Changes in the phosphatase activity of Baker's yeast during the growth phase and location of the phosphatases in the yeast cell

A molecular description of acid phosphatase

Acid phosphatase is ubiquitous in distribution in various organisms. Although it catalyzes simple hydrolytic reactions, it is considered as an interesting enzyme in biological systems due to its involvement in different physiological activities. However, earlier reviews on acid phosphatase reveal some fragmentary information and do not give a holistic view on this enzyme. So, the present review summarizes studies on biochemical properties, structure, catalytic mechanism, and applications of acid phosphatase. Recent advancement of acid phosphatase in agricultural and clinical fields is emphasized where it is presented as potent agent for sustainable agricultural practices and diagnostic marker in bone metabolic disorders. Also, its significance in prostate cancer therapies as a therapeutic target has been discussed. At the end, current studies and prospects of immobilized acid phosphatase are included.

Acid phosphatase production by recombinant Arxula adeninivorans

Acid phosphatase production by recombinant Arxula adeninivorans was carried out in submerged fermentation. Using the Plackett-Burman design, three fermentation variables (pH, sucrose concentration, and peptone concentration) were identified to significantly affect acid phosphatase and biomass production, and these were optimized using response surface methodology of central composite design. The highest enzyme yields were attained in the medium with 3.9% sucrose and 1.6% peptone at pH 3.8. Because of optimization, 3.86- and 4.19-fold enhancement in enzyme production was achieved in shake flasks (17,054 U g(-1) DYB) and laboratory fermenter (18,465 U g(-1) DYB), respectively.

A constitutive mutation, phoT, of the repressible acid phosphatase synthesis with inability to transport inorganic phosphate in Saccharomyces cerevisiae

Wild-type cells of Saccharomyces cerevisiae cultivated in low-Pi medium actively accumulate inorganic phosphate (Pi), while the same cells cultivated in high-Pi medium do not. A recessive constitutive mutant (phoT), for repressible acid phosphatase (EC 3.1.3.2) synthesis, is described. It shows severely reduced potency of Pi uptake, while the recessive constitutive mutants, phoR and phoU, in the same system show wild-type potency as.

Characterization of an exocellular protein phosphatase with dual substrate specificity from the yeast Yarrowia lipolytica

In previous work, the major endocellular protein phosphatase activity has been identified in the secretory yeast Yarrowia lipolytica as a PP2A. The aim of the present work was to seek the presence of one protein phosphatase excreted in the exocellular medium and to study its activity during yeast growth in media supplemented or not supplemented with inorganic phosphate. Protein phosphatase was purified and activity was assayed by following the dephosphorylation of three substrates, [32P]casein, phosphotyrosine and a synthetic tyrosine-phosphorylated peptide. Phosphatase activity recovered in the medium after 25 h culture was greatly enhanced by Pi-deficiency. After several purification steps, the enzyme preparation presents an apparent electrophoretic homogeneity on SDS-PAGE with associated phosphoseryl/threonyl and phosphotyrosyl activities. The kinetic properties exclude contamination by a copurified protein and it is concluded that the two activities are carried by the same single proteic species. It was characterized by gel filtration as a 33 kDa protein with one single subunit demonstrated by SDS-PAGE. An absolute requirement for reducing-agents is observed suggesting that the enzyme contains at least one essential reactive cysteinyl residue. Optimum pH value is 6.1, apparent K(m) for phosphotyrosine was calculated to be 760 microM and Hill coefficient 3.2 indicating a rather high cooperativity. These results showed that the involvement of alkaline and/or acid phosphatase was unlikely. In conclusion, a protein phosphatase distinct from endocellular PP2A is secreted by Yarrowia lipolytica and characterized as a phosphotyrosine protein phosphatase with associated phosphoseryl/threonyl activity.

