A novel alkali-tolerant Yarrowia lipolytica strain for dissecting Na+-coupled phosphate transport systems in yeasts

The newly isolated osmo-, salt- and alkali-tolerant Yarrowia lipolytica yeast strain is remarkable by its capacity to grow at alkaline pH values (pH 9.7), which makes it an excellent model system for studying Na(+)-coupled phosphate transport systems in yeast cells grown at alkaline conditions. In cells Y. lipolytica grown at pH 9.7, phosphate uptake was mediated by several kinetically discrete Na(+)-dependent systems that are specifically activated by Na(+) ions. One of these, a low-affinity transporter, operated at high-phosphate concentrations. The other two, derepressible, high-affinity, high-capacity systems, functioned during phosphate starvation. Both H(+)- and Na(+)-coupled high-affinity phosphate transport systems of Y. lipolytica cells were under the dual control of the prevailing extracellular phosphate concentrations and pH values. The contribution of the Na(+)/P(i)-cotransport systems into the total cellular phosphate uptake activity was progressively increased with increasing pH, reaching its maximum at pH > or = 9.     

Functional expression and characterization of the wild-type mammalian renal cortex sodium/phosphate cotransporter and an 215R mutant in Saccharomyces cerevisiae.

The wild-type and an R215E mutant of the rat renal cortex sodium/phosphate cotransporter type 2 (NaPi-2) were functionally expressed in the yeast Saccharomyces cerevisiae strain MB192, a cell line lacking the high-affinity endogenous H+/P(i) cotransporter. The expression of the mRNA molecules and corresponding proteins was confirmed by Northern and Western blot analysis, respectively. As detected by indirect immunofluorescence and antibody capture assay, both wild-type and mutant NaPi-2 proteins are expressed in the yeast plasma membrane in comparable amounts. In the presence of 5 microM phosphate, Na+ promotes phosphate uptake into yeast cells expressing the wild-type NaPi-2 with a K(0.5) of 5.6 +/- 1.1 mM. The maximum uptake of phosphate (649 +/- 30 pmol/10 min) is approximately 8-fold higher than the uptake obtained with nontransformed cells (76.8 +/- 8 pmol/10 min). Yeast cells expressing the R215E mutant of NaPi-2 accumulate 213 +/- 9 pmol of phosphate/10 min under the same conditions. The K(0.5) for the stimulation of phosphate uptake by Na+ is 4.2 +/- 0.8 mM for the R215E mutant and thus not significantly different from the value obtained with cells expressing the wild-type cotransporter. The reduced level of accumulation of phosphate in yeast cells expressing the R215E mutant is probably due to a reduction of the first-order rate constant k for phosphate uptake: while cells expressing wild-type NaPi-2 accumulate phosphate with a k of 0.06 min(-1), the rate for phosphate uptake into cells expressing the R215E mutant (k) is 0.016 min(-1) and therefore about 4-fold lower. In comparison, the rate for phosphate uptake into nontransformed cells (k) is 0.0075 min(-1). Phosphate uptake into yeast cells that express the wild-type NaPi-2 in the presence of 150 mM NaCl is promoted by extracellular phosphate with a K(0.5) of 45 +/- 4 microM. A phosphate-dependent phosphate accumulation is also observed with cells expressing the R215E mutant, but the K(0.5) is twice as high (86 +/- 5 microM) as that obtained with the wild-type cotransporter. We conclude that the yeast expression system is a useful tool for the investigation of structure-function relationships of the renal sodium/phosphate cotransporter and that (215)R, although not involved in Na+ recognition, is a part of the structure involved in phosphate recognition and considerably influences the rate of phosphate uptake by the NaPi-2 cotransporter.     

Cephamycin C production is regulated by relA and rsh genes in Streptomyces clavuligerus ATCC27064

The effects of growth rate and nutrient uptake rate on the production of cephamycin C were determined in the parental strain, deltarelA mutant, and deltarsh null mutant of S. clavuligerus. Production of cephamycin C was inversely related to mycelium growth and the phosphate feed rate was more critical for the production of cephamycin C. On the contrary, the production of cephamycin C was completely abolished in the deltarelA mutant, but not in deltarsh mutant. The changes in the cephamycin C production by disruption of the relA and rsh genes are presumably associated with the consequent ability of the mutants to accumulate (p)ppGpp under nutrient starvation. Therefore, it is concluded that the stringent response of S. clavuligerus to starvation for nutrients is governed mainly by RelA rather than Rsh and that the response is more apparently regulated by the limitation of phosphate.     

Interaction of phosphate with monovalent cation uptake in yeast.

