Cyclic AMP phosphodiesterase in Salmonella typhimurium: characteristics and physiological function.

The physiological function of cyclic AMP (cAMP) phosphodiesterase in Salmonella typhimurium was investigated with strains which were isogenic except for the cpd locus. In crude broken-cell extracts the properties of the enzyme were found to be similar to those reported for Escherichia coli. The specific activity in the mutant was less than 1% that in the wild type. Rates of cAMP production in the mutant were as much as twice those observed in the wild type. The amount of cAMP accumulated when cells grew overnight with limiting glucose was 4.5-fold greater in the mutant than in the wild type. The intracellular concentration of cAMP in the two strains was measured directly, using four different techniques to wash the cells to remove extracellular cAMP. The cAMP level in the cpd strain was only 25% greater than in the wild type. The functional concentration of the cAMP receptor protein-cAMP complex was estimated indirectly from the specific activity of beta-galactosidase in the two strains after introducing F'lac. When cells were grown with carbon sources permitting synthesis of different levels of cAMP, the specific activity of the enzyme was at most 25% greater in the cpd strain. The cpd strain was more sensitive to the effects of exogenous cAMP. Exogenous cAMP relieved both permanent and transient catabolite repression of the lac operon at lower concentrations in the cpd strain than in the wild type. When cells grew with glucose, glycerol, or ribose, exogenous cAMP inhibited growth of the mutant strain more than the wild type.     

Post-translational glycosylation of the contact site A protein of Dictyostelium discoideum is important for stability but not for its function in cell adhesion

The functions of type 1 and 2 carbohydrates of the contact site A (csA) glycoprotein of Dictyostelium discoideum have been investigated using mutants lacking type 2 carbohydrate. In two mutant strains, HG220 and HG701, a 68-kd glycoprotein was synthesized as the final product of csA biosynthesis. This glycoprotein accumulated to a much lower extent on the surfaces of mutant cells than the mature 80-kd glycoprotein did in wild-type cells. There was also no accumulation of the 68-kd glycoprotein observed within the mutant cells nor was a precursor of lower molecular mass detected, in accordance with previous findings that indicated cotranslational linkage of type 1 carbohydrate by N-glycosylation. Pulse-chase labelling showed that a 50-kd glycopeptide was cleaved off from the mutant 68-kd glycoprotein and released into the medium, while the fully glycosylated 80-kd glycoprotein of the wild type was stable. These results assign a function to type 2 carbohydrate in protecting the cell-surface-exposed csA glycoprotein against proteolytic cleavage. HG220 cells were still capable of forming EDTA-stable contacts to a reduced extent, consistent with the low amounts of the 68-kd glycoprotein present on their surfaces. Thus type 1 rather than type 2 carbohydrate appears to be directly involved in intercellular adhesion that is mediated by the csA glycoprotein. Tunicamycin-treated wild-type and mutant cells produce a 53-kd protein that lacks both type 1 and 2 carbohydrates. While this protein is stable and not transported to the cell surface in the wild type, it is cleaved in the mutants and fragments of it are released into the extracellular medium. These results suggest that the primary defect in the two mutants studied is relief from a restriction in protein transport to the cell surface, and that the defect in type 2 glycosylation is secondary.     

Characteristics of Fps1-dependent and -independent glycerol transport in Saccharomyces cerevisiae.

