UbiB proteins mediate an ATP-dependent decarboxylation step in bacterial ubiquinone biosynthesis

Abstract Polyisoprenoid quinones such as ubiquinone (UQ) play an essential role in cellular physiology, acting as membrane-bound electron and proton carriers in respiratory chains and other biological processes across all domains of life. In Escherichia coli , the canonical UQ biosynthesis pathway is well characterized. It involves twelve proteins (UbiA-UbiK and UbiX), most of which catalyzing one of the eight modifications of the aromatic ring derived from 4-hydroxybenzoic acid (4-HB), while others (UbiB, UbiJ, UbiK) act as accessory factors ensuring efficient UQ production. Following prenylation by UbiA and subsequent decarboxylation by the UbiX/UbiD system, the final six reactions are catalyzed within a soluble Ubi-complex. UbiB, an atypical protein kinase-like enzyme, was proposed to extract decarboxylated intermediates from the membrane and mediate their delivery to the Ubi-complex. In this study, we demonstrate the existence of an alternative decarboxylation system in E. coli , as UQ biosynthesis can proceed in the absence of the UbiX/UbiD system. Our results show that this alternative decarboxylation activity depends on UbiB and requires its ATPase activity. Bioinformatic analyses further revealed that approximately 27% of Pseudomonadota species lack UbiX/UbiD homologs, and we found that UbiB proteins from two such species enhance the alternative decarboxylation activity when expressed in E. coli . In addition, we identified conserved residues in UbiB that are specifically required for decarboxylation but dispensable for the delivery of UQ intermediates to the Ubi-complex. Taken together, our findings support a model in which UbiB acts as an ATP-dependent decarboxylase, thereby broadening the functional scope of this poorly characterized protein. Importance Polyisoprenoid quinones, including ubiquinone (UQ, also known as coenzyme Q), are essential electron and proton carriers in respiratory chains across all domains of life. After prenylation and decarboxylation, the final six steps of UQ biosynthesis are carried out by a soluble Ubi-complex. The only decarboxylation system currently identified in the UQ pathway, the UbiX/UbiD system, is absent from numerous bacterial genomes, and no isofunctional enzymes have been described to date. UbiB, an atypical protein kinase-like enzyme, has been proposed to mediate the extraction of UQ precursors from the membrane, thereby rendering them accessible to the soluble Ubi-complex. Here, we show that UbiB proteins fulfill an additional function in bacteria. Specifically, they contribute to the decarboxylation of UQ precursors through a mechanism that remains unknown but depends on ATP hydrolysis. Given that UbiB is conserved in all UQ-producing bacteria, it may represent a widespread decarboxylation system within this essential metabolic pathway.