Divalent Cation Block of Inward Currents and Low-Affinity K+ Uptake in Saccharomyces cerevisiae

We have used the patch clamp technique to characterize whole-cell currents in spheroplasts isolated from a trk1Δ trk2Δ strain of Saccharomyces cerevisiae which lacks high- and moderate-affinity K⁺ uptake capacity. In solutions in which extracellular divalent cation concentrations were 0.1 mM, cells exhibited a large inward current. This current was not the result of increasing leak between the glass pipette and membrane, as there was no effect on the outward current. The inward current comprised both instantaneous and time-dependent components. The magnitude of the inward current increased with increasing extracellular K⁺ and negative membrane potential but was insensitive to extracellular anions. Replacing extracellular K⁺ with Rb⁺, Cs⁺, or Na⁺ only slightly modulated the magnitude of the inward current, whereas replacement with Li⁺ reduced the inward current by approximately 50%, and tetraethylammonium (TEA⁺) and choline were relatively impermeant. The inward current was blocked by extracellular Ca²⁺ and Mg²⁺ with apparent K_is (at −140 mV) of 363 ± 78 and 96 ± 14 μM, respectively. Furthermore, decreasing cytosolic K⁺ increased the magnitude of the inward current independently of the electrochemical driving force for K⁺ influx, consistent with regulation of the inward current by cytosolic K⁺. Uptake of ⁸⁶Rb⁺ by intact trk1Δ trk2Δ cells was inhibited by extracellular Ca²⁺ with a K_i within the range observed for the inward current. Furthermore, increasing extracellular Ca²⁺ from 0.1 to 20 mM significantly inhibited the growth of these cells. These results are consistent with those of the patch clamp experiments in suggesting that low-affinity uptake of alkali cations in yeast is mediated by a transport system sensitive to divalent cations.     

TOK homologue in Neurospora crassa: first cloning and functional characterization of an ion channel in a filamentous fungus

In contrast to animal and plant cells, very little is known of ion channel function in fungal physiology. The life cycle of most fungi depends on the “filamentous” polarized growth of hyphal cells; however, no ion channels have been cloned from filamentous fungi and comparatively few preliminary recordings of ion channel activity have been made. In an attempt to gain an insight into the role of ion channels in fungal hyphal physiology, a homolog of the yeast K⁺ channel (ScTOK1) was cloned from the filamentous fungus, Neurospora crassa. The patch clamp technique was used to investigate the biophysical properties of the N. crassa K⁺ channel (NcTOKA) after heterologous expression of NcTOKA in yeast. NcTOKA mediated mainly time-dependent outward whole-cell currents, and the reversal potential of these currents indicated that it conducted K⁺ efflux. NcTOKA channel gating was sensitive to extracellular K⁺ such that channel activation was dependent on the reversal potential for K⁺. However, expression of NcTOKA was able to overcome the K⁺ auxotrophy of a yeast mutant missing the K⁺ uptake transporters TRK1 and TRK2, suggesting that NcTOKA also mediated K⁺ influx. Consistent with this, close inspection of NcTOKA-mediated currents revealed small inward K⁺ currents at potentials negative of E_K. NcTOKA single-channel activity was characterized by rapid flickering between the open and closed states with a unitary conductance of 16 pS. NcTOKA was effectively blocked by extracellular Ca²⁺, verapamil, quinine, and TEA⁺ but was insensitive to Cs⁺, 4-aminopyridine, and glibenclamide. The physiological significance of NcTOKA is discussed in the context of its biophysical properties.     

Trk2 transporter is a relevant player in K<Superscript>+</Superscript> supply and plasma-membrane potential control in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

In Saccharomyces cerevisiae, TRK1 and TRK2 genes encode partially redundant K⁺ transporters. Direct involvement in K⁺ uptake has been shown for Trk1p since cells growing under limiting environmental K⁺ concentrations demand its presence. The biological role of Trk2p is less understood. In our experiments, TRK2 overexpression improved the ability of trk1 cells to grow in low K⁺ and led to a higher accumulation of K⁺. Using diS-C₃(3) as a potentiometric probe, we revealed a higher hyperpolarization of trk2 cells compared to the wild type. In addition, the deletion of TRK2 in the trk1 genetic background increased the cell sensitivity to hygromycin B, spermine, and TMA. Our studies reinforced the conclusion that Trk1p is the prominent K⁺ uptake transporter and for the first time revealed that though Trk2p is much less effective, its activity contributes significantly to K⁺ supply and the maintenance of plasma-membrane potential.     

