Glucose-stimulated cAMP increase may be mediated by intracellular acidification in Saccharomyces cerevisiae

It has been reported that addition of glucose to cells of Saccharomycescerevisiae grown on a sugar-free medium causes a peak of intracellular cAMP levels. Also, it has been proposed that this effect might be mediated by plasma membrane depolarization. However, here, we observed a hyperpolarizing effect of glucose in S. cerevisiae and, in addition, no change in cAMP levels when depolarization was induced by valinomycin in the presence of K⁺. In contrast, treatments that induced a rapid intracellular acidification such as addition of the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone at pH 5.5 but not at pH 8.0, extracellular pH shift from 8.5 to 3.5, and glucose itself, also increased the cyclic nucleotide. Thus, our data strongly support the hypothesis that intracellular acidification mediates the effect of glucose on cAMP levels.     

Internal acidification and cAMP increase are not correlated in Saccharomyces cerevisiae

Addition of glucose to a yeast suspension can produce both an increase in the level of cAMP and a decrease in the intracellular pH. This observation led to the idea that internal acidification triggers the cAMP increase. We have tested this hypothesis using different approaches. To study the effect of sugar metabolism on internal pH we added to the yeast either glucose or a sugar, like xylose, that cannot be phosphorylated. We also utilized yeast strains lacking hexose kinases or phosphoglucose isomerase. We found that phosphorylation of the sugar added is a requisite for internal acidification but not for the cAMP increase. Internal acidification is due to an imbalance between the rate of the metabolic reactions that generate protons and the rate at which protons can be pumped out of the cell. We have manipulated the excretion of protons by using yeast harvested at different phases of growth and resuspended in a medium with or without added K+. Addition of glucose produced a marked drop in internal pH only when the yeast was harvested in the stationary phase of growth and transferred to a medium without added K+. In contrast an increase in cAMP was observed in all situations. We conclude that in yeast there is no correlation between internal acidification and cAMP increase.     

The mechanism of intracellular acidification induced by glucose in Saccharomyces cerevisiae

Addition of glucose or fructose to cells of Saccharomyces cerevisiae adapted to grow in the absence of glucose induced an acidification of the intracellular medium. This acidification appeared to be due to the phosphorylation of the sugar since: (i) glucose analogues which are not efficiently phosphorylated did not induce internal acidification; (ii) glucose addition did not cause internal acidification in a mutant deficient in all the three sugar-phosphorylating enzymes; (iii) fructose did not affect the intracellular pH in a double mutant having only glucokinase activity; (iv) glucose was as effective as fructose in inducing the internal pH drop in a mutant deficient in phosphoglucose isomerase activity; and (v) in strains deficient in two of the three sugar-phosphorylating activities, there was a good correlation between the specific glucose- or fructose-phosphorylating activity of cell extracts and the sugar-induced internal acidification. In addition, in whole cells any of the three yeast sugar kinases were capable of mediating the internal acidification described. Glucose-induced internal acidification was observed even when yeast cells were suspended in growth medium and in cells suspended in buffer containing K+, which supports the possible signalling function of the glucose-induced internal acidification. Evaluation of internal pH by following fluorescence changes of fluorescein-loaded cells indicated that the change in intracellular pH occurred immediately after addition of sugar. The apparent Km for glucose in this process was 2 mM. Changes in both the internal and external pH were determined and it was found that the internal acidification induced by glucose was followed by a partial alkalinization coincident with the initiation of H+ efflux. This reversal of acidification could be due to the activity of the H+-ATPase, since it was inhibited by diethylstilboestrol. Coincidence between internal alkalinization and the H+ efflux was also observed after addition of ethanol.     

