A comparative genomic analysis of the calcium signaling machinery in Neurospora crassa, Magnaporthe grisea, and Saccharomyces cerevisiae

A large number of Ca2+ -signaling proteins have been previously identified and characterized in Saccharomyces cerevisiae but relatively few have been discovered in filamentous fungi. In this study, a detailed, comparative genomic analysis of Ca2+ -signaling proteins in Neurospora crassa, Magnaporthe grisea, and S. cerevisiae has been made. Our BLAST analysis identified 48, 42, and 40 Ca2+ -signaling proteins in N. crassa, M. grisea, and S. cerevisiae, respectively. In N. crassa, M. grisea, and S. cerevisiae, 79, 100, and 13% of these proteins, respectively, were previously unknown. For N. crassa, M. grisea, and S. cerevisiae, respectively, we have identified: three Ca2+ -permeable channels in each species; 9, 12, and 5 Ca2+/cation-ATPases; eight, six, and four Ca2+ -exchangers; four, four, and two phospholipase C's; one calmodulin in each species; and 23, 21, and 29 Ca2+/calmodulin-regulated proteins. Homologs of a number of key proteins involved in the release of Ca2+ from intracellular stores, and in the sensing of extracellular Ca2+, in animal and plant cells, were not identified. The greater complexity of the Ca2+ -signaling machinery in N. crassa and M. grisea over that in S. cerevisiae probably reflects their more complex cellular organization and behavior, and the greater range of external signals which filamentous fungi have to respond to in their natural habitats. To complement the data presented in this paper, a comprehensive web-based database resource (http://www.fungalcell.org/fdf/) of all Ca2+ -signaling proteins identified in N. crassa, M. grisea, and S. cerevisiae has been provided.     

Neuronal calcium sensor-1 modulation of optimal calcium level for neurite outgrowth

Neurite extension and branching are affected by activity-dependent modulation of intracellular Ca2+, such that an optimal window of [Ca2+] is required for outgrowth. Our understanding of the molecular mechanisms regulating this optimal [Ca2+]i remains unclear. Taking advantage of the large growth cone size of cultured primary neurons from pond snail Lymnaea stagnalis combined with dsRNA knockdown, we show that neuronal calcium sensor-1 (NCS-1) regulates neurite extension and branching, and activity-dependent Ca2+ signals in growth cones. An NCS-1 C-terminal peptide enhances only neurite branching and moderately reduces the Ca2+ signal in growth cones compared with dsRNA knockdown. Our findings suggest that at least two separate structural domains in NCS-1 independently regulate Ca2+ influx and neurite outgrowth, with the C-terminus specifically affecting branching. We describe a model in which NCS-1 regulates cytosolic Ca2+ around the optimal window level to differentially control neurite extension and branching.     

Primary inhibition of hypocotyl growth and phototropism depend differently on phototropin-mediated increases in cytoplasmic calcium induced by blue light

The phototropin photoreceptors transduce blue-light signals into several physiological and developmental responses in plants. A transient rise in cytoplasmic calcium (Ca2+) that begins within seconds of phototropin 1 (phot1) excitation is believed to be an important element in the transduction pathways leading to one or more of the phot1-dependent responses. The goal of the present work was to determine whether the Ca2+ response was necessary for (a). the inhibition of hypocotyl elongation that develops within minutes of the irradiation, and (b). hypocotyl phototropism (curved growth of the stem in response to asymmetric illumination). After determining that pulses of light delivering photon fluences of between 1 and 1000 micromol m-2 induced growth inhibition mediated by phot1 without significant interference from other photosensory pathways, the effect of blocking the Ca2+ rise was assessed. Treatment of seedlings with a Ca2+ chelator prevented the rise in cytoplasmic Ca2+ and prevented phot1-mediated growth inhibition. However, the same chelator treatment did not impair phot1-mediated phototropism. Thus, it appears that the early, transient rise in cytoplasmic Ca2+ is an important intermediary process in at least one but not all phot1-signaling pathways.     

