用合成的Mini-RP4质粒载体通过复杂微生物群繁殖重组基因。

Q2 Agricultural and Biological Sciences 生物设计研究(英文) Pub Date : 2022-08-02 eCollection Date: 2022-01-01 DOI:10.34133/2022/9850305
Tomás Aparicio, Jillian Silbert, Sherezade Cepeda, Víctor de Lorenzo
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引用次数: 4

摘要

革兰氏阴性质粒RP4的混杂结合机制已经在一个最小化的、高度传播的载体中重新组装,用于通过各种类型的自然存在的微生物群落繁殖遗传编码的性状。为此,将整个RP4编码的转移决定簇(tra、mob基因和转移oriT的起源)从其自然环境中切除,最小化,并以由自选复制子携带的流线型DNA片段的形式重新创建。所得到的构建体(pMATING系列)可以通过使用这种合理设计的偶联物递送装置的各种原核和真核受体进行自转移。将GFP报告基因插入pMATING暴露了这种遗传工具将异源基因传递给特定交配伴侣和复杂群落(如植物/土壤根际)的价值。该结果证实了重组质粒向多种宿主的有效和功能转移。然而,在这种情况下,对限制种间DNA转移的因素的检查揭示了VI型分泌系统是检查测试的RP4衍生物的高结合频率的事实障碍之一。我们认为,本文提出的超功能基因转移程序可以成为通过各种规模的环境微生物组传播有益性状的非凡资产。
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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Propagation of Recombinant Genes through Complex Microbiomes with Synthetic Mini-RP4 Plasmid Vectors.

The promiscuous conjugation machinery of the Gram-negative plasmid RP4 has been reassembled in a minimized, highly transmissible vector for propagating genetically encoded traits through diverse types of naturally occurring microbial communities. To this end, the whole of the RP4-encoded transfer determinants (tra, mob genes, and origin of transfer oriT) was excised from their natural context, minimized, and recreated in the form of a streamlined DNA segment borne by an autoselective replicon. The resulting constructs (the pMATING series) could be self-transferred through a variety of prokaryotic and eukaryotic recipients employing such a rationally designed conjugal delivery device. Insertion of GFP reporter into pMATING exposed the value of this genetic tool for delivering heterologous genes to both specific mating partners and complex consortia (e.g., plant/soil rhizosphere). The results accredited the effective and functional transfer of the recombinant plasmids to a diversity of hosts. Yet the inspection of factors that limit interspecies DNA transfer in such scenarios uncovered type VI secretion systems as one of the factual barriers that check otherwise high conjugal frequencies of tested RP4 derivatives. We argue that the hereby presented programming of hyperpromiscuous gene transfer can become a phenomenal asset for the propagation of beneficial traits through various scales of the environmental microbiome.

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CiteScore
3.90
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0.00%
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12 weeks
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