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豇豆(Vigna unguiculata (L.) Walp.)抗科氏菌源的表型筛选与标记辅助验证

Phenotypic Screening and Marker-Assisted Validation of Sources of Koch Resistance in Cowpea ( L.).

作者信息

Gaonosi Galalea Gillian, Lekgari Lekgari, Mosupiemang Marang, Sehularo Metseyabeng Nametso, Tshegofatso Aobakwe Boisy, Tiroesele Bamphithi, Motlhaodi Tiny, Ngwako Samodimo, Pholo-Tait Motlalepula

机构信息

Department of Crop and Soil Sciences, Botswana University of Agriculture and Natural Resources, Gaborone 00267, Botswana.

Department of Field Crops and Horticulture, National Agricultural Research Development Institute, Gaborone 00267, Botswana.

出版信息

Int J Mol Sci. 2025 May 6;26(9):4406. doi: 10.3390/ijms26094406.

DOI:10.3390/ijms26094406
PMID:40362643
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12072677/
Abstract

significantly affects cowpea ( L.) production, leading to yield reductions. Management strategies encompass physical barriers and biological and chemical methods, which can be costly and detrimental to the environment. Host-plant resistance offers a more sustainable alternative. This study evaluated cowpea genotypes in a screenhouse experiment. Tswana and B261-B were resistant, while B301, B259, and ER7 showed a tolerance phenotype. Tswana exhibited a low aphid population and minimal plant damage, probably due to suppression of reproduction and fecundity. Conversely, IT97K-556-6, SARI-21KTA-6, SARC 1-57-2, B013-F, B339, and Blackeye were susceptible to aphids, as shown by high aphid populations and dense sooty molds. Severe damage to plant vigor may be linked to direct aphid feeding and reduced photosynthesis efficiency. SNP1_0912 and CP 171F/172R markers confirmed aphid resistance in Tswana and ER7 as well as in the IT97k-556-6 and SARI-21KTA-6 controls. The inverse susceptible phenotype in the control group suggests that the markers may not function properly due to negative interactions between quantitative trait loci (QTL) and environmental factors. This could also indicate the presence of different aphid biotypes that severely damage Western African breeding lines. This study offers essential insights for breeding aphid-resistant cowpea varieties. Future efforts will involve sequencing Tswana to identify more resistance sources and create novel markers.

摘要

这对豇豆(Vigna unguiculata (L.) Walp.)生产有显著影响,导致产量下降。管理策略包括物理屏障以及生物和化学方法,这些方法可能成本高昂且对环境有害。寄主植物抗性提供了一种更可持续的选择。本研究在温室试验中评估了豇豆基因型。茨瓦纳(Tswana)和B261 - B具有抗性,而B301、B259和ER7表现出耐受表型。茨瓦纳的蚜虫种群数量较低且植株损伤最小,这可能是由于繁殖和生育力受到抑制。相反,IT97K - 556 - 6、SARI - 21KTA - 6、SARC 1 - 57 - 2、B013 - F、B339和黑眼(Blackeye)对蚜虫敏感,表现为蚜虫种群数量高且有密集的煤烟霉。对植株活力的严重损害可能与蚜虫直接取食和光合作用效率降低有关。SNP1_0912和CP 171F/172R标记证实了茨瓦纳和ER7以及IT97k - 556 - 6和SARI - 21KTA - 6对照中的蚜虫抗性。对照组中相反的敏感表型表明,由于数量性状位点(QTL)与环境因素之间的负相互作用,这些标记可能无法正常发挥作用。这也可能表明存在严重损害西非育种系的不同蚜虫生物型。本研究为培育抗蚜虫豇豆品种提供了重要见解。未来的工作将包括对茨瓦纳进行测序,以确定更多的抗性来源并创建新的标记。

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