Roy, U.; Far, E.; Chattopadhyay, S.; Weissman, Z.; Kornitzer, D.

The fungal pathobiont Candida albicans acquires heme from host proteins via a set of soluble and anchored extracellular CFEM-type hemophores that can capture the bound heme and exchange it, eventually delivering it to the cell membrane for endocytosis into the yeast cell. Yet the molecular mechanism by which the heme is transferred through this protein cascade across the cell envelope remains unclear. To address this mechanism, we developed a set a fusions of three C. albicans hemophores with fluorescent proteins. Fluorescence of these fusion proteins is strongly quenched when heme is bound to the hemophore moiety, enabling to measure heme transfer instantaneously. Kinetic analysis of the different transfer reactions reveals that heme transfer from the host protein to the CFEM hemophores and between the CFEM hemophores are governed by different regimes. Kinetics of heme transfer from hemoglobin or serum albumin to the CFEM hemophores is mainly first-order, suggesting that heme stochastically released from host proteins is captured by the hemophores. In contrast, transfer of heme between the hemophores is near second-order, consistent with a mechanism requiring protein-protein interactions. To confirm this, we show that CFEM hemophores can interact in homodimeric and heterodimeric complexes. Furthermore, while dimerization-defective mutants of the soluble hemophore Csa2 are proficient in heme binding and extraction, they are defective in heme transfer. This supports a model of heme transfer by direct interaction between the members of the fungal hemophore cascade.