Calcium protects differentiating neuroblastoma cells during 50 Hz electromagnetic radiation.

Despite growing concern about electromagnetic radiation, the interaction between 50- to 60-Hz fields and biological structures remains obscure. Epidemiological studies have failed to prove a significantly correlation between exposure to radiation fields and particular pathologies. We demonstrate that a 50- to 60-Hz magnetic field interacts with cell differentiation through two opposing mechanisms: it antagonizes the shift in cell membrane surface charges that occur during the early phases of differentiation and it modulates hyperpolarizing K channels by increasing intracellular Ca. The simultaneous onset of both mechanisms prevents alterations in cell differentiation. We propose that cells are normally protected against electromagnetic insult. Pathologies may arise, however, if intracellular Ca regulation or K channel activation malfunctions.

The presence of NHE1 and NHE3 Na+-H+ exchangers and an apical cAMP-independent Cl- channel indicate that both absorptive and secretory functions are present in calf gall bladder epithelium.

We investigated the transport systems that can sustain Na+ and Cl- movements across bovine gall bladder epithelium, focusing on the Na+-H+ exchanger (NHE) family and chloride conductive pathways. Experiments conducted using the fluorescent probe acridine orange (AO) with brush-border membrane vesicles (BBMV) or vesicles obtained from the total epithelium (EMV) demonstrated the presence of a Na+-H+ exchange in both preparations. The use of specific inhibitors indicated the presence of an apical NHE3 exchanger and a NHE1 isoform which should reside in the basolateral membrane. Using reverse transcriptase (RT) PCR, we identified cDNA fragments corresponding to the NHE1, NHE3, Cl--HCO3- (AE2a) transporters and to the CFTR channel. Using the patch-clamp technique, we investigated Cl- conductances on cultured epithelial cells. We found a 5 pS Cl- channel with a voltage-independent open probability, insensitive to stilbenes (SITS), Zn2+ and cAMP. The results suggest that absorption and secretion coexist in calf gall bladder epithelium. A Na+-H+-Cl--HCO3- double exchange may, at least partially, sustain the absorptive function, and a Cl- apical conductive pathway may be involved in secretion. The conductance we observed does not seem to be cAMP-regulated, unlike other mammalian gall bladders.

Nucleocytoplasmic distribution of budding yeast protein kinase A regulatory subunit Bcy1 requires Zds1 and is regulated by Yak1-dependent phosphorylation of its targeting domain.

In Saccharomyces cerevisiae the subcellular distribution of Bcy1 is carbon source dependent. In glucose-grown cells, Bcy1 is almost exclusively nuclear, while it appears more evenly distributed between nucleus and cytoplasm in carbon source-derepressed cells. Here we show that phosphorylation of its N-terminal domain directs Bcy1 to the cytoplasm. Biochemical fractionation revealed that the cytoplasmic fraction contains mostly phosphorylated Bcy1, whereas unmodified Bcy1 is predominantly present in the nuclear fraction. Site-directed mutagenesis of two clusters (I and II) of serines near the N terminus to alanine resulted in an enhanced nuclear accumulation of Bcy1 in ethanol-grown cells. In contrast, substitutions to Asp led to a dramatic increase of cytoplasmic localization in glucose-grown cells. Bcy1 modification was found to be dependent on Yak1 kinase and, consequently, in ethanol-grown yak1 cells the Bcy1 remained nuclear. A two-hybrid screen aimed to isolate genes encoding proteins that interact with the Bcy1 N-terminal domain identified Zds1. In ethanol-grown zds1 cells, cytoplasmic localization of Bcy1 was largely absent, while overexpression of ZDS1 led to increased cytoplasmic Bcy1 localization. Zds1 does not regulate Bcy1 modification since this was found to be unaffected in zds1 cells. However, in zds1 cells cluster II-mediated, but not cluster I-mediated, cytoplasmic localization of Bcy1 was found to be absent. Altogether, these results suggest that Zds1-mediated cytoplasmic localization of Bcy1 is regulated by carbon source-dependent phosphorylation of cluster II serines, while cluster I acts in a Zds1-independent manner.

Phosphorylation of Cdc28 and regulation of cell size by the protein kinase CKII in Saccharomyces cerevisiae.