Intracellular glucose 1-phosphate and glucose 6-phosphate levels modulate Ca2+ homeostasis in Saccharomyces cerevisiae

The enzyme phosphoglucomutase plays a key role in cellular metabolism by virtue of its ability to interconvert Glc-1-P and Glc-6-P. It was recently shown that a yeast strain lacking the major isoform of phosphoglucomutase (pgm2Delta) accumulates a high level of Glc-1-P and exhibits several phenotypes related to altered Ca(2+) homeostasis when d-galactose is utilized as the carbon source (Fu, L., Miseta, A., Hunton, D., Marchase, R. B., and Bedwell, D. M. (2000) J. Biol. Chem. 275, 5431-5440). These phenotypes include increased Ca(2+) uptake and accumulation and sensitivity to high environmental Ca(2+) levels. In the present study, we overproduced the enzyme UDP-Glc pyrophosphorylase to test whether the overproduction of a downstream metabolite produced from Glc-1-P can also mediate changes in Ca(2+) homeostasis. We found that overproduction of UDP-Glc did not cause any alterations in Ca(2+) uptake or accumulation. We also examined whether Glc-6-P can influence cellular Ca(2+) homeostasis. A yeast strain lacking the beta-subunit of phosphofructokinase (pfk2Delta) accumulates a high level of Glc-6-P (Huang, D., Wilson, W. A., and Roach, P. J. (1997) J. Biol. Chem. 272, 22495-22501). We found that this increase in Glc-6-P led to a 1.5-2-fold increase in total cellular Ca(2+). We also found that the pgm2Delta/pfk2Delta strain, which accumulated high levels of both Glc-6-P and Glc-1-P, no longer exhibited the Ca(2+)-related phenotypes associated with high Glc-1-P levels in the pgm2Delta mutant. These results provide strong evidence that cellular Ca(2+) homeostasis is coupled to the relative levels of Glc-6-P and Glc-1-P in yeast.     

Activation of Ca2+ influx by metabolic substrates in Saccharomyces cerevisiae: role of membrane potential and cellular ATP levels

Influx of Ca2+ into cells of Saccharomyces cerevisiae was measured under non-steady-state conditions, which enable measurements of the initial rate of transport across plasma membranes without interference by the vacuolar Ca2+ transport system. Removal of glucose from the incubation medium led to inactivation of Ca2+ influx within 5 min. Readdition of glucose led to a transient increase in the rate of Ca2+ transport, reaching a peak after 3-5 min. A second increase was observed 60-80 min later. To examine whether the first transient activation of Ca2+ influx by glucose was mediated by membrane hyperpolarization, influx of 45Ca2+ was measured in the presence and absence of metabolic substrates (glucose, glycerol, and glucose plus antimycin A) in cells hyperpolarized to different values of membrane potential (delta psi). Logarithms of the rate of Ca2+ influx were plotted against values of delta psi. Two different slopes were obtained, depending upon whether the metabolic substrate was present or absent. Ca2+ influx in the presence of the metabolic substrates was always higher than expected by their effect on delta psi. Glycerol plus antimycin A did not affect Ca2+ influx. It was concluded that metabolized substrates activate Ca2+ influx not only by effects on delta psi but also by additional mechanism(s). Since no simple correlation between Ca2+ influx and intracellular ATP levels was observed, it was concluded that ATP levels do not affect the initial rates of Ca2+ transport across the plasma membrane of S. cerevisiae.     

Fig1p facilitates Ca2+ influx and cell fusion during mating of Saccharomyces cerevisiae

