RalGPS2 is involved in tunneling nanotubes formation in 5637 bladder cancer cells.

RalGPS2 is a Ras-independent Guanine Nucleotide Exchange Factor (GEF) for RalA containing a PH domain and an SH3-binding region and it is involved in several cellular processes, such as cytokinesis, control of cell cycle progression, differentiation, cytoskeleton organization and rearrangement. Up to now, few data have been published regarding RalGPS2 role in cancer cells, and its involvement in bladder cancer is yet to be established. In this paper we demonstrated that RalGPS2 is expressed in urothelial carcinoma-derived 5637 cancer cells and is essential for cellular growth. These cells produces thin membrane protrusions that displayed the characteristics of actin rich tunneling nanotubes (TNTs) and here we show that RalGPS2 is involved in the formation of these cellular protrusions. In fact the overexpression of RalGPS2 or of its PH-domain increased markedly the number and the length of nanotubes, while the knock-down of RalGPS2 caused a strong reduction of these structures. Moreover, using a series of RalA mutants impaired in the interaction with different downstream components (Sec5, Exo84, RalBP1) we demonstrated that the interaction of RalA with Sec5 is required for TNTs formation. Furthermore, we found that RalGPS2 interacts with the transmembrane MHC class III protein leukocyte specific transcript 1 (LST1) and RalA, leading to the formation of a complex which promotes TNTs generation. These findings allow us to add novel elements to molecular models that have been previously proposed regarding TNTs formation.

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.

The brain specific Ras exchange factor CDC25 Mm: modulation of its activity through Gi-protein-mediated signals.

CDC25Mm is a mouse guanine nucleotide exchange factor specific for Ras, exclusively expressed in the brain. We used a reporter gene containing a Ras-responsive fos-promoter in order to gain information on the role played by this exchange factor in signal transduction. Transient expression of CDC25Mm in CHO cells activates Ras. Moreover serum, but not insulin, can upregulate the response mediated by CDC25Mm and this modulation requires that the CDC25Mm maintains its N-terminal region. NIH3T3 fibroblasts, stably overexpressing this exchange factor, show a partially transformed phenotype, suggesting that the Ras-dependent pathway is constitutively active. In these cells serum and lysophosphatidic acid (LPA) stimulate Ras activity above the basal level while PDGF does not. Both serum and LPA-induced Ras activations in CDC25Mm overexpressing cells can be completely inhibited by pertussis toxin. Moreover, these responses are strongly reduced by coexpression of a truncated version of CDC25Mm lacking the C-terminal catalytic portion. This construct behaves in a dominant negative manner suggesting that it may compete with CDC25Mm by sequestering in an unproductive way signalling components activated by these factors. The data presented indicate that CDC25Mm does not participate in connecting tyrosine kinase receptors with Ras, while it could mediate Ras activation induced by pertussis toxin sensitive Gi-coupled receptors.

Posttranscriptional regulation of the expression of MET2 gene of Saccharomyces cerevisiae.

The first step of the specific pathway for methionine biosynthesis in the yeast Saccharomyces cerevisiae is catalyzed by the enzyme L-homoserine-O-acetyltransferase (HSTase) (EC 2.3.1.31), encoded by the MET2 gene. In order to ascertain whether there is a posttranscriptional control on the MET2 gene expression, as suggested by previous results on the expression of the cloned gene, systems for high inducible expression of MET2 gene were constructed. In these constructs the MET2 gene was cloned in yeast expression vectors under the control of an inducible yeast GAL promoter element so that the MET2 was transcribed at very high levels under induced conditions. Measurements of the specific mRNA levels showed a strong stimulation of MET2 gene transcription in yeast transformants grown on galactose as carbon source, corresponding to 50-100-fold the repressed conditions, while only a 2-fold increase of the enzymatic activity was observed. In addition, no evidence of a strong induced polypeptide of appropriate size on two dimensional gel electrophoresis was obtained. To understand the functional role of the non-coding 5' region of MET2 mRNA, we performed either a partial and a complete deletion of the 5' leader sequence, but even with these constructs an elevated mRNA level was not associated to a marked increase of the HSTase activity. These data support the idea of a posttranscriptional regulation of MET2 gene expression and show that the untranslated region of the specific mRNA is not involved in this regulatory mechanism.

