Biogenesis and Function of c-type Cytochromes in the Methanogenic Archaeon, Methanosarcina acetivorans

Abstract

C-type cytochromes (cyt c) are proteins that covalently bind heme and are integral to electron transport chains. A growing body of evidence suggests that cyt c play a vital role in both intra- and extra-cellular electron transfer processes in Archaea, especially in members that metabolize methane and other short chain alkanes. Elaborate mechanisms for the biogenesis of cyt c are known in Bacteria and Eukarya but this process remains largely uncharacterized in Archaea. Here, we have used the model methanogenic archaeon Methanosarcina acetivorans to characterize a distinct form of the system I cyt c maturation machinery (referred to as the Ccm machinery henceforth) that is broadly distributed in members of the Archaea. Phenotypic analyses of M. acetivorans mutants deficient in essential components of the Ccm machinery reveal that cyt c are broadly important for growth and methanogenesis, but the magnitude of their impact can vary substantially depending on the growth substrate. Heterologous expression of a synthetic operon with the Ccm machinery (CcmABCEF) from M. acetivorans is both necessary and sufficient for cyt c biogenesis in a non-native host (M. barkeri Fusaro) that is incapable of cyt c biogenesis. Even though components of the Ccm machinery are universally conserved across the Archaea, our evolutionary analyses indicate that different clades of Archaea acquired this pathway through multiple independent horizontal gene transfer events from different groups of Bacteria. Overall, we have demonstrated the convergent evolution of a novel Archaea-specific Ccm machinery for cyt c biogenesis and its role in methane metabolism.