During the mating process of yeast cells, two Ca2+ influx pathways become activated. The resulting elevation of cytosolic free Ca2+ activates downstream signaling factors that promote long term survival of unmated cells, but the roles of Ca2+ in conjugation have not been described. The high affinity Ca2+ influx system is composed of Cch1p and Mid1p and sensitive to feedback inhibition by calcineurin, a Ca2+/calmodulin-dependent protein phosphatase. To identify components and regulators of the low affinity Ca2+ influx system (LACS), we screened a collection of pheromone-responsive genes that when deleted lead to defects in LACS activity but not high affinity Ca2+ influx system activity. Numerous factors implicated in polarized morphogenesis and cell fusion (Fus1p, Fus2p, Rvs161p, Bni1p, Spa2p, and Pea2p) were found to be necessary for LACS activity. Each of these factors was also required for activation of the cell integrity mitogen-activated protein kinase cascade during the response to alpha-factor. Interestingly a polytopic plasma membrane protein, Fig1p, was required for LACS activity but not required for activation of Mpk1p mitogen-activated protein kinase. Mpk1p was not required for LACS activity, suggesting Mpk1p and Fig1p define two independent branches in the pheromone response pathways. Fig1p-deficient mutants exhibit defects in the cell-cell fusion step of mating, but unlike other fus1 and fus2 mutants the fusion defect of fig1 mutants can be largely suppressed by high Ca2+ conditions, which bypass the requirement for LACS. These findings suggest Fig1p is an important component or regulator of LACS and provide the first evidence for a role of Ca2+ signals in the cell fusion step of mating.     

Increased intracellular Ca2+ induces Ca2+ influx in human T lymphocytes.

One current hypothesis for the initiation of Ca2+ entry into nonelectrically excitable cells proposes that Ca2+ entry is linked to the state of filling of intracellular Ca2+ stores. In the human T lymphocyte cell line Jurkat, stimulation of the antigen receptor leads to release of Ca2+ from internal stores and influx of extracellular Ca2+. Similarly, treatment of Jurkat cells with the tumor promoter thapsigargin induced release of Ca2+ from internal stores and also resulted in influx of extracellular Ca2+. Initiation of Ca2+ entry by thapsigargin was blocked by chelation of Ca2+ released from the internal storage pool. The Ca2+ entry pathway also could be initiated by an increase in the intracellular concentration of Ca2+ after photolysis of the Ca(2+)-cage, nitr-5. Thus, three separate treatments that caused an increase in the intracellular concentration of Ca2+ initiated Ca2+ influx in Jurkat cells. In all cases, Ca(2+)-initiated Ca2+ influx was blocked by treatment with any of three phenothiazines or W-7, suggesting that it is mediated by calmodulin. These data suggest that release of Ca2+ from internal stores is not linked capacitatively to Ca2+ entry but that initiation is linked instead by Ca2+ itself, perhaps via calmodulin.     

Effect of endothelin on Ca2+ influx, intracellular free Ca2+ levels and ligand binding to N and L type Ca2+ channels in rat brain

The actions of endothelin, an endogenous vasoconstrictor compound with potent effects on various parameters of Ca2+ metabolism in peripheral tissue, were studied in several neuronal preparations. Endothelin, by itself, did not alter resting intracellular free Ca2+ levels or Ca2+ influx in either rat or chicken brain preparations; nor did it affect depolarization (K+) induced changes in these parameters. Endothelin also had no effect on the binding of [3H]-nitrendipine or [125I]-omega-conotoxin to "L " or "N" type channels respectively nor did it induce the release of endogenous acetylcholine from brain slices. The results show that, despite the proposed role of endothelin on voltage sensitive Ca2+ channels in peripheral tissue and despite the existence of endothelin binding sites on both smooth muscle and neurons, endothelin has no measurable effects on Ca2+ metabolism in neural tissue of central origin.     

Regulation of Ca2+ influx during mitosis: Ca2+ influx and depletion of intracellular Ca2+ stores are coupled in interphase but not mitosis.