Eadie-Hofstee plots of glycerol uptake in wild-type Saccharomyces cerevisiae W303-1A grown on glucose showed the presence of both saturable transport and simple diffusion, whereas an fps1delta mutant displayed only simple diffusion. Transformation of the fps1delta mutant with the glpF gene, which encodes glycerol transport in Escherichia coli, restored biphasic transport kinetics. Yeast extract-peptone-dextrose-grown wild-type cells had a higher passive diffusion constant than the fps1delta mutant, and ethanol enhanced the rate of proton diffusion to a greater extent in the wild type than in the fps1delta mutant. In addition, the lipid fraction of the fps1delta mutant contained a lower percentage of phospholipids and a higher percentage of glycolipids than that of the wild type. Fps1p, therefore, may be involved in the regulation of lipid metabolism in S. cerevisiae, affecting membrane permeability in addition to fulfilling its specific role in glycerol transport. Simultaneous uptake of glycerol and protons occurred in both glycerol- and ethanol-grown wild-type and fps1delta cells and resulted in the accumulation of glycerol at an inside-to-outside ratio of 12:1 to 15:1. Carbonyl cyanide m-chlorophenylhydrazone prevented glycerol accumulation in both strains and abolished transport in the fps1delta mutant grown on ethanol. Likewise, 2,4-dinitrophenol inhibited transport in glycerol-grown wild-type cells. These results indicate the presence of an Fps1p-dependent facilitated diffusion system in glucose-grown cells and an Fps1p-independent proton symport system in derepressed cells.     

Genetic effects of the decay of tritium incorporated into Saccharomyces cerevisiae yeast cells. I. Lethal effect of 3H-alanine on cells of different ploidy and radiosensitivity]

Lethal effect of 3H-alanine on cells of different ploidy (1n-4n) and radiosensitivity wild type haploid and diploid strains; xrs2 mutant and diploid strains homozygous for this mutation is studied. It is shown that the efficiency of the inactivation per tritium decay depends on ploidy, radiosensitivity and geometric dimension of cells and nuclei. Do for all the studied strains is slightly higher than Do for these strains in case of external beta-irradiation. RBE of beta-ray tritium with respect to beta-ray of 32P is 1.5.     

Study of the effect of 2 inhibitors of nucleotide synthesis, aminopterin and fluorodeoxyuridine, on wild type strains and vestigial mutants in Drosophila melanogaster

Two inhibitors of nucleotide metabolism, aminopterin and FUdR, were tested on a wild type strain, on two mutant strains: vg and vgnp, and on a vg strain with the wild type genetic background. Without inhibitors, a lengthening of the developing time was observed for the mutant strains compared to the wild type. With aminopterin, larval mortality and lengthening of developing time are significantly higher in the wild type than in the mutant strains. Mutant strains seemed to be resistant to low concentrations of FUdR. The hypothesis of a perturbed pyrimidine metabolism in the mutants seems to be confirmed.     

Absence of cardiolipin in the crd1 null mutant results in decreased mitochondrial membrane potential and reduced mitochondrial function

Cardiolipin (CL) is a unique phospholipid which is present throughout the eukaryotic kingdom and is localized in mitochondrial membranes. Saccharomyces cerevisiae cells containing a disruption of CRD1, the structural gene encoding CL synthase, have no CL in mitochondrial membranes. To elucidate the physiological role of CL, we compared mitochondrial functions in the crd1Delta mutant and isogenic wild type. The crd1Delta mutant loses viability at elevated temperature, and prolonged culture at 37 degrees C leads to loss of the mitochondrial genome. Mutant membranes have increased phosphatidylglycerol (PG) when grown in a nonfermentable carbon source but have almost no detectable PG in medium containing glucose. In glucose-grown cells, maximum respiratory rate, ATPase and cytochrome oxidase activities, and protein import are deficient in the mutant. The ADP/ATP carrier is defective even during growth in a nonfermentable carbon source. The mitochondrial membrane potential is decreased in mutant cells. The decrease is more pronounced in glucose-grown cells, which lack PG, but is also apparent in membranes containing PG (i.e. in nonfermentable carbon sources). We propose that CL is required for maintaining the mitochondrial membrane potential and that reduced membrane potential in the absence of CL leads to defects in protein import and other mitochondrial functions.     

