12-19