Reduction of ribosome activity and synthesis of stable RNA in Neurospora crassa.

The addition of cycloheximide (0.02 micrograms/ml) to exponentially growing cultures of Neurospora crassa causes a reduction in growth rate and a decrease in the rate of protein accumulation, due to a partial inhibition of protein synthesis, while RNA accumulation is unaffected for about 1 h. Thus, an increased RNA:protein ratio is established in the presence of the inhibitor. RNA that accumulates during treatment with cycloheximide has the same characteristics as that of the control cultures and this, together with the enhancement of the relative rate of synthesis of ribosomal proteins induced by cycloheximide, seems to indicate that more mature ribosomes are present in cycloheximide-treated cultures. The endocellular level of several amino acids begins to increase significantly only 60 min after cycloheximide addition. A possible explanation of the stimulation of ribosome production induced by cycloheximide is given in terms of the existence of a feed-back mechanism controlling ribosome synthesis.

Role of guanine nucleotides in the regulation of the Ras/cAMP pathway in Saccharomyces cerevisiae.

The CDC25 gene product is a guanine nucleotide exchange factor for Ras proteins in yeast. Recently it has been suggested that the intracellular levels of guanine nucleotides may influence the exchange reaction. To test this hypothesis we measured the levels of nucleotides in yeast cells under different growth conditions and the relative amount of Ras2-GTP. The intracellular GTP/GDP ratio was found to be very sensitive to growth conditions: the ratio is high, close to that of ATP/ADP during exponential growth, but it decreases rapidly before the beginning of stationary phase, and it drops further under starvation conditions. The addition of glucose to glucose-starved cells causes a fast increase of the GTP/GDP ratio. The relative amount of Ras2-GTP changes in a parallel way suggesting that there is a correlation with the cytosolic GTP/GDP ratio. In addition 'in vitro' mixed-nucleotide exchange experiments done on purified Ras2 protein demonstrated that the GTP and GDP concentrations influence the extent of Ras2-GTP loading giving further support to their possible regulatory role.

The overexpression of the 3' terminal region of the CDC25 gene of Saccharomyces cerevisiae causes growth inhibition and alteration of purine nucleotides pools.

The CDC25 gene is transcribed at a very low level in S. cerevisiae cells. We have studied the effects of an overexpression of this regulatory gene by cloning either the whole CDC25 open reading frame (pIND25-2 plasmid) or its 3' terminal portion (pIND25-1 plasmid) under the control of the inducible strong GAL promoter. The strain transformed with pIND25-2 produced high levels of CDC25 specific mRNA, induced by galactose. This strain does not show any apparent alteration of growth, both in glucose and in galactose. Instead the yeast cells transformed with pIND25-1, that overexpress the 3' terminal part of CDC25 gene, grow very slowly in galactose medium, while they grow normally in glucose medium. The nucleotides were extracted from transformed cells, separated by HPLC and quantitated. The ATP/ADP and GTP/GDP ratios were almost identical in control and in pIND25-2 transformed strains growing in glucose and in galactose, while the strain that overexpresses the 3' terminal portion of CDC25 gene showed a decrease of ATP/ADP ratio and a partial depletion of the GTP pool. The disruption of RAS genes was only partially able to 'cure' this phenotype. A ras2-ts1, ras1::URA3 strain, transformed with pIND25-1 plasmid, was able to grow in galactose at 36 degrees C. These results suggest that the carboxy-terminal domain of the CDC25 protein could stimulate an highly unregulated GTPase activity in yeast cells by interacting not only with RAS gene products but also with some other yeast G-proteins.

Analysis of the secondary structure of the catalytic domain of mouse Ras exchange factor CDC25Mm.

The minimal active domain (GEF domain) of the mouse Ras exchange factor CDC25Mm was purified to homogeneity from recombinant Escherichia coli culture. The 256 amino acids polypeptide shows high activity in vitro and forms a stable complex with H-ras p21 in absence of guanine nucleotides. Circular dichroism (CD) spectra in the far UV region indicate that this domain is highly structured with a high content of alpha-helix (42%). Near UV CD spectra evidenced good signal due to phenylalanine and tyrosine while a poor contribution was elicited by the three tryptophan residues contained in this domain. The tryptophan fluorescence signal was scarcely affected by denaturation of the protein or by formation of the binary complex with H-ras p21, suggesting that the Trp residues, which are well conserved in the GEF domain of several Ras-exchange factors, were exposed to the surface of the protein and they are not most probably directly involved in the interaction with Ras proteins.