EVIDENCE FOR AN EXOCELLULAR SITE FOR THE ACID PHOSPHATASE OF SACCHAROMYCES MELLIS

Weimberg, Ralph (Northern Regional Research Laboratory, Peoria, Ill.), and William L. Orton. Evidence for an exocellular site for the acid phosphatase of Saccharomyces mellis. J. Bacteriol. 88:1743-1754. 1964.-Evidence is presented which demonstrates an exocellular location for acid phosphatase in Saccharomyces mellis. Derepressed intact cells exhibit acid phosphatase activity. The properties of the system are similar to those shown by the enzyme in cell-free extracts. There is no increase in total activity when cell-free extracts are prepared. Enzymatically active cell walls were prepared by leaching acetone-dried cells of this yeast in dilute acetate buffer (pH 6.5) plus beta-mercaptoethanol. The insoluble residue, consisting mainly of cell-wall material and containing the phosphatase, was treated with a variety of hydrolytic enzymes and other chemicals. Only papain and crude snail gut extracts dissociated the enzyme from the particulate fraction in nearly quantitative amounts. The mechanism of release by these two enzymes probably differs. Of all enzymes tested, only the snail gut extract digested the cell walls. By dividing the procedure for making protoplasts of S. mellis into two steps, acid phosphatase may be dissociated from resting cells and recovered as an active soluble enzyme. The first step is to pretreat the cells with a thiol reagent. The second step is to digest the cell wall by enzymes present in crude snail gut extracts. Arsenite must be included in the second step to protect the phosphatase from inactivation. The phosphatase is quantitatively released before the cell becomes osmotically fragile.

SYNTHESIS AND BREAKDOWN OF THE POLYPHOSPHATE FRACTION AND ACID PHOSPHOMONOESTERASE OF SACCHAROMYCES MELLIS AND THEIR LOCATIONS IN THE CELL

Weimberg, Ralph (Northern Regional Research Laboratory, Peoria, Ill.), and William L. Orton. Synthesis and breakdown of the polyphosphate fraction and acid phosphomonoesterase of Saccharomyces mellis and their locations in the cell. J. Bacteriol. 89:740-747. 1965.-The conditions for accumulation of polyphosphate in cells of Saccharomyces mellis differ in several respects from those for acid phosphomonoesterase biosynthesis and maintenance. Polyphosphate can be synthesized or degraded in vivo by resting cells, provided an energy source is present. Experiments with growing cells indicate that the enzyme systems involved in the metabolism of the polyphosphate fraction are constitutive, since cells respond immediately to changes in the level of inorganic phosphate in the external medium. There is no change in the acid phosphatase level in either resting cells or in cells in the lag phase of growth. Enzyme formation or breakdown occurs only in cells that are exponentially dividing. Enzyme is lost rapidly from derepressed cells when they are transferred to a phosphate-rich medium, falling to a very low value by the time the cell mass had doubled. Protoplasts of repressed cells were prepared to determine the location of ortho- and polyphosphates in the cell. Previous studies have shown that phosphomonoesterase is released as a soluble enzyme when derepressed cells become protoplasts. Unlike phosphomonoesterase in derepressed cells, the two phosphate fractions in repressed cells are still attached to the protoplast after the cell wall has been digested and are eluted only when the protoplast structure is lysed in cold water. However, it is also possible to extract a part of the two phosphate fractions from intact cells in the absence of snail gut extract by osmotic shock if the cells are first suspended in a solution of high salt concentration. This treatment with salt does not affect viability. These results do not permit a definite conclusion concerning the location of ortho- and polyphosphates in the cell, other than that they are associated with the protoplast and thus occupy a position different from that of the phosphomonoesterase.

CYTOCHEMICAL LOCALIZATION OF ACID PHOSPHATASES IN EUGLENA GRACILIS

The localization of induced and constitutive acid phosphatase activity in Euglena was studied by light and electron microscopy, using two different cytochemical methods. Cells grown in high phosphate medium have constitutive acid phosphatase activity in three regions: in the Golgi complex, around the paramylum bodies, and in the peri-reservoir vesicles. Cells that have formed an induced acid phosphatase by exposure to a phosphate-deficient medium have, in addition to the constitutive activity localized exactly as in the uninduced cell, a strong activity in the pellicle. The induced activity is not uniformly distributed over the pellicle, but is localized at the notch of each pellicle complex, near a group of about four fibrils and near a characteristic vesicle of the endoplasmic reticulum. In the cytostome, where fission begins during division, there is an alternation of large and small pellicle complexes, both of which have induced phosphatase activity. A similar alternation is seen over the entire pellicle of dividing cells.

