Structure and function of the PHO82-pho4 locus controlling the synthesis of repressible acid phosphatase of Saccharomyces cerevisiae.

pho4 mutants of Saccharomyces cerevisiae, although rare among phosphatase-negative mutants isolated from wild-type strains, were isolated efficiently from pho80, pho85, or pho80 pho85 strains. The distribution of these pho4 mutants over the pho4 locus was determined by analyzing random spores of two- and three-factor crosses. The pho4-4 mutation confers temperature-sensitive synthesis of repressible acid phosphatase. An intragenic suppressor for the pho4-12 allele results in the temperature-sensitive synthesis of repressible acid phosphatase. Recombination between these sites occurs at 1.0 to 3.0%, the highest for any pair of sites within the pho4 locus. All these results strongly indicate that the information of the pho4 locus is translated into a protein. The PHO82 site was mapped inside the pho4 locus by random spore analysis. The order met10-pho4-1PHO82-1-pho4-9 on the right arm of chromosome VI was confirmed by tetrad analysis. Doubly heterozygous diploids, pho3 PHO82c PHO4+/pho3 pho82+ pho4, produce variable amounts of repressible acid phosphatase under repressive conditions depending on the combination of PHO82c and pho4 alleles. This phenomenon may reflect the constitutive production of the pho82+-pho4 product in the repressed condition, which interferes with the function of the PHO82c-PHO4+ product. The earlier model for the function of the PHO82-pho4 cluster, in which the PHO82 site acts as an operator of the pho4 gene, has been revised to a model in which the PHO82 site codes for the part of the pho4 protein that has affinity for the regulatory protein encoded by the pho80 and pho85 genes.     

Regulation of Repressible Acid Phosphatase by Cyclic Amp in SACCHAROMYCES CEREVISIAE

One of the cyr 1 mutants (cyr 1-2) in yeast produced low levels of adenylate cyclase and cyclic AMP at 25 degrees and was unable to derepress acid phosphatase. Addition of cyclic AMP to the cyr1-2 cultures elevated the level of repressible acid phosphatase activity. The bcy1 mutation, which suppresses the cyr1-2 mutation by allowing activity of a cyclic AMP-independent protein kinase, also allows acid phosphatase synthesis without restoring adenylate cyclase activity. The CYR3 mutant had structurally altered cyclic AMP-dependent protein kinase and was unable to derepress acid phosphatase. The cyr1 locus was different from pho2, pho4 and pho81, which were known to regulate acid phosphatase synthesis. Mutants carrying cyr1-2 and pho80, PHO81c, PHO82 or pho85 mutations, which confer constitutive synthesis of repressible acid phosphatase, produced acid phosphatase. The cyr1-2 mutant produced significantly low levels of invertase and alpha-D-glucosidase. These results indicated that cyclic AMP-dependent protein kinase exerts its function in the synthesis of repressible acid phosphatase and other enzymes.     

Identification and characterization of thiamin repressible acid phosphatase in yeast

We have identified a genetic locus, pho4, in Schizosaccharomyces pombe which encodes a minor expressed cell surface acid phosphatase that is repressed by low concentrations (0.5 microM) of thiamin. The enzyme was purified from a strain that overproduces the enzyme. It is an Asn-linked glycoprotein. Removal of the carbohydrates by endoglycosidase H does not abolish enzymatic activity. The molecular mass of deglycosylated and unglycosylated enzyme that accumulates in membranes when cells are grown in the presence of tunicamycin is 56 kDa as determined by sodium dodecyl sulfate-gel electrophoresis. Thiamin regulation, at least in part, operates by reducing the level of pho4-mRNA. Pho4 is not genetically linked to the phosphate repressible acid phosphatase gene pho1. Phosphate and thiamin repressible acid phosphatase differ in their substrate specificity. Their protein moieties are immunologically related. Pho4 and pho1 are the only genes in S. pombe that express cell surface acid phosphatases being enzymatically active with nitrophenyl phosphate as substrate. S. pombe is not unique in having a thiamin repressible acid phosphatase. In Saccharomyces cerevisiae this enzyme is encoded by PHO3.     