The PLC1 encoded phospholipase C in the yeast Saccharomyces cerevisiae is essential for glucose-induced phosphatidylinositol turnover and activation of plasma membrane H+-ATPase.

Addition of glucose to glucose-deprived cells of the yeast Saccharomyces cerevisiae triggers rapid turnover of phosphatidylinositol, phosphatidylinositol-phosphate and phosphatidylinositol 4,5-bisphosphate. Glucose stimulation of PI turnover was measured both as an increase in the specific ratio of 32P-labeling and as an increase in the level of diacylglycerol after addition of glucose. Glucose also causes rapid activation of plasma membrane H+-ATPase. We show that in a mutant lacking the PLC1 encoded phospholipase C, both processes were strongly reduced. Compound 48/80, a known inhibitor of mammalian phospholipase C, inhibits both processes. However, activation of the plasma membrane H+-ATPase is only inhibited by concentrations of compound 48/80 that strongly inhibit phospholipid turnover. Growth was inhibited by even lower concentrations. Our data suggest that in yeast cells, glucose triggers through activation of the PLC1 gene product a signaling pathway initiated by phosphatidylinositol turnover and involved in activation of the plasma membrane H+-ATPase.

Hypotonic stress-induced calcium signaling in Saccharomyces cerevisiae involves TRP-like transporters on the endoplasmic reticulum membrane.

Saccharomyces cerevisiae cells respond to hypotonic stress (HTS) by a cytosolic calcium rise, either generated by an influx of calcium from extracellular medium, when calcium is available, or by a release from intracellular stores in scarcity of extracellular calcium. Calcium release from intracellular compartments is peculiarly inhibited by external calcium in a calcineurin-independent and Cch1-, but not Mid1-, driven manner. HTS-induced calcium release is also negatively regulated by the ER protein Cls2 and involves a poorly characterized protein, FLC2/YAL053W gene product, previously proposed to be required for FAD transport in the ER, albeit, due to its molecular features, it was also previously classified as an ion transporter. A computational analysis revealed that this gene and its three homologs in S. cerevisiae, together with previously identified Schizosaccharomyces pombe pkd2 and Neurospora crassa calcium-related spray protein, belong to a fungal branch of TRP-like ion transporters related to human mucolipin and polycystin 2 calcium transporters. Moreover, disruption of FLC2 gene confers severe sensitivity to Calcofluor white and hyper-activation of the cell wall integrity MAPK cascade, suggesting a role in cell wall maintenance as previously suggested for the fission yeast homolog. Perturbation in cytosolic resting calcium concentration and hyper-activation of calcineurin in exponentially growing cells suggest a role for this transporter in calcium homeostasis in yeast.

The overexpression of the CDC25 gene of Saccharomyces cerevisiae causes a derepression of GAL system and an increase of GAL4 transcription.

The CDC25 gene product is an exchange factor for Ras proteins and it activates the Ras/cAMP pathway in the yeast Saccharomyces cerevisiae. The overexpression of the CDC25 gene in S. cerevisiae cells causes a partial glucose-derepressed phenotype which is particularly evident for expression of invertase. To define domains of Cdc25 protein relevant for this derepression and to test another glucose repressed system, different to invertase, we have overexpressed different regions of the CDC25 gene under the control of a GAL-promoter. We found that a derepression of both GAL regulated promoters and invertase was related to the overexpression of CDC25 regions that contain a functional guanine nucleotide exchange (GEF) domain. The effect on GAL-promoters was particular evident when the CDC25 gene was under the control of a UASgal element and operates at transcriptional level, although a moderate derepression was found also for UASgal/lacZ reporter gene. Finally, the overexpression of the GEF domain of CDC25 also caused an increase in the expression of the GAL4 regulatory gene, while a constitutive activation of the Ras/cAMP pathway did not produce any increase in GAL4 expression. These findings indicate that the overexpression of the catalytic domain of CDC25 gene is necessary and sufficient to give a glucose-derepression of GAL promoters and of invertase. They also suggest that the derepression of GAL promoters occurs through an increase of GAL4 expression in a Ras cAMP independent way.

