Heat shock inactivates a supernatant factor(s) specifically required for efficient expression of the amp gene in Escherichia coli

A 160,000 x g supernatant of E. coli extract prepared from cells grown at 30 degrees C stimulated specifically the expression of the amp gene on pBR322 and pBR328 in an in vitro gene expression system from E. coli. This activity of the supernatant was markedly reduced when the cells were exposed to 42 degrees C for 30 min prior to preparing the supernatant. These results are consistent with the view that heat shock-induced repression of the amp gene expression is due to inactivation of a supernatant factor(s) required for effective expression of the amp gene.     

Response to temperature shifts of expression of the amp gene on pBR322 in Escherichia coli K-12.

Synthesis of beta-lactamase, the product of the amp gene on pBR322, in Escherichia coli K-12 was reversibly repressed with a shift-up of the growth temperature from 30 to 42 degrees C. The temperature shift, however, did not affect the level of mRNA encoding beta-lactamase, which suggested the involvement of translational control.     

Temperature-sensitive mutants in rfaI and rfaJ, genes for galactosyltransferase I and glucosyltransferase II, for synthesis of lipopolysaccharide in Salmonella typhimurium

Certain rough mutants of Salmonella typhimurium LT2 were shown to be temperature sensitive for the production of lipopolysaccharide (LPS). When grown at the restrictive temperature (42 or 45 degrees C), the cells contained LPS deficient in O (somatic) side chains, based on phage-sensitivity data and gel electrophoresis of the LPS. Cells grown at the permissive temperature, 30 degrees C, made LPS resembling that of smooth cells. The mobility of the LPS in gels, the phage sensitivity patterns, and gas chromatographic analysis indicate that LPS of 45 degrees C-grown cells of SA126 (rfaJ3012) is of chemotype Rb2, with one glucose and two galactose units (and thus inferred to be due to a mutation in rfaJ), and LPS of 45 degrees C-grown cells of SA134 (rfa13020) is of chemotype Rb3, with one glucose and one galactose unit (inferred to be rfaI). These inferences were confirmed, for pKZ26 (pBR322-rfaGBIJ) and pKZ27 (pBR322-rfaGBI) both complement rfaI3020, but only pKZ26 complemented rfaJ3012. In addition, pKZ26 carrying a Tn5 insertion resulting in loss of complementation of a known rfaJ mutation, but not of rfaG, B, or I, also resulted in loss of rfaJ3012 complementation. Based on gel analysis, there is a small amount of the LPS containing smooth side chains in cells of SA126 grown at 45 degrees C; following a switch to 30 degrees C, the amount of LPS with O side chains gradually increased, and the amount of core LPS was reduced, though even after 3 h the LPS does not fully resemble that of smooth strains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of temperature and cycloheximide on secretion of cloned invertase from recombinant Saccharomyces cerevisiae

The effects of temperature on the kinetics and efficiency of secretion of cloned invertase were investigated in a recombinant yeast system. This system consisted of the baker's yeast Saccharomyces cerevisiae (SEY2102) transformed with the 2mu-based plasmid pBR58 which contains the entire SUC2 gene including the promoter, signal sequence, and structural gene. The recombinant yeast produces the naturally secreted yeast enzyme invertase. In transition experiments done at temperatures ranging from 25 degrees to 45 degrees C, the maximum invertase level and secretion rate exhibited maxima of 5.5 U/mL . OD and 4.6 U/mL . OD per hour, respectively, at 35 degrees C. Experiments involving the use of cycloheximide showed that it took approximately 15 min for secreted invertase to move through the secretion pathway, which held 0.4 U/mL . OD of specific activity. (c) 1995 John Wiley & Sons, Inc.     