Activation of a wide variety of membrane receptors leads to a sustained elevation of intracellular Ca2+ ([Ca2+]i) that is pivotal to subsequent cell responses. In general, in nonexcitable cells this elevation of [Ca2+]i results from two sources: an initial release of Ca2+ from intracellular stores followed by an influx of extracellular Ca2+. These two phases, release from intracellular stores and Ca2+ influx, are generally coupled: stimulation of influx is coordinated with depletion of Ca2+ from stores, although the mechanism of coupling is unclear. We have previously shown that histamine effects a typical [Ca2+]i response in interphase HeLa cells: a rapid rise in [Ca2+]i followed by a sustained elevation, the latter dependent entirely on extracellular Ca2+. In mitotic cells only the initial elevation, derived by Ca2+ release from intracellular stores, occurs. Thus, in mitotic cells the coupling of stores to influx may be specifically broken. In this report we first provide additional evidence that histamine-stimulated Ca2+ influx is strongly inhibited in mitotic cells. We show that efflux is also strongly stimulated by histamine in interphase cells but not in mitotics. It is possible, thus, that in mitotics intracellular stores are only very briefly depleted of Ca2+, being replenished by reuptake of Ca2+ that is retained within the cell. To ensure the depletion of Ca2+ stores in mitotic cells, we employed the sesquiterpenelactone, thapsigargin, that is known to affect the selective release of Ca2+ from intracellular stores by inhibition of a specific Ca(2+)-ATPase; reuptake is inhibited. In most cells, and in accord with Putney's capacitative model (1990), thapsigargin, presumably by depleting intracellular Ca2+ stores, stimulates Ca2+ influx. This is the case for interphase HeLa cells. Thapsigargin induces an increase in [Ca2+]i that is dependent on extracellular Ca2+ and is associated with a strong stimulation of 45Ca2+ influx. In mitotic cells thapsigargin also induces a [Ca2+]i elevation that is initially comparable in magnitude and largely independent of extracellular Ca2+. However, unlike interphase cells, in mitotic cells the elevation of [Ca2+]i is not sustained and 45Ca2+ influx is not stimulated by thapsigargin. Thus, the coupling between depletion of intracellular stores and Ca2+ influx is specifically broken in mitotic cells. Uncoupling could account for the failure of histamine to stimulate Ca2+ influx during mitosis and would effectively block all stimuli whose effects are mediated by Ca2+ influx and sustained elevations of [Ca2+]i.     

Discrete intracellular Ca2+ pools coupled to two distinct Ca2+ influx pathways in human platelets

Ca(2+) influx is an important event associated with platelet activation and regulated by the content of intracellular Ca(2+). Previous studies have suggested two different Ca(2+) pools and two Ca(2+) influx pathways exist in platelets. In the present study, we have investigated the regulation of thrombin- and thapsigargin-induced Ca(2+) entry into human platelets, using fluorescent indicators to monitor Ca(2+) mobilization and membrane potential. It was found that depletion of thapsigargin-sensitive Ca(2+) stores was coupled to Ca(2+) influx through a Ca(2+)-selective pathway. Additional release of Ca(2+) from the thapsigargin-insensitive pool by thrombin caused the opening of a nonselective cation channel.     

Protein secretion in cockroach salivary glands requires an increase in intracellular cAMP and Ca2+ concentrations

The salivary glands in the cockroach Periplaneta americana secrete protein-containing saliva when stimulated by serotonin (5-HT) and protein-free saliva upon dopamine stimulation. In order to obtain information concerning the signalling pathways involved in 5-HT-induced protein secretion, we have determined the protein content of saliva secreted after experimental manipulations that potentially elevate intracellular Ca2+ and cyclic nucleotide concentrations in isolated glands. We have found that 5-HT stimulates the rate of protein secretion in a dose-dependent manner (threshold: 3 x 10(-8)M; EC50 1.5 x 10(-6)M). The maximal rate of 5-HT-induced protein secretion was 2.2 +/- 0.2 microg/min. Increasing intracellular Ca2+ or cAMP by bath application of ionomycin (5 microM), db cAMP (10mM), forskolin (100 microM) or IBMX (100 microM), respectively, stimulated protein secretion at significantly lower rates, whereas db cGMP (1mM) did not activate protein secretion. The high rates and the kinetics of 5-HT-induced protein secretion could only be mimicked by either applying forskolin together with IBMX (with or without ionomycin) or by applying IBMX together with ionomycin. Our measurements suggest that 5-HT-induced protein secretion is mediated by an elevation of [cAMP]i and that Ca2+ may function as a co-agonist and augment the rate of protein secretion.     