A possible role for acid phosphatase with thiamin-binding activity encoded by PHO3 in yeast

Periplasmic soluble thiamin-binding protein in Saccharomyces cerevisiae (Iwashima, A. et al. (1979) Biochim. Biophys. Acta 577, 217-220) was demonstrated to be encoded by PHO3 gene that codes for thiamin repressible acid phosphatase (Schweingruber, M.E. et al. (1986) J. Biol. Chem. 261, 15877-15882) by genetic analysis. The pho3 mutant cells of S. cerevisiae in contrast to the parent cells have markedly reduced activity of the uptake of [14C]thiamin phosphates, suggesting that thiamin repressible acid phosphatase plays a role in the hydrolysis of thiamin phosphates in the periplasmic space prior to the uptake of their thiamin moieties by S. cerevisiae.     

Cloning and characteristics of a positive regulatory gene, THI2 (PHO6), of thiamin biosynthesis in Saccharomyces cerevisiae.

A thi2(pho6) mutant of Saccharomyces cerevisiae, defective in the expression of structural genes for thiamin-repressible acid phosphatase and enzymes involved in thiamin biosynthesis, was found to retain sufficient thiamin transport activity. The transport activity was repressed by thiamin in growth medium. We isolated from a S. cerevisiae genomic library two hybrid plasmids, pTSR1 and pTSR2, containing 10.2- and 12.0-kilobase (kb) DNA fragments, respectively, which complement the thi2(pho6) mutation of S. cerevisiae. This gene was localized on a 6.0-kb ClaI-ClaI fragment in the subclone pTSR3. Complementation of the enzyme activities for thiamin metabolism in the thi2(pho6) mutant transformed by some plasmids with the TH12(PHO6) gene was also examined.     

Regulation of inorganic phosphate transport systems in Saccharomyces cerevisiae.

A kinetic study of Pi transport with 32Pi revealed that Saccharomyces cerevisiae has two systems of Pi transport, one with a low Km value (8.2 microM) for external Pi and the other with a high Km value (770 microM). The low-Km system was derepressed by Pi starvation, and the activity was expressed under the control of a genetic system which regulates the repressible acid and alkaline phosphatases. The function of the PHO2 gene, which is essential for the derepression of repressible acid phosphatase but not for the derepression of repressible alkaline phosphatase, was also indispensable for the derepression of the low-Km system.     

Isolation and Characterization of Pep5, a Gene Essential for Vacuolar Biogenesis in Saccharomyces Cerevisiae

pep5 mutants of Saccharomyces cerevisiae accumulate inactive precursors to the vacuolar hydrolases. The PEP5 gene was isolated from a genomic DNA library by complementation of the pep5-8 mutation. Deletion analysis localized the complementing activity to a 3.3-kb DNA fragment. DNA sequence analysis of the PEP5 gene revealed an open reading frame of 1029 codons with a calculated molecular mass for the encoded protein of 117,403 D. Deletion/disruption of the PEP5 gene did not kill the cells. The resulting strains grow very slowly at 37 degrees. The disruption mutant showed greatly decreased activities of all vacuolar hydrolases examined, including PrA, PrB, CpY, and the repressible alkaline phosphatase. Apparently normal precursors forms of the proteases accumulated in pep5 mutants, as did novel forms of PrB antigen. Antibodies raised to a fusion protein that contained almost half of the PEP5 open reading frame allowed detection by immunoblot of a protein of relative molecular mass 107 kD in extracts prepared from wild-type cells. Cell fractionation showed the PEP5 gene product is enriched in the vacuolar fraction and appears to be a peripheral vacuolar membrane protein.     

Yeast fructose-2,6-bisphosphate 6-phosphatase is encoded by PHO8, the gene for nonspecific repressible alkaline phosphatase.

Yeast fructose-2,6-bisphosphate 6-phosphatase has been purified 7000-fold by heat treatment, poly(ethylene glycol) precipitation, ion-exchange chromatography with Q-Sepharose Fast Flow and Mono Q followed by affinity chromatography with concanavalin-A-Sepharose and gel filtration with Superose 12. The purified dimeric enzyme contains 1.5 mol zinc and 1.3 mol copper/mol subunit. It reacts with fructose 2,6-bisphosphate [Fru(2,6)P2] as well as with p-nitrophenyl phosphate (NpP) showing a pH optimum at pH 6-6.5 with Fru(2,6)P2 [Plankert, U., Purwin, C. & Holzer, H. (1988) FEBS Lett. 239, 69-72] and above pH 9.0 with NpP. The following observations suggest that activity with both substrates depends on the same protein. (a) During 7000-fold purification, the ratio of activity with NpP to that with Fru(2,6)P2 remained constant. (b) The time course of inactivation of enzyme activity in dilute solution at 30 degrees C is similar for both substrates. (c) At increasing temperatures, inactivation of enzyme activity measured with both substrates proceeds at nearly identical rates. (d) Activity with both substrates is found preferentially in the vacuoles. (e) Mutants defective in the nonspecific alkaline phosphatase coded by the PHO8 gene are also defective in Fru(2,6)P2 6-phosphatase activity. (f) A proteinase A mutant, defective in processing and activation of nonspecific alkaline phosphatase coded by the PHO8 gene, also fails to activate Fru(2,6)P2 6-phosphatase.     