Rifampicin-induced replication of the plasmid pBR322 in Escherichia coli strains carrying dnaA mutations

The replication pattern of the plasmid pBR322 was examined in the dnaA mutants of Escherichia coli. The rate of pBR322 DNA synthesis is markedly decreased after dnaA cells are shifted to the restrictive temperature of 42 degrees C. However, addition of rifampicin (RIF) to cultures of dnaA strains incubated at 42 degrees C after a lag of 90 min results in a burst of pBR322 synthesis. This RIF-induced pBR322 replication remains dependent on DNA polymerase I activity. Efficient plasmid pBR322 replication is observed at 42 degrees C in the double mutant dnaA46cos bearing an intragenic suppressor of dnaA46. Though replication of pBR322 in dnaA46cos growing at 42 degrees C is initially sensitive to RIF plasmid synthesis is restored after 90 min incubation in the presence of the drug. RIF-induced replication of the plasmid pBR327, lacking the rriB site implicated in RIF-resistant synthesis of the L strand of ColE1-like plasmids (Nomura and Ray 1981; Zipursky and Marians 1981), was observed also in dnaA46 at 42 degrees C.     

Molecular cloning of the cls gene responsible for cardiolipin synthesis in Escherichia coli and phenotypic consequences of its amplification.

The cls gene responsible for cardiolipin synthesis in Escherichia coli K-12 was cloned in a 5-kilobase-pair DNA fragment inserted in a mini-F vector, pML31, and then subcloned into a 2.0-kilobase-pair fragment inserted in pBR322. The initial selection of the gene was accomplished in a cls pss-1 double mutant that had lesions in both cardiolipin and phosphatidylserine synthases and required either the cls or the pss gene product for normal growth at 42 degrees C in a broth medium, NBY, supplemented with 200 mM sucrose. The cloned gene was identified as the cls gene by the recovery and amplification of both cardiolipin and cardiolipin synthase in a cls mutant as well as by the integration of a pBR322 derivative into its genetic locus at 27 min on the chromosome of a polA1 mutant. The maxicell analysis indicated that a protein of molecular weight 46,000 is the gene product. The cls gene is thus most likely the structural gene coding for cardiolipin synthase. Hybrid plasmids of high copy numbers containing the cls gene were growth inhibitory to pss-I mutants under the above selective conditions, whereas they inhibited neither the growth of pss-I mutants at 30 degrees C nor that of pss+ strains at any temperature. Amplification of cardiolipin synthase activity was observed, but was not proportional to the probable gene dosage (the enzyme activity was at most 10 times that in wild-type cells), and cardiolipin synthesis in vivo was at the maximum 1.5 times that in wild-type strains, implying the presence in E. coli cells of a mechanism that avoids cardiolipin overproduction, which is possibly disadvantageous to proper membrane functions.     

A plasmid vector with temperature-controlled gene expression

A 169 b.p. fragment including the bla gene promoter p3 has been removed from pBR327 plasmid, and the deleted plasmid used for cloning the TaqI/BglII-fragment of the lambda c1857ind- DNA containing promoter pR and gene cI to obtain plasmid pCE119. Cells containing pCE119 produced a high level of beta-lactamase at 42 degrees C, the yield at 42 degrees C being 100 times higher than at 32 degrees C. For cloning and functional assays a pCEZ12 plasmid was constructed, in which promoter pR and repressor cI of lambda phage control the expression of the semi-synthetic beta-galactosidase gene. Yield of beta-galactosidase produced by pCEZ12 at 42 degrees C was ca. 300 times higher than at 32 degrees C.     