A flavonoid, 5-hydroxy-3,7-dimethoxyflavone,from Kaempferia parviflora Wall. Ex. Baker as an inhibitor of Ca2+ signal-mediated cell-cycle regulation in yeast

Calcium (Ca²⁺) signal transduction pathways play important roles in the regulation of diverse biological processes in eukaryotes ranging from unicellular (e.g., yeasts) to complex multicellular (e.g., humans) organisms. Small-molecule inhibitors of Ca²⁺-signaling pathways in humans can be of great medical importance, as represented by the immunosuppressants FK506 and cyclosporine A. A high-throughput drug screening assay for inhibitors of Ca²⁺-signaling has been developed on the basis of the ability of test compounds to restore the severe growth defect of a Ca²⁺-sensitive zds1 null-mutant strain YNS17 of Saccharomyces cerevisiae in a medium containing a high concentration of calcium ions. A previous screening of Thai medicinal plants using this yeast-based assay indicated that the crude extract of Kaempferia parviflora Wall. Ex. Baker contains a potent inhibitory activity. The aim of this study was to isolate and characterize the pure compound(s) responsible for this inhibitory activity against Ca²⁺-mediated cell-cycle regulation in yeast. Dichloromethane and methanol extracts of K. parviflora rhizomes were subjected to bioassay-mediated chromatographic fractionation using this yeast [YNS17 (Δzds1) strain]-based assay to screen for and select positive fractions. From the dichloromethane extract, four known flavonoid compounds with significant inhibitory bioactivity were obtained: compounds 1 (5-hydroxy-3,7-dimethoxyflavone), 2 (5-hydroxy-7-methoxyflavone), 3 (5-hydroxy-3,7,4’-trimethoxyflavone) and 4 (5,7-dimethoxyflavone). The inhibitory activity of all four compounds was dose-dependent. Compound 1 exhibited the highest activity and with no observed cytotoxic activity against the yeast. The Ca²⁺ induced severe growth defect, abnormal budding morphology, and G2 cell-cycle delay of the Δzds1 yeast strain were all alleviated or abrogated by 200 μM compound 1. Therefore, we conclude that 5-hydroxy-3,7-dimethoxyflavone possesses a potent inhibitory activity against the Ca²⁺-mediated cell-cycle regulation.     

Amplification of Ca2+ signaling by diacylglycerol-mediated inositol 1,4,5-trisphosphate production

Stimulation of various cell surface receptors leads to the production of inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG) through phospholipase C (PLC) activation, and the IP3 and DAG in turn trigger Ca2+ release through IP3 receptors and protein kinase C activation, respectively. The amount of IP(3) produced is particularly critical to determining the spatio-temporally coordinated Ca(2+)-signaling patterns. In this paper, we report a novel signal cross-talk between DAG and the IP3-mediated Ca(2+)-signaling pathway. We found that a DAG derivative, 1-oleoyl-2-acyl-sn-glycerol (OAG), induces Ca2+ oscillation in various types of cells independently of protein kinase C activity and extracellular Ca2+. The OAG-induced Ca2+ oscillation was completely abolished by depletion of Ca2+ stores or inhibition of PLC and IP3 receptors, indicating that OAG stimulates IP3 production through PLC activation and thereby induces IP3-induced Ca2+ release. Furthermore, intracellular accumulation of endogenous DAG by a DAG-lipase inhibitor greatly increased the number of cells responding to agonist stimulation at low doses. These results suggest a novel physiological function of DAG, i.e. amplification of Ca2+ signaling by enhancing IP3 production via its positive feedback effect on PLC activity.     