An inducible acid phosphatase from the yeast Pichia pastoris: characterization of the gene and its product

To develop the budding yeast Pichia pastoris (Pp) as a model system for the study of protein secretion, we have characterized a secreted acid phosphatase (Pho1p) from this yeast. Pho1p can be induced 100-fold by starvation for phosphate. The enzyme was purified to homogeneity from a cell-wall extract by DEAE-Sepharose chromatography. We selected mutants that lacked extracellular phosphatase activity and the gene (PHO1) encoding Pho1p was isolated from a recombinant plasmid library of Pp DNA by complementation of the mutant defect. PHO1 encodes a protein of 468 amino acids (aa) with homology to repressible acid phosphatases from other yeast species. The sequence contains a 15-aa N-terminal signal sequence and six potential N-linked glycosylation sites. Antiserum to Pho1p was used to show that Pho1p transits the Pp secretory pathway in less than 5 min.

Cloning and sequencing of the PHO80 gene and CEN15 of Saccharomyces cerevisiae

The PHO80 gene, which is one of the regulatory genes exerting negative control in the pho system of Saccharomyces cerevisiae, was cloned. The 1.8 kb DNA fragment carrying the PHO80 gene was sequenced and one open reading frame large enough to encode 293 amino acids was found in the sequence. Northern blot analysis of poly(A)+-RNA isolated from cells grown under repressed and derepressed conditions revealed that (i) the size of the PHO80 message was around 1.4 kb, (ii) the expression of the PHO80 gene was not affected by the presence or absence of inorganic phosphate in the medium, and (iii) the expression of the PHO80 gene was not affected by pho2, pho4, pho81, or by pho80 itself. A centromere sequence was found downstream of the PHO80 coding region.

Asparagine-linked carbohydrate does not determine the cellular location of yeast vacuolar nonspecific alkaline phosphatase

The nonspecific alkaline phosphatase of Saccharomyces sp. strain 1710 has been shown by phosphatase cytochemistry to be exclusively located in the vacuole, para-Nitrophenyl phosphate-specific alkaline phosphatase is not detected by this procedure because the activity of this enzyme is sensitive to the fixative agent, glutaraldehyde. To determine whether the oligosaccharide of nonspecific alkaline phosphatase is necessary to transport the enzyme into the vacuole, protoplasts were derepressed in the absence or in the presence of tunicamycin, an antibiotic which interferes with the glycosylation of asparagine residues in proteins. The location of the enzyme in the tunicamycin-treated protoplasts, as determined by electron microscopy and subcellular fractionation, was identical to its location in control protoplasts. In addition, carbohydrate-free alkaline phosphatase was found in vacuoles from tunicamycin-treated protoplasts. Our findings indicate that the asparagine-linked carbohydrate moiety does not determine the cellular location of the enzyme.

Enzyme activities during early ascosporulation in Saccharomyces cerevisiae

1. Several enzyme activities were examined during the initial sporulating phase in Saccharomyces cerevisiae. 2. Catalase activity increased obviously after transfer to sporulation medium. 3. Catalase is probably considered to play an essential role in sporulation. 4. Both activities of inorganic pyrophosphatase and glycerol-2-phosphatase decreased. 5. Conditions necessary for sporulation were suggested.

A particulate form of alkaline phosphatase in the yeast, Saccharomyces cerevisiae

A new form of alkaline phosphatase (orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1) has been identified in the yeast Saccharomyces cerevisiae. Utilizing either synthetic or natural substrates, the enzyme exhibited a broad pH activity curve with maximum activity between 8.5 and 9.0. The enzyme was nonspecific with respect to substrate, attacking a variety of compounds containing phosphomonoester linkages, but has no detectable activity against polyphosphate, pyrophosphate or phosphodiester linkages. The enzyme exhibited an apparent Km of 0.25 mM with respect to p-nitrophenyl phosphate, 0.38 mM with respect to alpha-naphthyl phosphate, and 1.0 mM with respect to 5'AMP. The enzyme is regulated in a constitutive manner and its activity does not increase during phosphate starvation or sporulation, as does the repressible alkaline phosphatase. The enzyme is tightly bound to a particulate fraction of the cell, tentatively identified as the tonoplast membrane. It is not solubilized by treatment with high concentrations of NaCl, KH2PO4 or chaotropic agents. Triton X-100 (0.1%) solubilizes 12% of the particulate activity. This enzyme is differentiated from the other alkaline phosphatases found in yeast by its chromatographic elution DEAE-cellulose, kinetic parameters, heat stability and pH stability, as well as its particulate nature. This particulate alkaline phosphatase was found in every strain examined. It has a significantly lower specific activity in the phoH mutant and a higher activity in the acid phosphatase constitutive mutant A137.

