LAUSR

Bacteria and archaea accumulate cytoplasmic polyhydroxyalkanoate (PHA) granules under nutrient-limited conditions with excess carbon. The transcriptional regulatory (TR) proteins found on the surface of PHA granules act as repressors as well as activators for the expression of major surface proteins called phasins. Until now, detailed information on the evolutionary relationships between these transcription regulators has not been available. Here, we conducted homology searches and analyzed information available for the domains and protein families of the TR proteins through phylogenetic studies. A total of 282 TR proteins were identified and further classified into four distinct subfamilies based upon the presence of conserved motifs: PHB_acc, TetR-like, AbrB-like, and PadR-like. Depending upon the particular family, the DNA-binding domains were located at either the N- or C-terminus. Our results indicated that TR proteins containing the PHB_acc domain are highly conserved within the bacteria, while other TR proteins are present only within archaea (AbrB-like), gram positive bacteria (PadR-like), or the Pseudomonas genera (TetR-like). The repression domains are charged, hydrophobic, and rich in leucine or glutamine. In phylogenetic analyses, many groups of TR proteins were clustered together according to identical domain architectures showing the independent origins of the TR proteins in the PHA reserve storage system. Further analyses revealed that the TR proteins have experienced multiple gene duplications across prokaryotes. Thus, this study investigated the evolutionary framework of TR proteins and has provided a comprehensive catalog of TR proteins for ongoing studies to characterize the functions of these proteins within diverse organisms.