Agp2, a Member of the Yeast Amino Acid Permease Family,Positively Regulates Polyamine Transport at the Transcriptional Level

Agp2 is a plasma membrane protein of the Saccharomyces cerevisiae amino acid transporter family, involved in high-affinity uptake of various substrates including L-carnitine and polyamines. The discovery of two high affinity polyamine permeases, Dur3 and Sam3, prompted us to investigate whether Agp2 directly transports polyamines or acts instead as a regulator. Herein, we show that neither dur3Δ nor sam3Δ single mutant is defective in polyamine transport, while the dur3Δ sam3Δ double mutant exhibits a sharp decrease in polyamine uptake and an increased resistance to polyamine toxicity similar to the agp2Δ mutant. Studies of Agp2 localization indicate that in the double mutant dur3Δ sam3Δ, Agp2-GFP remains plasma membrane-localized, even though transport of polyamines is strongly reduced. We further demonstrate that Agp2 controls the expression of several transporter genes including DUR3 and SAM3, the carnitine transporter HNM1 and several hexose, nucleoside and vitamin permease genes, in addition to SKY1 encoding a SR kinase that positively regulates low-affinity polyamine uptake. Furthermore, gene expression analysis clearly suggests that Agp2 is a strong positive regulator of additional biological processes. Collectively, our data suggest that Agp2 might respond to environmental cues and thus regulate the expression of several genes including those involved in polyamine transport.     

In Vitro Analysis of the H-Hexose Symporter on the Plasma Membrane of Sugarbeets (Beta vulgaris L.)

The mechanism of hexose transport into plasma membrane vesicles isolated from mature sugarbeet leaves (Beta vulgaris L.) was investigated. The initial rate of glucose uptake into the vesicles was stimulated approximately fivefold by imposing a transmembrane pH gradient (ΔpH), alkaline inside, and approximately fourfold by a negative membrane potential (ΔΨ), generated as a K⁺-diffusion potential, negative inside. The -fold stimulation was directly related to the relative ΔpH or ΔΨ gradient imposed, which were determined by the uptake of acetate or tetraphenylphosphonium, respectively. ΔΨ- and ΔpH-dependent glucose uptake showed saturation kinetics with a K_m of 286 micromolar for glucose. Other hexose molecules (e.g. 2-deoxy-d-glucose, 3-O-methyl-d-glucose, and d-mannose) were also accumulated into plasma membrane vesicles in a ΔpH-dependent manner. Inhibition constants of a number of compounds for glucose uptake were determined. Effective inhibitors of glucose uptake included: 3-O-methyl-d-glucose, 5-thio-d-glucose, d-fructose, d-galactose, and d-mannose, but not 1-O-methyl-d-glucose, d- and l-xylose, l-glucose, d-ribose, and l-sorbose. Under all conditions of proton motive force magnitude and glucose and sucrose concentration tested, there was no effect of sucrose on glucose uptake. Thus, hexose transport on the sugarbeet leaf plasma membrane was by a H⁺-hexose symporter, and the carrier and possibly the energy source were not shared by the plasma membrane H⁺-sucrose symporter.     

Assessing Glucose Uptake through the Yeast Hexose Transporter 1 (Hxt1)