Induction and genetics of two alpha-galactosidase activities in Saccharomyces cerevisiae

The induction of alpha-galactosidase of Saccharomyces cerevisiae was investigated. We have demonstrated the existence of inducible internal and external alpha-galactosidase activities and have studied the relationship between the two alpha-galactosidases by examining a mutant strain which lacks both the internal and external activities. The mutant possesses a mutation in a single locus (mel1-1) which does not affect the synthesis of the other galactose pathway enzymes or the ability of the yeast to grow on media containing only galactose as the carbon source. Genetic studies of the mutant indicate that mel 1-1 is recessive and allelic to the wild tye allele for melibiose fermentation Mel 1.

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.

A possible rôle for acid phosphatase in gamma-amino-n-butyrate uptake in Aspergillus nidulans

Previously published work from another laboratory has shown that the mutation pacC-5 in the ascomycete Aspergillus nidulans leads to loss of an acid phosphatase (EC 3.1.3.2) activity and is probably located in the structural gene for this enzyme. Here, we show that, pleiotropically, pacC-5 considerably reduces gamma-amino-n-butyrate transport levels as shown both by direct uptake measurements and two kinds of growth tests. A reduction in expression of the permease specified by the gabA gene is almost certainly responsible for the gamma-amino-n-butyrate uptake defect in pacC-5 strains. pacC-5 does not reduce L-proline uptake, mainly mediated by the prnB permease, or beta-alanine uptake. This work and our previously published results suggest that, although it does not uniquely reduce gamma-amino-n-butyrate uptake, pacC-5 is highly selective in its effects on transport processes. It is therefore probable that the acid phosphatase specified by the pacC gene plays some rôle in the synthesis, membrane integration or functioning of a particular class of permeases. A rôle for acid phosphatases in membrane processes casts an intriguing new light on the fact that these enzymes are periplasmic and extracellular in many micro-organisms including A. nidulans.

Regulation of acid phosphatase synthesis in Saccharomyces cerevisiae

In Saccharomyces cerevisiae-136ts (Hutchison, H.T., Hartwell, L.H. and McLaughlin, C.S. (1969) J. Bacteriol. 99, 807--814) derepressed acid phosphatase was almost exclusively located outside the permeability barrier. Only a minor part of the activity was associated with the protoplasts; about half of it (48%) in the soluble fraction, the rest bound to the internal (45%) and plasma (7%) membranes. The activity found in the membranes of derepressed cells decreased by 30--40% after addition of inorganic phosphate or cycloheximide suggesting that this activity is the precursor of the external enzyme. The alkaline phosphatase activity level could not be modified by changes in the concentration of inorganic phosphate. Acid phosphatase was not synthesized if the cells were transferred to a low phosphate medium at the moment of incubation at 37 degrees C or in the presence of cycloheximide at 23 degrees C. The data suggested that enzyme formation is the result of the transcription and translation of a specific gene(s) and not the activation of a proenzyme. Inorganic phosphate did not inhibit the translation of mRNA though it may act at the level of the transcription.

Relationship between extracellular enzymes and cell growth during the cell cycle of the fission yeast Schizosaccharomyces pombe: acid phosphatase

By using the intact cells of the fission yeast Schizosaccharomyces pombe, the activity of acid phosphatase (EC 3.1.3.2) was compared through the cell cycle with the growth in cell length as a measure of cell growth. The cells of a growing asynchronous culture increased exponentially in number and in total enzyme activity, but remained constant in average length and in specific activity, In a synchronous culture prepared by selection or by induction, the specific activity was periodic in parallel with the increase in average cell length. When hydroxyurea was added to an asynchronous or a synchronous culture by selection, both specific and total activity followed the same continuous pattern as the growth in cell length after the stoppage of cell division. When oversized cells produced by a hydroxyurea pulse treatment to the culture previously syndronized by selection were transferred to a poor medium, they divided synchronously but could hardly grow in the total cell length. In this experimental situation, the total enzyme activity also scarcely increased through three division cycles. These results suggested that the increase in acid phosphatase in dependent on cell elongation.

