A Proteomic and Lipidomic Characterization of Bradyrhizobium diazoefficiens Membranes Under Microaerobic Conditions

Hopanoids are a class of sterol-like molecules found in modern bacterial membranes. Remarkably, they can leave behind carbon skeletons (hopanes) that persist for millions of years. Previously, hopanes were thought to be biomarkers of cyanobacteria, and thus, indirectly, the evolution of oxygen. As our understanding of the biosynthetic pathway of hopanoids has improved, we have learned that oxygen is not required for hopanoid biosynthesis and that many different bacteria have the genetic potential to synthesize hopanoids. These facts motivate a deeper understanding of the distribution and role(s) of hopanoids in bacteria. Bioinformatic approaches revealed that a subgroup of bacteria that synthesize hopanoids have symbiotic relationships with plants. These symbioses often take the form of root nodules, which have a unique microenvironment including microaerobic conditions to promote nitrogen fixation. We utilized the legume symbiont Bradyrhizobium diazoefficiens to investigate the molecular composition of membranes through lipidomic and proteomic studies. A B. diazoefficiens mutant lacking the C-2 hopanoid methylase (ΔhpnP) was previously shown to have a growth defect compared to wildtype under microaerobic conditions, whereas a mutant unable to synthesize C35 hopanoids (ΔhpnH) failed to grow entirely. Because these different hopanoid classes impact the fitness of this organism under nodule-like growth conditions, we sought to determine how these classes affect the rest of the membrane. Here, we present how the presence or absence of specific hopanoid classes alters the membrane proteome and lipidome of B. diazoefficiens; this information provides clues regarding their cellular function. By constraining the roles hopanoids play in modern niches, we hope to identify conserved biochemical functions that will advance our interpretations of the hopane rock record.