Ratiometric and nonratiometric Ca2+ indicators for the assessment of intracellular free Ca2+ in a breast cancer cell line using a fluorescence microplate reader

Transporters of Ca2+ are potential drug targets and Ca2+ is a useful signal in the assessment of G-protein-coupled receptor activation. Assays involving the assessment of intracellular Ca2+ using microplate readers most often use Ca2+ indicators which do not exhibit a spectra shift on Ca2+ binding (e.g. fluo-3). Indicators that do exhibit a spectral shift upon Ca2+ binding (e.g. fura-2) offer potential advantages for the calibration of intracellular Ca2+ levels. However, experimental limitations may limit the use of ratiometric dyes in microplate readers capable of screening. In this study, we compared the assessment of intracellular Ca2+ in adherent breast cancer cells using ratiometric and nonratiometric Ca2+ indicators. Our results demonstrate that both fluo-3 and fura-2 detect ATP dose-dependent increases in intracellular Ca2+ in the MCF-7 breast cancer cell line and that some of the limitations in the use of fura-2 appear to be overcome by the use of glass bottom microplates. The calibrated intracellular Ca2+ levels derived using fura-2 are consistent with those from microscopy and cuvette-based studies. Fura-2 may be useful in microplate studies, where cell lines with different properties are compared or where screening treatments lead to differences in the number of cells or dye loading.     

Apical localization of a functional TRPC3/TRPC6-Ca2+-signaling complex in polarized epithelial cells. Role in apical Ca2+ influx

Receptor-coupled [Ca2+]i increase is initiated in the apical region of epithelial cells and has been associated with apically localized Ca2+-signaling proteins. However, localization of Ca2+ channels that are regulated by such Ca2+-signaling events has not yet been established. This study examines the localization of TRPC channels in polarized epithelial cells and demonstrates a role for TRPC3 in apical Ca2+ uptake. Endogenously and exogenously expressed TRPC3 was localized apically in polarized Madin-Darby canine kidney cells (MDCK) and salivary gland epithelial cells. In contrast, TRPC1 was localized basolaterally, whereas TRPC6 was detected in both locations. Localization of Galpha(q/11), inositol 1,4,5-trisphosphate receptor-3, and phospholipase Cbeta1 and -beta2 was also predominantly apical. TRPC3 co-immunoprecipitated with endogenous TRPC6, phospholipase Cbetas, Galpha(q/11), inositol 1,4,5-trisphosphate receptor-3, and syntaxin 3 but not with TRPC1. Furthermore, 1-oleoyl-2-acetyl-sn-glycerol (OAG)-stimulated apical 45Ca2+ uptake was higher in TRPC3-MDCK cells compared with control (MDCK) cells. Bradykinin-stimulated apical 45Ca2+ uptake and transepithelial 45Ca2+ flux were also higher in TRPC3-expressing cells. Consistent with this, OAG induced [Ca2+]i increase in the apical, but not basal, region of TRPC3-MDCK cells that was blocked by EGTA addition to the apical medium. Most importantly, (i) TRPC3 was detected in the apical region of rat submandibular gland ducts, whereas TRPC6 was present in apical as well as basolateral regions of ducts and acini; and (ii) OAG stimulated Ca2+ influx into dispersed ductal cells. These data demonstrate functional localization of TRPC3/TRPC6 channels in the apical region of polarized epithelial cells. In salivary gland ducts this could contribute to the regulation of salivary [Ca2+] and secretion.     

Protein 4.1N does not interact with the inositol 1,4,5-trisphosphate receptor in an epithelial cell line

Cytosolic Ca2+ regulates a variety of cell functions, and the spatial patterns of Ca2+ signals are responsible in part for the versatility of this second messenger. The subcellular distribution of the inositol 1,4,5-trisphosphate receptor (IP3R) is thought to regulate Ca2+-signaling patterns but little is known about how the distribution of the IP3R itself is regulated. Here we examined the relationship between the IP3R and the cytoskeletal linker protein 4.1N in the polarized WIF-B cell line because protein 4.1N regulates targeting of the type I IP3R in neurons, but WIF-B cells do not express this cytoskeletal protein. WIF-B cells expressed all three isoforms of the IP3R, and each isoform was distributed throughout the cell. These cells did not express the ryanodine receptor. Photorelease of microinjected, caged IP3 induced a rapid rise in cytosolic Ca2+, but the increase began uniformly throughout the cell rather than at a specific initiation site. Expression of protein 4.1N was not associated with redistribution of the IP3R or changes in Ca2+-signaling patterns. These findings are consistent with the hypothesis that the subcellular distribution of IP3R isoforms regulates the formation of Ca2+ waves, and the finding that interactions between protein 4.1N and the IP3R vary among cell types may provide an additional, tissue-specific mechanism to shape the pattern of Ca2+ waves.     

