Abstract
Copper homeostasis in pathogenic bacteria is critical for cuproprotein assembly and virulence. However, in vivo biochemical analyses of these processes are challenging, which has prevented defining and quantifying the homeostatic interplay between Cu+-sensing transcriptional regulators, chaperones, and sequestering molecules. The cytoplasm of Pseudomonas aeruginosa contains a Cu+-sensing transcriptional regulator, CueR, and two homologous metal chaperones, CopZ1 and CopZ2, forming a unique system for studying Cu+ homeostasis. We found here that both chaperones exchange Cu+, albeit at a slow rate, reaching equilibrium after 3 h, a time much longer than P. aeruginosa duplication time. Therefore, they appeared as two separate cellular Cu+ pools. Although both chaperones transferred Cu+ to CueR in vitro, experiments in vivo indicated that CopZ1 metallates CueR, eliciting the translation of Cu+ efflux transporters involved in metal tolerance. Although this observation was consistent with the relative Cu+ affinities of the three proteins (CopZ1 < CueR < CopZ2), in vitro and in silico analyses also indicated a stronger interaction between CopZ1 and CueR that was independent of Cu+ In contrast, CopZ2 function was defined by its distinctly high abundance during Cu2+ stress. Under resting conditions, CopZ2 remained largely in its apo form. Metal stress quickly induced CopZ2 expression, and its holo form predominated, reaching levels commensurate with the cytoplasmic Cu+ levels. In summary, these results show that CopZ1 acts as chaperone delivering Cu+ to the CueR sensor, whereas CopZ2 functions as a fast-response Cu+-sequestering storage protein. We propose that equivalent proteins likely play similar roles in most bacterial systems.
Highlights
Copper homeostasis in pathogenic bacteria is critical for cuproprotein assembly and virulence
Assuming that copper homeostasis is enabled by an integrated molecular system distributing Cuϩ to various targets, we characterized this molecular network in Pseudomonas aeruginosa under nondeleterious extracellular Cu2ϩ stress
Genome-wide transcriptomic analysis revealed the presence of cytoplasmic (CueR) and periplasmic (CopS/R) Cuϩ sensing regulators, their corresponding regulons, multiple metal chaperones, and specific Cuϩ efflux and influx systems bridging the membranes separating cellular compartments [15]
Summary
The structural similarities between CopZ1 and CopZ2, sharing 37% sequence identity and the invariant CXXC Cu-binding motif, might suggest an analogous functional role. CopZ2-like proteins (352 sequences) are only present in prokaryotes and the Cuϩ-binding loop has an invariant His (MXCXHC) (Fig. 1B) This His is likely responsible for the higher Cuϩ affinity observed in P. aeruginosa CopZ2 [15], as it has been shown that its removal decreases S. lividans CopZs affinity for Cuϩ [25]. The ⌬copZ2 mutation did not affect the cell copper levels paralleling its lack of growth phenotype These differences in Cu2ϩ tolerance and cellular metal levels observed in ⌬copZ1 and ⌬copZ2 strains point out distinct functional roles for the corresponding proteins. Cuϩ transfer between homologous CopZ proteins and the structurally similar N-terminal metal-binding domains present in Cuϩ-ATPases is well characterized (38 –40).
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