The CDK (cyclin-dependent kinase) family of enzymes is required for the G(1)-to-S-phase and G(2)-to-M-phase transitions during the cell-division cycle of eukaryotes. We have shown previously that the protein kinase CKII catalyses the phosphorylation of Ser-39 in Cdc2 during the G(1) phase of the HeLa cell-division cycle [Russo, Vandenberg, Yu, Bae, Franza and Marshak (1992) J. Biol. Chem. 267, 20317-20325]. To identify a functional role for this phosphorylation, we have studied the homologous enzymes in the budding yeast Saccharomyces cerevisiae. The S. cerevisiae homologue of Cdc2, Cdc28, contains a consensus CKII site (Ser-46), which is homologous with that of human Cdc2. Using in vitro kinase assays, metabolic labelling, peptide mapping and phosphoamino acid analysis, we demonstrate that this site is phosphorylated in Cdc28 in vivo as well in vitro. In addition, S. cerevisiae cells in which Ser-46 has been mutated to alanine show a decrease in both cell volume and protein content of 33%, and this effect is most pronounced in the stationary phase. Because cell size in S. cerevisiae is regulated primarily at the G(1) stage, we suggest that CKII contributes to the regulation of the cell cycle in budding yeast by phosphorylation of Cdc28 as a checkpoint for G(1) progression.

Two and three-color fluorescence flow cytometric analysis of immunoidentified viable bacteria.

BACKGROUND: Traditional culture methods well established in the past and still in use are not able to detect the environmental microorganisms that exist in a viable but not culturable state. A number of different fluorescence-based assays have been developed over the past decade to detect and identify viable bacteria in the environment. METHODS: We have developed a simple and rapid method for measuring the number and viability of immunolabeled bacteria by means of a two/three color fluorescence flow cytometric analysis. After washing, cultured bacteria in suspension were labeled with a rabbit polyclonal antibody recognizing the wall lipopolysaccharide complex. A secondary biotinylated anti-rabbit polyclonal antibody was added allowing the cells to be labeled with the streptavidin R-phycoerythrin-Cyanine 5 (RPE-Cy5) fluorochrome. Before flow cytometric analysis, bacterial suspensions were stained with SYBR Green I and propidium iodide which stain all of the cells and the non viable ones, respectively. RESULTS AND CONCLUSIONS: With the appropriate filter sets of both Bryte-HS (Bio-Rad, Hercules, CA) and FACScan (Becton Dickinson, San Jose, CA) flow cytometers, the measurement of separated green (SYBR Green I), orange-red (propidium iodide), and far red (RPE-Cy5) fluorescence was possible, allowing the enumeration of viable immunodetected bacteria. The entire protocol is completed in less than 3 h, offering numerous possibilities for rapid and precise analyses in sanitary, industrial, and environmental microbiology.

Apical Na+-Cl- symport in rabbit gallbladder epithelium: a thiazide-sensitive cotransporter (TSC).

Cl- apically enters the epithelium of rabbit gallbladder by a Na+-Cl- symport, sensitive to hydrochlorothiazide (HCTZ). Since HCTZ also activates an apical SITS-sensitive Cl- conductance (G(Cl)), the symport inhibition might be merely due to a short circuit of the symport by G(Cl) rather than to a direct action of HCTZ on the symporter. To examine whether the symport is directly inhibited by HCTZ and whether the symporter belongs to the family of thiazide-sensitive cotransporters (TSC), radiochemical measurements of the apical Cl- uptake, electrophysiological determinations of intracellular Cl- and Na+ activities (a(i,Cl) and a(i,Na)) with selective theta microelectrodes and molecular biology methods were used. The 13Cl- uptake proved to be a measurement of the apical unidirectional Cl- influx (Jmc) and of the symport only (without backflux components), with measuring times of 45 sec under all experiment conditions; its inhibition by HCTZ was unaffected by G(Cl) activation or abolition. After HCTZ treatment the decrease in a(i,Cl) (measured as the initial rate or in 3 min) was larger than the decrease in a(i,Na). The difference was reduced to one third in a group of epithelia in which the elicited G(Cl) was reduced to one third; moreover it was abolished in any case when G(Cl) was abolished with 10(-4) M SITS. The SITS-insensitive rate of a(i,Cl) decrease was equal to that of the a(i,Na) decrease in any case. Thus the a(i,Cl) decrease displays a component dependent on G(Cl) activation and a second component dependent on symport inhibition. Using the RT-PCR technique a cDNA fragment was obtained that was 99% identical to the corresponding region of the rabbit renal TSC isoform. The results indicate that in rabbit gallbladder epithelium HCTZ displays a dual action, namely G(Cl) activation and Na+-Cl- symport inhibition. This Na+-Cl- symporter is the first TSC found to be functionally expressed in a nonrenal or nonrenal-like epithelium.