The uptake of monovalent cations by yeast via the monovalent cation uptake mechanism is inhibited by phosphate. The inhibition of Rb+ uptake shows saturation kinetics and the phosphate concentration at which half-maximal inhibition is observed is equal to the Km of phosphate for the sodium-independent phosphate uptake mechanism. The kinetic coefficients of Rb+ and TI+ uptake are affected by phosphate: the maximal rate of uptake is decreased and the apparent affinity constants for the translocation sites are increased. In the case of Na+ uptake, the inhibition by phosphate may be partly or completely compensated by stimulation of Na+ uptake via a sodium-phosphate cotransport mechanism. Phosphate effects a transient stimulation of the efflux of the lipophilic cation dibenzyldimethylammonium from preloaded yeast cells and a transient inhibition of dibenzyldimethylammonium uptake. Possibly, the inhibition of monovalent cation uptake in yeast can be explained by a transient depolarization of the cell membrane by phosphate.     

Synthesis and degradation of polyphosphate in the fission yeast Schizosaccharomyces pombe: mutations in phosphatase genes do not affect polyphosphate metabolism

The fission yeast Schizosaccharomyces pombe was found to accumulate large amounts of polyphosphate, particularly when grown on arginine as the nitrogen source. Upon transfer to a medium without phosphate, polyphosphate was degraded and served as an endogenous phosphate reserve. When phosphate was added again after a prolonged period of phosphate starvation, fission yeast cells synthesized more polyphosphate than they had contained before starvation, a phenomenon known as over-compensation. Strains carrying mutated structural genes for three different phosphatases, pho1, pho2 or pho3, degraded polyphosphate at the same rate as the wild-type strain during phosphate starvation and showed the same type of over-compensation when phosphate was added again.     

Proline-induced germ-tube formation in Candida albicans: role of proline uptake and nitrogen metabolism

Proline-induced germ-tube formation and cell-cell aggregation in four strains of Candida albicans were completely inhibited when the pH of the medium was 5.0 or lower, whereas morphogenesis induced by N-acetylglucosamine (GlcNAc) was unaffected even at pH 4.5. The pH sensitivity of proline-induced germ-tube formation was not caused by a modulation of proline uptake, which was unchanged over the pH range 4.5-6.5. The proline uptake system was specific, constitutive and subject to ammonium repression, and only one permease was detected, with a Km of 179 microM. Cultures deprived of nitrogen in the presence of glucose were derepressed for proline uptake but the yeast-mycelial transition could not be mediated by either proline or GlcNAc. The inhibition of morphogenesis was reversed when the nitrogen starvation was relieved by the addition of ammonium ions, proline, or certain amino acids. These results indicate that the nitrogen status of the cells is critical for the morphogenesis of C. albicans.     

Vanadate-Resistant Mutants of Neurospora crassa Are Deficient in a High-Affinity Phosphate Transport System

Mutant strains of Neurospora crassa have been selected which grow on media containing vanadate, an inhibitor of the plasma membrane ATPase. The mutations all map to a single region (designated van) on the left arm of linkage group VII. The van mutants are unable to take up vanadate from the medium and are also deficient in the uptake of phosphate via a derepressible, high-affinity phosphate transport system. In the van mutants, the K(m) for phosphate transport is elevated as much as 35-fold, indicating that the van locus may code for a structural component of the high-affinity phosphate transport system.     

Cotransport of phosphate and sodium by yeast.

Phosphate uptake by yeast at pH 7.2 is mediated by two mechanisms, one of which has a Km of 30 micronM and is independent of sodium, and a sodium-dependent mechanism with a Km of 0.6 micronM, both Km values with respect to monovalent phosphate. The sodium-dependent mechanism has two sites with affinity for Na+, with affinity constants of 0.04 and 29 mM. Also lithium enhances phosphate uptake; the affinity constants for lithium are 0.3 and 36 mM. Other alkali ions do not stimulate phosphate uptake at pH 7.2. Ribidium has no effect on the stimulation of phosphate uptake by sodium. Phosphate and arsenate enhance sodium uptake at pH 7.2. The Km of this stimulation with regard to monovalent orthophosphate is about equal to that of the sodium-dependent phosphate uptake. The properties of the cation binding sites of the phosphate uptake mechanism and those of the phosphate-dependent cation transport mechanism have been compared. The existence of a separate sodium-phosphate cotransport system is proposed.     