The transport of glucose across the plasma membrane is mediated by members of the glucose transporter family. In this study, we investigated glucose uptake through the yeast hexose transporter 1 (Hxt1) by measuring incorporation of 2-NBDG, a non-metabolizable, fluorescent glucose analog, into the yeast Saccharomyces cerevisiae. We find that 2-NBDG is not incorporated into the hxt null strain lacking all glucose transporter genes and that this defect is rescued by expression of wild type Hxt1, but not of Hxt1 with mutations at the putative glucose-binding residues, inferred from the alignment of yeast and human glucose transporter sequences. Similarly, the growth defect of the hxt null strain on glucose is fully complemented by expression of wild type Hxt1, but not of the mutant Hxt1 proteins. Thus, 2-NBDG, like glucose, is likely to be transported into the yeast cells through the glucose transport system. Hxt1 is internalized and targeted to the vacuole for degradation in response to glucose starvation. Among the mutant Hxt1 proteins, Hxt1^N370A and HXT1^W473A are resistant to such degradation. Hxt1^N370A, in particular, is able to neither uptake 2-NBDG nor restore the growth defect of the hxt null strain on glucose. These results demonstrate 2-NBDG as a fluorescent probe for glucose uptake in the yeast cells and identify N370 as a critical residue for the stability and function of Hxt1.     

The Arabidopsis HKT1 Gene Homolog Mediates Inward Na+ Currents in Xenopus laevis Oocytes and Na+ Uptake in Saccharomyces cerevisiae

The Na⁺-K⁺ co-transporter HKT1, first isolated from wheat, mediates high-affinity K⁺ uptake. The function of HKT1 in plants, however, remains to be elucidated, and the isolation of HKT1 homologs from Arabidopsis would further studies of the roles of HKT1 genes in plants. We report here the isolation of a cDNA homologous to HKT1 from Arabidopsis (AtHKT1) and the characterization of its mode of ion transport in heterologous systems. The deduced amino acid sequence of AtHKT1 is 41% identical to that of HKT1, and the hydropathy profiles are very similar. AtHKT1 is expressed in roots and, to a lesser extent, in other tissues. Interestingly, we found that the ion transport properties of AtHKT1 are significantly different from the wheat counterpart. As detected by electrophysiological measurements, AtHKT1 functioned as a selective Na⁺ uptake transporter in Xenopus laevis oocytes, and the presence of external K⁺ did not affect the AtHKT1-mediated ion conductance (unlike that of HKT1). When expressed in Saccharomyces cerevisiae, AtHKT1 inhibited growth of the yeast in a medium containing high levels of Na⁺, which correlates to the large inward Na⁺ currents found in the oocytes. Furthermore, in contrast to HKT1, AtHKT1 did not complement the growth of yeast cells deficient in K⁺ uptake when cultured in K⁺-limiting medium. However, expression of AtHKT1 did rescue Escherichia coli mutants carrying deletions in K⁺ transporters. The rescue was associated with a less than 2-fold stimulation of K⁺ uptake into K⁺-depleted cells. These data demonstrate that AtHKT1 differs in its transport properties from the wheat HKT1, and that AtHKT1 can mediate Na⁺ and, to a small degree, K⁺ transport in heterologous expression systems.     

Roles of multiple glucose transporters in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, TRK1 and TRK2 are required for high- and low-affinity K+ transport. Among suppressors of the K+ transport defect in trk1 delta trk2 delta cells, we have identified members of the sugar transporter gene superfamily. One suppressor encodes the previously identified glucose transporter HXT1, and another encodes a new member of this family, HXT3. The inferred amino acid sequence of HXT3 is 87% identical to that of HXT1, 64% identical to that of HXT2, and 32% identical to that of SNF3. Like HXT1 and HXT2, overexpression of HXT3 in snf3 delta cells confers growth on low-glucose or raffinose media. The function of another new member of the HXT superfamily, HXT4 (previously identified by its ability to suppress the snf3 delta phenotype; L. Bisson, personal communication), was revealed in experiments that deleted all possible combinations of the five members of the glucose transporter gene family. Neither SNF3, HXT1, HXT2, HXT3, nor HXT4 is essential for viability. snf3 delta hxt1 delta hxt2 delta hxt3 delta hxt4 delta cells are unable to grow on media containing high concentrations of glucose (5%) but can grow on low-glucose (0.5%) media, revealing the presence of a sixth transporter that is itself glucose repressible. This transporter may be negatively regulated by SNF3 since expression of SNF3 abolishes growth of hxt1 delta hxt2 delta hxt3 delta hxt4 delta cells on low-glucose medium. HXT1, HXT2, HXT3, and HXT4 can function independently: expression of any one of these genes is sufficient to confer growth on medium containing at least 1% glucose. A synergistic relationship between SNF3 and each of the HXT genes is suggested by the observation that SNF2 hxt1 delta hxt2 delta hxt3 delta hxt4 delta cells and snf3 delta HXT1 HXT2 HXT3 HXT4 cells are unable to grow on raffinose (low fructose) yet SNF3 in combination with any single HXT gene is sufficient for growth on raffinose. HXT1 and HXT3 are differentially regulated. HXT1::lacZ is maximally expressed during exponential growth whereas HXT3::lacZ is maximally expressed after entry into stationary phase.     