Genetic effects of cosmic radiation in Drosophila melanogaster]

To examine possible effects of space radiation on living organism, we have analyzedtwo types of mutations, sex-linked recessive lethal mutations and somatic mutations, in fruit fly of the species Drosophila melanogaster. Drosophila strains used were wild type strains and a radiation-sensitive strain mei-41. Two different developmental stages of samples were sent into space; young adult males to analyze sex-linked recessive lethal mutations and about 30hr-old larvae to detect somatic mutations in wing epidermal cells. For wild type and mei-41 strains each, about 200 adult male flies and about 6,000 larvae were loaded on space shuttle Endeavour. The male flies returned from space were mated to virgin female flies of a tester strain, and the presence of the lethal mutations was analyzed at F2 generation. The frequencies of sex-linked recessive lethal mutations in flight groups were 2 and 3 times higher for wild type Canton-S and mei-4 1, respectively, than those in ground control groups. Most larvae sent to space emerged as adult flies within about 10 days after the landing. The presence of wing-hair somatic mutations, which give morphological change in hairs growing on the surface of wing epidermal cells, was analyzed under microscope. In wild type strain Muller-5, the frequency of wing hair mutant spots in flight group was about 1.5-fold higher than that in ground control, and in Canton-S-derived wild type strain the frequencies were similar between the two groups. By contrast, for mei-41 strain the mutation frequency was lower in flight group than in control group. The observed higher frequency of lethal mutations in the flight group might be due to a possibility that radiation effects on reproductive cells could be greatly enhanced under micro gravity. However, if this would be the case, we do not have appropriate explanation for the apparent absence of such synergistic effects on somatic wing-hair mutation system.     

Pleiotrophic cellular deficiencies conferred by the blm5-1 mutation of Saccharomyces cerevisiae.

Mutational alteration of the BLM5 gene of the model eukaryote, Saccharomyces cerevisiae, confers extreme hypersensitivities to lethal effects of ionizing radiation, anticancer bleomycins and structurally-related phleomycins. Additional properties conferred by the blm5-1 mutation in haploid and diploid strains were investigated for the current report. Only one copy of blm5-1 together with the normal BLM5 allele was sufficient to produce mitotic and meiotic defects in diploids, and greatly increase killing by bleomycin beyond wild type levels. Mitotic growth rates of blm5-1/blm5-1 homozygous mutant strains were slower than wild type or BLM5/blm5-1 heterozygous strains at 30 degrees C, and growth was nearly completely inhibited at 37 degrees C. Meiosis was inhibited at 30 degrees C and 37 degrees C in mutant homozygotes, and at 37 degrees C in BLM5/blm5-1 heterozygotes, while meiosis occurred at equivalent frequencies in wild type strains at both temperatures. Surprisingly, mutant strains were found to associate extremely low quantities of [S-methyl-3H]bleomycin A2, in contrast to normal strains that associated quite high amounts. However, the fractions of the total associated radioactivities that were released from normal and blm5-1 cells were equivalent. These results suggested that the extremely high killing suffered by blm5-1 mutant strains in response to bleomycin treatments results from something other than increased intracellular drug concentrations.     

Proteome of Haemophilus ducreyi by 2-D SDS-PAGE and mass spectrometry: strain variation, virulence, and carbohydrate expression

We have analyzed the proteome of several strains of Haemophilus ducreyi by two-dimensional gel electrophoresis (2-DE) and mass spectrometry. Over 100 spots were analyzed from the soluble and insoluble protein fractions from the prototype strain 35000HP and 122 distinct proteins were identified. Functions of approximately 80% of the 122 proteins were deduced by identification with close homologues of Haemophilus influenzae. Four additional wild type and three mutant strains were also analyzed that vary in their virulence and/or outer-membrane lipooligosaccharide structures. Overall, the 2-DE gel maps of the wild type and mutant strains were similar to strain 35000HP, suggesting little proteome diversity in relation to carbohydrate expression and/or virulence. An exception was the Kenyan strain 33921 which contained significant differences in its proteome 2-DE map and also synthesizes an unusual LOS with a trisaccharide branch structure. This African strain may represent a prototype of a second clonal group of H. ducreyi.     