Sodium-dependent phosphate transport by apical membrane vesicles from a cultured renal epithelial cell line (LLC-PK1)

Apical membrane vesicles were prepared from confluent monolayers of LLC-PK1 cells grown upon microcarrier beads. The final membrane preparation, obtained by a modified divalent cation precipitation technique, was enriched in alkaline phosphatase, leucine aminopeptidase and trehalase (8-fold compared to the initial homogenate). Analysis of phosphate uptake into the vesicles identified a specific sodium-dependent pathway. Lithium and other cations were unable to replace sodium. At 100 mmol/l sodium and pH 7.4, an apparent Km for phosphate of 99 +/- 19 mumol/l and an apparent Ki for arsenate of 1.9 mmol/l were found. Analysis of the sodium activation of phosphate uptake gave an apparent Km for sodium of 32 +/- 12 mmol/l and suggested the involvement of two sodium ions in the transport mechanism. Sodium modified the apparent Km of the transport system for phosphate. The rate of sodium-dependent phosphate uptake was higher at pH 6.4 than at pH 7.4. At both pH values, an inside negative membrane potential (potassium gradient plus valinomycin) had no stimulatory effect on the rate of the sodium-dependent component of phosphate uptake. It is concluded that the apical membrane of LLC-PK1 cells contains a sodium-phosphate cotransport system with a stoichiometry of 2 sodium ions: 1 phosphate anion.     

Phosphate transport in arsenate-resistant mutants of Micrococcus lysodeikticus.

Two types of arsenate-resistant mutants of Micrococcus lysodeikticus were found: (i) mutants that grow in the presence of 10 mM but not 1 mM phosphate (Pi) with low uptake rate for Pi and arsenate, and (ii) mutants able to grow in the presence of 10 mM and 1 mM Pi, with a near-normal uptake rate for Pi but a low one for arsenate. The Km values for Pi transport and the Ki values for its competitive inhibition by arsenate were similar for the mutants and the wild type. Similar to the wild type, the mutants also accumulated Pi to high concentrations. In all strains, the transport of Pi was subject to repression by Pi. Mutant types showed lower Vmax but unaltered Km values for arsenate as compared to the wild type, and they accumulated arsenate to markedly lower levels. The results suggest a two-component transport system common to Pi and arsenate.     

The Mep2p ammonium permease controls nitrogen starvation-induced filamentous growth in Candida albicans

Nitrogen starvation is one of the signals that induce Candida albicans, the major fungal pathogen of humans, to switch from yeast to filamentous growth. In response to nitrogen starvation, C. albicans expresses the MEP1 and MEP2 genes, which encode two ammonium permeases that enable growth when limiting concentrations of ammonium are the only available nitrogen source. In addition to its role as an ammonium transporter, Mep2p, but not Mep1p, also has a central function in the induction of filamentous growth on a solid surface under limiting nitrogen conditions. When ammonium is absent or present at low concentrations, Mep2p activates both the Cph1p-dependent mitogen-activated protein (MAP) kinase pathway and the cAMP-dependent signalling pathway in a Ras1p-dependent fashion via its C-terminal cytoplasmic tail, which is essential for signalling but dispensable for ammonium transport. In contrast, under ammonium-replete conditions that require transporter-mediated uptake Mep2p is engaged in ammonium transport and signalling is blocked such that C. albicans continues to grow in the budding yeast form. Mep2p is a less efficient ammonium transporter than Mep1p and is expressed at much higher levels, a distinguishing feature that is important for its signalling function. At sufficiently high concentrations, ammonium represses filamentous growth even when the signalling pathways are artificially activated. Therefore, C. albicans has established a regulatory circuit in which a preferred nitrogen source, ammonium, also serves as an inhibitor of morphogenesis that is taken up into the cell by the same transporter that mediates the induction of filamentous growth in response to nitrogen starvation.     

Internalization of lucifer yellow in Candida albicans by fluid phase endocytosis

Lucifer yellow (LY), an impermeable fluorescent dye used as a marker for fluid phase endocytosis, was internalized by Candida albicans. As observed by fluorescence microscopy, incubation of C. albicans with LY in potassium phosphate buffer (pH 6.0) and glucose (2%, w/v) resulted in localization of the dye inside vacuoles. Sodium azide and carbonyl cyanide m-chlorophenylhydrazone, which are inhibitors of energy metabolism, decreased the uptake of the dye. The optimum temperature for uptake was 30 degrees C; no internalization was observed at 0 degrees C. Quantification of cell-associated LY by fluorescence spectrometry showed an uptake linear with time and not saturable over a 400-fold range of concentration. Thus, C. albicans internalized LY into vacuoles by a nonsaturable and time-, temperature- and energy-dependent process consistent with fluid phase endocytosis. Both the yeast and mould phase of this dimorphic fungus endocytosed LY. Growth in complex medium appeared to be required to enable the cells to internalize LY. However, addition of peptone or yeast extract to the phosphate buffer/glucose assay medium interfered with LY uptake by causing an apparent increase of exocytosis. These studies provide the first evidence of fluid phase endocytosis in C. albicans and may explain how some large molecules, such as toxins and cationic proteins, enter C. albicans.     

