Sensitivity to Sn2+ of the yeast Saccharomyces cerevisiae depends on general energy metabolism, metal transport, anti-oxidative defences, and DNA repair.

Resistance to stannous chloride (SnCl(2)) of the yeast Saccharomyces cerevisiae is a product of several metabolic pathways of this unicellular eukaryote. Sensitivity testing of different null mutants of yeast to SnCl(2) revealed that DNA repair contributes to resistance, mainly via recombinational (Rad52p) and error-prone (Rev3p) steps. Independently, the membrane transporter Atr1p/Snq1p (facilitated transport) contributed significantly to Sn(2+)-resistance whereas absence of ABC export permease Snq2p did not enhance sensitivity. Sensitivity of the superoxide dismutase mutants sod1 and sod2 revealed the importance of these anti-oxidative defence enzymes against Sn(2+)-imposed DNA damage while a catalase-deficient mutant (ctt1) showed wild type (WT) resistance. Lack of transcription factor Yap1, responsible for the oxidative stress response in yeast, led to 3-fold increase in Sn(2+)-sensitivity. While loss of mitochondrial DNA did not change the Sn(2+)-resistance phenotype in any yeast strain, cells with defect cytochrome c oxidase (CcO mutants) showed gradually enhanced sensitivities to Sn(2+) and different spontaneous mutation rates. Highest sensitivity to Sn(2+) was observed when yeast was in exponential growth phase under glucose repression. During diauxic shift (release from glucose repression) Sn(2+)-resistance increased several hundred-fold and fully respiring and resting cells were sensitive only at more than 1000-fold exposure dose, i.e. they survived better at 25 mM than exponentially growing cells at 25 microM Sn(2+). This phenomenon was observed not only in WT but also in already Sn(2+)-sensitive rad52 as well as in sod1, sod2 and CcO mutant strains. The impact of metabolic steps in contribution to Sn(2+)-resistance had the following ranking: Resting WT cells > membrane transporter Snq1p > superoxide dismutases > transcription factor Yap1p >or= DNA repair >> exponentially growing WT cells.

Localization of cellular retinoic acid-binding protein (CRABP) II and CRABP in developing rat testis.

Retinoic acid (RA) has been implicated as a signaling molecule for the morphogenesis of some tissues and organs. The morphogenesis of the rat testis occurs relatively late in development, culminating in puberty. Two members of the superfamily of small intracellular carrier proteins for lipophilic compounds are cellular Ra-binding protein (CRABP) and cellular RA-binding protein II (CRABP-II). Both CRABP and CRABP-II are present at various sites in the developing mouse embryo. Here we report the developmental expression and localization of CRABP and CRABP-II in rat testis. Northern blot analysis of CRABP-II demonstrated the highest messenger RNA expression on day 4 (the earliest time point assayed by this technique), decreasing thereafter until day 20, when it became undetectable. Western blot analysis, begun on day 19 of fetal development, indicated that high levels of protein expression in the testis already existed at that time. CRABP messenger RNA expression reached its highest levels between postnatal days 16-20 and decreased thereafter. Immunolocalization revealed that CRABP-II was confined to the fetal population of Leydig and Sertoli cells. We observed that CRABP-II was expressed in certain cells that synthesized retinoic acid in the uterus and ovary (unpublished). The expression of CRABP-II in Sertoli cells and fetal Leydig cells suggested that these cells may well be the site of RA synthesis in the developing testis. CRABP was localized to gonocytes in earlier stages and spermatogonia later, where it was clearly excluded from the nucleus, indicating that the role of CRABP may be to protect these cells from the effects of RA. The reported expression of CRABP-II in embryonal tissues, which are RA responsive and undergoing morphogenesis, coupled with CRABP-II expression in the testis at a critical morphogenic stage suggest that RA may play a prominent role in the morphogenesis of the testis.

A novel, testis-specific member of the cellular lipophilic transport protein superfamily, deduced from a complimentary deoxyribonucleic acid clone.

A novel member of the cellular lipophilic transport protein superfamily was identified after an antiserum raised against cellular retinoic acid-binding protein (CRABP) was found also to contain antibodies against another 15-kDa protein present in the cytosol of pubertal and adult rat testis. These antibodies were used to screen a rat testis cDNA expression library and isolate a 561-bp clone containing a full open reading frame from which the sequence of a novel 132 amino acid protein was deduced. The protein has 58% amino acid sequence identity to bovine myelin P2, 58% identity to murine adipocyte lipid-binding protein, and 40% identity to rat CRABP. Although the endogenous ligand has not yet been identified, conservation of residues involved in the binding of carboxylate groups suggests that the ligand is a fatty acid or an acidic retinoid. Tissue-specific expression was examined by Northern analysis and immunolocalization and appears to be restricted to late germ cells within the testis and epididymis. Immunostaining was first detectable in mid-pachytene spermatocytes and increased in intensity as these cells progressed to elongated spermatids, suggesting that this testis lipid-binding protein has a specific role in sperm development.

