醋酸菌中CRISPR位点的比较基因组学与进化分析

doi:10.16288/j.yczz.15-244

遗传 ›› 2015, Vol. 37 ›› Issue (12): 1242-1250.doi: 10.16288/j.yczz.15-244

醋酸菌中CRISPR位点的比较基因组学与进化分析

夏凯, 梁新乐, 李余动

浙江工商大学食品与生物工程学院,杭州 310018

收稿日期:2015-06-01 出版日期:2015-12-20 发布日期:2015-10-08
通讯作者: 李余动,博士,副教授,研究方向：微生物基因组学。E-mail: lyd@zjsu.edu.cn E-mail:xiakai333@126.com
作者简介:夏凯,硕士研究生,专业方向：醋酸菌分子生物学。E-mail: xiakai333@126.com
基金资助:
国家自然科学基金(编号：3117175)和浙江省自然科学基金(编号：LY14C060001)资助

Comparative genomics and evolutionary analysis of CRISPR loci in acetic acid bacteria

Kai Xia, Xinle Liang, Yudong Li

College of Food and Biotechnology, Zhejiang Gongshang University, Hangzhou 310018, China

Received:2015-06-01 Online:2015-12-20 Published:2015-10-08

摘要/Abstract

摘要： CRISPR (Clustered regularly interspaced short palindromic repeats)是近几年发现的一种广泛存在于细菌和古菌中,能够应对外源DNA干扰(噬菌体、病毒、质粒等),并提供免疫机制的重复序列结构。CRISPR系统通常由同向重复序列、前导序列、间隔序列和CRISPR相关蛋白组成。本研究以醋酸发酵中常见3个属醋杆菌属(Acetobacter)、葡糖醋杆菌属(Gluconacetobacter)和葡糖杆菌属(Gluconobacter)的48个菌株为研究对象,通过其基因组上CRISPR相关基因序列的生物信息学分析,探索CRISPR位点在醋酸菌中的多态性及其进化模式。结果表明48株醋酸菌中有32株存在CRISPR结构,大部分CRISPR-Cas结构属于type I-E和type I-C类型。除了葡糖杆菌属外,葡糖醋杆菌属和醋杆菌属中的部分菌株含有II类的CRISPR-Cas系统结构(CRISPR-Cas9)。来自不同属菌株的CRISPR结构中重复序列具有较强的保守性,而且部分菌株CRISPR结构中的前导序列具有保守的motif (与基因的转录调控有关)及启动子序列。进化树分析表明cas1适合用于醋酸菌株的分类,而不同菌株间cas1基因的进化与重复序列的保守性相关,预示它们可能受相似的功能选择压力。此外,间隔序列的数量与噬菌体数量及插入序列(Insertion sequence, IS)数量有正相关的趋势,说明醋酸菌在进化过程中可能正不断受新的外源DNA入侵。醋酸菌中CRISPR结构位点的分析,为进一步研究不同醋酸菌株对醋酸胁迫耐受性差异及其基因组稳定性的分子机制奠定了基础。

关键词: 醋酸菌, CRISPR, 重复序列, 遗传进化

Abstract: The clustered regularly interspaced short palindromic repeat (CRISPR) is a widespread adaptive immunity system that exists in most archaea and many bacteria against foreign DNA, such as phages, viruses and plasmids. In general, CRISPR system consists of direct repeat, leader, spacer and CRISPR-associated sequences. Acetic acid bacteria (AAB) play an important role in industrial fermentation of vinegar and bioelectrochemistry. To investigate the polymorphism and evolution pattern of CRISPR loci in acetic acid bacteria, bioinformatic analyses were performed on 48 species from three main genera (Acetobacter, Gluconacetobacter and Gluconobacter) with whole genome sequences available from the NCBI database. The results showed that the CRISPR system existed in 32 species of the 48 strains studied. Most of the CRISPR-Cas system in AAB belonged to type I CRISPR-Cas system (subtype E and C), but type II CRISPR-Cas system which contain cas9 gene was only found in the genus Acetobacter and Gluconacetobacter. The repeat sequences of some CRISPR were highly conserved among species from different genera, and the leader sequences of some CRISPR possessed conservative motif, which was associated with regulated promoters. Moreover, phylogenetic analysis of cas1 demonstrated that they were suitable for classification of species. The conservation of cas1 genes was associated with that of repeat sequences among different strains, suggesting they were subjected to similar functional constraints. Moreover, the number of spacer was positively correlated with the number of prophages and insertion sequences, indicating the acetic acid bacteria were continually invaded by new foreign DNA. The comparative analysis of CRISR loci in acetic acid bacteria provided the basis for investigating the molecular mechanism of different acetic acid tolerance and genome stability in acetic acid bacteria.

Key words: acetic acid bacteria, CRISPR, repeat sequence, genetic evolution

夏凯, 梁新乐, 李余动. 醋酸菌中CRISPR位点的比较基因组学与进化分析[J]. 遗传, 2015, 37(12): 1242-1250.

Kai Xia, Xinle Liang, Yudong Li. Comparative genomics and evolutionary analysis of CRISPR loci in acetic acid bacteria[J]. HEREDITAS(Beijing), 2015, 37(12): 1242-1250.