G protein-dependent Ca2+ signaling complexes in polarized cells

Polarized cells signal in a polarized manner. This is exemplified in the patterns of [Ca2+]i waves and [Ca2+]i oscillations evoked by stimulation of G protein-coupled receptors in these cells. Organization of Ca(2+)-signaling complexes in cellular microdomains, with the aid of scaffolding proteins, is likely to have a major role in shaping G protein-coupled [Ca2+]i signal pathways. In epithelial cells, these domains coincide with sites of [Ca2+]i-wave initiation and local [Ca2+]i oscillations. Cellular microdomains enriched with Ca(2+)-signaling proteins have been found in several cell types. Microdomains organize communication between Ca(2+)-signaling proteins in the plasma membrane and internal Ca2+ stores in the endoplasmic reticulum through the interaction between the IP3 receptors in the endoplasmic reticulum and Ca(2+)-influx channels in the plasma membrane. Ca2+ signaling appears to be controlled within the receptor complex by the regulators of G protein-signaling (RGS) proteins. Three domains in RGS4 and related RGS proteins contribute important regulatory features. The RGS domain accelerates GTP hydrolysis on the G alpha subunit to uncouple receptor stimulation from IP3 production; the C-terminus may mediate interaction with accessory proteins in the complex; and the N-terminus acts in a receptor-selective manner to confer regulatory specificity. Hence, RGS proteins have both catalytic and scaffolding function in Ca2+ signaling. Organization of Ca(2+)-signaling proteins into complexes within microdomains is likely to play a prominent role in the localized control of [Ca2+]i and in [Ca2+]i oscillations.     

The yeast Ca(2+)-ATPase homologue, PMR1, is required for normal Golgi function and localizes in a novel Golgi-like distribution.

PMR1, a Ca(2+)-adenosine triphosphatase (ATPase) homologue in the yeast Saccharomyces cerevisiae localizes to a novel Golgi-like organelle. Consistent with a Golgi localization, the bulk of PMR1 comigrates with Golgi markers in subcellular fractionation experiments, and staining of PMR1 by indirect immunofluorescence reveals a punctate pattern resembling Golgi staining in yeast. However, PMR1 shows only partial colocalization with known Golgi markers, KEX2 and SEC7, in double-label immunofluorescence experiments. The effect of PMR1 on Golgi function is indicated by pleiotropic defects in various Golgi processes in pmr1 mutants, including impaired proteolytic processing of pro-alpha factor and incomplete outer chain glycosylation of invertase. Consistent with the proposed role of PMR1 as a Ca2+ pump, these defects are reversed by the addition of millimolar levels of extracellular Ca2+, suggesting that Ca2+ disposition is essential to normal Golgi function. Absence of PMR1 function partially suppresses the temperature-sensitive growth defects of several sec mutants, and overexpression of PMR1 restricts the growth of others. Some of these interactions are modulated by changes in external Ca2+ concentrations. These results imply a global role for Ca2+ in the proper function of components governing transit and processing through the secretory pathway.     

MID1, a novel Saccharomyces cerevisiae gene encoding a plasma membrane protein,is required for Ca2+ influx and mating.

By establishing a unique screening method, we have isolated yeast mutants that die only after differentiating into cells with a mating projection, and some of them are also defective in Ca2+ signaling. The mutants were classified into five complementation groups, one of which we studied extensively. This mutation defines a new gene, designated MID1, which encodes an N-glycosylated, integral plasma membrane protein with 548 amino acid residues. The mid1-1 mutant has low Ca2+ uptake activity, loses viability after receiving mating pheromones, and escapes death when incubated with high concentrations of CaCl2. The MID1 gene is nonessential for vegetative growth. The efficiency of mating between MATa mid1-1 and MAT alpha mid1-1 cells is low. These results demonstrate that MID1 is required for Ca2+ influx and mating.     