Expression of cellular retinol-binding protein and lecithin-retinol acyltransferase in developing rat testis.

Vitamin A deficiency in mammals results in the loss of germ cells on the adluminal side of the blood-testis barrier, suggesting a need for vitamin A that would be supplied by the surrounding Sertoli cells. Cellular retinol-binding protein (CRBP) and lecithin-retinol acyltransferase (LRAT) are two proteins found in Sertoli cells that are known to be involved in vitamin A trafficking. To clarify the role of these two proteins in the delivery of vitamin A to developing germ cells, we have examined changes in their cell-specific expression during the onset of puberty in the rat. In adult rats, Sertoli cell expression of CRBP varies with the cycle of the seminiferous epithelium. Here, we demonstrate that differences in the intensity of CRBP immunoreactivity are detectable in Sertoli cells of different tubules as early as postnatal Day 4, prior to the onset of meiosis. This indicates that variable expression of CRBP by Sertoli cells is established independently of late germ cells and may anticipate the cyclical variation seen in the adult. We further demonstrate that the specific activity of LRAT in rat testis increases tenfold between postnatal Days 20 and 35. This increase is attributable to the appearance of post-meiotic germ cells: the LRAT activity of microsomes prepared from a round spermatid-enriched cell fraction from post-pubertal rat testis could account for the majority of the LRAT activity observed in the whole testis. The presence of LRAT activity within adluminal germ cells suggests that they receive vitamin A as retinol and synthesize the retinyl esters that have been shown to be present in mature sperm.

Stimulation of dihydrofolate reductase promoter activity by antimetabolic drugs.

Dihydrofolate reductase (DHFR; EC 1.5.1.3) is required in folate metabolism for the synthesis of purines, thymidine, and glycine. Although there have been several reports of induction of DHFR enzyme by methotrexate (MTX), a drug that competitively inhibits DHFR, there are no studies reported that examine the effect of MTX on DHFR gene transcription. We have examined the effect of MTX and other inhibitors of DNA synthesis on DHFR transcription using a transient expression assay. MTX stimulates transient expression in a concentration-dependent manner from a hamster DHFR promoter construct containing 150 base pairs 5' to the start of transcription. Addition of either tetrahydrofolate or hypoxanthine plus thymidine prevents the promoter induction in response to MTX, suggesting that stimulation by MTX results from inhibition of these metabolites. Furthermore, two other antimetabolic drugs--fluorodeoxyuridine and hydroxyurea--also stimulate the DHFR promoter in a concentration-dependent manner. In contrast, aphidicolin, which blocks cell growth through inhibition of DNA polymerase alpha, has no effect on the DHFR promoter. The potential relevance of these results to cross-resistance to chemotherapeutic agents and to the process of gene amplification is discussed.

Evidence for a precursor of the high-affinity metastasis-associated murine laminin receptor.

The high-affinity cellular receptor for the basement membrane component laminin is differentially expressed during tumor invasion and metastasis. A cDNA clone encoding the murine laminin receptor was isolated and identified on the basis of sequence homology to the human laminin receptor [Wewer et al. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 7137-7141]. Primer extension experiments demonstrated that the clone contained the complete 5' sequence of the murine laminin receptor mRNA. RNA blot data demonstrated a single-sized laminin receptor mRNA, approximately 1400 bases long, in human, mouse, and rat. The nascent laminin receptor predicted from the cDNA sequence is 295 amino acids long, with a molecular weight of 33,000, and contains one intradisulfide bridge, a short putative transmembrane domain, and an extracellular carboxy-terminal region which has abundant glutamic acid residues and multiple repeat sequences. The precursor of the laminin receptor is apparently smaller than the 67-kilodalton protein isolated from tissue. The apparent molecular weight on SDS-polyacrylamide gels of the rabbit reticulocyte cell-free translation product of selectively hybridized laminin receptor mRNA is 37,000. Antisera to three different domains of the cDNA-predicted receptor were used to study the relationship between the 37- and 67-kilodalton polypeptides. Antisera to cDNA-deduced synthetic peptides of the receptor immunoprecipitated a 37-kilodalton band both from cell-free translation products and from pulse-labeled cell extracts. On immunoblots of cell extracts, one antisynthetic peptide antiserum recognized only the 67-kilodalton receptor, while another antiserum identified both 37- and 67-kilodalton polypeptides, suggesting a precursor-product relationship between the two polypeptides.