A continuous culture study of an obligately psychrophilic Pseudomonas species

Summary The optimum temperatures for growth and respiration of an obligately psychrophilic Pseudomonas spec. were 14°C and 23°C, respectively. The maximum temperature for growth was between 19 and 20°C. When cells were grown in a chemostat with lactate as the growth-limiting substrate at a specific growth rate of 0.05 hr^-1 over a temperature range of 5–19°C, it was found that RNA concentration was lowest at 14°C. At lower temperatures the cells compensated the decrease of reaction rates by increasing the concentration of RNA and of respiratory enzymes. A temperature raise above 14°C also increased cellular RNA, which probably counteracted an impairment of protein synthesis. Above 18°C the RNA increase ceased, resulting in a rapid decrease of protein synthesis, until between 19 and 20°C growth ceased entirely. Cells grown at 14°C showed a linear increase of RNA content and values with growth rate, when this was varied from 0.025 to the maximum value of 0.2 hr^-1.Dedicated to Prof. C. B. van Niel on the occasion of his 70th birthday.     

Growth and macromolecular synthesis phenotypes of a heat-sensitive mutant strain, rip-1, of Neurospora crassa

Summary A heat-sensitive mutant of Neurospora crassa, strain 4M(t), was isolated using ultraviolet-light mutagenesis followed by the inositol-less death enrichment technique. The heat-sensitivity is the result of a single gene mutation which maps to the distal end of the right arm of linkage group II. The mutation defines the rip-1 gene locus. Both conidial germination and mycelial extension are inhibited in the mutant at 35°C and above (the nonpermissive temperature) but prolonged incubation at that temperature is not lethal to either cell type. Analysis of the lateral mycelial growth rates of wild type and of the rip-1 mutant at a variety of temperatures between 10 and 40°C indicated that the maximal growth rate occurs at 35°C in the wild type, and at 25°C in the rip-1 strain. The rip-1 mutant grows 239-times slower at 35°C than at 25°C, whereas the wild type grows 1.4-times faster. Temperature shift-up experiments showed that even 3 h at 20°C is not sufficient to allow germination at 37°C, thereby showing that the mutant cannot accumulate enough heat-sensitive product at the permissive temperature to contribute to germination at 37°C. The reciprocal temperature shift-down experiments showed that the molecular events at 37°C may be qualitatively useful for germination after shifting to 20°C. Studies of macromolecular synthesis showed that the biochemical defect in the heat-sensitive strain appears to affect RNA synthesis before protein synthesis, although there were differences in the relative effects depending on the age of the germinating conidia and the inhibition of the two processes was never complete. Messenger RNA synthesis is normal in the mutant at 37°C. Previous work has shown that the rip-1 mutant strain has a conditional defect in the accumulation of 25S rRNA and, hence, in 60S ribosomal subunit production (Loo et al. 1981). There are also indications from those studies that the 60S ribosomal subunit may be functionally impaired at the higher temperature. Thus, the growth and macromolecular synthesis phenotypes may result as a consequence of a conditional, ribosome function defect and leads to the hypothesis that the mutation in the rip-1 strain may be in a gene for a 60S ribosomal subunit component, perhaps a ribosomal protein.     

A novel extranuclear mutant of Neurospora with a temperature-sensitive defect in mitochondrial protein synthesis and mitochondrial ATPase

Summary [C93] is a novel, extranuclear mutant of Neurospora crassa which has a normal mitochondrial phenotype when grown at 25°, but which is deficient in cytochromes b and aa ₃ when grown at 37° (Pittenger and West 1979). In the present work, the phenotype of [C93] was characterized in greater detail. When [C93] is grown at 37°, the rate of mitochondrial protein synthesis is decreased to approximately 25% that of wild type; the ratio of mitochondrial small to large ribosomal subunits is decreased to 1:4 and mitochondrial small subunits are deficient in the mitochondrially-synthesized protein, S-5. The mitochondrial ribosome assembly defects in 37°-grown [C93] resemble those in chloramphenicol-treated wild-type cells and could merely be a consequence of the decreased rates of mitochondrial protein synthesis. Analysis of mitochondrial translation products by SDS gel electrophoresis suggests that 37°-grown [C93] is grossly deficient in the 19,000 Mr subunit of the oligomycin-sensitive ATPase relative to other mitochondrially-synthesized proteins. The ATPase defect was not found in other extranuclear or nuclear mutants deficient in mitochondrial protein synthesis. These data and additional evidence suggest that the primary defect in [C93] may be in the assembly of the ATPase complex. The possible connection between the ATPase defect and the deficiency of mitochondrial protein synthesis is discussed.     

