Toward Drought Tolerance in Tomato: Selection of F2BC1 Plants Obtained from Crosses Between Wild and Commercial Genotypes

IF 1.4 Q3 AGRONOMY

Agricultural Research Pub Date : 2023-12-06 DOI:10.1007/s40003-023-00678-3

André Ricardo Zeist, Juliane Macel Henschel, Amanda Carvalho Perrud, André Dutra Silva Júnior, Joana Nascimento Oliveira Zeist, Guilherme José Almeida Oliveira, Adriana Lima Moro, Juliano Tadeu Vilela de Resende

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Abstract

The tomato plant (Solanum lycopersicum L.) demands more water than other vegetables. However, water availability has become a limiting factor worldwide due to climate change. Thus, it is essential to explore the genetic variability of species to develop genotypes with satisfactory yields under low water availability. In this context, the objective of this study was to identify water-deficit-tolerant plants within the genetic variability of tomatoes and to select drought-tolerant genotypes from the second generation of the first backcross (F₂BC₁). For this, seven wild accessions, three S. lycopersicum var. cerasiforme accessions, and six commercial cultivars were tested. Moreover, intra- and interspecific crosses were performed and from the crosses S. lycopersicum × S. pennellii, two F₂BC₁ populations were obtained. Three experiments were conducted where the genotypes were subjected to water deficit and physiological and growth parameters. The commercial tomatoes were the most susceptible to water deficit. Among the tested cerasiform varieties, the RVC 66 accession was the least affected by the reduced water supply. The LA 716 accession (S. pennellii) had the highest tolerance to water deficit, followed by ‘LA 1401’ (S. galapagense) and ‘LA 1967’ (S. chilense). The LA 716 accession was the most promising to introgress drought tolerance-related genes in the commercial tomatoes compared to the intraspecific crosses. In addition, crossing between ‘LA 716’ and the commercial tomatoes ‘Clara’ and ‘Redenção’ allowed the development and selection of drought-tolerant F₂BC₁ genotypes.

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番茄的耐旱性：野生基因型与商业基因型杂交获得的 F2BC1 株的选择

番茄（Solanum lycopersicum L.）比其他蔬菜需要更多的水。然而，由于气候变化，水的供应已成为全世界的一个限制因素。因此，必须探索物种的遗传变异性，以开发出在低水分供应条件下产量令人满意的基因型。在此背景下，本研究的目的是在番茄的遗传变异中找出耐缺水植物，并从第一代回交的第二代中筛选出耐旱基因型（F2BC1）。为此，对 7 个野生品种、3 个番茄变种 cerasiforme 品种和 6 个商业栽培品种进行了测试。此外，还进行了种内和种间杂交，并从 S. lycopersicum × S. pennellii 杂交中获得了两个 F2BC1 群体。进行了三项实验，对基因型进行缺水和生理生长参数测试。商品番茄最易受缺水影响。在测试的葡萄品种中，RVC 66 受水分供应减少的影响最小。LA 716（S. pennellii）对水分亏缺的耐受力最强，其次是'LA 1401'（S. galapagense）和'LA 1967'（S. chilense）。与种内杂交相比，"LA 716 "最有希望在商品番茄中导入耐旱相关基因。此外，通过'LA 716'与商品番茄'Clara'和'Redenção'杂交，可以培育和筛选出耐旱的 F2BC1 基因型。

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来源期刊

Agricultural Research AGRONOMY-

CiteScore

3.80

自引率

0.00%

发文量

期刊介绍： The main objective of this initiative is to promote agricultural research and development. The journal will publish high quality original research papers and critical reviews on emerging fields and concepts for providing future directions. The publications will include both applied and basic research covering the following disciplines of agricultural sciences: Genetic resources, genetics and breeding, biotechnology, physiology, biochemistry, management of biotic and abiotic stresses, and nutrition of field crops, horticultural crops, livestock and fishes; agricultural meteorology, environmental sciences, forestry and agro forestry, agronomy, soils and soil management, microbiology, water management, agricultural engineering and technology, agricultural policy, agricultural economics, food nutrition, agricultural statistics, and extension research; impact of climate change and the emerging technologies on agriculture, and the role of agricultural research and innovation for development.