A CAM- and starch-deficient mutant of the facultative CAM species Mesembryanthemum crystallinum reconciles sink demands by repartitioning carbon during acclimation to salinity

In the halophytic species Mesembryanthemum crystallinum, the induction of crassulacean acid metabolism (CAM) by salinity requires a substantial investment of resources in storage carbohydrates to provide substrate for nocturnal CO(2) uptake. Acclimation to salinity also requires the synthesis and accumulation of cyclitols as compatible solutes, maintenance of root respiration, and nitrate assimilation. This study assessed the hierarchy and coordination of sinks for carbohydrate in leaves and roots during acclimation to salinity in M. crystallinum. By comparing wild type and a CAM-/starch-deficient mutant of this species, it was sought to determine if other metabolic sinks could compensate for a curtailment in CAM and enable acclimation to salinity. Under salinity, CAM deficiency reduced 24?h photosynthetic carbon gain by >50%. Cyclitols were accumulated to comparable levels in leaves and roots of both the wild type and mutant, but represented only 5% of 24?h carbon balance. Dark respiration of leaves and roots was a stronger sink for carbohydrate in the mutant compared with the wild type and implied higher maintenance costs for the metabolic processes underpinning acclimation to salinity when CAM was curtailed. CAM required the nocturnal mobilization of >70% of primary carbohydrate in the wild type and >85% of carbohydrate in the mutant. The substantial allocation of carbohydrate to CAM limited the export of sugars to roots, and the root:shoot ratio declined under salinity. The data suggest a key role for the vacuole in regulating the supply and demand for carbohydrate over the day/night cycle in the starch-/CAM-deficient mutant.     

Genetic effects of sulfur-35 decay in Saccharomyces cerevisiae cells. V. Comparative study of the lethal and mutagenic effectiveness of the decay of 35S and 32P incorporated into cells of the radiosensitive mutant xrs2]

The lethal effect of 35S and 32P decays on cells of yeast radiation-sensitive mutant xrs2 was studied. The mutant is 7 times more sensitive than the wild type to transmutation of both isotopes. The survival curve for xrs2 was exponential. In spite of the lethal effect, mutant cells are not more mutable than the wild type under decays of both isotopes (the number of mutations in ade1 and ade2 genes was counted), xrs2 and wild type strains differ in kinds of mutations induced by the decay of incorporated 35S in ade2 locus. Namely, there are 82% of base substitutions and 18% of other types mutations induced in xrs2 strain despite 97% and 3% respectively for the wild type strain. Also it was shown that complete and mosaic mutants, induced by the the 35S decay in xrs2 strain, differ in a pattern of interallelic complementation.     

Properties of a Novel Pleiotropic Bacteriophage-Resistant Mutant of Staphylococcus aureus H

A phage-resistant mutant of Staphylococcus aureus H (Sm(R)), S. aureus 52A5, was previously shown to lack polymeric teichoic acid. This paper characterizes other phenotypic differences between the strains. In broth cultures the mutant cells grew more slowly, were larger, and formed much larger clumps than the parent strain. The clumps of cells appeared to be covalently linked and could only be separated by mild sonic energy-a process which yielded viable cells. Mutant and parent cells autolyzed at equal rates, whereas isolated cell walls of the mutant strain autolyzed faster than the wild type. Nevertheless, the specific activity of the autolytic enzyme in the wild type soluble fraction was much higher than in the mutant. In contrast to the parent, strain 52A5 failed to accumulate nucleotide-bound murein precursors when treated with penicillin. Mutant strains with these characteristics were repeatedly isolated both spontaneously and by chemical mutagenesis. Strain 52A5 was shown to be fully revertible. Thus, it appears to be a pleiotropic mutation, and the possible nature of the defect which causes these varied effects is discussed.     

