Depending on the pH of the growth medium, the yeast Yarrowia lipolytica secretes both an acidic proteinase and an alkaline proteinase, the synthesis of which is also controlled by carbon, nitrogen, and sulfur availability, as well as by the presence of extracellular proteins. Recessive mutations at four unlinked loci, named PAL1 to PAL4, were isolated which prevent alkaline proteinase derepression under conditions of carbon and nitrogen limitation at pH 6.8. These mutations markedly affect mating and sporulation. A dominant suppressor of all four PAL mutations was isolated from a wild-type genomic library, which turned out to be a C-terminally truncated form of a 585-residue transcriptional factor of the His 2 Cys 2 zinc finger family, which we propose to call YlRim101p. Another C-terminally truncated version of YlRim101p (419 residues) is encoded by the dominant RPH2 mutation previously isolated as expressing alkaline protease independently of the pH. YlRim101p is homologous to the transcriptional activators Rim101p of Saccharomyces cerevisiae, required for entry into meiosis, and PacC of Aspergillus nidulans and Penicillium chrysogenum, which were recently shown to mediate regulation by ambient pH. YlRim101p appears essential for mating and sporulation and for alkaline proteinase derepression. YlRIM101 expression is autoregulated, maximal at alkaline pH, and strongly impaired by PAL mutations.
The XPR2 gene from Yarrowia lipolytica encodes an inducible alkaline extracellular protease. Its complex regulation involves pH, carbon, nitrogen and peptones. Two previously identified upstream activating sequence (UAS) regions were analysed in a reporter system, outside the XPR2 context. Fragments from the UAS regions were inserted upstream of a minimal LEU2 promoter directing the expression of a reporter gene. The activity of the hybrid promoters was assessed following integration into the Y. lipolyfica genome. This study confirmed the presence of two UASs composed of several interacting elements. Within the distal UAS (UASl), a TUFfRAPl binding site exhibited a UAS activity, which was enhanced by the presence of two adjacent repeats, overlapping sites similar to the CAR1 upstream repressing sequence from Saccharomyces cerewisiae. Within the proximal UAS (UASZ), the UAS activity required the interaction of both an ABF1-like binding site and a decameric repeat, containing Aspergillus nidulans PacC site consensus sequences. This decameric repeat was able to mediate repression due to carbon and/or nitrogen sources as well as pH-dependent activation. A study in the context of frans-regulatory mutations in the Y. /ipo/yfica RIM101 gene showed that the PacC-like sites, potential binding sites for YIRimlOlp, were implicated in the derepression of UASZ-driven expression at neutral-alkaline pH. The in vivo response of the PacC-like decamers to external pH was dependent on the status of the pH-regulated activator YIRimlOlp, which is homologous to the A. nidulans PacC regulator. The carboninitrogen regulation imposed on the decamers was shown to be independent of YlRimlOlp and to override its effects.
Ambient pH signaling involves a cascade of conserved Rim or Pal products in ascomycetous yeasts or filamentous fungi, respectively. Recent evidences in the fungi Aspergillus nidulans, Saccharomyces cerevisiae, Yarrowia lipolytica, and Candida albicans suggested that components of endosomal sorting complexes required for transport (ESCRT) involved in endocytic trafficking were needed for signal transduction along the Rim pathway. In this study, we confirm these findings with C. albicans and show that Vps28p (ESCRT-I) and Vps32p/Snf7p (ESCRT-III) are required for the transcriptional regulation of known targets of the Rim pathway, such as the PHR1 and PHR2 genes encoding cell surface proteins, which are expressed at alkaline and acidic pH, respectively. We additionally show that deletion of these two VPS genes, particularly VPS32, has a more drastic effect than a RIM101 deletion on growth at alkaline pH and that this effect is only partially suppressed by expression of a constitutively active form of Rim101p. Finally, in an in vivo mouse model, both vps null mutants were significantly less virulent than a rim101 mutant, suggesting that VPS28 and VPS32 gene products affect virulence both through Rim-dependent and Rim-independent pathways.
We have initiated a study of the promoter region of the alkaline extracellular protease gene (XPR2) from Yarrowia lipolytica to identify upstream sequences possibly involved in carbon, nitrogen, and peptone control ofXPR2 expression. Deletion analysis showed that the TATA box and two major upstream activation sequences (UASs) were essential for promoter activity under conditions of repression or full induction. Within the distal UAS (UAS1), in vivo footprinting studies with dimethyl sulfate (DMS) identified two sequences similar to Saccharomyces cerevisiae GCN4 (-800 to -792)-and TUF/RAP1 (-790 to -778)-binding sites and two sequences which partially overlap a repeated sequence (-778 to -771 and -720 to -713) similar to the CAR] upstream repression sequence of S. cerevisiae. Oligonucleotides carrying the TUF/RAPi-like-binding site and adjacent downstream nucleotides restored full transcriptional activity of a UAS1-deleted promoter. Within the proximal UAS (UAS2), a directly repeated decameric sequence (-146 to -137 and -136 to -127) was protected against DMS in vivo. Sequences identical to the ABF1-binding site of S. cerevisiae (-121 to -109) or similar to the GCN4-binding site (-113 to -105) were not clearly protected from DMS in vivo. An oligomer (-150 to -106) carrying these three sequences, inserted into a UAS2-deleted promoter, increased the transcriptional activity. The results from footprints under different physiological conditions suggested that protein binding to both UASs was constitutive. Deletion of both UASs greatly reducedXPR2 expression without abolishing its regulation. Our results strongly suggest that these UASs are targets for transcriptional factors required for assisting specific regulatory proteins.
In Yarrowia lipolytica, the transcription factor Rim101p mediates both pH regulation and control of mating and sporulation. Like its homologues PacC of Aspergillus nidulans and Rim101p of Saccharomyces cerevisiae, Y1Rim101p is activated by proteolytic C-terminal processing, which occurs in response to a signal transduced by a pathway involving several PAL gene products. We report here the cloning and sequencing of two of these genes, PAL2 and PAL3. PAL2 encodes a putative 632-residue protein with six possible transmembrane segments, which differs from the transmembrane proteins Rim9p of S. cerevisiae and Pall of A. nidulans, but is homologous to A. nidulans Pa1H and to the product of the ORF YNL294c, a predicted polypeptide of unknown function in S. cerevisiae. PAL3 encodes an 881-residue polypeptide that is homologous to PalF of A. nidulans and to a newly identified putative polypeptide of S. cerevisiae. Both PAL2 and PAL3 are expressed constitutively, regardless of ambient pH. Mutations in these genes affect growth at alkaline pH and sporulation in both Y. lipolytica and in S. cerevisiae. They affect invasiveness of haploid strains in S. cerevisiae only, and conjugation in Y. lipolytica only. These results highlight the conservation of the Pal pathway initially described in A. nidulans.
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