Iron is one of the essential elements for all living organisms. Pathogenic bacteria acquire heme from the host proteins as an iron source. Gram-negative opportunistic pathogen, Burkholderia cenocepacia have ATP-binding cassette (ABC) transporter BhuUV-T complex to permeate heme through inner membrane. BhuT, periplasmic binding protein (PBP), bind and deliver heme(s) to inner membrane transporter BhuUV complex. BhuUV is 2:2 complex of the transmembrane permease subunit and cytoplasmic ATP-binding subunit which couple ATP hydrolysis to solute translocation. The molecular level mechanism of heme recognition and dissociation by PBP and heme transport by transporter complex are not fully understood. Here we describe the crystal structures of the heme-free and two types of heme-bound state of BhuT. These crystals were obtained in different crystallization conditions. Crystals diffracted to high resolution at SPring-8. BhuT is composed of two globular domains linked by a long a-helix. The transport ligand heme is bound between the two domains. A detailed structural comparison of the conformation of the domain and residues involved in the heme binding will be presented.

Iron is an essential element for almost all organisms, since iron serves as a catalytic center for redox reactions in many enzymes. Bacterial pathogens need to acquire iron from tissues of host to survive. Heme transport by ATP-binding cassette (ABC) transporter plays a key role in pathological processes. In gram-negative bacteria, the heme or heme protein binds to specific outer membrane receptors on the bacterial surface. The heme is then transported into the cell via ABC transporters. Here, we present the crystal structure of the heme transporter complex BhuUV-T from Burkholderia cenocepacia at 3.5 Å resolution in nucleotide-free state. The permeation pathway created by transmembrane helices of two BhuU subunit exhibits an inward-facing conformation. Comparison with the outward-facing conformation previously reported for the heme transporter HmuUV from Yersinia pestis and homologous vitamin B12 transporter BtuCD-F from E. coli indicates the structural mechanism involving the translational shift of nucleotide binding subunit and repositioning of the helices of permease subunits for substrate translocation. Structure of interface between BhuUV and periplasmic heme-binding protein BhuT suggests that the acidic residues of BhuU at the periplasmic interface may have an important role in releasing the heme from BhuT. We also determined the BhuT in apo and two types of holo form, providing the structural basis for transient and ambiguous heme recognition.