State Key Laboratory of Microbial Metabolism, Joint International Laboratory on Metabolic & Developmental Sciences, School of Life Sciences & Biotechnology, Shanghai Jiao Tong Universitygrid.16821.3c, Shanghai, China.
Intensive Care Unit, First Affiliated Hospital of Guangxi Medical University, Nanning, Guangxi Province, China.
Microbiol Spectr. 2022 Aug 31;10(4):e0032022. doi: 10.1128/spectrum.00320-22. Epub 2022 Jun 15.
Toxin-antitoxin (TA) modules containing a Gcn5-related -acetyltransferase (GNAT) toxin domain regulate bacterial physiology under adverse environmental stresses. Multiple GNAT-ribbon-helix-helix domain (RHH) TA loci have been identified in single bacterial genomes. However, their diversity and interactions are still obscure. Our previous analysis showed that the GNAT toxin of Klebsiella pneumoniae, KacT, introduces antibiotic tolerance and the toxicity of GNAT is neutralized by KacA, an RHH antitoxin. We here present a phylogenetic analysis of GNAT toxins of more than 1,000 GNAT-RHH pairs detected in completely sequenced K. pneumoniae genomes, revealing that the GNAT toxins are diverse and grouped into four distinct clades. Overexpression of GNAT toxins representative of each of the four clades halts the cell growth of K. pneumoniae, while the coexpression of the cognate RHH antitoxin neutralizes GNAT toxicity. We also identify point mutations that inactivate the GNAT toxins. Moreover, we observe a cross-interaction between GNAT-RHH pairs encoded by different replicons, where a chromosomal toxin (KacT2) can be neutralized by its cognate RHH antitoxin (KacA2 on a chromosome) and another antitoxin (KacA3 on a plasmid). Finally, statistical analysis of the distribution of GNAT-RHH loci in K. pneumoniae strains shows pronounced deviation from random distribution within the same clades. Moreover, we also obtain statistically significant correlations between different clades, which we discuss in terms of the experimental results. Elucidating the roles of multifaceted GNAT-RHH TA loci is essential for understanding how these TAs interact among themselves. Recently, the reaction mechanisms and structures of several GNAT-RHH pairs have been reported. While bacterial strains can carry multiple GNAT-RHH loci with diverse origins, studies on the possible cross-interactions of these TA pairs are still limited. Here, we find that 1,000 predicted GNAT toxins of K. pneumoniae can be grouped into four distinct clades. The distributions of TA loci within these clades in K. pneumoniae strains are highly nonrandom, with the presence of a single locus of each clade per strain being highly overrepresented. Moreover, the toxicity of a GNAT toxin encoded by a chromosome was alleviated by a noncognate RHH antitoxin on a plasmid. These results might yield a profound understanding of the widespread GNAT-RHH TA pairs and the cross-interactions between noncognate TA pairs located on different replicons.
毒素-抗毒素 (TA) 模块包含一个 Gcn5 相关的乙酰转移酶 (GNAT) 毒素结构域,可在不利的环境压力下调节细菌的生理机能。在单个细菌基因组中已经鉴定出多个 GNAT-卷曲螺旋-螺旋结构域 (RHH) TA 基因座。然而,它们的多样性和相互作用仍然不清楚。我们之前的分析表明,肺炎克雷伯氏菌的 GNAT 毒素 KacT 会引入抗生素耐受性,并且 RHH 抗毒素 KacA 可以中和 GNAT 的毒性。我们在此展示了在完全测序的肺炎克雷伯氏菌基因组中检测到的超过 1000 个 GNAT-RHH 对的 GNAT 毒素的系统发育分析,结果表明 GNAT 毒素种类繁多,并分为四个不同的进化枝。代表四个进化枝中的每一个的 GNAT 毒素的过表达都会阻止肺炎克雷伯氏菌的细胞生长,而同源 RHH 抗毒素的共表达则可以中和 GNAT 的毒性。我们还鉴定了使 GNAT 毒素失活的点突变。此外,我们观察到来自不同复制子的 GNAT-RHH 对之间的交叉相互作用,其中染色体毒素 (KacT2) 可以被其同源 RHH 抗毒素 (染色体上的 KacA2) 和另一种抗毒素 (质粒上的 KacA3) 中和。最后,对肺炎克雷伯氏菌菌株中 GNAT-RHH 基因座的分布进行统计分析表明,同一进化枝内的分布明显偏离随机分布。此外,我们还获得了不同进化枝之间具有统计学意义的相关性,我们将根据实验结果对此进行讨论。阐明多方面的 GNAT-RHH TA 基因座的作用对于理解这些 TA 如何相互作用至关重要。最近,已经报道了几个 GNAT-RHH 对的反应机制和结构。尽管细菌株可以携带具有不同来源的多个 GNAT-RHH 基因座,但对这些 TA 对之间可能发生的交叉相互作用的研究仍然有限。在这里,我们发现 1000 个预测的肺炎克雷伯氏菌的 GNAT 毒素可以分为四个不同的进化枝。在肺炎克雷伯氏菌菌株中,这些进化枝内的 TA 基因座的分布高度非随机,每个菌株中每个进化枝的单个基因座的存在高度过表达。此外,染色体上编码的 GNAT 毒素的毒性被质粒上的非同源 RHH 抗毒素减轻。这些结果可能会深入了解广泛存在的 GNAT-RHH TA 对以及位于不同复制子上的非同源 TA 对之间的交叉相互作用。
