"Genome-Centric Evaluation of Bacillus sp. strain –ATCC55673 and Response to Uranium Biomineralization"

Significances of Bioengineering & Biosciences Pub Date : 2018-08-03 DOI:10.31031/SBB.2018.02.000539

V. Ibeanusi, A. Pathak, Ashvini Chauhan, Jada Hoyle-Gardner, T. Cooper, L. Turker, H. Howard, Oluchukwu Obinegbo, Gang Chen, J. Seaman

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引用次数: 2

Abstract

A patented microbial systems process was conducted on microbial-mediated biodegradative mechanisms at a coal-pile run off basin discharged from the coal fired plant at Savannah River Site, Aiken, South Carolina (SC). One of the isolated strains, ATCC 55673, grew robustly on number of dissolved toxic metals. Genome-centric evaluation revealed the isolate to belong to the genus Bacillus with close affiliation to B. cereus , an aggressive polychlorinated biphenyl-degrader. At a coverage of 90x, the genome of strain ATCC 55673 consisted of 4,615,850 bases with a total number of 4,590 putative genes assembling into 51 contigs with an N50 contig length of 2,597,36 bases. Several gene homologues coding for resistance to heavy metals were identified, such as a suite of outer membrane efflux pump proteins like nickel/cobalt transporter regulators, peptide/nickel transport substrate and ATP-binding proteins, permease proteins, a high-affinity nickel-transport protein, and several genes for metabolism of aromatic compounds (Table 1).

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芽孢杆菌菌株-ATCC55673的基因组中心评价及其对铀生物矿化的响应

在南卡罗来纳州艾肯萨凡纳河煤厂排放的煤堆径流盆地中进行了微生物介导的生物降解机制的专利微生物系统过程。其中一个分离菌株ATCC 55673在溶解有毒金属的数量上增长强劲。以基因组为中心的评估显示，该分离物属于芽孢杆菌属，与具有侵略性的多氯联苯降解物蜡样芽孢杆菌密切相关。在覆盖率为90倍时，菌株ATCC 55673的基因组包含4,615,850个碱基，共有4,590个假定基因组装成51个contig, N50 contig长度为2,597,36个碱基。几个编码重金属抗性的基因同源物被鉴定出来，如一套外膜外排泵蛋白，如镍/钴转运调节因子，肽/镍转运底物和atp结合蛋白，渗透酶蛋白，高亲和力镍转运蛋白，以及一些芳香化合物代谢基因(表1)。

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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Significances of Bioengineering & Biosciences

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