Nutritional control of nucleocytoplasmic localization of cAMP-dependent protein kinase catalytic and regulatory subunits in Saccharomyces cerevisiae.

In budding yeast, cAMP-dependent protein kinase (PKA) plays a central role in the nutritional control of metabolism, cell cycle, and transcription. This study shows that both the regulatory subunit Bcy1p and the catalytic subunit Tpk1p associated with it are predominantly localized in the nucleus of rapidly growing cells. Activation of nuclear PKA by cAMP leads to fast entry of a significant part of Tpk1p into the cytoplasm, while the regulatory subunit remains nuclear. In contrast to rapidly proliferating cells, both Bcy1p and Tpk1p are distributed over nucleus and cytoplasm in cells growing on a nonfermentable carbon source or in stationary phase cells. These results demonstrate that at least two different mechanisms determine the subcellular localization of PKA; cAMP controls the localization of Tpk1p, and the carbon source determines that of Bcy1p. The N-terminal domain of Bcy1p serves to target it properly during logarithmic and stationary phase. Studies with Bcy1p mutant versions unable to concentrate in the nucleus revealed that cells producing them are less viable in stationary phase than wild type cells, display delayed reproliferation following transfer to fresh growth medium, and, as diploids, exhibit reduced efficiency of sporulation.

Chromosome separation and exit from mitosis in budding yeast: dependence on growth revealed by cAMP-mediated inhibition.

Cell cycle progression of somatic cells depends on net mass accumulation. In Saccharomyces cerevisiae the cAMP-dependent kinases (PKAs) promote cytoplasmic growth and modulate the growth-regulated mechanism triggering the begin of DNA synthesis. By altering the cAMP signal in budding yeast cells we show here that mitotic events can also depend on growth. In fact, the hyperactivation of PKAs permanently inhibited both anaphase and exit from mitosis when cell growth was repressed. In S. cerevisiae the anaphase promoting complex (APC) triggers entry into anaphase by mediating the degradation of Pds1p. The cAMP pathway activation was lethal together with a partial impairment of the Cdc16p APC subunit, causing a preanaphase arrest, and conversely low PKA activity suppressed the lethality of cdc16-1 cells. Deregulated PKAs partially prevented the decrease of Pds1p intracellular levels concomitantly with the anaphase inhibition, and the PKA-dependent preanaphase arrest could be suppressed in pds1(-) cells. Thus, the cAMP pathway and APC functionally interact in S. cerevisiae and Pds1p is required for the cAMP-mediated inhibition of chromosome separation. Exit from mitosis requires APC, Cdc15p, and the polo-like Cdc5p kinase. PKA hyperactivation and a cdc15 mutation were synthetically lethal and brought to a telophase arrest. Finally, a low cAMP signal allowed cell division at a small cell size and suppressed the lethality of cdc15-2 or cdc5-1 cells. We propose that mitosis progression and the M/G1 phase transition specifically depend on cell growth through a mechanism modulated by PKAs and interacting with the APC/CDC15/CDC5 mitotic system. A possible functional antagonism between PKAs and the mitosis promoting factor is also discussed.

Repression of growth-regulated G1 cyclin expression by cyclic AMP in budding yeast.

A yeast cell becomes committed to the cell division cycle only if it grows to a critical size and reaches a critical rate of protein synthesis. The coordination between growth and division takes place at a control step during the G1 phase of the cell cycle called Start. It relies on the G1-specific cyclins encoded by CLN1, 2 and 3, which trigger Start through the activation of the Cdc28 protein kinase. In fact, the Cln cyclins are rate-limiting for Start execution and depend on growth. Here we report that the cyclic AMP signal pathway modulates the dependency of Cln cyclins on growth. In particular, more growth is required to trigger Start because CLN1 and CLN2 are repressed by the cAMP signal, thus explaining the previously observed cAMP-dependent increase of the critical size and critical rate of protein synthesis. Cln3 is not inhibited by the cAMP pathway and counteracts this mechanism by partially mediating the growth-dependent expression of other G1 cyclins.