Disturbance of the machinery for the gene expression by acidic pH in the repressible acid phosphatase system of Saccharomyces cerevisiae

When the pH of growth medium containing a limited amount of inorganic phosphate is kept below 3.0, cells of Saccharomyces cerevisiae produce repressible alkaline phosphatase but no repressible acid phosphatase. The same cells produce acid phosphatase immediately on shifting the medium pH to 4.0 or above. Like intact cells, spheroplasts prepared from cells grown at pH 3.0 or 4.5 in medium with a limited amount of inorganic phosphate in suspension begin production of acid phosphatase immediately after pH shift from below 3.0 to 4.0 whereas sheroplasts from cells grown in inorganic phosphate-rich medium showed a prolonged lag period (3 h). The enzyme formation on the pH shift was sensitive to cycloheximide. No significant differences could be detected in cellular growth or in incorporation of 3H-L-lysine or 14C-adenine between cells cultivated at pH 3.0 and 4.5. These results along with the fact that the expression of structural genes of repressible acid and alkaline phosphatases is controlled by a common genetic regulatory system, at least in part, indicate that the genetic regulatory system operates to express the structural genes even at low pH, though the expression of repressible acid phosphatase is interrupted. Coupled experiments of temperature and pH shifts with the temperature-sensitive mutants of the regulatory genes suggest that the acidic pH affects the function of the cytoplasmic products of those genes in the expression of the structural gene. Based on these observations, a revised model involving the simultaneous functioning of the regulatory factors was suggested for the genetic regulation of repressible acid phosphatase synthesis.

Alkaline phosphatase of Blastocladiella emersonii: partial purification and characterization

Alkaline phosphomonoesterase (EC 3.1.3.1) activity from Blastocladiella emersonii, while displaying typically broad substrate specificity for phosphorylated organic compounds, exhibited nearly complete substrate preference for N-acetylglucosamine-6-phosphate over N-acetylglucosamine-1-phosphate. Enzyme in zoospore extracts was purified 43-fold by differential centrifugation followed by gel filtration (Sephadex G-200) and then by ion-exchange chromatography (diethylaminoethyl-cellulose). The partially purified enzyme displayed an apparent molecular weight (Sephadex G-200) of approximately 170,000. The activity of partially purified enzyme exhibited a pH optimum of pH 8.5, did not require a metal divalent cation, but was inhibitable by ethylenediaminetetraacetic acid. During the life cycle of the organism, the specific activity of the phosphatase decreased slightly during germination and early exponential growth but then increased about 4.5-fold during sporulation. B. emersonii alkaline phosphatase does not appear to be a repressible enzyme.

Genes coding for the structure of the acid phosphatases in Saccharomyces cerevisiae

The phoE locus, one of the loci in which mutations lack the activity for repressible acid phosphatase, was found to be the structural gene for the enzyme by examining the enzymic characteristics of repressible acid phosphatase activity using cell extracts prepared from the leaky phoE mutants, the PHOE revertants and the PHOE recombinants between the different phoE mutants. Other evidence which strongly suggests that the phoC locus is coding for the constitutive acid phosphatase was obtained by a similar investigation. Although the phoC and phoE loci are tightly linked, they were separable by meiotic recombination.

Simple and sensitive procedure for screening yeast mutants that lyse at nonpermissive temperatures

After mutagenesis, surviving yeast cells are grown on plates at 25 C and later exposed to 37 C. The plates are then overlaid with a soft agar containing p-nitrophenylphosphate at pH 9.7. Lysed cells liberate alkaline phosphatase which gives rise to a yellow color on and around colonies.

Isolation and characterization of recessive, constitutive mutations for repressible acid phosphatase synthesis in Saccharomyces cerevisiae

Two new classes of mutants containing recessive constitutive mutations, phoT and phoU, that affect the repressible acid phosphatase (EC 3.1.3.2) in Saccharomyces cerevisiae were isolated along with many previously known phoR mutants. These loci segregated independently from each other, from the phoS gene, and from another regulatory gene, phoD, that exerts positive control for acid phosphatase synthesis. The phoR and phoU mutations showed the same genetic behavior in the double mutants, which also contained the phoS or phoD mutation. In contrast, the phoT mutation could not suppress the phoS mutation, which caused a loss of enzyme activity. Many mutant alleles of phoR and phoU were found to be temperature sensitive (ts), whereas those of phoT were not. These ts mutants were constitutive at 35 C but severely repressible at 25 C. These facts strongly suggest that both the phoR and phoU genes are cooperatively concerned with the production of the repressor, whereas the phoT gene might be involved in another mechanism distinct from that in which phoR and phoU are involved. No single mutation of phoR, phoT, or phoU result in an enzyme level comparable to that of fully derepressed enzyme activities, and the temperature sensitivity of the ts phoR and ts phoU mutations in such combinations almost disappeared. In addition to these observations, since the ts phoR phoS and ts phoU phoS double mutants showed some enzyme synthesis at 25 C under derepressing conditions, a defect in the ts mutant repressors was strongly suggested, even at 25 C.

