{"title":"鉴定和表征反硝化细菌 DYTN-1 中的 R-M 系统以提高质粒共轭转移效率","authors":"Yunpeng Shi, Wenyan Cao, Zhiping Zheng, Sha Xu, Lijuan Chai, Shenghu Zhou, Yu Deng","doi":"10.4014/jmb.2402.02041","DOIUrl":null,"url":null,"abstract":"<p><p><i>Paracoccus denitrificans</i> has been identified as a representative strain with heterotrophic nitrification-aerobic denitrification capabilities (HN-AD), and demonstrates strong denitrification proficiency. Previously, we isolated the DYTN-1 strain from activated sludge, and it has showcased remarkable nitrogen removal abilities and genetic editability, which positions <i>P. denitrificans</i> DYTN-1 as a promising chassis cell for synthetic biology engineering, with versatile pollutant degradation capabilities. However, the strain's low stability in plasmid conjugation transfer efficiency (PCTE) hampers gene editing efficacy, and is attributed to its restriction modification system (R-M system). To overcome this limitation, we characterized the R-M system in <i>P. denitrificans</i> DYTN-1 and identified a DNA endonuclease and 13 DNA methylases, with the DNA endonuclease identified as HNH endonuclease. Subsequently, we developed a plasmid artificial modification approach to enhance conjugation transfer efficiency, which resulted in a remarkable 44-fold improvement in single colony production. This was accompanied by an increase in the frequency of positive colonies from 33.3% to 100%. Simultaneously, we cloned, expressed, and characterized the speculative HNH endonuclease capable of degrading unmethylated DNA at 30°C without specific cutting site preference. Notably, the impact of DNA methylase M9 modification on the plasmid was discovered, significantly impeding the cutting efficiency of the HNH endonuclease. This revelation unveils a novel R-M system in <i>P. denitrificans</i> and sheds light on protective mechanisms employed against exogenous DNA invasion. These findings pave the way for future engineering endeavors aimed at enhancing the DNA editability of <i>P. denitrificans</i>.</p>","PeriodicalId":16481,"journal":{"name":"Journal of microbiology and biotechnology","volume":"34 9","pages":"1826-1835"},"PeriodicalIF":2.5000,"publicationDate":"2024-09-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11473606/pdf/","citationCount":"0","resultStr":"{\"title\":\"Identification and Characterization of an R-M System in <i>Paracoccus denitrifican</i> DYTN-1 to Improve the Plasmid Conjugation Transfer Efficiency.\",\"authors\":\"Yunpeng Shi, Wenyan Cao, Zhiping Zheng, Sha Xu, Lijuan Chai, Shenghu Zhou, Yu Deng\",\"doi\":\"10.4014/jmb.2402.02041\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p><i>Paracoccus denitrificans</i> has been identified as a representative strain with heterotrophic nitrification-aerobic denitrification capabilities (HN-AD), and demonstrates strong denitrification proficiency. Previously, we isolated the DYTN-1 strain from activated sludge, and it has showcased remarkable nitrogen removal abilities and genetic editability, which positions <i>P. denitrificans</i> DYTN-1 as a promising chassis cell for synthetic biology engineering, with versatile pollutant degradation capabilities. However, the strain's low stability in plasmid conjugation transfer efficiency (PCTE) hampers gene editing efficacy, and is attributed to its restriction modification system (R-M system). To overcome this limitation, we characterized the R-M system in <i>P. denitrificans</i> DYTN-1 and identified a DNA endonuclease and 13 DNA methylases, with the DNA endonuclease identified as HNH endonuclease. Subsequently, we developed a plasmid artificial modification approach to enhance conjugation transfer efficiency, which resulted in a remarkable 44-fold improvement in single colony production. This