Identification of Saccharomyces cerevisiae Tub1 alpha-tubulin as a potential target for NKH-7, a cytotoxic 1-naphthol derivative compound

In a screening for small-molecule compounds that alleviate the deleterious effects of external CaCl(2) on zds1 Delta strain yeast, we found 2-((1-(hydroxymethyl) cyclohexyl) methyl) naphthalen-1-ol (NKH-7) to be an active compound. NKH-7 also inhibited cell growth at higher concentrations. To identify its target in growth inhibition, we isolated NKH-7-resistant mutants and selected those mutants that exhibited dominant or semi-dominant resistance specifically to NKH-7. By gene cloning, a TUB1 mutant gene encoding alpha-tubulin with a Ser248Pro mutation was identified. Deletion of the TUB3 gene, a minor gene encoding alpha-tubulin, led to supersensitivity to NKH-7. Cellular tubulin-containing arrays as visualized by green fluorescent protein (GFP)-labeled alpha-tubulin diminished rapidly on exposure to the inhibitor. The mutation was situated proximal to the alpha-beta interface of alpha-tubulin in microtubule protofilaments, suggesting the possibility that NKH-7 affects the hydrolysis of GTP bound to beta-tubulin. A functional connection perhaps exists between the tubulin inhibition and Ca(2+)-dependent cell-cycle regulation.     

Xenon induces metaphase arrest in rat astrocytes.

The use of xenon as an almost ideal anesthetic with very little side effects is gaining clinical acceptance, yet its effects on the cellular level are still unclear. It affects intracellular Ca2+-homeostasis but up to now no cellular event or Ca2+-signaling system has been described to be specifically sensitive to xenon. Here we report for the first time a specific effect of xenon on astroglial cells not found with another volatile anesthetic, isoflurane, nor with helium nor with N2: treatment of primary astroglial cells from embryonic rat brain with xenon induces, apart from a slight retardation of the cell cycle, a block at metaphase. Upon removal of xenon cells arrested at metaphase complete their mitosis normally. Even under continuous exposure to xenon, cells can be rescued from metaphase arrest by a small and transient increase in intracellular Ca2+; cells enter anaphase despite the presence of xenon and complete cell division, exhibiting normal rate of chromosome movement and normal chromosome separation. These results suggest that xenon interferes with some Ca2+-dependent regulatory system required for the metaphase-anaphase transition; taking into account its anesthetic effects, xenon may be also involved in the control of glia-mediated signaling transfer.     

AMPA glutamate receptor-mediated calcium signaling is transiently enhanced during development of oligodendrocytes

Cells of the oligodendroglial lineage express Ca2+-permeable alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate-preferring glutamate receptors (AMPA-GluR) during development. Prolonged activation of their AMPA-GluR causes Ca2+ overload, resulting in excitotoxic death. Prior studies have shown that oligodendroglial progenitors and immature oligodendrocytes are susceptible to excitotoxicity, whereas mature oligodendrocytes are resistant. An unresolved issue has been why Ca2+-permeability of AMPA-GluR varies so markedly with oligodendroglial development, although the level of expression of edited GluR2, an AMPA-GluR subunit which blocks Ca2+ entry, is relatively constant. To address this question, we performed Ca2+ imaging, molecular and electrophysiological analyses using purified cultures of the rat oligodendroglial lineage. We demonstrate that transient up-regulation of expression of GluR3 and GluR4 subunits in oligodendroglial progenitors and immature oligodendrocytes results in the assembly by these cells, but not by oligodendroglial pre-progenitors or mature oligodendrocytes, of a population of AMPA-GluR which lack GluR2. This stage-specific up-regulation of edited GluR2-free, and hence Ca2+-permeable, AMPA-GluR explains the selective susceptibility to excitotoxicity of cells at these stages of oligodendroglial differentiation, and is likely to be important to these cells in the trans-synaptic Ca2+-signaling from glutamatergic neurons, which occurs in hippocampus     

The product of HUM1, a novel yeast gene, is required for vacuolar Ca2+/H+ exchange and is related to mammalian Na+/Ca2+ exchangers.