The Na+-Responsive ntp Operon Is Indispensable for Homeostatis of K+ and Na+ in Enterococcus hirae at Limited Proton Potential

Enterococcus hirae ATCC 9790 grew well in Na⁺-deficient, low-K⁺ medium, but growth was inhibited by carbonylcyanide m-chlorophenylhydrazone (CCCP). Growth inhibition and decrease of cellular K⁺ levels in the presence of CCCP were relieved by the addition of Na⁺ and a high concentration of K⁺. In contrast, in the mutant defective in Na⁺-ATPase or the NtpJ component of the KtrII K⁺ uptake system, CCCP-induced growth inhibition was rescued by a high concentration of K⁺ but not of Na⁺. These transporters are thus indispensable for homeostatis of K⁺ and Na⁺ at low proton potential.     

Molecular Basis of Fructose Utilization by the Wine Yeast Saccharomyces cerevisiae: a Mutated HXT3 Allele Enhances Fructose Fermentation

Fructose utilization by wine yeasts is critically important for the maintenance of a high fermentation rate at the end of alcoholic fermentation. A Saccharomyces cerevisiae wine yeast able to ferment grape must sugars to dryness was found to have a high fructose utilization capacity. We investigated the molecular basis of this enhanced fructose utilization capacity by studying the properties of several hexose transporter (HXT) genes. We found that this wine yeast harbored a mutated HXT3 allele. A functional analysis of this mutated allele was performed by examining expression in an hxt1-7Δ strain. Expression of the mutated allele alone was found to be sufficient for producing an increase in fructose utilization during fermentation similar to that observed in the commercial wine yeast. This work provides the first demonstration that the pattern of fructose utilization during wine fermentation can be altered by expression of a mutated hexose transporter in a wine yeast. We also found that the glycolytic flux could be increased by overexpression of the mutant transporter gene, with no effect on fructose utilization. Our data demonstrate that the Hxt3 hexose transporter plays a key role in determining the glucose/fructose utilization ratio during fermentation.     

The severe slow growth of Deltasrs2 Deltarqh1 in Schizosaccharomyces pombe is suppressed by loss of recombination and checkpoint genes

Our interest in the Schizosaccharomyces pombe RecQ helicase, rqh1⁺, led us to investigate the function of a related putative DNA helicase, srs2⁺. We identified the srs2⁺ homolog in S.pombe, and found that srs2⁺ is not essential for cell viability. A Δsrs2 Δrqh1 double mutant grows extremely slowly with aberrant shaped cells and low viability. This slow growth does not appear to be related to stalled replication, as Δsrs2 Δrqh1 cells showed higher survival rates, compared with Δrqh1, when stalled forks were increased by UV irradiation or hydroxy urea treatment. Consistent with this result, we found that Δsrs2 Δrqh1 cells progress through S-phase with a slight delay, but undergo a checkpoint-dependent arrest presumably at G₂/M. Further, we found that Δsrs2 Δrqh1 slow growth is related to recombination, as loss of either the rhp51⁺ or rhp57⁺ recombination genes improves cell growth in the double mutant. Δsrs2 is also synthetic lethal with Δrhp54, another homologous recombination gene. This lethality is suppressed in a Δrhp51 background. Together, these results demonstrate a clear genetic interaction between rqh1⁺, srs2⁺ and the genes of the homologous recombination pathway.     