Hierarchical and metabolic regulation of glucose influx in starved Saccharomyces cerevisiae

A novel method dissecting the regulation of a cellular function into direct metabolic regulation and hierarchical (e.g., gene-expression) regulation is applied to yeast starved for nitrogen or carbon. Upon nitrogen starvation glucose influx is down-regulated hierarchically. Upon carbon starvation it is down-regulated both metabolically and hierarchically. The method is expounded in terms of its implications for diverse types of regulation. It is also fine-tuned for cases where isoenzymes catalyze the flux through a single metabolic step.     

Kinetic properties of Ca2+/calmodulin-dependent phosphodiesterase isoforms dictate intracellular cAMP dynamics in response to elevation of cytosolic Ca2+

Multiply regulated adenylyl cyclases (AC) and phosphodiesterases (PDE) can yield complex intracellular cAMP signals. Ca2+-sensitive ACs have received far greater attention than the Ca2+/calmodulin-dependent PDE (PDE1) family in governing intracellular cAMP dynamics in response to changes in the cytosolic Ca2+ concentration ([Ca2+]i). Here, we have stably expressed two isoforms of PDE1, PDE1A2 and PDE1C4, in HEK-293 cells to determine whether they exert different impacts on cellular cAMP. Fractionation and imaging showed that both PDEs occurred mainly in the cytosol. However, PDE1A2 and PDE1C4 differed considerably in their ability to hydrolyze cAMP and in their susceptibility to inhibition by the non-selective PDE inhibitor, IBMX and the PDE1-selective inhibitor, MMX. PDE1A2 had an approximately 30-fold greater Km for cAMP than PDE1C4 and yet was more susceptible to inhibition by IBMX and MMX than was PDE1C4. These differences were mirrored in intact cells when thapsigargin-induced capacitative Ca2+ entry (CCE) activated the PDEs. Mirroring their kinetic properties, PDE1C4 was active at near basal cAMP levels, whereas PDE1A2 required agonist-triggered levels of cAMP, produced in response to stimulation of ACs. The effectiveness of IBMX and MMX to inhibit PDE1A2 and PDE1C4 in functional studies was inversely related to their respective affinities for cAMP. To assess the impact of the two isoforms on cAMP dynamics, real-time cAMP measurements were performed in single cells expressing the two PDE isoforms and a fluorescent Epac-1 cAMP biosensor, in response to CCE. These measurements showed that prostaglandin E1-mediated cAMP production was markedly attenuated in PDE1C4-expressing cells upon induction of CCE and cAMP hydrolysis occurred at a faster rate than in cells expressing PDE1A2 under similar conditions. These results prove that the kinetic properties of PDE isoforms play a major role in determining intracellular cAMP signals in response to physiological elevation of [Ca2+]i and thereby provide a rationale for the utility of diverse PDE1 species.     

tRNAHis 5-methylcytidine levels increase in response to several growth arrest conditions in Saccharomyces cerevisiae

tRNAs are highly modified, each with a unique set of modifications. Several reports suggest that tRNAs are hypomodified or, in some cases, hypermodified under different growth conditions and in certain cancers. We previously demonstrated that yeast strains depleted of tRNA^His guanylyltransferase accumulate uncharged tRNA^His lacking the G₋₁ residue and subsequently accumulate additional 5-methylcytidine (m⁵C) at residues C₄₈ and C₅₀ of tRNA^His, due to the activity of the m⁵C-methyltransferase Trm4. We show here that the increase in tRNA^His m⁵C levels does not require loss of Thg1, loss of G₋₁ of tRNA^His, or cell death but is associated with growth arrest following different stress conditions. We find substantially increased tRNA^His m⁵C levels after temperature-sensitive strains are grown at nonpermissive temperature, and after wild-type strains are grown to stationary phase, starved for required amino acids, or treated with rapamycin. We observe more modest accumulations of m⁵C in tRNA^His after starvation for glucose and after starvation for uracil. In virtually all cases examined, the additional m⁵C on tRNA^His occurs while cells are fully viable, and the increase is neither due to the GCN4 pathway, nor to increased Trm4 levels. Moreover, the increased m⁵C appears specific to tRNA^His, as tRNA^Val(AAC) and tRNA^Gly(GCC) have much reduced additional m⁵C during these growth arrest conditions, although they also have C₄₈ and C₅₀ and are capable of having increased m⁵C levels. Thus, tRNA^His m⁵C levels are unusually responsive to yeast growth conditions, although the significance of this additional m⁵C remains unclear.     

