Detection of Avirulence Gene AvrPi9 in Magnaporthe oryzae, a Rice Blast Fungus, Using a Combination of RPA and CRISPR-Cas12a Techniques

Q3 Agricultural and Biological Sciences

HAYATI Journal of Biosciences Pub Date : 2023-07-01 DOI:10.4308/hjb.30.5.885-894

Piyawan Puanprapai, Pattavipha Songkumarn, T. Toojinda, C. Jantasuriyarat

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Abstract

Rice blast disease is one of the most devastating diseases of rice production worldwide, which causes by an ascomycete fungus, Magnaporthe oryzae. The virulence of the rice blast fungus is determined by avirulence genes (Avr genes). Therefore, the identification of Avr genes is important for rice resistance variety improvement. Avr genes are currently identified using the pathogenicity assay with rice near-isogenic lines (NILs) or PCR amplification and gene sequencing, both of which are time-consuming and labor-intensive methods. This study aims to develop a simple method for Avr gene identification using AvrPi9 as a model. A recombinase polymerase amplification (RPA) technique was carried out to amplify AvrPi9 by incubating rice blast fungus genomic DNA with gene-specific primers at 37°C for 20 min. Cas12a-based AvrPi9 detection was performed by incubating at 37°C for 5 min. The fluorescence signal was visualized by the naked eye under an LED transilluminator. The study found that AvrPi9 can be amplified and detected using RPA and a Cas12a-based method. AvrPi9_crRNA2 has a higher efficiency than AvrPi9_crRNA1. The sensitivity of the method was 3.8 ng of DNA target for AvrPi9_crRNA1 and 1.9 ng of DNA target for AvrPi9_crRNA2. This RPA and Cas12a combination technique is a newer method for Avr gene detection in plants and has several advantages over traditional methods. It is considered easier to use and more efficient in terms of time and labor, making it a potentially useful tool for plant breeders and pathologists.

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RPA和CRISPR-Cas12a联合检测稻瘟病菌稻瘟病基因AvrPi9

稻瘟病是世界范围内水稻生产中最具破坏性的疾病之一，由子囊菌稻瘟病菌引起。稻瘟病菌的毒力由无毒基因决定。因此，Avr基因的鉴定对水稻抗性品种的改良具有重要意义。Avr基因目前使用水稻近等基因系（NILs）的致病性测定或PCR扩增和基因测序来鉴定，这两种方法都是耗时且劳动密集的方法。本研究旨在以AvrPi9为模型，开发一种简单的Avr基因鉴定方法。通过用基因特异性引物在37°C下孵育20分钟，进行重组酶聚合酶扩增（RPA）技术来扩增AvrPi9。通过在37°C.孵育5分钟，进行基于Cas12a的AvrPi9检测。在LED透照器下通过肉眼观察荧光信号。研究发现，使用RPA和基于Cas12a的方法可以扩增和检测AvrPi9。AvrPi9_crRNA2具有比AvrBi9_crNA1更高的效率。该方法的灵敏度为3.8ng的DNA靶标对AvrPi9_crRNA1和1.9ng的DNA靶对AvrBi9_crNA2。这种RPA和Cas12a组合技术是一种新的植物Avr基因检测方法，与传统方法相比具有几个优点。它被认为更容易使用，在时间和劳动力方面更高效，这使它成为植物育种家和病理学家的潜在有用工具。

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来源期刊

HAYATI Journal of Biosciences Agricultural and Biological Sciences-Agricultural and Biological Sciences (all)

CiteScore

1.10

自引率

0.00%

发文量

审稿时长

24 weeks

期刊介绍： HAYATI Journal of Biosciences (HAYATI J Biosci) is an international peer-reviewed and open access journal that publishes significant and important research from all area of biosciences fields such as biodiversity, biosystematics, ecology, physiology, behavior, genetics and biotechnology. All life forms, ranging from microbes, fungi, plants, animals, and human, including virus, are covered by HAYATI J Biosci. HAYATI J Biosci published by Department of Biology, Bogor Agricultural University, Indonesia and the Indonesian Society for Biology. We accept submission from all over the world. Our Editorial Board members are prominent and active international researchers in biosciences fields who ensure efficient, fair, and constructive peer-review process. All accepted articles will be published on payment of an article-processing charge, and will be freely available to all readers with worldwide visibility and coverage.