Department of Crop Physiology, University of Agricultural Sciences, GKVK, Bangalore, 560065, India; Department of Botany, Sri Krishnadevaraya University, Anantapur, 515001, India; Department of Agriculture and Natural Resources, Delaware State University, Dover, DE, 19901, USA.
Laboratory of Plant Functional Genomics, Regional Center for Biotechnology, Faridabad, 121001, India.
Plant Physiol Biochem. 2022 Oct 15;189:126-138. doi: 10.1016/j.plaphy.2022.08.025. Epub 2022 Sep 3.
Glyphosate residues retained in the growing meristematic tissues or in grains of glyphosate-resistant crops affect the plants physiological functions and crop yield. Removing glyphosate residues in the plants is desirable with no penalty on crop yield and quality. We report a new combination of scientific strategy to detoxify glyphosate that reduces the residual levels and improve crop resistance. The glyphosate detoxifying enzymes Aldo-keto reductase (AKR1) and mutated glycine oxidase (mGO) with different modes of action were co-expressed with modified EPSPS, which is insensitive to glyphosate in tobacco (Nicotiana tabacum L.) and rice (Oryza sativa L.). The transgenic tobacco plants expressing individual PsAKR1, mGO, CP4-EPSPS, combinations of PsAKR1:CP4EPSPS, PsAKR1:mGO, and multigene with PsAKR1: mGO: CP4EPSPS genes were developed. The bio-efficacy studies of in-vitro leaf regeneration on different concentrations of glyphosate, seedling bioassay, and spray on transgenic tobacco plants demonstrate that glyphosate detoxification with enhanced resistance. Comparative analysis of the transgenic tobacco plants reveals that double and multigene expressing transgenics had reduced accumulation of shikimic acid, glyphosate, and its primary residue AMPA, and increased levels of sarcosine were observed in all PsAKR1 expressing transgenics. The multigene expressing rice transgenics showed improved glyphosate resistance with yield maintenance. In summary, results suggest that stacking genes with two different detoxification mechanisms and insensitive EPSPS is a potential approach for developing glyphosate-resistant plants with less residual content.
草甘膦残留保留在生长的分生组织或耐草甘膦作物的谷物中会影响植物的生理功能和作物产量。去除植物中的草甘膦残留是理想的,不会对作物产量和质量造成不利影响。我们报告了一种新的科学策略组合,用于解毒草甘膦,可降低残留水平并提高作物的抗性。具有不同作用方式的醛酮还原酶 (AKR1) 和突变的甘氨酸氧化酶 (mGO) 与突变的 EPSPS 一起表达,突变的 EPSPS 对烟草(Nicotiana tabacum L.)和水稻(Oryza sativa L.)中的草甘膦不敏感。表达单个 PsAKR1、mGO、CP4-EPSPS、PsAKR1:CP4EPSPS、PsAKR1:mGO 和多基因 PsAKR1:mGO:CP4EPSPS 基因的转基因烟草植物被开发出来。对不同浓度草甘膦的离体叶片再生、幼苗生物测定和转基因烟草植物喷雾的生物功效研究表明,草甘膦解毒与增强抗性。对转基因烟草植物的比较分析表明,双基因和多基因表达的转化体中,莽草酸、草甘膦及其主要残留物 AMPA 的积累减少,所有表达 PsAKR1 的转化体中肌氨酸的水平增加。多基因表达的水稻转化体表现出提高的草甘膦抗性和产量保持。总之,结果表明,两种不同解毒机制和不敏感 EPSPS 的基因叠加是开发残留含量较低的抗草甘膦植物的一种潜在方法。
