Research on the function of CsMYB36 based on an effective hair root transformation system.

Plant signaling & behavior Pub Date : 2024-12-31 Epub Date: 2024-04-30 DOI:10.1080/15592324.2024.2345983
Xi Shen, Ting Yang, Yalin Du, Ning Hao, Jiajian Cao, Tao Wu, Chunhua Wang
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Abstract

The hairy root induction system was used to efficiently investigate gene expression and function in plant root. Cucumber is a significant vegetable crop worldwide, with shallow roots, few lateral roots, and weak root systems, resulting in low nutrient absorption and utilization efficiency. Identifying essential genes related to root development and nutrient absorption is an effective way to improve the growth and development of cucumbers. However, genetic mechanisms underlying cucumber root development have not been explored. Here, we report a novel, rapid, effective hairy root transformation system. Compared to the in vitro cotyledon transformation method, this method shortened the time needed to obtain transgenic roots by 13 days. Furthermore, we combined this root transformation method with CRISPR/Cas9 technology and validated our system by exploring the expression and function of CsMYB36, a pivotal gene associated with root development and nutrient uptake. The hairy root transformation system established in this study provides a powerful method for rapidly identifying essential genes related to root development in cucumber and other horticultural crop species. This advancement holds promise for expediting research on root biology and molecular breeding strategies, contributing to the broader understanding and improvements crop growth and development.

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基于有效发根转化系统的 CsMYB36 功能研究。
毛细根诱导系统用于有效研究植物根部的基因表达和功能。黄瓜是世界上重要的蔬菜作物,根系浅、侧根少、根系弱,导致养分吸收和利用效率低。鉴定与根系发育和养分吸收相关的重要基因是改善黄瓜生长发育的有效途径。然而,黄瓜根系发育的遗传机制尚未探明。在此,我们报告了一种新型、快速、有效的毛细根转化系统。与离体子叶转化法相比,这种方法将获得转基因根所需的时间缩短了 13 天。此外,我们还将这种根转化方法与 CRISPR/Cas9 技术相结合,并通过探索与根系发育和养分吸收相关的关键基因 CsMYB36 的表达和功能验证了我们的系统。本研究建立的毛细根转化系统为快速鉴定黄瓜和其他园艺作物根系发育相关的重要基因提供了一种强有力的方法。这一进展有望加快根生物学和分子育种策略的研究,有助于更广泛地了解和改善作物的生长和发育。
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