was accompanied by an increase in the frequency of positive colonies from 33.3% to 100%. Simultaneously, we cloned, expressed, and characterized the speculative HNH endonuclease capable of degrading unmethylated DNA at 30°C without specific cutting site preference. Notably, the impact of DNA methylase M9 modification on the plasmid was discovered, significantly impeding the cutting efficiency of the HNH endonuclease. This revelation unveils a novel R-M system in <i>P. denitrificans</i> and sheds light on protective mechanisms employed against exogenous DNA invasion. 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引用次数: 0
摘要
反硝化副球菌(Paracoccus denitrificans)已被确定为具有异养硝化-好氧反硝化能力(HN-AD)的代表性菌株,并表现出很强的反硝化能力。此前,我们从活性污泥中分离出了 DYTN-1 菌株,该菌株具有显著的脱氮能力和遗传编辑能力,这使得 P. denitrificans DYTN-1 成为一种具有多功能污染物降解能力的合成生物学工程底盘细胞。然而,该菌株的限制性修饰系统(R-M 系统)导致其质粒连接转移效率(PCTE)稳定性较低,影响了基因编辑的效果。为了克服这一限制,我们对脱硝杆菌 DYTN-1 的 R-M 系统进行了鉴定,发现了一种 DNA 内切酶和 13 种 DNA 甲基化酶,其中 DNA 内切酶被鉴定为 HNH 内切酶。随后,我们开发了一种质粒人工修饰方法来提高接合转移效率,结果单菌落产量显著提高了 44 倍。同时,阳性菌落的频率也从 33.3% 提高到了 100%。与此同时,我们克隆、表达并鉴定了推测的 HNH 内切酶,它能够在 30°C 下降解未甲基化的 DNA,而没有特定的切割位点偏好。值得注意的是,我们发现 DNA 甲基化酶 M9 修饰对质粒的影响极大地阻碍了 HNH 内切酶的切割效率。这一发现揭示了脱硝杆菌中一种新型的 R-M 系统,并揭示了防止外源 DNA 入侵的保护机制。这些发现为未来旨在提高变硝酸梭菌 DNA 可编辑性的工程努力铺平了道路。
Identification and Characterization of an R-M System in Paracoccus denitrifican DYTN-1 to Improve the Plasmid Conjugation Transfer Efficiency.
Paracoccus denitrificans has been identified as a representative strain with heterotrophic nitrification-aerobic denitrification capabilities (HN-AD), and demonstrates strong denitrification proficiency. Previously, we isolated the DYTN-1 strain from activated sludge, and it has showcased remarkable nitrogen removal abilities and genetic editability, which positions P. denitrificans DYTN-1 as a promising chassis cell for synthetic biology engineering, with versatile pollutant degradation capabilities. However, the strain's low stability in plasmid conjugation transfer efficiency (PCTE) hampers gene editing efficacy, and is attributed to its restriction modification system (R-M system). To overcome this limitation, we characterized the R-M system in P. denitrificans DYTN-1 and identified a DNA endonuclease and 13 DNA methylases, with the DNA endonuclease identified as HNH endonuclease. Subsequently, we developed a plasmid artificial modification approach to enhance conjugation transfer efficiency, which resulted in a remarkable 44-fold improvement in single colony production. This was accompanied by an increase in the frequency of positive colonies from 33.3% to 100%. Simultaneously, we cloned, expressed, and characterized the speculative HNH endonuclease capable of degrading unmethylated DNA at 30°C without specific cutting site preference. Notably, the impact of DNA methylase M9 modification on the plasmid was discovered, significantly impeding the cutting efficiency of the HNH endonuclease. This revelation unveils a novel R-M system in P. denitrificans and sheds light on protective mechanisms employed against exogenous DNA invasion. These findings pave the way for future engineering endeavors aimed at enhancing the DNA editability of P. denitrificans.
期刊介绍:
The Journal of Microbiology and Biotechnology (JMB) is a monthly international journal devoted to the advancement and dissemination of scientific knowledge pertaining to microbiology, biotechnology, and related academic disciplines. It covers various scientific and technological aspects of Molecular and Cellular Microbiology, Environmental Microbiology and Biotechnology, Food Biotechnology, and Biotechnology and Bioengineering (subcategories are listed below). Launched in March 1991, the JMB is published by the Korean Society for Microbiology and Biotechnology (KMB) and distributed worldwide.