One-step gene replacement in yeast by cotransformation

A general method to replace chromosomal DNA sequences of Saccharomyces cerevisiae by any in vitro modified DNA sequence has been developed and was applied to the PHO5 locus on chromosome II. A recipient strain was constructed in which part of the chromosomal PHO5 sequence was substituted by the URA3 gene. Replacement of this pho5-URA3 substitution by pho5 mutant alleles was achieved in one step by cotransformation with a pho5 DNA fragment and the self-replicating plasmid YEp13, which contains the LEU2 gene as a selectable marker. Leu+ transformants were selected, and the replacement events at the PHO5 locus were detected by their Ura- phenotype (1-4% of the Leu+ were Ura-). In a similar way the PHO5 coding sequence was replaced by the sequence coding for human tissue-type plasminogen activator (t-PA).     

The two positively acting regulatory proteins PHO2 and PHO4 physically interact with PHO5 upstream activation regions.

The repressible acid phosphatase gene PHO5 of Saccharomyces cerevisiae requires the two positively acting regulatory proteins PHO2 and PHO4 for expression. pho2 or pho4 mutants are not able to derepress the PHO5 gene under low-Pi conditions. Here we show that both PHO2 and PHO4 bind specifically to the PHO5 promoter in vitro. Gel retardation assays using promoter deletions revealed two regions involved in PHO4 binding. Further characterization by DNase I footprinting showed two protected areas, one located at -347 to -373 (relative to the ATG initiator codon) (UASp1) and the other located at -239 to -262 (UASp2). Exonuclease III footprint experiments revealed stops at -349 and -368 (UASp1) as well as at -245 and -260 (UASp2). Gel retardation assays with the PHO2 protein revealed a binding region that lay between the two PHO4-binding sites. DNase I footprint analysis suggested a PHO2-binding site covering the region between -277 and -296.     

PEP4 Gene Function Is Required for Expression of Several Vacuolar Hydrolases in SACCHAROMYCES CEREVISIAE

The pep4-3 mutation results in a 90–95% reduction in the levels of five vacuolar hydrolases in yeast, including proteinases A and B, carboxypeptidase Y, RNase(s) and the repressible alkaline phosphatase. The mutation is without effect on two secreted glycoproteins, on an enzyme of the vacuolar membrane, and on a proteinase located outside of the vacuole. Mutations at the PEP4 locus exhibit a dosage effect on the levels of some, but not all, of the enzymes whose expression requires the function of the gene.     

Molecular analysis of the PHO81 gene of Saccharomyces cerevisiae.

The PHO81 gene product is a positive regulatory factor required for the synthesis of the phosphate repressible acid phosphatase (encoded by the PHO5 gene) in Saccharomyces cerevisiae. Genetic analysis has suggested that PHO81 may be the signal acceptor molecule; however, the biochemical function of the PHO81 gene product is not known. We have cloned the PHO81 gene and sequenced the promoter. A PHO81-LacZ fusion was shown to be a valid reporter since its expression is regulated by the level of inorganic phosphate and is controlled by the same regulatory factors that regulate PHO5 expression. To elucidate the mechanism by which PHO81 functions, we have isolated and cloned dominant mutations in the PHO81 gene which confer constitutive synthesis of acid phosphatase. We have demonstrated that overexpression of the negative regulatory factor, PHO80, but not the negative regulatory factor PHO85, partially blocks the constitutive acid phosphatase synthesis in a strain containing a dominant constitutive allele of PHO81. This suggests that PHO81 may function by interacting with PHO80 or that these molecules compete for the same target.