Characterization of Cadmium Uptake in Lactobacillus plantarum and Isolation of Cadmium and Manganese Uptake Mutants

Two different Cd²⁺ uptake systems were identified in Lactobacillus plantarum. One is a high-affinity, high-velocity Mn²⁺ uptake system which also takes up Cd²⁺ and is induced by Mn²⁺ starvation. The calculated K_m and V_max are 0.26 μM and 3.6 μmol g of dry cell⁻¹ min⁻¹, respectively. Unlike Mn²⁺ uptake, which is facilitated by citrate and related tricarboxylic acids, Cd²⁺ uptake is weakly inhibited by citrate. Cd²⁺ and Mn²⁺ are competitive inhibitors of each other, and the affinity of the system for Cd²⁺ is higher than that for Mn²⁺. The other Cd²⁺ uptake system is expressed in Mn²⁺-sufficient cells, and no K_m can be calculated for it because uptake is nonsaturable. Mn²⁺ does not compete for transport through this system, nor does any other tested cation, i.e., Zn²⁺, Cu²⁺, Co²⁺, Mg²⁺, Ca²⁺, Fe²⁺, or Ni²⁺. Both systems require energy, since uncouplers completely inhibit their activities. Two Mn²⁺-dependent L. plantarum mutants were isolated by chemical mutagenesis and ampicillin enrichment. They required more than 5,000 times as much Mn²⁺ for growth as the parental strain. Mn²⁺ starvation-induced Cd²⁺ uptake in both mutants was less than 5% the wild-type rate. The low level of long-term Mn²⁺ or Cd²⁺ accumulation by the mutant strains also shows that the mutations eliminate the high-affinity Mn²⁺ and Cd²⁺ uptake system.     

A Saccharomyces cerevisiae Mutant Lacking a K+/H+ Exchanger

The KHA1 gene corresponding to the open reading frame YJL094c (2.62 kb) encoding a putative K⁺/H⁺ antiporter (873 amino acids) in Saccharomyces cerevisiae was disrupted by homologous recombination. The core protein is similar to the putative Na⁺/H⁺ antiporters from Enterococcus hirae (NAPA gene) and Lactococcus lactis (LLUPP gene) and the putative K⁺/H⁺ exchanger from Escherichia coli (KEFC gene). Disruption of the KHA1 gene resulted in an increased K⁺ accumulation and net influx without a significant difference in efflux, as well as an increased growth rate, smaller cells, and twice the cell yield per glucose used. Flow cytometry analysis showed an increase of the DNA duplication rate in the mutant. Kinetic studies of ⁸⁶Rb⁺ uptake showed the same saturable system for wild-type and disruptant strains. Mutant cells also produced a greater acidification of the medium coincident with an internal pH alkalinization and showed a higher oxygen consumption velocity. We speculate that higher K⁺ accumulation and increased osmotic pressure accelerate the cell cycle and metabolic activity.     

Identification of an Na+-Dependent Malonate Transporter of Malonomonas rubra and Its Dependence on Two Separate Genes

Two membrane proteins encoded by the malonate fermentation gene cluster of Malonomonas rubra, MadL and MadM, have been synthesized in Escherichia coli. MadL and MadM were shown to function together as a malonate transport system, whereas each protein alone was unable to catalyze malonate transport. Malonate transport by MadLM is Na⁺ dependent, and imposition of a ΔpNa⁺ markedly enhanced the rate of malonate uptake. The kinetics of malonate uptake into E. coli BL21(DE3) cells synthesizing MadLM at different pH values indicated that Hmalonate⁻ is the transported malonate species. The stimulation of malonate uptake by Na⁺ ions showed Michaelis-Menten kinetics, and a K_m for Na⁺ of 1.2 mM was determined. These results suggest that MadLM is an electroneutral Na⁺/Hmalonate⁻ symporter and that it is dependent on two separate genes.     