参考文献

[1] Illeghems K, Vuyst LD, Weckx S. Complete genome sequence and comparative analysis of Acetobacter pasteurianus 386B, a strain well-adapted to the cocoa bean fermentation ecosystem. BMC Genomics , 2013, 14: 526.
[2] Azuma Y, Hosoyama A, Matsutani M, Furuya N, Horikawa H, Harada T, Hirakawa H, Kuhara S, Matsushita K, Fujita N, Shirai, M. Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus . Nucl Acids Res , 2009, 37(17): 5768-5783.
[3] Matsutani M, Hirakawa H, Saichana N, Soemphol W, Yakushi T, Matsushita K. Genome-wide phylogenetic analysis of differences in thermotolerance among closely related Acetobacter pasteurianus strains. Microbiology , 2012, 158(Pt 1): 229-239.
[4] Hambly E, Suttle CA. The viriosphere, diversity, and genetic exchange within phage communities. Curr Opin Microbiol , 2005, 8(4): 444-450.
[5] Matsutani M, Hirakawa H, Yakushi T, Matsushita K. Genome-wide phylogenetic analysis of Gluconobacter , Acetobacter , and Gluconacetobacter . FEMS Microbiol Lett , 2011, 315(2): 122-128.
[6] Heler R, Marraffini LA, Bikard D. Adapting to new threats: the generation of memory by CRISPR-Cas immune systems. Mol Microbiol , 2014, 93(1): 1-9.
[7] 李君, 张毅, 陈坤玲, 单奇伟, 王延鹏, 梁振, 高彩霞. CRISPR/Cas系统: RNA靶向的基因组定向编辑新技术. 遗传, 2013, 35(11): 1265-1273.
[8] 李铁民, 杜波. CRISPR-Cas系统与细菌和噬菌体的共进化. 遗传, 2011, 33(3): 213-218.
[9] Barrangou R, Marraffini LA. CRISPR-Cas systems: Prokaryotes upgrade to adaptive immunity. Mol Cell , 2014, 54(2): 234-244.
[10] Grissa I, Vergnaud G, Pourcel C. The CRISPRdb database and tools to display CRISPRs and to generate dictionaries of spacers and repeats. BMC Bioinformatics , 2007, 8: 172.
[11] Millen AM, Horvath P, Boyaval P, Romero DA. Mobile CRISPR/Cas-mediated bacteriophage resistance in Lactococcus lactis. PLoS One , 2012, 7(12): e51663.
[12] Terns RM, Terns MP. CRISPR-based technologies: prokaryotic defense weapons repurposed. Trends Genet , 2014, 30(3): 111-118.
[13] Makarova KS, Haft DH, Barrangou R, Brouns SJJ, Charpentier E, Horvath P, Moineau S, Mojica FJM, Wolf YI, Yakunin AF, van der Oost J, Koonin EV. Evolution and classification of the CRISPR-Cas systems. Nat Rev Microbiol , 2011, 9(6): 467-477.
[14] Pourcel C, Salvignol G, Vergnaud G. CRISPR elements in Yersinia pestis acquire new repeats by preferential uptake of bacteriophage DNA, and provide additional tools for evolutionary studies. Microbiology , 2005, 151(Pt 3): 653-663.
[15] Horvath P, Romero DA, Coûté-Monvoisin AC, Richards M, Deveau H, Moineau S, Boyaval P, Fremaux C, Barrangou R. Diversity, activity, and evolution of CRISPR loci in Streptococcus thermophilus . J Bacteriol , 2008, 190(4): 1401-1412.
[16] Barrangou R, Fremaux C, Deveau H, Richards M, Boyaval P, Moineau S, Romero DA, Horvath P. CRISPR provides acquired resistance against viruses in prokaryotes. Science , 2007, 315(5819): 1709-1712.
[17] Brouns SJJ, Jore MM, Lundgren M, Westra ER, Slijkhuis RJH, Snijders APL, Dickman MJ, Makarova KS, Koonin EV, van der Oost J. Small CRISPR RNAs guide antiviral defense in prokaryotes. Science , 2008, 321(5891): 960-964.
[18] Haft DH, Selengut J, Mongodin EF, Nelson KE. A guild of 45 CRISPR-associated (Cas) protein families and multiple CRISPR/Cas subtypes exist in prokaryotic genomes. PLoS Comput Biol , 2005, 1(6): e60.
[19] Horvath P, Coûté-Monvoisin AC, Romero DA, Boyaval P, Fremaux C, Barrangou R. Comparative analysis of CRISPR loci in lactic acid bacteria genomes. Int J Food Microbiol , 2009, 131(1): 62-70.
[20] Díez-Villaseñor C, Almendros C, García-Martínez J, Mojica FJ. Diversity of CRISPR loci in Escherichia coli . Microbiology , 2010, 156(Pt 5): 1351-1361.
[21] Bland C, Ramsey TL, Sabree F, Lowe M, Brown K, Kyrpides NC, Hugenholtz P. CRISPR recognition tool (CRT): a tool for automatic detection of clustered regularly interspaced palindromic repeats. BMC Bioinformatics , 2007, 8: 209.
[22] Crooks GE, Hon G, Chandonia JM, Brenner SE. WebLogo: a sequence logo generator. Genome Res , 2004, 14(6): 1188-1190.
[23] Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. MEGA6: molecular evolutionary genetics analysis version 6.0. Mol Biol Evol , 2013, 30(12): 2725-2729.
[24] Zhou Y, Liang YJ, Lynch KH, Dennis JJ, Wishart DS. PHAST: a fast phage search tool. Nucleic Acids Res , 2011, 39(Web Server issue): W347-W352.
[25] Lima-Mendez G, Van Helden J, Toussaint A, Leplae R. Prophinder: a computational tool for prophage prediction in prokaryotic genomes. Bioinformatics , 2008, 24(6): 863-865.
[26] Siguier P, Perochon J, Lestrade L, Mahillon J, Chandler M. ISfinder: the reference centre for bacterial insertion sequences. Nucl Acids Res , 2006, 34(Database issue): D32-D36.
[27] Jiang FG, Doudna JA. The structural biology of CRISPR- Cas systems. Curr Opin Struct Biol , 2015, 30: 100-111.
[28] Nozawa T, Furukawa N, Aikawa C, Watanabe T, Haobam B, Kurokawa K, Maruyama F, Nakagawa I. CRISPR inhibition of prophage acquisition in Streptococcus pyogenes . PLoS One , 2011, 6(5): e19543.