Substrate specificity of peptide permeases in Candida albicans

Abstract Specificity of peptide transport systems in Candida albicans was studied using as an experimental tool novel anticandidal peptides, containing the N³-4-methoxyfumaroyl- l -2,3-diamino-propanoic acid residue. Studies on cross-resistance and on peptide uptake by spontaneous mutants resistant to toxic peptides, confirmed the multiplicity of peptide permeases in Candida albicans . At least two peptide permeases exist in this microorganism; the first one, specific for di- and tripeptides and the second, for oligopeptides containing 3–6 amino acids. The rate of the tritetra tetra-, penta- and hexapeptide transport in the mycelial form of Candida albicans is about 2-times higher than in the yeast form, while that of dipeptides is markedly reduced.
Tripeptides are proposed as the most efficient carriers for the delivery of 'warhead' amino acids into Candida albicans cells.     

白念珠菌CaPPEl的克隆及其在酿酒酵母形态发生中的功能研究

白念珠菌的致病性与其形态转变相关,白念珠菌的形态转换受各种外界信号和细胞内信号转导途径的调控。转录因子Flo8在酿酒酵母形态发生中起重要作用,我们将白念珠菌基因组文库导入flo8缺失株中,筛选能够校正flo8缺失株侵入生长缺陷的基因,分离得到一个与酿酒酵母蛋白磷酸酯酶甲基酯酶PPEl同源的基因,命名为CaPPEl。CaPPEl的基因编码区全长1083bp,推测编码一个361氨基酸的蛋白。在单倍体酿酒酵母中,CaPPEl基因的表达可以部分回复flo8缺失株的侵入生长缺陷,但是在MAPK途径缺失株中不能进行侵入生长。在双倍体酿酒酵母中,CaPPEl基因的表达可以部分激活MAPK途径成员缺失株的菌丝生长缺陷,但却只能在flo8缺失株中产生微弱的激活作用。结果表明CaPpel在酿酒酵母的假菌丝生长和侵入生长中参与的信号转导途径不同。     

白念珠菌CaPPE1的克隆及其在酿酒酵母形态发生中的功能研究

白念珠茵的致病性与其形态转变相关,白念珠茵的形态转换受各种外界信号和细胞内信号转导途径的调控。转录因子Flo8在酿酒酵母形态发生中起重要作用,我们将白念珠茵基因组文库导入flo8缺失株中,筛选能够校正flo8缺失株侵入生长缺陷的基因,分离得到一个与酿酒酵母蛋白磷酸酯酶甲基酯酶PPEI同源的基因,命名为CaPPEl。CaPPEl的基因编码区全长1083bp,推测编码一个361氨基酸的蛋白。在单倍体酿酒酵母中,CaPPE1基因的表达可以部分回复flo8缺失株的侵入生长缺陷,但是在MAPK途径缺失株中不能进行侵入生长。在双倍体酿酒酵母中,CaPPEl基因的表达可以部分激活MAPK途径成员缺失株的茵丝生长缺陷,但却只能在flo8缺失株中产生微弱的激活作用。结果表明CaPpel在酿酒酵母的假茵丝生长和侵入生长中参与的信号转导途径不同。     

A single mutation confers vanadate resistance to the plasma membrane H+-ATPase from the yeast Schizosaccharomyces pombe

A single-gene nuclear mutant has been selected from the yeast Schizosaccharomyces pombe for growth resistance to Dio-9, a plasma membrane H+-ATPase inhibitor. From this mutant, called pma1, an ATPase activity has been purified. It contains a Mr = 100,000 major polypeptide which is phosphorylated by [gamma-32P] ATP. Proton pumping is not impaired since the isolated mutant ATPase is able, in reconstituted proteoliposomes, to quench the fluorescence of the delta pH probe 9-amino-6-chloro-2-methoxy acridine. The isolated mutant ATPase is sensitive to Dio-9 as well as to seven other plasma membrane H+-ATPase inhibitors. The mutant H+-ATPase activity tested in vitro is, however, insensitive to vanadate. Its Km for MgATP is modified and its ATPase specific activity is decreased. The pma1 mutation decreases the rate of extracellular acidification induced by glucose when cells are incubated at pH 4.5 under nongrowing conditions. During growth, the intracellular mutant pH is more acid than the wild type one. The derepression by ammonia starvation of methionine transport is decreased in the mutant. The growth rate of pma1 mutants is reduced in minimal medium compared to rich medium, especially when combined to an auxotrophic mutation. It is concluded that the H+-ATPase activity from yeast plasma membranes controls the intracellular pH as well as the derepression of amino acid, purine, and pyrimidine uptakes. The pma1 mutation modifies several transport properties of the cells including those responsible for the uptake of Dio-9 and other inhibitors (Ulaszewski, S., Coddington, A., and Goffeau, A. (1986) Curr. Genet. 10, 359-364).     