Control of stable RNA synthesis in a temperature-sensitive mutant of elongation factor G of Bacillus subtilis

Summary A temperature-sensitive EFG mutant of Bacillus subtilis was isolated and characterized. This mutant, ts32, synthesizes stable RNA at 48° C with or at 50° C without accompanied protein synthesis. The initial rate of the RNA synthesis at 48° C or 50° C was 1.5 to 2.0 times as much as that at 30° C.This mutant as well as its parent (both leu ^-) showed stringent response for the RNA synthesis upon deprivation of amino acids with an accumulation of the MS nucleotides (pp Gpp and pppGpp). On raising temperature to 48° C or 50° C, the ts-cells immediately began to synthesize the stable RNA with an initial increase of the MS nucleotides. No drastic decrease in amount of the MS was observed during the active RNA synthesis.These results suggest that EFG is somehow involved in repressing the stable RNA synthesis, and have broken the close relationship between the stable RNA synthesis and the MS nucleotides hitherto reported.     

The heat shock response inLocusta migratoria

Summary Locusta migratoria adults reared at 27–30°C die after 2 h at 50°C, but they survive this temperature stress if first exposed to 45°C for 0.5 to 4.5 h. Fat bodies from adult females produce a set of at least six specific polypeptides with molecular weights of 81, 73, 68, 42, 28, and 24×10³ in reponse to heat shock (39–47°C for 1.5 h). These molecular weights closely match those of the heat shock proteins (hsps) observed inDrosophila, with the possible exception of the 42 kd protein of locusts. The optimal temperature for induction of hsps in locusts is 45°C, which is one of the highest heat shock temperatures reported in metazoans. The correspondence between the optimal temperature for hsp induction and the temperature at which enhanced heat tolerance is acquired (both 45 °C) suggests that the hsps may be associated with thermal protection in these insects.There appears to be no substantial translational control in the locust heat shock response, since other proteins are produced, albeit with some reduction, under heat shock conditions. Vitellogenin synthesis in fat bodies at 45°C is 55% of that observed at 30°C. The high optimal heat shock induction temperature and the continued synthesis of non-heat shock proteins may be adaptive to the locust's natural environment.     

Effect of altered efficiency of the RNA I and RNA II promoters on in vivo replication of ColE1-like plasmids in Escherichia coli

Summary Thermal inactivation of the dnaA gene product leads to a considerable decrease in the rate of replication of ColE1-like plasmids. To test the possiblity that the dnaA protein may affect synthesis of RNA I, which is an inhibitor of primer formation, or synthesis of RNA II, which is the primer precursor for replication of ColE1 (Tomizawa and Itoh 1982), the effect of the dnaA46 mutation on the efficiency of the RNA I and the RNA II promoters was examined. It appears that thermal inactivation of the dnaA protein results in a considerable increase in the activity of the RNA I promoter. We suggest that overproduction of RNA I in dnaA mutants grown at the restrictive temperature is responsible for the reduced replication of ColE1-like plasmids.It has been found that addition of rifampicin to cultures of the dnaA46 or the dna ⁺ strain grown at 42°C results in a dramatic increase in the rate of replication of ColE1-like plasmids. We show that the activity of the RNA II promoter at 42°C is exceptionally resistant to rifampicin. In the presence of the drug, this leads, to an altered ratio of RNA I to RNA II, in favor of the latter RNA species.     