编辑推荐

Metrics

www.chinagene.cn
备案号：京ICP备09063187号-4
总访问:,今日访问:,当前在线:

醋酸菌中CRISPR位点的比较基因组学与进化分析

Comparative genomics and evolutionary analysis of CRISPR loci in acetic acid bacteria

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

[1]	宗媛,高彩霞. 碱基编辑系统研究进展[J]. 遗传, 2019, 41(9): 777-800.
[2]	郑晓飞,黄海燕,吴强. 染色质架构蛋白CTCF调控UGT1基因簇的表达[J]. 遗传, 2019, 41(6): 509-523.
[3]	王珏, 黄娟, 许蕊. 利用CRISPR/Cas9和piggyBac实现果蝇基因组无缝编辑[J]. 遗传, 2019, 41(5): 422-429.
[4]	张楷, 刘蔚, 刘小凤, 陈瑶生, 刘小红, 何祖勇. 利用CRISPR/Cas9系统构建人HPRT1基因定点突变细胞株[J]. 遗传, 2019, 41(10): 939-949.
[5]	刘恒, 李东明, 朱兰玉, 赖乐锦, 闫婉云, 陆玉双, 韦伊, 黄月琪, 方媚, 苏元港, 杨芳, 舒伟. 利用CRISPR/Cas9敲除人源细胞系中LMNA基因的研究[J]. 遗传, 2019, 41(1): 66-75.
[6]	任云晓, 肖茹丹, 娄晓敏, 方向东. 基因编辑技术及其在基因治疗中的应用[J]. 遗传, 2019, 41(1): 18-27.
[7]	张桂珊, 杨勇, 张灵敏, 戴宪华. 机器学习方法在CRISPR/Cas9系统中的应用[J]. 遗传, 2018, 40(9): 704-723.
[8]	刘海龙, 谌阳, 高杨, 周玲, 韩晓松, 赵长志, 杨高娟, 陈毅龙, 杨慧, 谢胜松. 靶向miRNA前体不同类型sgRNA的丰度及特异性评估[J]. 遗传, 2018, 40(7): 561-571.
[9]	唐浚博, 曹浩伟, 许蕊, 张丹丹, 黄娟. 果蝇睾丸基因敲除突变体的构建及表型分析[J]. 遗传, 2018, 40(6): 478-487.
[10]	李慧卿, 陈超, 陈冉冉, 宋雪薇, 李佶娜, 朱延明, 丁晓东. 利用CRISPR/Cas9双基因敲除系统初步解析大豆GmSnRK1.1和GmSnRK1.2对ABA及碱胁迫的响应[J]. 遗传, 2018, 40(6): 496-507.
[11]	梁彩娇, 孟繁梅, 艾云灿. 基于CRISPR/Cas系统的噬菌体基因组编辑[J]. 遗传, 2018, 40(5): 378-389.
[12]	童晓玲,方春燕,盖停停,石津,鲁成,代方银. CRISPR/Cas9系统在昆虫中的应用[J]. 遗传, 2018, 40(4): 266-278.
[13]	谢晶, 范辰, 张景龙, 张仕强. Ash2l-1/Ash2l-2在小鼠胚胎干细胞中的表达特异性及互补效应[J]. 遗传, 2018, 40(3): 237-249.
[14]	辛高伟, 胡熙璕, 王克剑, 王兴春. Cas9蛋白变体VQR高效识别水稻NGAC前间区序列邻近基序[J]. 遗传, 2018, 40(12): 1112-1119.
[15]	陈一欧, 宝颖, 马华峥, 伊宗裔, 周卓, 魏文胜. 基因编辑技术及其在中国的研究发展[J]. 遗传, 2018, 40(10): 900-915.