利用RNA干扰技术赋予转基因家蚕对家蚕核型多角体病毒更强的抗性。

Use of RNAi technology to confer enhanced resistance to BmNPV on transgenic silkworms.

作者信息

Isobe R, Kojima K, Matsuyama T, Quan G X, Kanda T, Tamura T, Sahara K, Asano S I, Bando H

机构信息

Division of Applied Bioscience, Graduate School of Agriculture, Hokkaido University, Sapporo, Japan.

出版信息

Arch Virol. 2004 Oct;149(10):1931-40. doi: 10.1007/s00705-004-0349-0.

DOI:10.1007/s00705-004-0349-0

PMID:15669105

Abstract

dsRNA is a powerful tool for gene-specific silencing in plants and animals. In this study, we examined the use of gene silencing in generating transgenic silkworms resistant to the Bombyx mori nucleopolyhedrovirus (BmNPV). Using a transposon piggyBac system, we first generated BmN cells (rBmN-lef1), which carried artificial genes designed for expressing dsRNAs with sequences of the essential viral gene lef-1. NPV DNA microarray analysis revealed that the accumulation of lef-1 mRNA was successfully inhibited in rBmN-lef1 infected with BmNPV. The virus titer in the culture medium of rBmN-lef1 at 48 hr post-infection (h.p.i.) was 50% of that of the control cells. Moderate BmNPV-resistance caused by transgenesis of the artificial dsRNA-expressing gene was confirmed in the transgenic silkworms. Virus production was reduced in transgenic silkworms relative to controls up to 96 hrs after viral inoculation. Although complete protection was not achieved and the transgenic larvae ultimately died, this is the first report to show the use of RNAi in confering enhanced viral resistance on transgenic animals.

摘要

双链RNA（dsRNA）是在植物和动物中实现基因特异性沉默的强大工具。在本研究中，我们研究了利用基因沉默技术培育抗家蚕核型多角体病毒（BmNPV）的转基因家蚕。我们首先使用转座子piggyBac系统构建了BmN细胞（rBmN-lef1），该细胞携带人工基因，这些基因被设计用于表达具有必需病毒基因lef-1序列的dsRNA。NPV DNA微阵列分析表明，在感染BmNPV的rBmN-lef1细胞中，lef-1 mRNA的积累被成功抑制。感染后48小时（h.p.i.），rBmN-lef1培养基中的病毒滴度是对照细胞的50%。在转基因家蚕中证实了由表达人工dsRNA的基因转基因引起的中度BmNPV抗性。在病毒接种后长达96小时内，转基因家蚕中的病毒产量相对于对照有所降低。虽然没有实现完全保护，转基因幼虫最终死亡，但这是首次报道在转基因动物中利用RNAi赋予增强的病毒抗性。

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利用RNA干扰技术赋予转基因家蚕对家蚕核型多角体病毒更强的抗性。

Use of RNAi technology to confer enhanced resistance to BmNPV on transgenic silkworms.

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