Kinetics of bacteriophage lambda repressor synthesis directed by the PRE promoter: influence of temperature, multiplicity of infection, and mutation of PRM or the cro gene

Summary Expression of the P _RE (establishment) pathway for repressor synthesis is regulated both by phage-specific genetic elements and by physiological conditions. Here we describe the effects of temperature, multiplicity of infection, mutations in the cro gene, and a mutation in P _RM on P _RE-directed repressor synthesis. As Reichardt (1975a) has shown, repressor synthesis begins 5–15 min after infection by wildtype phage, and is shut off at 20–30 min after infection, depending on the temperature. At 43°, synthesis starts sooner, shuts off earlier, and leads to lower repressor levels than are attained at lower temperatures. Experiments with the temperature sensitive mutant crots20 demonstrate that, as had been shown previously in experiments at 30° and 37° C, cro protein is responsible for the shut-off of repressor synthesis at 43°. In addition to the effects of temperature, the kinetics of repressor synthesis are strongly affected by multiplicity of infection (moi). At mois greater than 10, repressor synthesis after infection by wildtype at 30° is dramatically inhibited. Unexpectedly, the P _RM mutation prm116, under certain conditions, can alleviate both cro-mediated shutoff and the inhibition of P _RE-directed repressor synthesis at high moi. These effects of prm116 are observed only at low temperature (30°–32° C) and at mois of about 6–10 or greater; they also appear to be cis-specific. Possible mechanisms for the effects of the prm116 mutation are discussed. Finally, these studies demonstrate that crots20, which was isolated as a temperature-sensitive lethal mutation in the cro gene (Herskowitz, unpublished), is temperature-sensitive with respect to the ability to shutoff P _RE-directed repressor synthesis; however, even at low temperature (30° C), the crots20 gene product is only partially active.     

Loss and restoration of viability of E. coli due to combinations of mutations affecting DNA polymerase I and repair activities

Summary We have found that the cells possessing the polA6 mutation affecting DNA polymerase I are unable to accept another mutation (uvr502) leading to UV-sensitivity. The introduction of the polA12 mutation determining the synthesis of a temperature sensitive DNA polymerase I into the uvr502 mutant results in the temperature sensitivity of colony forming ability of the double mutant. These data show that the uvr502 derivatives lacking DNA polymerase I are inviable. Reversions to temperature resistance in the population of the double mutant uvr502 polA12 may occur because of reverse mutations at one of the mutated sites or because of mutations suppressing DNA polymerase I deficiency but not UV- or MMS-sensitivity of revertants. DNA and protein synthesis in uvr502 polA12 cells continues after a shift to 45°C with rates almost indistinguishable from those in single mutants or wild type cells. No differences in DNA degradation were observed during incubation of single and double mutants at 45°C. The single strand molecular weight distribution of parent DNA from the double mutant as well as that from wild type cells is not affected by the shift to 45°C and 3 hours incubation at this temperature. We suggest that DNA polymerase I and/or the product altered by the uvr502 mutation are required for some step(s) of discontinuous DNA replication nonessential for the formation of acid insoluble DNA. The DNA polymerase I and the uvr gene product seem to be able to substitute for each other in accomplishing this process.     

Effect of Low Temperature on the Protein Metabolism of Wheat Leaves

The effect of low temperature on the protein metabolism of wheat primary leaves was examined. In seedlings transferred from 25 to 5 °C, total soluble protein accumulation, in vivo protein synthesis and breakdown, in vitro protein breakdown, and SDS-PAGE profiles of proteinases in gelatine-containing gels were analysed. Leaf protein content increased within a 7-d period (70 % over the initial value) in plants exposed to 5 °C. The fast protein accumulation observed on days 0 – 2 was mainly attributed to a decreased breakdown. In further days, parallelly to a slowdown in the rate of protein accumulation, the leaf proteolytic activity increased. The incubation temperature also had an influence on the proteolytic activity: Q ₁₀ values for the 15 – 5 °C range were 80 – 200 % higher than those observed for the 25 – 15 °C range. On the other hand, the in vivo protein synthesis capacity, at either 25 or 55 °C, was not significantly modified in cold-treated plants. In addition to the enhanced activities of two serine-proteinases (previously found in control plants by SDS-PAGE analysis), cold-treated plants displayed a new proteinase, which had not been detected so far.     

