Acquisition of ionic copper by the bacterial outer membrane protein OprC through a novel binding site

Copper, while toxic in excess, is an essential micronutrient in all kingdoms of life due to its essential role in the structure and function of many proteins. Proteins mediating ionic copper import have been characterised in detail for eukaryotes, but much less so for prokaryotes. In particular, it is still unclear whether and how gram-negative bacteria acquire ionic copper. Here, we show that Pseudomonas aeruginosa OprC is an outer membrane, TonB-dependent transporter that is conserved in many Proteobacteria and which mediates acquisition of both reduced and oxidised ionic copper via an unprecedented CxxxM-HxM metal binding site. Crystal structures of wild-type and mutant OprC variants with silver and copper suggest that acquisition of Cu(I) occurs via a surface-exposed “methionine track” leading towards the principal metal binding site. Together with whole-cell copper quantitation and quantitative proteomics in a murine lung infection model, our data identify OprC as an abundant component of bacterial copper biology that may enable copper acquisition under a wide range of conditions.

Acquisition of ionic copper by a bacterial outer membrane protein

Copper, while toxic in excess, is an essential micronutrient in all kingdoms of life due to its essential role in the structure and function of many proteins. Proteins mediating ionic copper import are known in eukaryotes, but have not yet been described in prokaryotes. Here we show that Pseudomonas aeruginosa OprC is a TonB-dependent transporter that mediates acquisition of ionic copper. Crystal structures of wild type and mutant OprC variants with silver and copper, as well as ICP-MS and electron paramagnetic resonance (EPR), suggest that binding of Cu(I) occurs via a surface-exposed methionine track leading towards an unprecedented CxxxM-HxM metal binding site that binds Cu(I) directly and can facilitate reduction of Cu(II) via the cysteine thiol. Together with quantitative proteomics and growth assays, our data identify OprC as an abundant component of bacterial copper biology that enables copper acquisition and potentially copper storage under a wide range of environmental conditions.

Nanoporous photonic crystals with tailored surface chemistry for ionic copper sensing

We present a study on optical and surface chemistry engineering of nanoporous photonic crystals as sensing platforms for detection of ionic copper.