Elizabeth Vaisbourd, Anat Bren, Uri Alon, David Shaanan Glass
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引用次数: 0
摘要
质粒是基础研究和生物技术应用的重要工具。要优化基于质粒的电路,控制质粒的完整性至关重要,包括质粒多聚体的形成。多聚体是整个质粒在复制过程中由于二聚体解析失败而形成的串联重复。多聚体会影响合成电路的行为,尤其是包含 DNA 编辑酶的电路。然而,多聚体的出现并不常见。在这里,我们调查了四种常用质粒骨架在克隆(JM109)和野生型(MG1655)菌株中出现多聚体的情况。我们发现,只有在 MG1655 中才会出现明显的多聚体,质粒多聚体的比例随着质粒拷贝数和培养传代的增加而增加。相比之下,将多聚体引入 JM109 能产生只含有多聚体的菌株。我们介绍了一种避免产生多聚体的 MG1655 ΔrecA 单基因敲除方法。这些结果有助于合成生物学家改进基于质粒的电路的设计和可靠性。
Preventing plasmid multimer formation in commonly used synthetic biology plasmids
Plasmids are an essential tool for basic research and biotechnology applications. To optimize plasmid-based circuits, it is crucial to control plasmid integrity, including the formation of plasmid multimers. Multimers are tandem repeats of entire plasmids formed during replication by failed dimer resolution. Multimers can affect the behavior of synthetic circuits, especially ones that include DNA-editing enzymes. However, occurrence of multimers is not commonly assayed. Here we survey four commonly used plasmid backbones for occurrence of multimers in cloning (JM109) and wild-type (MG1655) strains. We find that multimers occur appreciably only in MG1655, with the fraction of plasmids existing as multimers increasing with both plasmid copy number and culture passaging. In contrast, introduction of multimers into JM109 can produce strains containing only multimers. We present an MG1655 ΔrecA single-locus knockout that avoids multimer production. These results can aid synthetic biologists in improving design and reliability of plasmid-based circuits.
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