猪链球菌2型荚膜唾液酸对细菌毒力和宿主炎症反应的影响

【目的】阐明猪链球菌2型荚膜唾液酸是否影响细菌毒力以及宿主对其炎症反应应答,为研究猪链球菌2型的致病机制奠定基础。【方法】比较实验菌株对BLAB/c小鼠模型的致病性;通过涂板计数的方法检测实验菌株在小鼠体内的分布;观察小鼠脑组织病理改变,分析实验菌株感染小鼠后中枢神经系统的病变差异;从小鼠体外全血细胞水平,运用ELISA法检测实验菌株感染后细胞炎性因子的分泌水平。【结果】荚膜唾液酸合成基因neuB缺失突变株ΔneuB相比野生株05ZYH33株,对小鼠毒力显著降低,回复突变株cΔneuB毒力回复至野生株水平;野生株和突变株在血液及脑组织中分布具有显著差异,均可致BLAB/c小鼠脑组织不同程度的损伤;与野生株组相比较,细菌/细胞相互作用不同时间点后,突变株组体外刺激小鼠全血细胞分泌MCP-1、IL-6的水平显著提高;【结论】荚膜唾液酸影响细菌的毒力及宿主细胞对其的炎症反应应答,它是猪链球菌2型穿透血脑屏障导致脑膜炎的重要毒力因子。     

Effect of carbon source on enzymes involved in glycerol metabolism inNeurospora crassa

Specific activities of eight enzymes involved in glycerol metabolism were determined in crude extracts of three strains ofNeurospora crassa after growth on six different carbon sources. One of the strains was wild type, which grew poorly on glycerol as sole carbon source; the other two were mutant strains which were efficient glycerol utilizers. A possible basis for this greater effeciency of glycerol utilization was catabolite repression of glyceraldehyde kinase by glycerol in wild type, and two-fold higher glycerate kinase activity in the mutant strains after growth on glycerol, thus apparently allowing two routes for glyceraldehyde to enter the glycolytic pathway in the mutant strains but only one in wild type. The preferential entry of glyceraldehyde to the glycolytic pathway through glycerate was suggested by the lack of glyceraldehyde kinase in all three strains after growth on one or more of the carbon sources and the generally higher levels of aldehyde dehydrogenase and of glycerate kinase than of glyceraldehyde kinase.     

Effect of mutations in extracellular nuclease on the characteristics of the pigmented and nonpigmented <Emphasis Type="Italic">Serratia marcescens</Emphasis> strains

Comparative characterization of the pigmented and nonpigmented Serratia marcescens strains and their extracellular nuclease mutants was carried out. Biomass accumulation by the mutant strains decreased on average by 20%, while proteolytic activity of the culture liquid was 4–5 times lower than in the case of the wild type strains. The mutants with impaired extracellular nuclease genes exhibited higher sensitivity to reactive oxygen species. Comparative analysis of motility of the strains revealed the highest flagellar activity in the wild type nonpigmented strain, while the cells of its mutant completely lost this feature.     

Sensitivity of Escherichia coli acrA mutants to psoralen plus near-ultraviolet radiation

The sensitivity to psoralen plus near-ultraviolet radiation (PUVA) was compared in a pair of E. coli strains differing at the acrA locus. Survival was determined for both bacteria and phage lambda. AcrA mutant cells were 40 times more sensitive than wild type to the lethal effect of PUVA. Free lambda phage exposed to PUVA survived as well when plated on acrA mutants as on wild type. In contrast, prophage lambda CI857 ind carried in lysogenic acrA strains was hypersensitive to PUVA. The enhanced sensitivity of bacterial and lambda DNA, when inside acrA cells, was paralleled by an increased photobinding of radiolabelled psoralens in the mutant. Binding was increased specifically to DNA rather than to nucleic acids in general. The difference in psoralen-binding ability determined by the acrA gene persisted after permeabilizing treatment of the cells. The results suggest that the acrA mutation causes an alteration specifically in the environment of the cellular DNA so as to allow increased intercalation and photobinding of psoralens.     

Endonuclease A degrades chromosomal and plasmid DNA of Escherichia coli present in most preparations of single stranded DNA from phagemids.

