The human ZIP4 transporter has two distinct binding affinities and mediates transport of multiple transition metals

Zinc is the second most abundant transition metal in the body. Despite the fact that hundreds of biomolecules require zinc for proper function and/or structure, the mechanism of zinc transport into cells is not well-understood. The ZIP (Zrt- and Irt-like proteins; SLC39A) family of proteins acts to increase cytosolic concentrations of zinc. Mutations in one member of the ZIP family of proteins, the human ZIP4 (hZIP4; SLC39A4) protein, can result in the disease acrodermatitis enteropathica (AE). AE is characterized by growth retardation and diarrhea, as well as behavioral and neurological disturbances. While the cellular distribution of hZIP4 protein expression has been elucidated, the cation specificity, kinetic parameters of zinc transport, and residues involved in cation translocation are unresolved questions. Therefore, we have established a high signal-to-noise zinc uptake assay following heterologous expression of hZIP4 in Xenopus laevis oocytes. The results from our experiments have demonstrated that zinc, copper(II), and nickel can be transported by hZIP4 when the cation concentration is in the micromolar range. We have also identified a nanomolar binding affinity where copper(II) and zinc can be transported. In contrast, under these conditions, nickel can bind but is not transported by hZIP4. Finally, labeling of hZIP4 with maleimide or diethylpyrocarbonate indicates that extracellularly accessible histidine, but not cysteine, residues are required, either directly or indirectly, for cation uptake. The results of our experiments identify at least two coordination sites for divalent cations and provide a new framework for investigating the ZIP family of proteins.     

Computation and Functional Studies Provide a Model for the Structure of the Zinc Transporter hZIP4

Members of the Zrt and Irt protein (ZIP) family are a central participant in transition metal homeostasis as they function to increase the cytosolic concentration of zinc and/or iron. However, the lack of a crystal structure hinders elucidation of the molecular mechanism of ZIP proteins. Here, we employed GREMLIN, a co-evolution-based contact prediction approach in conjunction with the Rosetta structure prediction program to construct a structural model of the human (h) ZIP4 transporter. The predicted contact data are best fit by modeling hZIP4 as a dimer. Mutagenesis of residues that comprise a central putative hZIP4 transmembrane transition metal coordination site in the structural model alter the kinetics and specificity of hZIP4. Comparison of the hZIP4 dimer model to all known membrane protein structures identifies the 12-transmembrane monomeric Piriformospora indica phosphate transporter (PiPT), a member of the major facilitator superfamily (MFS), as a likely structural homolog.     

β-Hemolysin/Cytolysin of Group B Streptococcus Enhances Host Inflammation but Is Dispensable for Establishment of Urinary Tract Infection

Group B Streptococcus (GBS; Streptococcus agalactiae) is a major human pathogen that disproportionately affects neonates and women in the peripartum period and is an emerging cause of infection in older adults. The primary toxin of GBS, β-hemolysin/cytolysin (βH/C), has a well-defined role in the pathogenesis of invasive disease, but its role in urinary tract infection (UTI) is unknown. Using both in vitro and in vivo models, we analyzed the importance of βH/C in GBS uropathogenesis. There were no significant differences in bacterial density from the bladders or kidneys from mice infected with wild-type or isogenic βH/C-deficient GBS, and competitive indices from co-infection experiments were near 1. Thus, βH/C is dispensable for the establishment of GBS-UTI. However, βH/C-sufficient GBS induced a more robust proinflammatory cytokine response in cultured bladder epithelial cells and in the urinary tracts of infected mice. Given the near ubiquity of βH/C-expressing strains in epidemiologic studies and the importance of local inflammation in dictating outcomes and sequelae of UTI, we hypothesize that βH/C-driven inflammatory signaling may be important in the clinical course of GBS-UTI.