Acid phosphatase and adenosine triphosphatase activities in the cell wall of baker's yeast

In order to establish whether a specific adenosine triphosphatase is present in yeast cell wall, hydrolysis rates for p-nitrophenylphosphate (acid phosphatase activity) and for ATP (ATPase activity) were compared under various conditions. Rate determinations were made with both, intact cells and with preparations containing secreted enzymes from protoplasts. Acid phosphatase and ATPase activities had the same pH profile and were susceptible in the same way to the repression by orthophosphate and to the inhibition by 2-deoxyglucose. The Lineweaver-Burk plot shows biphasic kinetic behaviour for the hydrolysis of either p-nitrophenylphosphate or ATP. This suggests the existence of two enzymes with different affinities for the substrates, or one enzyme with at least two active sites. The two activities differ in thermostability and only one activity could be completely abolished by heat treatment. The thermostable enzyme activity had K-m values of 0.475 mM for p-nitrophenylphosphate, and 0.040 mM for ATP. ATP behaved as a partially competitive inhibitor of p-nitrophenylphosphate hydrolysis. Substrate competition studies showed that only a non-specific acid phosphatase is responsible for the hydrolysis of ATP.

Biosynthesis of acid phosphatase of baker's yeast. Characterization of a protoplast-bound fraction containing precursors of the exo-enzyme

1. Yeast protoplasts, secreting acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum) EC 3.1.3.2) contain a small amount of firmly bound enzyme, even after lysis (Van Rijn, H.J.M., Boer, P. and Steyn-Parvé, E.P. (1972) Biochim. Biophys. Acta 268, 431-441). The major part (70%) of this protoplast-bound acid phosphatase can be solubilized by nonionic detergents, such as Triton X-100. 2. The kinetics of radioactive amino acid incorporation in the solubilized and in the secreted enzyme has been estimated by pulse-chase labelling of secreting protoplasts, followed by fractionation and counting radioactivity in the enzyme band in polyacrylamide gels after electrophoresis at pH 5.0. A precursor-product relationship between the Triton X-100-extractable fraction of the protoplast-bound acid phosphatase and the secreted enzyme is apparent. 3. The solubilized acid phosphatase is essentially indistinguishable from the secreted enzyme with regard to a number of enzymatic properties and its stability towards pH and temperature. Both enzymes also behave alike on polyacrylamide-gel electrophoresis, producing a single acid phosphatase band with glycoprotein character and comparable mobility. 4. A striking difference is seen in isopycnic equilibrium sedimentation in CsCl: the secreted acid phosphatase is homogeneous, with a buoyant density of p equals 1.47 g/cm3, while the Triton X-100-extractable part of the protoplast-bound acid phosphatase is heterogeneous; besides heavier material a major component with buoyant density of p equals 1.37 g/cm3 is always visible.

Characterization of a dominant, constitutive mutation, PHOO, for the repressible acid phosphatase synthesis in Saccharomyces cerevisiae

An apparent operator-constitutive mutation was discovered in the repressible acid phosphatase system in Saccharomyces cerevisiae. The site of mutation, designated PHOO, was found to be closely linked to the phoD locus. The mutant allele, PHOO, was semidominant over the wild-type allele and effective for the expression of the phoD gene in cis position. The phoD mutation gave rise to a defective phenotype for the formation of the repressible acid phosphatase. On the other hand, neither the repressible acid phosphatase activity in the cell-free extracts prepared from cells of the temperature-sensitive phoD mutant grown at 25 C, nor that of the revertants from the phoD mutants, could be distinguished from that of the wild-type strain with respect to thermolability and K(m) value for p-nitrophenylphosphate. These results strongly suggest that the phoD gene is not a structural gene, but a regulatory gene exerting positive control for the formation of repressible acid phosphatase. Close similarity between the apparent role of the phoO-PHOD gene cluster and that of the c-GAL4 gene cluster in the galactose system of S. cerevisiae could be inferred.