Disruption of the gene for Hsp30, an alpha-crystallin-related heat shock protein of Neurospora crassa, causes defects in import of proteins into mitochondria

The gene for Hsp30, the only known alpha-crystallin-related heat shock protein of Neurospora crassa, was disrupted by repeat-induced point mutagenesis, leading to loss of cell survival at high temperature. Hsp30, which is not synthesized at 30 degrees C, associates reversibly with the mitochondria at high temperature (45 degrees C). In this study, we found that import of selected proteins into internal compartments of mitochondria, following their synthesis in the cytosol, was severely impaired at high temperature in a strain mutant in Hsp30. After 70 min of cell incubation at 45 degrees C, most matrix, inner membrane, and intermembrane-space proteins tested were reduced in import by about 50-70% in the mutant, as compared to wild-type cells. In contrast, assembly of selected proteins into the outer mitochondrial membrane was not reduced, except for one component of the preprotein translocase complex of the mitochondrial outer membrane. Three proteins of this complex co-immunoprecipitated with Hsp30 of wild-type cells incubated at 45 degrees C. We propose that Hsp30 interacts with the preprotein translocase of the mitochondrial outer membrane and that it chaperones the activity of one or more components of this translocase complex at high temperature.     

Exposure to pretreatment hypothermia as a determinant of heat killing

When Chinese hamster ovary (CHO) cells were exposed to 22 degrees C for 2 hr prior to 42.4 degrees C hyperthermia, neither the shoulder region of the survival curve nor the characteristic development of thermotolerance after 3-4 hr of heating were observed. Absolute cell survival after 4 hr at 42.4 degrees C was decreased by a factor of between 10 and 100 (depending on the rate of heating of nonprecooled controls). Conditioning at 30 degrees C for 2 hr, 26 degrees C for 2 hr, or 22 degrees C for 20 min followed by heating to 42.4 degrees C over 30 min did not result in sensitization. Prolonged (16 hr) conditioning at 30 degrees C, however, increased the cytotoxicity of immediate exposure to 41.4 or 45 degrees C with maximum sensitization to 45 degrees C occurring after 6 hr at 30 degrees C. Both 3- and 18-hr pretreatments at 30 degrees C similarly increased the cytotoxicity of 45-41.5 degrees C step-down heating (D0 = 28 min in precooled versus 40 min in nonprecooled cells).     

Two-level factorial screening for influence of temperature, pH, and aeration on production of Serratia marcescens nuclease

Two high-nuclease-yielding mutants of Serratia marcescens, derived by chemical mutagenesis (W280, W355), and two strains with the pBR322 plasmid 403-SD2, carrying a nuclease gene and a chloramphenicol resistance gene [Escherichia coli CSH50(403-SD2) and S. marcescens CH30(403-SD2)] were investigated for nuclease production in a factorial shake flask experiment, with temperature (30 and 37 degrees C), pH (with or without CaCO3 tablets), and aeration (with or without baffles) as variable conditions. Yields varied 10-fold depending on the conditions investigated.     

Partition functions of unit-copy plasmids can stabilize the maintenance of plasmid pBR322 at low copy number.

The maintenance of plasmid pBR322 is highly unstable in a polA12 strain of Escherichia coli at 29 degrees C due to severely reduced copy number. Under these conditions, introduction of the par (partition) locus of plasmid P1 or the par (sop) region of F into pBR322 stabilizes it. A region with similar activity was detected in the P7 plasmid. The activity of the P1 par locus was dependent on the P1 parA gene product and was sensitive to par-specified incompatibility.     

Two-level factorial screening for influence of temperature, pH, and aeration on production of Serratia marcescens nuclease.

Two high-nuclease-yielding mutants of Serratia marcescens, derived by chemical mutagenesis (W280, W355), and two strains with the pBR322 plasmid 403-SD2, carrying a nuclease gene and a chloramphenicol resistance gene [Escherichia coli CSH50(403-SD2) and S. marcescens CH30(403-SD2)] were investigated for nuclease production in a factorial shake flask experiment, with temperature (30 and 37 degrees C), pH (with or without CaCO3 tablets), and aeration (with or without baffles) as variable conditions. Yields varied 10-fold depending on the conditions investigated.     

Function of the N-terminal half of RepA in activation of Rts1 ori.

