Abstract
Facultative phototrophic bacterium Rhodobacter capsulatus DsbA-null mutants are proficient in photosynthesis but are defective in respiration especially in enriched growth medium at 35 degrees C. They also exhibit severe pleiotropic phenotypes extending from motility defects to osmofragility and oxidative stresses. In this work, using a combined proteomics and molecular genetics approach, we demonstrated that the respiratory defect of R. capsulatus DsbA-null mutants originates from the overproduction of the periplasmic protease DegP, which renders them temperature-sensitive for growth. The DsbA-null mutants reverted frequently to overcome this growth defect by decreasing, but not completely eliminating, their DegP activity. In agreement with these findings, we showed that overproduction of DegP abolishes the newly restored respiratory growth ability of the revertants in all growth media. Structural localizations of the reversion mutations in DegP revealed the regions and amino acids that are important for its protease-chaperone activity. Remarkably although R. capsulatus DsbA-null or DegP-null mutants were viable, DegP-null DsbA-null double mutants were lethal at all growth temperatures. This is unlike Escherichia coli, and it indicates that in the absence of DsbA some DegP activity is required for survival of R. capsulatus. Absence of a DegQ protease homologue in some bacteria together with major structural variations among the DegP homologues, including a critical disulfide bond-bearing region, correlates well with the differences seen between various species like R. capsulatus and E. coli. Our findings illustrate the occurrence of two related but distinct periplasmic protease families in bacterial species.
Highlights
Facultative phototrophic bacterium Rhodobacter capsulatus DsbA-null mutants are proficient in photosynthesis but are defective in respiration especially in enriched growth medium at 35 °C
Pleiotropic Phenotypes of R. capsulatus DsbA-null Mutants and Their Revertants—R. capsulatus DsbA-null mutants (e.g. MD20 ⌬(dsbA::kan)) exhibit severe pleiotropic phenotypes extending from motility defects to increased osmosensitivity and oxidative stresses
In an earlier study on cyt c biogenesis, we had observed that R. capsulatus DsbA-null mutants lacking the major periplasmic dithiol:disulfide oxidoreductase were unable to grow by respiration especially on enriched medium [16]
Summary
3D, three-dimensional; MPYE, mineral-peptone-yeast extract; MedA, Sistrom’s minimal medium A; Res, respiratory; Ps, photosynthetic; 2D, two-dimensional; GE, gel electrophoresis; ACTH, adrenocorticotropin; nLC, nano-LC; ABC, ATPbinding cassette; cyt, cytochrome; WT, wild type. The data led us to the major extracytoplasmic stress response protein DegP ( called HtrA or protease Do), which was apparently the only protein highly overproduced in the DsbA mutant and which decreased back to the wild-type levels in a respiration-proficient DsbA revertant. This suggested that overproduction of DegP might be the culprit for the Res growth deficiency of the DsbA-null mutants of R. capsulatus, and we demonstrated this to be the case using molecular genetics approaches. These species differences correlated well with a DsbA-controlled disulfide bondbearing domain, which is present in E. coli but absent in R. capsulatus DegP homologues, and illustrated the occurrence of two interrelated but distinct extracytoplasmic protease families in bacterial species
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