Single Amino Acid Substitutions in HXT2.4 from Scheffersomyces stipitis Lead to Improved Cellobiose Fermentation by Engineered Saccharomyces cerevisiae

Saccharomyces cerevisiae cannot utilize cellobiose, but this yeast can be engineered to ferment cellobiose by introducing both cellodextrin transporter (cdt-1) and intracellular β-glucosidase (gh1-1) genes from Neurospora crassa. Here, we report that an engineered S. cerevisiae strain expressing the putative hexose transporter gene HXT2.4 from Scheffersomyces stipitis and gh1-1 can also ferment cellobiose. This result suggests that HXT2.4p may function as a cellobiose transporter when HXT2.4 is overexpressed in S. cerevisiae. However, cellobiose fermentation by the engineered strain expressing HXT2.4 and gh1-1 was much slower and less efficient than that by an engineered strain that initially expressed cdt-1 and gh1-1. The rate of cellobiose fermentation by the HXT2.4-expressing strain increased drastically after serial subcultures on cellobiose. Sequencing and retransformation of the isolated plasmids from a single colony of the fast cellobiose-fermenting culture led to the identification of a mutation (A291D) in HXT2.4 that is responsible for improved cellobiose fermentation by the evolved S. cerevisiae strain. Substitutions for alanine (A291) of negatively charged amino acids (A291E and A291D) or positively charged amino acids (A291K and A291R) significantly improved cellobiose fermentation. The mutant HXT2.4(A291D) exhibited 1.5-fold higher K_m and 4-fold higher V_max values than those from wild-type HXT2.4, whereas the expression levels were the same. These results suggest that the kinetic properties of wild-type HXT2.4 expressed in S. cerevisiae are suboptimal, and mutations of A291 into bulky charged amino acids might transform HXT2.4p into an efficient transporter, enabling rapid cellobiose fermentation by engineered S. cerevisiae strains.     

Glucose Accumulation Can Account for the Initial Water Flux Triggered by Na+/Glucose Cotransport

Over the last decade, several cotransport studies have led to the proposal of secondary active transport of water, challenging the dogma that all water transport is passive. The major observation leading to this interpretation was that a Na⁺ influx failed to reproduce the large and rapid cell swelling induced by Na⁺/solute cotransport. We have investigated this phenomenon by comparing a Na⁺/glucose (hSGLT1) induced water flux to water fluxes triggered either by a cationic inward current (using ROMK2 K⁺ channels) or by a glucose influx (using GLUT2, a passive glucose transporter). These proteins were overexpressed in Xenopus oocytes and assayed through volumetric measurements combined with double-electrode electrophysiology or radioactive uptake measurements. The osmotic gradients driving the observed water fluxes were estimated by comparison with the swelling induced by osmotic shocks of known amplitude. We found that, for equivalent cation or glucose uptakes, the combination of substrate accumulations observed with ROMK2 and GLUT2 are sufficient to provide the osmotic gradient necessary to account for a passive water flux through SGLT1. Despite the fact that the Na⁺/glucose stoichiometry of SGLT1 is 2:1, glucose accumulation accounts for two-thirds of the osmotic gradient responsible for the water flux observed at t = 30 s. It is concluded that the different accumulation processes for neutral versus charged solutes can quantitatively account for the fast water flux associated with Na⁺/glucose cotransport activation without having to propose the presence of secondary active water transport.     

AtCCX3 is an Arabidopsis endomembrane H+ -dependent K+ transporter

The Arabidopsis (Arabidopsis thaliana) cation calcium exchangers (CCXs) were recently identified as a subfamily of cation transporters; however, no plant CCXs have been functionally characterized. Here, we show that Arabidopsis AtCCX3 (At3g14070) and AtCCX4 (At1g54115) can suppress yeast mutants defective in Na⁺, K⁺, and Mn²⁺ transport. We also report high-capacity uptake of ⁸⁶Rb⁺ in tonoplast-enriched vesicles from yeast expressing AtCCX3. Cation competition studies showed inhibition of ⁸⁶Rb⁺ uptake in AtCCX3 cells by excess Na⁺, K⁺, and Mn²⁺. Functional epitope-tagged AtCCX3 fusion proteins were localized to endomembranes in plants and yeast. In Arabidopsis, AtCCX3 is primarily expressed in flowers, while AtCCX4 is expressed throughout the plant. Quantitative polymerase chain reaction showed that expression of AtCCX3 increased in plants treated with NaCl, KCl, and MnCl₂. Insertional mutant lines of AtCCX3 and AtCCX4 displayed no apparent growth defects; however, overexpression of AtCCX3 caused increased Na⁺ accumulation and increased ⁸⁶Rb⁺ transport. Uptake of ⁸⁶Rb⁺ increased in tonoplast-enriched membranes isolated from Arabidopsis lines expressing CCX3 driven by the cauliflower mosaic virus 35S promoter. Overexpression of AtCCX3 in tobacco (Nicotiana tabacum) produced lesions in the leaves, stunted growth, and resulted in the accumulation of higher levels of numerous cations. In summary, these findings suggest that AtCCX3 is an endomembrane-localized H⁺-dependent K⁺ transporter with apparent Na⁺ and Mn²⁺ transport properties distinct from those of previously characterized plant transporters.     

