组 II（非蛋白水解）肉毒梭菌的基因组和生理变异性。

Genomic and physiological variability within Group II (non-proteolytic) Clostridium botulinum.

机构信息

Institute of Food Research (IFR), Norwich Research Park, Colney, Norwich NR4 7UA, UK.

出版信息

BMC Genomics. 2013 May 16;14:333. doi: 10.1186/1471-2164-14-333.

DOI:10.1186/1471-2164-14-333

PMID:23679073

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3672017/

Abstract

BACKGROUND

Clostridium botulinum is a group of four physiologically and phylogenetically distinct bacteria that produce botulinum neurotoxin. While studies have characterised variability between strains of Group I (proteolytic) C. botulinum, the genetic and physiological variability and relationships between strains within Group II (non-proteolytic) C. botulinum are not well understood. In this study the genome of Group II strain C. botulinum Eklund 17B (NRP) was sequenced and used to construct a whole genome DNA microarray. This was used in a comparative genomic indexing study to compare the relatedness of 43 strains of Group II C. botulinum (14 type B, 24 type E and 5 type F). These results were compared with characteristics determined from physiological tests.

RESULTS

Whole genome indexing showed that strains of Group II C. botulinum isolated from a wide variety of environments over more than 75 years clustered together indicating the genetic background of Group II C. botulinum is stable. Further analysis showed that strains forming type B or type F toxin are closely related with only toxin cluster genes targets being unique to either type. Strains producing type E toxin formed a separate subset. Carbohydrate fermentation tests supported the observation that type B and F strains form a separate subset to type E strains. All the type F strains and most of type B strains produced acid from amylopectin, amylose and glycogen whereas type E strains did not. However, these two subsets did not differ strongly in minimum growth temperature or maximum NaCl concentration for growth. No relationship was found between tellurite resistance and toxin type despite all the tested type B and type F strains carrying tehB, while the sequence was absent or diverged in all type E strains.

CONCLUSIONS

Although Group II C. botulinum form a tight genetic group, genomic and physiological analysis indicates there are two distinct subsets within this group. All type B strains and type F strains are in one subset and all type E strains in the other.

摘要

背景

肉毒梭菌是一组生理和系统发育上明显不同的细菌，可产生肉毒神经毒素。虽然已经研究了 I 组（蛋白水解）肉毒梭菌菌株之间的变异性，但 II 组（非蛋白水解）肉毒梭菌菌株之间的遗传和生理变异性以及菌株之间的关系尚不清楚。在这项研究中，测序了 II 组菌株 C. botulinum Eklund 17B（NRP）的基因组，并构建了全基因组 DNA 微阵列。该微阵列用于比较基因组索引研究，以比较 43 株 II 组 C. botulinum（14 株 B 型、24 株 E 型和 5 株 F 型）的亲缘关系。这些结果与从生理测试中确定的特征进行了比较。

结果

全基因组索引显示，从多种环境中分离出的超过 75 年的 II 组 C. botulinum 菌株聚集在一起，表明 II 组 C. botulinum 的遗传背景是稳定的。进一步分析表明，形成 B 型或 F 型毒素的菌株密切相关，只有毒素簇基因的靶标是各自类型所特有的。产生 E 型毒素的菌株形成了一个单独的亚群。碳水化合物发酵试验支持了这样的观察结果，即 B 型和 F 型菌株与 E 型菌株形成了一个单独的亚群。所有 F 型菌株和大多数 B 型菌株都能从支链淀粉、直链淀粉和糖原中产生酸，而 E 型菌株则不能。然而，这两个亚群在最低生长温度或最大 NaCl 浓度下的生长差异并不明显。尽管所有测试的 B 型和 F 型菌株都携带 tehB，但碲酸盐抗性与毒素类型之间没有关系，而所有 E 型菌株的序列都缺失或变异。

结论

尽管 II 组 C. botulinum 形成了一个紧密的遗传群体，但基因组和生理分析表明，该群体中有两个明显的亚群。所有 B 型菌株和 F 型菌株都在一个亚群中，所有 E 型菌株都在另一个亚群中。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e3c4/3672017/2225e079cdcc/1471-2164-14-333-1.jpg

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组 II（非蛋白水解）肉毒梭菌的基因组和生理变异性。

Genomic and physiological variability within Group II (non-proteolytic) Clostridium botulinum.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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