Regulatory network modelling of iron acquisition by a fungal pathogen in contact with epithelial cells

Peer reviewedPublisher PD

Serological Profiling of a Candida albicans Protein Microarray Reveals Permanent Host-Pathogen Interplay and Stage-Specific Responses during Candidemia

Candida albicans in the immunocompetent host is a benign member of the human microbiota. Though, when host physiology is disrupted, this commensal-host interaction can degenerate and lead to an opportunistic infection. Relatively little is known regarding the dynamics of C. albicans colonization and pathogenesis. We developed a C. albicans cell surface protein microarray to profile the immunoglobulin G response during commensal colonization and candidemia. The antibody response from the sera of patients with candidemia and our negative control groups indicate that the immunocompetent host exists in permanent host-pathogen interplay with commensal C. albicans. This report also identifies cell surface antigens that are specific to different phases (i.e. acute, early and mid convalescence) of candidemia. We identified a set of thirteen cell surface antigens capable of distinguishing acute candidemia from healthy individuals and uninfected hospital patients with commensal colonization. Interestingly, a large proportion of these cell surface antigens are involved in either oxidative stress or drug resistance. In addition, we identified 33 antigenic proteins that are enriched in convalescent sera of the candidemia patients. Intriguingly, we found within this subset an increase in antigens associated with heme-associated iron acquisition. These findings have important implications for the mechanisms of C. albicans colonization as well as the development of systemic infection

Peptides accelerate their uptake by activating a ubiquitin-dependent proteolytic pathway

Protein degradation by the ubiquitin system controls the intracellular concentrations of many regulatory proteins. A protein substrate of the ubiquitin system is conjugated to ubiquitin through the action of three enzymes, E1, E2 and E3, with the degradation signal (degron) of the substrate recognized by E3 (refs 1-3). The resulting multi-ubiquitylated substrate is degraded by the 26S proteasome. Here we describe the physiological regulation of a ubiquitin-dependent pathway through allosteric modulation of its E3 activity by small compounds. Ubr1, the E3 enzyme of the N-end rule pathway (a ubiquitin-dependent proteolytic system) in Saccharomyces cerevisiae mediates the degradation of Cup9, a transcriptional repressor of the peptide transporter Ptr2 (ref. 5). Ubr1 also targets proteins that have destabilizing amino-terminal residues. We show that the degradation of Cup9 is allosterically activated by dipeptides with destabilizing N-terminal residues. In the resulting positive feedback circuit, imported dipeptides bind to Ubr1 and accelerate the Ubr1-dependent degradation of Cup9, thereby de-repressing the expression of Ptr2 and increasing the cell's capacity to import peptides. These findings identify the physiological rationale for the targeting of Cup9 by Ubr1, and indicate that small compounds may regulate other ubiquitin-dependent pathways