Lipid catabolism of relapsing fever borreliae

Relapsing fever borreliae require lipid compounds for growth in vitro. In this study, the major pathways of lipid catabolism in three species of tick-borne relapsing fever borreliae were investigated. Thin-layer chromatography was used to compare chloroform-methanol extracts of fresh culture media with extracts of exhausted culture media after organisms were removed by centrifugation. The chromatographic data demonstrated that lysolecithin was removed from the culture media during growth of the spirochetes, whereas lecithin, sphingomyelin, triglycerides, and cholesterol esters were not affected by growth of the organisms. Sonic extracts of the organism were tested for the presence of specific enzymes of lipid catabolism. Lysolecithinase, glycerophosphorylcholine diesterase, and acid phosphatase activities were demonstrated. Thus, these organisms can sequentially dissimilate lysolecithin to fatty acids, choline, inorganic phosphate, and glycerol. Assays for phospholipases A, C, and D, alpha-glycerophosphate dehydrogenase, alkaline phosphatase, and lipase were negative.

Purification and properties of a glycoprotein acid phosphatase from Candida albicans

An acid phosphomonoesterase was purified 87-fold with a 4% recovery from disintegrated cells of Candida albicans by four stages of column chromatography. The purified enzyme was homogeneous by ultracentrifugal, electrophoretic, and immunological analyses. The fully corrected sedimentation coefficient, s(20,w), was calculated to be 5.51s. Molecular weight estimated from ultracentrifugal data was 124.3 x 10(3), from gel chromatography was 115 x 10(3), and from acrylamide gel electrophoretic data was 131 x 10(3). Buoyant density in sucrose was 1.15 g/cm(3). The enzyme was a mannoprotein with a hexose to protein ratio of 7: 1. The Michaelis constant of the enzyme was 3.3 x 10(-4) M for p-nitrophenyl phosphate as substrate, and the pH optimum was 4.5. The enzyme was competitively inhibited by inorganic phosphate (K(i) = 10(-4) M) and by arsenate (K(i) = 0.5 x 10(-4) M). A wide range of inorganic cations and anions did not affect enzyme activity, but Hg(2+), Cd(2+), and Cu(2+) were inhibitory. F(-) was also inhibitory at low concentrations, but the effect was reversed at higher concentrations. Phosphatase activity was completely destroyed by exposure of the enzyme to 70 C for 12 min, but was destroyed only slowly by proteolytic hydrolysis. The purified glycoprotein enzyme gave a line of identity with the "b" antigen of crude C. albicans homogenates in immunodiffusion and immunoelectrophoresis tests with sera from rabbits inoculated with intact C. albicans cells and from humans with proven candidiasis. Preliminary evidence suggests that the mannan and not the protein portion of the enzyme molecule is responsible for this antigenicity.

Isolation and characterization of acid phosphatase mutants in Saccharomyces cerevisiae

Saccharomyces cerevisiae strain H-42 seems to have two kinds of acid phosphatase: one which is constitutive and one which is repressible by inorganic phosphate. The constitutive enzyme was significantly unstable to heat inactivation, and its K(m) of 9.1 x 10(-4)m for p-nitrophenylphosphate was higher than that of the repressible enzyme (2.4 x 10(-4)m). The constitutive and the repressible acid phosphatases are specified by the phoC gene and by the phoB, phoD, or phoE gene, respectively. Results of tetrad analysis suggested that the phoC and phoE genes are linked to the lys2 locus on chromosome II. Since both repressible acid and alkaline phosphatases were affected simultaneously in the phoR, phoD, and phoS mutants, it was concluded that these enzymes were under the same regulatory mechanism or that they shared a common polypeptide. The phoR mutant produced acid phosphatase constitutively, and the phoR mutant allele was recessive to its wild-type counterpart. The phoS mutant showed a phenotype similar to that of a mutant defective in one of the phoB, phoD, or phoE genes. However, the results of genetic analysis of the phoS mutant clearly indicated that the phoS gene is not a structural gene for either of the repressible acid and alkaline phosphatases, but is a kind of regulatory gene. According to the proposed model, the phoS gene controls the expression of the phoR gene, and inorganic phosphate would act primarily as an inducer for the formation of the phoR product which represses phosphatase synthesis.