Hemoglobin Regulates Expression of an Activator of Mating-Type Locus α Genes in Candida albicans

Conservation of the predicted amino acid sequences of HBR1 and FAP7. The alignment of predicted protein sequences of Hbr1p and Fap7p is shown. A consensus sequence was generated using DIALIGN 2.2 (37; http://bibiserv.techfak.uni-bielefeld.de/dialign/ ) with the following eukaryotic orthologs of Hbr1p: Schizosaccharomyces (CAB52884), Candida (AF466197), Saccharomyces (CAA98740), Caenorhabditis (Q09527), Drosophila (AAF58491), Oryctolagus (AAF09498), Homo sapiens (Q9Y3D8), Mus (BAB29612), Anopheles (EAA06472), and Arabidopsis (BAB10972). All uppercase residues were aligned in the analysis. Consensus residues that were highly conserved are indicated below the aligned yeast sequences. Residues 65 to 68 are the SUMO consensus (43).

HBR1 deletion leads to high-frequency white-opaque phase switching. (A) Prototrophic HBR1^+/− strain CAMP 43 growing on phloxine B agar plates (frame 1), showing an opaque colony (center) surrounded by white colonies, from microscopic examination of CAMP 43 (frame 2, opaque; frame 3, white), and Red 3/6 (frame 4, opaque) cells. Bar, 10 μm. (B) Scanning electron micrograph of a CAMP 43 opaque cell, illustrating the surface protrusions or pimples characteristic of opaque cells. Bar, 3 μm. (C) Regulation of phase-specific genes in the HBR1 heterozygote was determined by RT-PCR analysis of RNA isolated from 4-h exponential-phase cultures of strain CAMP 43 grown at 30°C in YNB-glucose. W, white; O, opaque; ACT1, actin. Probes for phase-specific transcription were as follows: white, WH11 (59); opaque, OP4 and SAP1 (38).

Hbr1p is a positive regulator of MTLα expression. (A) HBR1 heterozygosity does not lead to MTL gene deletions. Results of PCR analysis of genomic DNA using primers specific for MTL genes and for the λimm434 region used in construction of parental strain CAI-4 (14) are shown. Lanes 1 and 2, CAMP43, white and opaque, respectively; lane 3, Red 3/6, white; lane 4, CAI-4, white; lane 5, clinical isolate 156, white. (B) MTL α gene expression is not detectable in the HBR1 heterozygote, as shown by an RT-PCR analysis of RNA isolated from 4-h exponential-phase cells cultured in YNB-glucose medium at 30°C. Gene-specific primers listed on the left were used in PCRs of 26 cycles (MTL genes) or 20 cycles (ACT1). Lane 1, strain CAMP 48; lanes 2 and 3, strain CAMP 43; lane 4, strain CAI-4. (C) MTLα genes are induced only during exponential growth. Results of the RT-PCR analysis of RNA isolated from CAF2-1 cells at the indicated times after transfer of stationary-phase cells to YNB-glucose medium are shown. (D) HBR1 overexpression sustains MTLα expression into early stationary phase. Results of RT-PCR analysis of RNA harvested at 4 and 24 h after transfer of stationary-phase cells to low-methionine medium are shown. CAMP 63 contains an HBR1 copy under the control of the MET3 promoter. The MET3 promoter maintained HBR1 RNA at higher levels in the CAMP 63 strain than in strains containing only the native HBR1 promoter (see Fig. 6B). (E) Hemoglobin can sustain MTLα gene expression into stationary phase. Strain CAF2-1 cells were cultivated in the presence or absence of 0.5 mg of hemoglobin/ml, and RNA was harvested at the indicated times. Primer sets for RT-PCR analysis are listed in the figure. MTLα, 26 cycles; rRNA, 15 cycles.

Regulation of a1/α2 repression and α-cell gene targets through HBR1. (A) An a1/α2 target is derepressed in an HBR1 heterozygote. Results of qPCR analysis of RNA isolated from 4-h log-phase cells with and without 0.5 mg of hemoglobin/ml are shown. MTL and HBR1 genotypes as well as white (W) and opaque (O) phenotypes are indicated. CAG1 expression from each strain was corrected for the level of the CDC36 internal standard and then normalized to CAF2-1 levels (arbitrarily set at 1). Strain designations (from left to right): CAF2-1, CAMP 43, CAMP 43, CHY477, CAMP 49, and MM278. This figure represents two separate analyses. Levels are reported as ± the SD. (B). YEL007w expression is derepressed in HBR1 heterozygous cells. qPCR analysis was carried out with the same cDNA preparations as described for panel A. Strain designations are as in panel A, except CAMP 43 opaque cells were not tested. Normalized levels are reported as ± the SD. (C and D) Two α-specific genes are down-regulated in CAMP 43 opaque cells. Mating factor α and STE3 mRNA levels were determined using qPCR with the same cDNA preparations as described for panel A. Levels are reported as ± the SD.

HBR1 regulates a-specific genes and is a negative regulator of MTL a. (A) Two a-specific genes are regulated through HBR1. qPCR analysis was performed using the same cDNA preparations as in Fig. 5. (B) Hbr1p expression represses MTLa1 expression. Strain CAMP 43 contains only one HBR1 allele, and CAMP 63 contains HBR1 expressed at high levels under the control of the MET3 promoter.