Role of a mitogen-activated protein kinase cascade in ion flux-mediated turgor regulation in fungi

Fungi normally maintain a high internal hydrostatic pressure (turgor) of about 500 kPa. In response to hyperosmotic shock, there are immediate electrical changes: a transient depolarization (1 to 2 min) followed by a sustained hyperpolarization (5 to 10 min) prior to turgor recovery (10 to 60 min). Using ion-selective vibrating probes, we established that the transient depolarization is due to Ca²⁺ influx and the sustained hyperpolarization is due to H⁺ efflux by activation of the plasma membrane H⁺-ATPase. Protein synthesis is not required for H⁺-ATPase activation. Net K⁺ and Cl⁻ uptake occurs at the same time as turgor recovery. The magnitude of the ion uptake is more than sufficient to account for the osmotic gradients required for turgor to return to its original level. Two osmotic mutants, os-1 and os-2, homologs of a two-component histidine kinase sensor and the yeast high osmotic glycerol mitogen-activated protein (MAP) kinase, respectively, have lower turgor than the wild type and do not exhibit the sustained hyperpolarization after hyperosmotic treatment. The os-1 mutant does not exhibit all of the wild-type turgor-adaptive ion fluxes (Cl⁻ uptake increases, but net K⁺ flux barely changes and net H⁺ efflux declines) (os-2 was not examined). Both os mutants are able to regulate turgor but at a lower level than the wild type. Our results demonstrate that a MAP kinase cascade regulates ion transport, activation of the H⁺-ATPase, and net K⁺ and Cl⁻ uptake during turgor regulation. Other pathways regulating turgor must also exist.     

The Adhesion-Associated sca Operon in Streptococcus gordonii Encodes an Inducible High-Affinity ABC Transporter for Mn2+ Uptake

ScaA lipoprotein in Streptococcus gordonii is a member of the LraI family of homologous polypeptides found among streptococci, pneumococci, and enterococci. It is the product of the third gene within the scaCBA operon encoding the components of an ATP-binding cassette (ABC) transporter system. Inactivation of scaC (ATP-binding protein) or scaA (substrate-binding protein) genes resulted in both impaired growth of cells and >70% inhibition of ⁵⁴Mn²⁺ uptake in media containing <0.5 μM Mn²⁺. In wild-type and scaC mutant cells, production of ScaA was induced at low concentrations of extracellular Mn²⁺ (<0.5 μM) and by the addition of ≥20 μM Zn²⁺. Sca permease-mediated uptake of ⁵⁴Mn²⁺ was inhibited by Zn²⁺ but not by Ca²⁺, Mg²⁺, Fe²⁺, or Cu²⁺. Reduced uptake of ⁵⁴Mn²⁺ by sca mutants and by wild-type cells in the presence of Zn²⁺ was abrogated by the uncoupler carbonylcyanide m-chlorophenylhydrazone, suggesting that Mn²⁺ uptake under these conditions was proton motive force dependent. The frequency of DNA-mediated transformation was reduced >20-fold in sca mutants. The addition of 0.1 mM Mn²⁺ to the transformation medium restored only partly the transformability of mutant cells, implying an alternate role for Sca proteins in the transformation process. Cells of sca mutants were unaffected in other binding properties tested and were unaffected in sensitivity to oxidants. The results show that Sca permease is a high-affinity mechanism for the acquisition of Mn²⁺ and is essential for growth of streptococci under Mn²⁺-limiting conditions.