Cell cycle and growth regulation in RAS2 mutant cells of Saccharomyces cerevisiae.

Yeast cells carrying ras2 temperature-sensitive mutations undergo a specific arrest in the prereplicative unbudded phase of the cell cycle when they are shifted to non-permissive temperatures. At 36.5 degrees C, in spite of their abnormally large cell size, bulk protein synthesis and accumulation rates are depressed in ras2 temperature-sensitive cells in comparison with isogenic wild type. At the same temperature, total RNA synthesis and accumulation rates are much more inhibited, suggesting that a defective Ras2/cAMP pathway alters the coordination between RNA and protein synthesis rates. The preferential RNA synthesis inhibition is correlated to a specific inhibition of the synthesis of the 35S rRNA precursor. These findings, taken together with the results of previous analyses, are in favour of a control by the cAMP pathway on rRNA biosynthesis.

cAMP-mediated increase in the critical cell size required for the G1 to S transition in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, cyclic AMP is required for cellular growth. In this study we show that cAMP also specifically inhibits the G1-S transition of the S. cerevisiae cell cycle by increasing the critical cell size required at start, the major yeast cell cycle control step. In fact: (a) addition of cAMP delays the time of entering into the S budded phase of small G1 cells, while it is ineffective on large fast-growing cells. (b) If cell growth is strongly depressed, cAMP permanently inhibits cell cycle commitment of cells arrested at the alpha-factor-sensitive step. The cell fraction inhibited by cAMP is inversely correlated with the average cell size of treated populations. (c) The critical protein content (Ps) and the critical cell volume (VB) required for budding in unperturbed exponentially growing yeast populations are largely increased by cAMP. On these bases, we propose a new cAMP role at start.

In vitro interaction between Saccharomyces cerevisiae CDC25 and RAS2 proteins.

In Saccharomyces cerevisiae the CDC25 protein is a positive regulator of RAS/cAMP pathway [1-4], enhancing the GDP-releasing rate of RAS2 protein [5]. In this work we have tried to detect a direct interaction between CDC25 and RAS2 gene products. The results indicate that both the whole RAS2 protein and a truncated version that lacks approximately 25 C-terminal residues interact specifically with the CDC25 protein. On the contrary, a derivative of RAS2 that lacks the 112 C-terminal residues as well as the p21TI-ras is not able to bind the CDC25 protein in our assay conditions. The 310 C-terminal aminoacids of CDC25 bind RAS2 while a C-terminus deletion within this aminoacid stretch abolishes the binding. The possible physiological significance of these findings is discussed.

Cell size modulation by CDC25 and RAS2 genes in Saccharomyces cerevisiae.

A detailed kinetic analysis of the cell cycle of cdc25-1, RAS2Val-19, or cdc25-1/RAS2Val-19 mutants during exponential growth is presented. At the permissive temperature (24 degrees C), cdc25-1 cells show a longer G1/unbudded phase of the cell cycle and have a smaller critical cell size required for budding without changing the growth rate in comparison to an isogenic wild type. The RAS2Val-19 mutation efficiently suppresses the ts growth defect of the cdc25-1 mutant at 36 degrees C and the increase of G1 phase at 24 degrees C. Moreover, it causes a marked increase of the critical cell mass required to enter into a new cell division cycle compared with that of the wild type. Since the critical cell mass is physiologically modulated by nutritional conditions, we have also studied the behavior of these mutants in different media. The increase in cell size caused by the RAS2Val-19 mutation is evident in all tested growth conditions, while the effect of cdc25-1 is apparently more pronounced in rich culture media. CDC25 and RAS2 gene products have been showed to control cell growth by regulating the cyclic AMP metabolic pathway. Experimental evidence reported herein suggests that the modulation of the critical cell size by CDC25 and RAS2 may involve adenylate cyclase.