Cell cycle control by Ca2+ in Saccharomyces cerevisiae

We established an experimental system suitable for study of cell cycle regulation by Ca2+ in the yeast Saccharomyces cerevisiae. Systematic cell cycle analysis using media containing various concentrations of Ca2+, a Ca2(+)-ionophore (A23187), and a Ca2(+)-chelator [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (EGTA) revealed that simultaneous addition of 10 microM A23187 and 10 mM EGTA to cells growing in a Ca2(+)-deficient medium at 22 degrees C caused rapid decrease in intracellular Ca content and resulted in transient G1 arrest followed by block mostly at G2/M, as revealed by flow cytometry. Recovery from G1 arrest was not due to coordinated initiation of DNA synthesis and bud emergence: unbudded cells with S or G2/M DNA were observed. Examination of terminal phenotype suggested that Ca2+ was required at all the stages of the cell cycle except for the initiation of DNA synthesis. The intracellular cAMP level decreased within 10 min of addition of A23187 and EGTA. No significant transient G1 arrest was observed in cells incubated with 8-Br-cAMP, or RAS2val19 and delta bcy1 mutants, which produce a high level of cAMP and have constitutively activated cAMP-dependent protein kinase, respectively. These results indicate that Ca2+ is essential for cell cycle progression and suggest that Ca2+ may regulate the cAMP level. This system will be useful for genetic and molecular studies on cell cycle events regulated by Ca2+.     

Novel role of the Ca2+-ATPase in NMDA-induced intracellular acidification

The mechanism involved inN-methyl-D-glucamine(NMDA)-induced Ca²⁺-dependentintracellular acidosis is not clear. In this study, we investigated indetail several possible mechanisms using cultured rat cerebellargranule cells and microfluorometry [fura 2-AM or 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein-AM].When 100 µM NMDA or 40 mM KCl was added, a marked increase in theintracellular Ca²⁺ concentration([Ca²⁺]_i)and a decrease in the intracellular pH were seen. Acidosis wascompletely prevented by the use ofCa²⁺-free medium or1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid-AM, suggesting that it resulted from an influx of extracellular Ca²⁺. The following fourmechanisms that could conceivably have been involved were excluded:1)Ca²⁺ displacement of intracellularH⁺ from common binding sites;2) activation of an acid loader or inhibition of acid extruders; 3)overproduction of CO₂ or lactate; and 4) collapse of the mitochondrialmembrane potential due to Ca²⁺uptake, resulting in inhibition of cytosolicH⁺ uptake. However,NMDA/KCl-induced acidosis was largely prevented by glycolyticinhibitors (iodoacetate or deoxyglucose in glucose-free medium) or byinhibitors of the Ca²⁺-ATPase(i.e.,Ca²⁺/H⁺exchanger), including La³⁺,orthovanadate, eosin B, or an extracellular pH of 8.5. Our results therefore suggest that Ca²⁺-ATPaseis involved in NMDA-induced intracellular acidosis in granule cells. Wealso provide new evidence that NMDA-evoked intracellular acidosisprobably serves as a negative feedback signal, probably with theacidification itself inhibiting the NMDA-induced[Ca²⁺]_i increase.