Strategies for Engineering of Virus-Resistant Plants: Focus on RNases

Pub Date : 2024-04-01 DOI:10.3103/s0095452724020099
A. O. Potrokhov, O. O. Ovcharenko
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Abstract

Currently, there are approximately 6500 species of viruses known in the world, among which more than 1500 are plant viruses. Most of them are capable of causing epiphytoties, which lead to decreased yields, reduced product quality, and sometimes put valuable commercial varieties or even entire plant species at risk of extinction. The global spread of viruses leads to the need to strengthen phytosanitary and quarantine restrictions, which requires additional financial costs. Understanding of viral biology and the principles of its propagation is a key factor in the formation of strategies and methods for combating these pathogens. Among the newest approaches are the genetic engineering technologies. Their use made it possible to create a number of plant varieties with increased resistance to viruses. However, the problem of creating virus-resistant plants still remains one of the most urgent since viruses acquire the ability to bypass defense mechanisms with time and there is a need to obtain new resistant varieties. There are several main approaches for obtaining of transgenic plants with increased resistance to viruses. They are based on RNA interference, resistance associated with viral capsid proteins, RNA-satellites, antisense RNAs, replicases, RNA-dependent RNA polymerase, the action of ribonucleases, ribosome-inactivating proteins, hammerhead ribozymes, miRNAs, plant antibodies, etc. One of the approaches to creating virus-resistant plants is the use of ribonuclease genes. The genes encoding ribonucleases have different origin and belong to a wide range of hosts: bacteria, fungi, plants, and animals. In particular, extracellular ribonucleases are able to cut nonspecifically molecules of viral RNA in apoplast that allows for creating plants with increased resistance to various plant viruses. This review is focused on the study of various genetic engineering approaches and the prospects of their use for the creation of virus-resistant plants. Emphasis is placed on the study of heterologous ribonuclease genes influence.

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抗病毒植物的工程设计策略:聚焦 RNase
摘要目前,全世界已知的病毒约有 6500 种,其中植物病毒超过 1500 种。它们中的大多数都能引起附生虫病,导致产量下降、产品质量降低,有时还会使珍贵的商业品种甚至整个植物物种面临灭绝的危险。病毒的全球传播导致需要加强植物检疫和检疫限制,这需要额外的财政成本。对病毒生物学及其繁殖原理的了解是制定抗击这些病原体的策略和方法的关键因素。最新的方法包括基因工程技术。利用这些技术可以培育出许多对病毒有更强抵抗力的植物品种。然而,培育抗病毒植物的问题仍然是最紧迫的问题之一,因为随着时间的推移,病毒有能力绕过防御机制,因此需要获得新的抗病毒品种。获得抗病毒转基因植物主要有几种方法。它们基于 RNA 干扰、与病毒外壳蛋白相关的抗性、RNA 卫星、反义 RNA、复制酶、RNA 依赖性 RNA 聚合酶、核糖核酸酶的作用、核糖体失活蛋白、锤头核酶、miRNA、植物抗体等。利用核糖核酸酶基因是培育抗病毒植物的方法之一。编码核糖核酸酶的基因有不同的来源,属于多种宿主:细菌、真菌、植物和动物。特别是细胞外核糖核酸酶能够非特异性地切割细胞质中的病毒 RNA 分子,从而提高植物对各种植物病毒的抗性。本综述侧重于研究各种基因工程方法及其用于培育抗病毒植物的前景。重点是研究异源核糖核酸酶基因的影响。
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