Construction of microsporidia-inducible GAL4/UAS-RTA system to generate resistance to Nosema bombycis in Bombyx mori.

IF 2.9 1区农林科学 Q1 ENTOMOLOGY

Insect Science Pub Date : 2025-03-23 DOI:10.1111/1744-7917.70028

Bin Yu, Chunxia Wang, Shaogang He, Yuanke Hu, Xianzhi Meng, Junhong Wei, Tian Li, Guoqing Pan, Zeyang Zhou, Chunfeng Li

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引用次数: 0

Abstract

The presence of microsporidian infections in the animal industry could result in substantial economic losses. Nosema bombycis, as the first identified species of microsporidia, poses a significant threat to the silkworm industry. Currently, there is no strain of silkworm with obvious resistance that can inhibit the proliferation of N. bombycis in silkworm rearing. In this study, we developed a microsporidia-inducible GAL4/UAS-RTA (Ricin toxin A chain) system in silkworms that confers resistance against N. bombycis. This system utilizes the microsporidia-inducible promoters of BmUGT2 and BmUGT3 genes (PUGT2 and PUGT3) to drive the expression of GAL4 gene, while RTA is driven by a UAS cis-acting element. We generated hybrid silkworms through crosses between GAL4 transgenic silkworms (PUGT2-GAL4 or PUGT3-GAL4) and UAS-RTA transgenic silkworms. Under normal conditions, these hybrid lines exhibited unaltered fundamental economic characteristics compared to wild-type silkworms. However, when exposed to N. bombycis infection, they displayed significantly enhanced resistance against microsporidia. Our research successfully demonstrated mitigation of microsporidia proliferation in transgenic individuals using the microsporidia-inducible GAL4/UAS-RTA system in silkworms. This approach not only provides a novel strategy for developing resistant strains against microsporidia but also serves as an important reference for genetically enhancing resistance against intracellular pathogens in other economically significant insects.

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畜牧业中的微孢子虫感染可能会造成巨大的经济损失。Nosema bombycis 是第一个被确认的微孢子虫种类，对养蚕业构成了重大威胁。目前，还没有一种具有明显抗性的蚕品系能在养蚕过程中抑制 N. bombycis 的增殖。在这项研究中，我们在家蚕中开发了一种微孢子诱导的 GAL4/UAS-RTA（蓖麻毒素 A 链）系统，该系统可赋予家蚕对 N. bombycis 的抗性。该系统利用 BmUGT2 和 BmUGT3 基因（PUGT2 和 PUGT3）的微孢子虫诱导启动子来驱动 GAL4 基因的表达，而 RTA 则由 UAS 顺式作用元件驱动。我们通过 GAL4 转基因家蚕（PUGT2-GAL4 或 PUGT3-GAL4）与 UAS-RTA 转基因家蚕杂交产生了杂交家蚕。在正常条件下，与野生型家蚕相比，这些杂交品系的基本经济特征没有改变。然而，当受到 N. bombycis 感染时，它们对小孢子虫的抗性明显增强。我们的研究成功证明了利用微孢子虫诱导的 GAL4/UAS-RTA 系统在蚕的转基因个体中缓解了微孢子虫的增殖。这种方法不仅为开发抗小孢子虫菌株提供了一种新的策略，也为其他具有重要经济价值的昆虫通过基因增强对细胞内病原体的抗性提供了重要参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Insect Science 生物-昆虫学

CiteScore

7.80

自引率

5.00%

发文量

1379

审稿时长

6.0 months

期刊介绍： Insect Science is an English-language journal, which publishes original research articles dealing with all fields of research in into insects and other terrestrial arthropods. Papers in any of the following fields will be considered: ecology, behavior, biogeography, physiology, biochemistry, sociobiology, phylogeny, pest management, and exotic incursions. The emphasis of the journal is on the adaptation and evolutionary biology of insects from the molecular to the ecosystem level. Reviews, mini reviews and letters to the editor, book reviews, and information about academic activities of the society are also published.