Copper Stress Causes an in Vivo Requirement for the Escherichia coli Disulfide Isomerase DsbC

Abstract: In Escherichia coli, the periplasmic disulfide oxidoreductase DsbA is thought to be a powerful but nonspecific oxidant, joining cysteines together the moment they enter the periplasm. DsbC, the primary disulfide isomerase, likely resolves incorrect disulfides. Given the reliance of protein function on correct disulfide bonds, it is surprising that no phenotype has been established for null mutations in dsbC. Here we demonstrate that mutations in the entire DsbC disulfide isomerization pathway cause an increase… Show more

“…Only when the entire type 1 pilus gene cluster was overexpressed via a plasmid in a dsbA deletion strain could type 1 pilus biogenesis still be observed, but at reduced levels compared to wild-type cells 23,24 . The latter finding does not contradict the dependence on DsbA of type 1 pilus biogenesis in wild-type E. coli strains and may be explained by partial oxidation of overexpressed pilus subunits by air oxygen, which is possibly catalyzed by traces of transition metals such as copper 45 . The periplasmic disulfide isomerase DsbC might also act as an oxidant under certain growth conditions 19,20,46 .…”

Quality control of disulfide bond formation in pilus subunits by the chaperone FimC

“…Only when the entire type 1 pilus gene cluster was overexpressed via a plasmid in a dsbA deletion strain could type 1 pilus biogenesis still be observed, but at reduced levels compared to wild-type cells 23,24 . The latter finding does not contradict the dependence on DsbA of type 1 pilus biogenesis in wild-type E. coli strains and may be explained by partial oxidation of overexpressed pilus subunits by air oxygen, which is possibly catalyzed by traces of transition metals such as copper 45 . The periplasmic disulfide isomerase DsbC might also act as an oxidant under certain growth conditions 19,20,46 .…”

Quality control of disulfide bond formation in pilus subunits by the chaperone FimC

“…Since there is increasing evidence to indicate that the periplasm is an important cellular compartment for copper homeostasis (Bagai et al, 2008;Egler et al, 2005;Hiniker et al, 2005;Macomber et al, 2007), elucidating the involvement of VcCot (VCA0261-0260) and Vc-CopG (VC2216) homologues in V. cholerae copper tolerance represented an interesting topic of study. The evaluation of the role of VC2215 and VC0974 genes in copper resistance was also interesting, since their original annotations were only based on sequence similarity.…”

Periplasmic proteins encoded by VCA0261–0260 and VC2216 genes together with copA and cueR products are required for copper tolerance but not for virulence in Vibrio cholerae

“…When in excess, however, copper is highly toxic to living cells, as it interacts with free proteinogenic thiol groups, destabilizes iron-sulfur cofactors, competes with other metals for protein binding sites, and possibly leads to formation of reactive oxygen species (Chillappagari et al, 2010;Hiniker et al, 2005;Macomber & Imlay, 2009). Remarkably, disturbance of copper homeostasis is thought to lead to human diseases such as Alzheimer's disease, Parkinson's disease, Wilson's disease and Menkes syndrome (Barnham & Bush, 2008;Lenartowicz et al, 2011;Lutsenko, 2010).…”

Copper-responsive gene regulation in bacteria