两个小麦磷转运蛋白基因的分离、功能鉴定和表达研究

磷是能量代谢、核酸以及许多生物膜合成的重要底物。在光合作用、呼吸作用等过程中发挥了重要作用。中国大多数小麦产区的土壤存在着缺磷的问题。磷饥饿给小麦生产造成了很大损失。培育耐低磷小麦是解决这一问题的一个重要途径。在磷饥饿的过程中,哪些基因的表达发生了变化．它们是如何变化的,弄清楚这些问题对于培育转基因耐低磷小麦具有重要的意义。磷转运蛋白基因在植物吸收磷的过程中发挥着重要作用。利用RT—PCR的方法,我们从普通小麦“小偃54”中分离了两个磷转运蛋白基因TaPT8和TaPHT2;1。通过与酵母突变体互补分析表明这两个基因都能够与磷吸收功能存在缺陷的酵母突变体实现功能互补,在低磷条件下有促进酵母突变体吸收磷的作用。进一步分析表明TaPT8属于Pht1家族。TaPHT2;1属于Pht2家族。运用RQRT—PCR的方法进行分析后发现TaPT8在根中表达,受磷饥饿的诱导;TaPHT2;1主要在绿色组织中表达,受磷饥饿的抑制,受光的诱导。TaPT8可能主要参与了小麦的根从土壤中吸收磷的过程。TaPHT2;1可能在磷从细胞质向叶绿体内转运的过程中发挥了重要作用。     

Starvation response of Saccharomyces cerevisiae grown in anaerobic nitrogen- or carbon-limited chemostat cultures

Anaerobic starvation conditions are frequent in industrial fermentation and can affect the performance of the cells. In this study, the anaerobic carbon or nitrogen starvation response of Saccharomyces cerevisiae was investigated for cells grown in anaerobic carbon or nitrogen-limited chemostat cultures at a dilution rate of 0.1 h(-1) at pH 3.25 or 5. Lactic or benzoic acid was present in the growth medium at different concentrations, resulting in 16 different growth conditions. At steady state, cells were harvested and then starved for either carbon or nitrogen for 24 h under anaerobic conditions. We measured fermentative capacity, glucose uptake capacity, intracellular ATP content, and reserve carbohydrates and found that the carbon, but not the nitrogen, starvation response was dependent upon the previous growth conditions. All cells subjected to nitrogen starvation retained a large portion of their initial fermentative capacity, independently of previous growth conditions. However, nitrogen-limited cells that were starved for carbon lost almost all their fermentative capacity, while carbon-limited cells managed to preserve a larger portion of their fermentative capacity during carbon starvation. There was a positive correlation between the amount of glycogen before carbon starvation and the fermentative capacity and ATP content of the cells after carbon starvation. Fermentative capacity and glucose uptake capacity were not correlated under any of the conditions tested. Thus, the successful adaptation to sudden carbon starvation requires energy and, under anaerobic conditions, fermentable endogenous resources. In an industrial setting, carbon starvation in anaerobic fermentations should be avoided to maintain a productive yeast population.     

磷胁迫条件下落叶松幼苗对难溶性磷的利用

以ＡｌＰＯ４为Ｐ源在温室内采用砂培的方法,研究了落叶松（Ｌａｒｉｘ ｇｍｅｌｉｎｉ）２年生幼苗对难溶性Ｐ酸盐的利用状况。结果表明,落叶松幼苗可以利用一定数量的ＡｌＰＯ４。在供ＡｌＰＯ４不接种菌根菌时,落叶松幼苗吸收的Ｐ可达正常供Ｐ时的３５．１％和６４．９％。不同菌种对落叶松幼苗利用ＡｌＰＯ４的影响不同。接种点柄乳牛肝菌（Ｓｕｉｌｌｕｓ ｇｒａｎｕｌａｔｕｓ）时,落叶松幼苗对ＡｌＰＯ４的利用量高于不