Molecular cloning and regulation of the expression of the MET2 gene of Saccharomyces cerevisiae.

The MET2 gene of Saccharomyces cerevisiae, which codes for homoserine-O-acetyltransferase, a key enzyme in methionine biosynthesis, was isolated by complementation of a met2 mutant strain of S. cerevisiae with a yeast gene bank. A 3.9-kb genomic fragment contains the entire gene, as demonstrated by genetic and molecular analysis of the integrative transformants. A polyadenylated mRNA of 1700 nt is detected by Northern blot hybridization with a MET2 probe. The level of this mRNA decreases by addition of exogenous methionine or of S-adenosylmethionine, suggesting a transcriptional regulation. The level of specific mRNA and the enzyme activity found in transformants that bear the MET2 gene on a multicopy plasmid suggest that also a post-transcriptional regulatory mechanism may be operative in budding yeast.

The glucose-induced polyphosphoinositides turnover in Saccharomyces cerevisiae is not dependent on the CDC25-RAS mediated signal transduction pathway.

Recently the polyphosphoinositides (PI) turnover has been related to the control of growth and cell cycle also in Saccharomyces cerevisiae, and the RAS2 and RAS1 gene products have been shown to be involved in the stimulation of PI turnover in G0/G1 arrested yeast cells. Here we show that addition of glucose to previously glucose-starved cells, stimulates, the PI turnover with fast kinetics also in yeast cells that were not arrested in the G0/G1 phase of the cell cycle. In addition PI turnover is equally stimulated in temperature sensitive cdc25-1 and cdc25-5 strains at restrictive temperature, as well as in ras1, ras2-ts strain, suggesting that PI turnover stimulation is not dependent on the CDC25-RAS mediated signal transduction pathway.

The promoter of Saccharomyces cerevisiae FBA1 gene contains a single positive upstream regulatory element.

The glycolytic enzyme fructose 1,6-bisphosphate aldolase is encoded by the FBA1 gene of Saccharomyces cerevisiae. Transcription of aldolase gene is not regulated by glucose and high levels of expression have been observed also during growth on nonfermentable carbon source. A FBA1::lacZ gene fusion was constructed and a deletion analysis demonstrated the presence of a unique cis-acting positive upstream element (UAS) required for high levels of FBA1 expression. This element is located between positions -550 and -440 upstream of the aldolase open reading frame and it contains sequences known to constitute the binding sites for the multifunctional proteins RAP1 and ABFI and two TTCC motifs.

Mutations at position 1122 in the catalytic domain of the mouse ras-specific guanine nucleotide exchange factor CDC25Mm originate both loss-of-function and gain-of-function proteins.

The role of two residues within the catalytic domain of CDC25Mm, a mouse ras-specific guanine nucleotide exchange factor (GEF), was investigated by site-directed mutagenesis. The function of the mutant proteins was tested in vivo in both a Saccharomyces cerevisiae cdc25 complementation assay and in a mammalian fos-luciferase assay, and in in vitro assays on human and yeast Ras proteins. Mutants CDC25Mm(E1048K) and CDC25Mm(S1122V) were shown to be (partly) inactive proteins, similar to their yeast homologs. Mutant CDC25Mm(S1122A) showed higher nucleotide exchange activity than the wild type protein on the basis of both in vitro and in vivo assays. Thus, alanine and valine substitutions at position 1122 within the GEF catalytic domain originate mutations with opposite biological properties, indicating an important role for position 1122 in GEF function.

Dansylalanyllysylchloromethyl ketone as a fluorescent probe for localization of acrosin activity in boar and human spermatozoa.

