Linkage, Mobility, and Selfishness in the MazF Family of Bacterial Toxins: A Snapshot of Bacterial Evolution

Chopra, Nikita ; Saumitra, ; Pathak, Abhinandan ; Bhatnagar, Rakesh ; Bhatnagar, Sonika (2013) Linkage, Mobility, and Selfishness in the MazF Family of Bacterial Toxins: A Snapshot of Bacterial Evolution Genome Biology and Evolution, 5 (12). pp. 2268-2284. ISSN 1759-6653

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Official URL: http://doi.org/10.1093/gbe/evt175

Related URL: http://dx.doi.org/10.1093/gbe/evt175

Abstract

Prokaryotic MazF family toxins cooccur with cognate antitoxins having divergent DNA-binding folds and can be of chromosomal or plasmid origin. Sequence similarity search was carried out to identify the Toxin-Antitoxin (TA) operons of MazF family followed by sequence analysis and phylogenetic studies. The genomic DNA upstream of the TA operons was searched for the presence of regulatory motifs. The MazF family toxins showed a conserved hydrophobic pocket in a multibinding site and are present in pathogenic bacteria. The toxins of the MazF family are associated with four main types of cognate antitoxin partners and cluster as a subfamily on the branches of the phylogenetic tree. This indicates that transmission of the entire operon is the dominant mode of inheritance. The plasmid borne TA modules were interspersed between the chromosomal TA modules of the same subfamily, compatible with a frequent interchange of TA genes between the chromosome and the plasmid akin to that observed for antibiotic resistance gens. The split network of the MazF family toxins showed the AbrB-linked toxins as a hub of horizontal gene transfer. Distinct motifs are present in the upstream region of each subfamily. The presence of MazF family TA modules in pathogenic bacteria and identification of a conserved binding pocket are significant for the development of novel antibacterials to disrupt the TA interaction. However, the role of TAs in stress resistance needs to be established. Phylogenetic studies provide insight into the evolution of MazF family TAs and effect on the bacterial genome.

Item Type:Article
Source:Copyright of this article belongs to Oxford University Press.
ID Code:133765
Deposited On:30 Dec 2022 06:43
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