High temperature enhances cytotoxicity of mercury (HgCl2) on Hela S3 cells

The combined effect of mercury (HgCl₂) and high temperature on the growth and synthesis of nucleic acid and protein, and on the cell cycle of HeLa S₃ cells was investigated. The subsequent growth of the cells was dose-dependently inhibited by mercury at 37.2° and 41.2°C. The inhibitory effect of mercury on subsequent growth was enhanced at the higher temperature. IC₅₀ values for DNA and RNA synthesis but not protein synthesis, at 41.2°C, were significantly lower than those at 37.2°C (P<0.05,P<0.01, respectively). Flow cytometric analysis using synchronous cells indicated the possibility of blocking of cell cycle progression in the early part of S phase by the combined treatment. These results suggest that the cytotoxicity of mercury to cell growth was enhanced at the higher temperature and that this enhancement is related to the increased inhibitory effect of mercury on DNA and RNA synthesis and on the cell cycle at high temperatures.     

Thermotolerant nalidixic acid-resistant mutants ofEscherichia coli

Nalidixic acid-resistant mutants ofEscherichia coli CGSC #6353 capable of growth at 48°C were obtained by mutagenesis withN-methyl-N-nitro-N-nitrosoguanidine. Cotransductional analyses employing phage P1 indicated that the mutation resulting in the phenotype of growth at 48°C is an allele of thegyrA structural gene. Similar thermal inactivation kinetics were observed for ribosomes isolated from a thermotolerant (T/r) mutant grown at both 37°C and 48°C and from the parental strain grown at 37°C. Cell-free extracts prepared from the T/r mutant grown at 48°C exhibited a sharp increase in protein synthesis at 55°C, whereas this effect was not displayed by extracts from the mutant or parental strains grown at 37°C. In addition, preincubation at 55°C enhanced protein synthesis at 37°C up to 15-fold in an extract prepared from the T/r mutant grown at 48°C, whereas comparable values were 2.6- to 3.0-fold for extracts from the mutant and parental strains grown at 37°C.     

Stage dependent synthesis of heat shock induced proteins in early embryos of Drosophila melanogaster

Summary The synthesis of heat shock proteins (hsp) has been examined during the early embryogenesis of Drosophila melanogaster. Normal protein synthesis stops after heat shock at all developmental stages, while hsp synthesis is induced only after treatment at blastoderm and later stages. The small hsps continue to be synthesised after heat shock for a longer period than the larger ones. Heat shocks at 35°C, 37°C and 40°C were compared for their effect on hsp synthesis and the effect of heat shock on the normal course of development was analysed.     

Heat sensitivity and protein synthesis during heat-shock in the tobacco hornworm,Manduca sexta

Summary Fifth instar larvae of the tobacco hornworm,Manduca sexta, tolerate 1-h exposures to temperatures as high as 42°C. Above 42°C, survival declines rapidly to 18% at 44°C and 0% at 48°C. As in other insects, the heat-shock response ofManduca sexta involves the induction of synthesis of heat-shock proteins very similar in size to theDrosophila heat-shock proteins (84, 73, 71, 27, 25, 23, and 22 kd). In the epidermis, heat-shock protein synthesis peaks at 42°C, correlating with the heat sensitivity of both the tissue itself and the intact larva. Some heat-shock proteins have different isoelectric forms depending on tissue. Also, the heat-shock proteins are synthesized over a wider range of temperatures in the imaginal discs and the fat body as compared to the epidermis. In contrast to dipteran insects,Manduca sexta does not exhibit a strong repression of non-heat-shock protein synthesis under tolerable conditions.Abbreviations TCA trichloroacetic acid - PAGE polyacrylamide gel electrophoresis - AZT arbitrary Zeitgeber time - kd kilodaltons     

