The copper resistome of group B Streptococcus reveals insight into the genetic basis of cellular survival during metal ion stress
2021
In bacteria, copper (Cu) can support metabolic processes as an enzymatic cofactor but can also cause cell damage if present in excess, leading to intoxication. In group B Streptococcus (GBS) a system for control of Cu efflux based on the canonical cop operon supports survival during Cu stress. In some other bacteria, genetic systems additional to the cop operon are engaged during Cu stress and also contribute to Cu management. Here, we examined genetic systems beyond the cop operon in GBS for regions that contribute to survival of GBS in Cu stress using a forward genetic screen and probe of the entire bacterial genome. A high-density mutant library, generated using pGh9-ISS1, was used to expose GBS to Cu stress and compared to non-exposed controls en masse. Nine genes were identified as essential for GBS survival in Cu stress, whereas five genes constrained GBS growth in Cu stress. The genes encode varied factors including enzymes for metabolism, cell wall synthesis, transporters and global transcriptional regulators. Targeted mutation of the genes validated their roles in GBS resistance to Cu stress. Notably, several genes, including stp1, yceG, plyB and rfaB were also essential for resistance to Zn stress. Excepting copA, the genes identified are new to the area of bacterial metal ion intoxication. We conclude that a discrete and limited suite of genes beyond the cop operon in GBS contribute to a repertoire of mechanisms used to survive Cu stress in vitro and achieve cellular homeostasis. Significance StatementGenetic systems for copper (Cu) homeostasis in bacteria, including Streptococci, are vital to survive metal ion stress. Genetic systems that underpin survival of GBS during Cu stress, beyond for the archetypal cop operon for Cu management, are undefined. We show that Streptococcus resists Cu intoxication by utilizing a discrete and limited suite of genes beyond the cop operon, including several genes that are new to the area of bacterial cell metal ion homeostasis. The Cu resistome of GBS defined here enhances our understanding of metal ion homeostasis in GBS.
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