Calcineurin, or PP2B, plays a critical role in mediating Ca2+-dependent signaling in many cell types. In yeast cells, this highly conserved protein phosphatase regulates aspects of ion homeostasis and cell wall synthesis. We show that calcineurin mutants are sensitive to high concentrations of Mn2+ and identify two genes, CCC1 and HUM1, that, at high dosages, increase the Mn2+ tolerance of calcineurin mutants. CCC1 was previously identified by complementation of a Ca2+-sensitive (csg1) mutant. HUM1 (for "high copy number undoes manganese") is a novel gene whose predicted protein product shows similarity to mammalian Na+/Ca2+ exchangers. hum1 mutations confer Mn2+ sensitivity in some genetic backgrounds and exacerbate the Mn2+ sensitivity of calcineurin mutants. Furthermore, disruption of HUM1 in a calcineurin mutant strain results in a Ca2+-sensitive phenotype. We investigated the effect of disrupting HUM1 in other strains with defects in Ca2+ homeostasis. The Ca2+ sensitivity of pmc1 mutants, which lack a P-type ATPase presumed to transport Ca2+ into the vacuole, is exacerbated in a hum1 mutant strain background. Also, the Ca2+ content of hum1 pmc1 cells is less than that of pmc1 cells. In contrast, the Ca2+ sensitivity of vph1 mutants, which are specifically defective in vacuolar acidification, is not significantly altered by disruption of Hum1p function. These genetic interactions suggest that Hum1p may participate in vacuolar Ca2+/H+ exchange. Therefore, we prepared vacuolar membrane vesicles from wild-type and hum1 cells and compared their Ca2+ transport properties. Vacuolar membrane vesicles from hum1 mutants lack all Ca2+/H+ antiport activity, demonstrating that Hum1p catalyzes the exchange of Ca2+ for H+ across the yeast vacuolar membrane.     

Calcineurin-dependent growth control in Saccharomyces cerevisiae mutants lacking PMC1, a homolog of plasma membrane Ca2+ ATPases

Ca2+ ATPases deplete the cytosol of Ca2+ ions and are crucial to cellular Ca2+ homeostasis. The PMC1 gene of Saccharomyces cerevisiae encodes a vacuole membrane protein that is 40% identical to the plasma membrane Ca2+ ATPases (PMCAs) of mammalian cells. Mutants lacking PMC1 grow well in standard media, but sequester Ca2+ into the vacuole at 20% of the wild-type levels. pmc1 null mutants fail to grow in media containing high levels of Ca2+, suggesting a role of PMC1 in Ca2+ tolerance. The growth inhibitory effect of added Ca2+ requires activation of calcineurin, a Ca2+ and calmodulin-dependent protein phosphatase. Mutations in calcineurin A or B subunits or the inhibitory compounds FK506 and cyclosporin A restore growth of pmc1 mutants in high Ca2+ media. Also, growth is restored by recessive mutations that inactivate the high-affinity Ca(2+)-binding sites in calmodulin. This mutant calmodulin has apparently lost the ability to activate calcineurin in vivo. These results suggest that activation of calcineurin by Ca2+ and calmodulin can negatively affect yeast growth. A second Ca2+ ATPase homolog encoded by the PMR1 gene acts together with PMC1 to prevent lethal activation of calcineurin even in standard (low Ca2+) conditions. We propose that these Ca2+ ATPase homologs are essential in yeast to deplete the cytosol of Ca2+ ions which, at elevated concentrations, inhibits yeast growth through inappropriate activation of calcineurin.     

The Yersinia pestis V antigen is a regulatory protein necessary for Ca2(+)-dependent growth and maximal expression of low-Ca2+ response virulence genes.