A comparison of proline, thiol levels and GAPDH activity in cyanobacteria of different origins facing temperature-stress

Three cyanobacterial strains originating from different habitats were subjected to temperature shift exposures and monitored for levels of proline, thiol and activity of glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Thermophile Mastigocladus laminosus (growth optimum, 40 °C), raised the proline level 4.2-fold at low temperature (20 °C), for the psychrophile Nostoc 593 (growth optimum, 20 °C), it was raised 8-fold at 40 °C while in the mesophile Nostoc muscorum (growth optimum, 30 °C), the imino acid level increased 2.3-fold during temperature shiftdown to 20 °C or 3.5-fold in sets facing shiftup (40 °C). Alterations in thiol levels in the above strains were in line with proline. It is suggested that such fluctuations reflect metabolic shifts as a response to stress. Interestingly, GAPDH activity was maximum at the respective growth temperature optimum of M. laminosus (122 nmol NADPH oxidized min ^–1 mg ^–1 protein) and Nostoc 593 (141 nmol NADPH oxidized min ^–1 mg ^–1 protein) while in N. muscorum, it increased at 40 °C (101 nmol NADPH oxidized min ^–1 mg ^–1 protein) and to 93.3 nmol NADPH oxidized min ^–1 mg ^–1 protein (20 °C) relative to 86 nmol NADPH oxidized min ^–1 mg ^–1 protein at 30 °C. It seems that extremophiles maintain the GAPDH activity/level during growth at their respective temperatures optimal while the mesophile increases it in order to cope up with temperature-stress.     

Pigment–Protein Complexes and the Number of Reaction Centers of the Photosystems in Pea Chlorophyll Mutants

We studied fluorescent and absorption properties of the chloroplasts and pigment–protein complexes isolated by gel electrophoresis from the leaves of pea, the parent cultivar Torsdag and mutants chlorotica 2004 and 2014. Specific fluorescence peaks of chlorophyll forms in individual complexes have been determined from the absorption and fluorescence spectra of the chloroplast chlorophyll and their second derivatives at 23 and –196°C. The mutant chlorotica 2004 proved to have an increased intensity of a long-wave band of the light-harvesting complex I at both 23°C (745 nm) and –196°C (728 nm). At the same time, this mutant manifested a decreased accumulation of the chlorophyll forms making up the nearest-neighbor antenna of the PS I reaction center (at 690, 697, and 708 nm). No spectral differences have been revealed between chlorotica 2014 mutant and the parent cultivar. Gel electrophoresis revealed the synthesis of all chlorophyll–protein complexes in both mutants. At the same time, analysis of photochemical activity of PS I and PS II reaction centers and calculations of their number and the size of the light-harvesting antenna have shown that the number of reaction centers in the PS I of chlorotica 2004 mutant is reduced by a factor of 1.7 because its chlorophyll a–protein complex is disturbed by the mutation. The primary effect of chlorotica 2014 mutation remains unclear. The proportional changes in the content of photosystem complexes in this mutant suggest that they are secondary and result from a 50% decrease in chlorophyll content.     

Induction of cold shock proteins in Bacillus subtilis

The cold shock response in the Gram-positive soil bacterium Bacillus subtilis is described. Cells were exposed to sudden decreases in temperature from their optimal growth temperature of 37°C. The B. subtilis cells were cold shocked at 25°C, 20°C, 15°C, and 10°C. A total of 53 polypeptides were induced at the various cold shock temperatures and were revealed by two-dimensional gel electrophoresis. General stress proteins were identified by a comparative analysis with the heat shock response of B. subtilis. Some unique, prominent cold shock proteins such as the 115 kDa, 97 kDa, and 21 kDa polypeptides were microsequenced. Sequence comparison demonstrated that the 115-kDa protein had homology to the TCA cycle enzyme, aconitase.     

Isolation and characterisation of a strain of Saccharomyces cerevisiae deficient in in vitro RNA polymerase B(II) activity.