The localization of acrosin (EC 3.4.21.10) activity in mammalian spermatozoa was investigated by use of the fluorescent site-directed acrosin inhibitor, dansylalanyllysylchloromethyl ketone (DALCK). Fluorescence microscope preparations revealed, after the spermatozoa were subjected to a specific treatment, that acrosin activity is confined specifically to the inner acrosomal membrane (IAM). Spectrofluorometric and fluorescence polarization investigations verified that the fluorescent probe, once it is specifically bound to the treated spermatozoa, lies in a very hydrophobic environment and shows a remarkable reduction of rotational freedom. These results are compatible with the hypothesis that, under the experimental conditions used, active acrosin is tightly bound to the IAM and that the "specificity site" of the acrosin-active center is probably of a highly hydrophobic nature.

Development of a pH-controlled fed-batch system for budding yeast.

In the manufacturing of baker's yeast by aerobic fed-batch systems, continuous assessment of the state of the process is necessary for regulating the flow rate (on/off) for growth medium addition. A new, simple method for the fed-batch yeast process has been developed. It is based on pH changes as a suitable parameter for regulating the feed of fresh concentrated medium in response to metabolic activities of the yeast population. Experimental results have shown that it enables the attaining of high cell density with both high productivity and high yields.

Identification of different daughter and parent subpopulations in an asynchronously growing Saccharomyces cerevisiae population.

Under all growth conditions, a growing Saccharomyces cerevisiae yeast population is extremely heterogeneous, since individual cells differ in their cell size; this is due to their position in the cell division cycle and their genealogical age. To gain insight into the structure of a growing yeast population, we used a recently developed flow cytometric approach which enables, in asynchronously growing S. cerevisiae populations, tagging of both the cell age and the protein content of individual cells. This approach enabled the identification of daughter cells belonging to different cell cycle positions (i.e. newborn, G1, S + G2 + M + G1*, and dividing), thus yielding information about the relative fraction in the whole population, cell size and variability. More limited information could be obtained for the parent subpopulation; however, we were able to identify and characterize the dividing parent cells. The coefficient of variation (CV) of the protein content distribution for the dividing parents (27) was much higher than the CV of dividing daughters (18). Further findings obtained indicated a large overlap between the cell protein content distributions of daughter and parent cells as well as between the protein content of cells of the same subpopulation but belonging to different stages of the cell division cycle. The analysis of these differences enables a better understanding of the complex structure of an asynchronously growing yeast population.

Cloning, sequencing and expression in E. coli of a D-amino acid oxidase cDNA from Rhodotorula gracilis active on cephalosporin C.

We have cloned the cDNA coding for the Rhodotorula gracilis D-amino acid oxidase (DAAO), an enzyme that performs with high catalytic efficiency biotechnologically relevant bioconversions, by PCR amplification. The first strand cDNA was synthesised from the total mRNA fraction isolated from R. gracilis cells grown under DAAO-inducing conditions. The R. gracilis DAAO cDNA consists of 1104 bp encoding a protein of 368 amino acids. The insertion of the cDNA into the pKK223-3 plasmid allowed the expression of recombinant DAAO in Escherichia coli as a wholly soluble and catalytically active holoenzyme (approximately 0.5 U mg-1 protein) with a fermentation yield, in terms of DAAO units, of 800 U l-1. This level of expression allowed the purification, in homogeneous form and high yield (50%), of the recombinant enzyme which showed a high catalytic activity on cephalosporin C as substrate. The nucleotide sequence reported in this paper will appear in the nucleotide sequence databases under accession number.

Flow cytometry and cell cycle kinetics in continuous and fed-batch fermentations of budding yeast.

Cell size distributions, obtained either as protein distribution by flow cytometry or as cell volume distribution by a Coulter counter, give relevant information about the growth conditions of populations of budding yeast Saccharomyces cerevisiae. We have previously found a good correlation between these distributions and the growth rate in continuous cultures (Ranzi et al., Biotechnol. Bioeng. 1986, 28, 185-190). We now present determinations of the protein distributions and cell volume distributions during different fed-batch fermentations performed with a simple on/off controller. Since during the fed-batch fermentation a true steady state is not obtained, the distributions continuously change with time, but nevertheless we observed a good correlation between the average of both distributions and the actual growth rate. The behavior of the cell size distributions can be interpreted on the basis of a two-threshold cell cycle model in which both the critical protein content at budding (Ps) and the critical protein content for cell division (Pm) are differently modulated by the growth rate. Additional findings will be presented showing that this model can be used to successfully explain the insurgence and the maintenance of oscillatory states in continuous cultures.