The low-Ca2+ response is a multicomponent virulence regulon of the human-pathogenic yersiniae in which 12 known virulence genes are coordinately regulated in response to environmental cues of temperature, Ca2+, and nucleotides such as ATP. Yersinial growth also is regulated, with full growth yield being permitted at 37 degrees C only if Ca2+ or a nucleotide is present. In this study, we constructed and characterized a mutant Yersinia pestis specifically defective in the gene encoding the V antigen, one of the virulence genes of the low-Ca2+ response. An in-frame internal deletion-insertion mutation was made by removing bases 51 through 645 of lcrV and inserting 61 new bases. The altered lcrV was introduced into the low-Ca2+ response plasmid in Y. pestis by allelic exchange, and the resulting mutant was characterized for its two-dimensional protein profiles, growth, expression of an operon fusion to another low-Ca2+ response virulence operon, and virulence in mice. The mutant had lost its Ca2+ and nucleotide requirement for growth, showed diminished expression of Ca2(+)-and nucleotide-regulated virulence genes, and was avirulent in mice. The mutation could be complemented with respect to the growth property by supplying native V antigen operon sequences in trans in high copy number (on pBR322). Partial complementation of the growth defect and almost complete complementation of the virulence defect were seen with a lower-copy-number complementing replicon (a pACYC184 derivative). The data are consistent with the interpretation that V antigen is bifunctional, with a role in regulating growth and expression of low-Ca2+ response virulence genes in addition to its putative role as a secreted virulence protein.     

Regulation of K+ transport in tomato roots by the TSS1 locus. Implications in salt tolerance

The tss1 tomato (Lycopersicon esculentum) mutant exhibited reduced growth in low K+ and hypersensitivity to Na+ and Li+. Increased Ca2+ in the culture medium suppressed the Na+ hypersensitivity and the growth defect on low K+ medium of tss1 seedlings. Interestingly, removing NH4+ from the growth medium suppressed all growth defects of tss1, suggesting a defective NH4(+)-insensitive component of K+ transport. We performed electrophysiological studies to understand the contribution of the NH4(+)-sensitive and -insensitive components of K+ transport in wild-type and tss1 roots. Although at 1 mm Ca2+ we found no differences in affinity for K+ uptake between wild type and tss1 in the absence of NH4+, the maximum depolarization value was about one-half in tss1, suggesting that a set of K+ transporters is inactive in the mutant. However, these transporters became active by raising the external Ca2+ concentration. In the presence of NH4+, a reduced affinity for K+ was observed in both types of seedlings, but tss1 at 1 mm Ca2+ exhibited a 2-fold higher Km than wild type did. This defect was again corrected by raising the external concentration of Ca2+. Therefore, membrane potential measurements in root cells indicated that tss1 is affected in both NH4(+)-sensitive and -insensitive components of K+ transport at low Ca2+ concentrations and that this defective transport is rescued by increasing the concentration of Ca2+. Our results suggest that the TSS1 gene product is part of a crucial pathway mediating the beneficial effects of Ca2+ involved in K+ nutrition and salt tolerance.     

N-acetyl-sphingenine-1-phosphate is a potent calcium mobilizing agent.

Calcium mobilization induced by phosphorylated sphingoid bases was analyzed in calf pulmonary artery endothelial cells by confocal microscopy. A sphingenine-1-phosphate (SeP) analogue, N-acetyl-sphingenine-1-phosphate (N-C2-SeP), exogenously added to these cells, caused a fast and transient intracellular rise in calcium and was as potent as SeP. A minimal concentration of 0.6 nM for N-C2-SeP versus 1 nM for SeP was determined. The N-C2-SeP-induced Ca2+-signaling, like the response to SeP, was due to a release from thapsigargin-sensitive, ryanodine-insensitive, intracellular Ca2+-stores and not to a Ca2+-influx. N-C2-SeP can be considered as a truncated ceramide-phosphate, a lipid already reported to be mitogenic (Gomez-Munoz, A., Duffy, P.A., Martin, A., O'Brien, L., Byun, H.S., Bittman, R. and Brindley, D.N. (1995) Mol. Pharmacol. 47, 833-839), an effect that might be secondary to Ca2+-mobilization.