Summary Two hundred strains of Saccharomyces cerevisiae temperature sensitive for RNA synthesis were selected and screened in crude extracts for DNA-dependent RNA polymerase activities. One strain was isolated which had only residual in vitro RNA polymerase B activity. In normal growth conditions total RNA, poly A⁺ RNA and protein synthesis were indistinguishable from those of the wild type strain at 23°C and after shift to 37°C. A temperature sensitive phenotype was detected only when rpoB containing strains were grown in adverse conditions. The mutant character showed mendelian segregation and was coexpressed with the wild type character in heterozygous diploids. Residual enzyme activity was characterised in crude extracts using synthetic polymers and natural templates in different ionic conditions.     

Stress response in Drosophila subobscura

The pattern of puffing and protein synthesis was determined in individuals of Drosophila subobscura subjected to heat shock. Depending on the extent of the heat treatment, the response at the puffing level varied. Some puffs were expressed at 31°–34°C, and others at 37° C. Considering the response as a whole the depression of gene activity after shock at 31°–34° C in individuals raised at 19° C was greater than with the other treatments. Six major heat shock proteins (Hsps) were found in this species. The properties of the high molecular weight proteins are conserved their electrophoretic characteristics and the range of temperatures over which they are synthesized are close to those in other Drosophila species. Remarkable heterogeneity was found in the small Hsps. In addition, an M_r=41000 Hsp was clearly identified in this species. A low level of variability in the patterns of protein synthesis compared with those of puffing activity was detected.     

Temperature-dependent lipid content and fatty acid composition of three thermophilic bacteria

The lipid content and fatty acid composition of a strain ofBacillus caldolyticus and of two facultative thermophiles (B. flavothermus and strain NZ-2) were analysed after growth at different temperatures. In all three strains the amount of membrane, as a fraction of total cellular dry mass, was found to increase with temperature, however, in varying degrees. Changes of lipid content and protein/lipid ratio inB. caldolyticus between 60°C and 100°C and in strain NZ-2 between 45°C and 70°C were minor; inB. f avothermus the alterations in the 50°C–70°C range were more pronounced. The same was found for changes observed in the phospholipid/total lipid and phospholipid/membrane ratios, and also in the amounts of individual phospholipids. The alterations of the fatty acid composition were most significant inB. caldolyticus, especially between 80°C and 95°C. In contrast, the main changes inB. flavothermus and NZ-2 were found to occur between 30°C and 50°C, and between 45°C and 60°C, respectively. Based on these data, strain NZ-2 could be characterized as the least andB. flavothermus as the most versatile of the three organisms.     

Regulation of histidine biosynthetic enzymes in a mutant of Escherichia coli with an altered histidyl-tRNA synthetase

Summary A mutant of Escherichia coli was isolated that grew at a normal rate in minimal medium at 26°C, grew at a normal rate in minimal medium at 37°C only if exogenous histidine was supplied, and grew more slowly than normal at 42°C even in the presence of histidine. In very rich media the growth rate of the mutant was normal at 26°C and 30°C, but not at 37°C or 42°C. It may be described as a temperature-conditional histidine bradytroph with a decreased ceiling to its growth rate.The histidyl-tRNA synthetase of the mutant was found to be abnormal; in crude extracts the enzyme activity was less stable and had approximately a tenfold higher apparent K _Mfor histidine than normal.Under many growth conditions the histidine biosynthetic enzymes in the mutant were derepressed several hundred fold compared to the wild strain, even in the presence of exogenous genous histidine. In general, the degree of derepression in the mutant was proportional to the difference in growth rate between the mutant and normal strains; this relationship, however, did not hold below 30°C or above 37°C.The properties of the mutant could be related to the properties of its histidyl-tRNA synthetase by assuming that the enzyme participates both in protein synthesis and in histidine biosynthetic enzyme regulation and that at low temperature it functions relatively more effectively in protein synthesis than in repression, while at high temperature it functions relatively more effectively in repression.Abbreviations used tRNA transfer RNA - AICAR aminoimidazole carboxamide ribose-5-phosphate