高迭代重定向 1 (HIP1) 序列以同源和甲基化依赖的方式提高了 Synechococcus sp.

Cody Kamoku, David R Nielsen
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摘要

要想精确控制蓝藻的新陈代谢,首先需要具备高效传递工程 DNA 构建物的能力。在这里,我们研究了如何利用原生的、丰富的蓝藻高迭代重合色素 1(HIP1)序列来大大提高 Synechococcus sp.在整合质粒的同源臂中包含至少一个同源的 HIP1 位点可将整合效率提高 7 倍,而通过 HIP1 甲基转移酶(由 Synechococcus sp.非同源 HIP1 位点也提高了整合质粒和复制外显子质粒的转化效率(分别提高了 60 倍和 9 倍),但仅限于甲基化时。这些数据进一步表明,HIP1 在 PCC 7002 中并不作为原生限制酶系统的一部分发挥作用,而是可能通过两种互补机制提高转化效率:i)在同源重组之前改变 DNA 结合/摄取/处理;ii)以类似于交叉热点唆使(Chi)位点的方式提高同源重组的效率。不过,要更清楚地阐明 HIP1 在蓝藻自然转化过程中的具体作用,还需要今后的研究。
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Highly Iterated Palindrome 1 (HIP1) sequence improves Synechococcus sp. PCC 7002 transformation efficiencies in a homology- and methylation-dependent manner
The ability to precisely control cyanobacterial metabolism first requires the ability to efficiently deliver engineered DNA constructs. Here, we investigate how natural transformation efficiencies in Synechococcus sp. PCC 7002 can be greatly improved by leveraging the native and abundant cyanobacterial Highly Iterated Palindrome 1 (HIP1) sequence. While including at least one homologous HIP1 site within the homology arms of an integrating plasmid increased integration efficiency by up to 7-fold, methylation of those sites by HIP1 methyltransferase (encoded by slr0214 from Synechococcus sp. PCC 6803) boosted this to greater than a 100-fold improvement overall. Non-homologous HIP1 sites also improved transformation efficiencies of both integrating and replicating episomal plasmids (by up to 60- and 9-fold, respectively), but only when methylated. The collective data further reveal that HIP1 does not function as part of a native restriction enzyme system in PCC 7002, but rather may improve transformation efficiency via two complementary mechanisms: i) altering DNA binding/uptake/processing prior to homologous recombination, and ii) increasing the efficiency of homologous recombination in a manner reminiscent of a crossover hotspot instigator (Chi) site. Future studies are needed, however, to more clearly elucidate the specific role of HIP1 during natural transformation of cyanobacteria.
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