With E. coli, large and variable amounts of chromosomal and plasmid DNAs are observed in the supernatants of overnight cultures when the cells carry an endA mutation, but are not detected by gel electrophoresis when the cells carry the wild type allele of endA. Significant amounts of nuclease activity in DH11S endA+ supernatants were detected by two simple assays; the rapid degradation of added pBR322 plasmid DNA, as judged by agarose gel electrophoresis, and a decrease of more than 100000 fold in transformation efficiency of the added pBR322 plasmid DNA. By employing isogenic endA mutant and wild type strains of DH11S and DH10B/F' proAB+ laclq Z delta M15, it was shown that detectable levels of chromosomal and plasmid DNAs are observed only in the endA mutant strains. These results indicate that Endonuclease I activity is responsible for degradation of chromosomal and plasmid DNA usually present in preparations of ssDNA. Therefore, a wild type endA gene is useful for the rapid and simple production of highly purified ssDNA from cells containing phagemid vectors.     

Effect of growth conditions on production of rhamnose-containing cell wall and capsular polysaccharides by strains of Lactobacillus casei subsp. rhamnosus.

Strains of Lactobacillus casei subsp. rhamnosus possessing two cell wall polysaccharides, a hexosamine-containing H-polysaccharide and a rhamnose-containing R-polysaccharide, were examined for the effect of growth conditions on the production of these two components. In strain NCTC 6375, R- and H-polysaccharides accounted for an estimated 44 and 20%, respectively, of the cell wall for organisms grown in batch culture with glucose as the carbohydrate source. Growth on fructose-containing media reduced the amount of R-polysaccharide by approximately 50% without affecting the amount of H-polysaccharide. Subculture of fructose-grown organisms in glucose restored the original proportions of the two polysaccharides. Galactose- and sucrose-grown cells behaved similarly to glucose-grown cells with respect to polysaccharide production, whereas growth in rhamnose or ribose showed values close to those for fructose-grown cells. Continuous culture of strain NCTC 6375 for more than 100 generations showed a gradual and irreversible reduction of the R-polysaccharide to less than 5% of the cell wall and an increase of the H-polysaccharide to 40% of the cell wall. Other type culture strains of L. casei subsp. rhamnosus, NCIB 7473 and ATCC 7469, behaved similarly in batch and continuous culture. In contrast, strains of L. casei subsp. rhamnosus isolated at the Institute of Dental Research showed phenotypic stability with respect to the relative proportions of R- and H-polysaccharides in both batch and continuous culture. Changes in polysaccharide composition of type culture strains were also mirrored in changes in the immunogenicity of the two components and resistance to the rate of enzymic lysis of whole organisms. For L. casei subsp. rhamnosus strain NCTC 10302 the R-polysaccharide is present entirely as capsular material. The amount of R-polysaccharide produced was also markedly dependent on the carbohydrate component of the medium in batch culture and both dilution rate and nature of the limiting carbohydrate in continuous culture, varying over a 10-fold range, whereas the cell wall H-polysaccharide remained constant.     

Biochemical characterization of a mutant asparaginyl-tRNA synthetase from Chinese hamster ovary cells

The biochemical and physical properties of asparaginyl-tRNA synthetase from wild type Chinese hamster ovary cells and a temperature sensitive mutant strain (lys 65a) are compared. The asparaginyl-tRNA synthetase in the mutant strain exhibits a greater temperature lability in vitro, a higher temperature-independent Km for asparagine, and a lower temperature-dependent catalytic capacity than the enzyme from the wild type strain. The mutant enzyme shows no differences in its molecular weight, its Km for tRNAAsn, or its ability to aminoacylate tRNAAsn isoacceptor species compared to the wild type enzyme. These observations, as well as the growth properties of the mutant cells as a function of temperature and exogenous asparagine concentrations, are consistent with their decreased ability to aminoacylate tRNAAsn in vivo.