The RepA protein of the Rts1 plasmid, consisting of 288 amino acids, is a trans-acting protein essential for replication. A mutant repA gene, repA delta C143, carrying a deletion that removed the 143 C-terminal amino acids of RepA, could transform, but at a low frequency, an Escherichia coli polA strain, JG112, when repA delta C143 was cloned into pBR322 with Rts1 ori in the natural configuration. The transformation was less efficient without the dyad DnaA box in the ori region, and no transformation occurred at 42 degrees C, characteristic of Rts1 replication. A fusion of the 3'-terminal half of repA of the P1 plasmid to repA delta C143 yielded a pBR322 chimeric plasmid that contained Rts1 ori through hybrid (Rts1-P1) repA. This plasmid was maintained much more stably in JG112 at 37 degrees C. At 42 degrees C, however, it was quite unstable. The overproduced hybrid RepA protein showed interference with mini-Rts1 replication in trans and also exhibited an autorepressor function, although both activities were decreased. These findings suggest that the N-terminal half of the RepA molecule of Rts1 is involved in the activation of the replication origin.     

Isolation of a dnaA mutant of Bacillus subtilis defective in initiation of replication: amount of DnaA protein determines cells'' initiation potential.

The dnaA gene is essential for initiation of chromosomal replication in Escherichia coli. A gene homologous with the E. coli dnaA was found in the replication origin region of the Bacillus subtilis chromosome. We have now isolated a temperature sensitive mutant of the B. subtilis dnaA by in vitro mutagenesis of the cloned gene. At a nonpermissive temperature, 49 degrees C, DNA replication stops completely after 60% increase in a rich medium, while cell mass continues to increase exponentially at 2.5 times the rate at 30 degrees C. A ratio of gene frequency between purA (origin marker) and metB (terminus marker) changes gradually from 2.7 at 30 degrees C to 1.0 in 45 min at 49 degrees C, indicating completion of the ongoing replication cycle. Upon the temperature shift down to 30 degrees C after the incubation at 49 degrees C for 60 min, DNA replication resumes without delay, and the purA/metB ratio increases rapidly to 6, i.e. consecutive initiation of more than two rounds of replication. Addition of chloramphenicol at the time of the temperature shift down did not inhibit the increase in the purA/metB ratio, while rifampicin inhibited the re-initiation completely. The mutation is a single base change from C to T in the dnaA gene resulting in an amino acid substitution from Ser to Phe in the DnaA protein. The mutation was responsible for both temperature sensitive growth and the defect in initiation of chromosomal replication. We observed a remarkable correlation between the amount of DnaA protein and the amount of initiation potential accumulated during incubation at the non-permissive temperature.     

The translation start signal region of TEM beta-lactamase mRNA is responsible for heat shock-induced repression of amp gene expression in Escherichia coli.

pBR322 contains the amp gene encoding beta-lactamase. When Escherichia coli carrying this plasmid is exposed to heat shock, beta-lactamase synthesis is repressed transiently at the translational level. To identify the DNA element responsible for this translational repression, DNA segments containing the translation start region of the amp gene were excised from pAT153 and fused in frame with the lacZ reading frame in the open reading frame vector pORF1. These constructs were introduced into E. coli, and the effect of heat shock of the cells on the synthesis of beta-galactosidase starting from the amp start codon was examined. As is the case for pBR322-encoded synthesis of beta-lactamase, the synthesis of beta-galactosidase encoded by the fused genes also ceased transiently upon heat shock. It is concluded that the heat shock-induced repression of the amp gene occurs at the initiation step of translation. As far as the present study is concerned, the minimum DNA segment responsible for the repression is AT TGA AAA AGG AAG AGT ATG AG, which includes the Shine-Dalgarno sequence (AAGGA) and the initiation codon (ATG).     

Integration of hybrid plasmids-derivatives of staphylococcal plasmid pE3692 and pBR322 vector with Bacillus subtilis chromosome

Bacillus subtilis is a nonpathogenic microorganism which certainly for also that feature is widely used in several biotechnological processes. Certainly, because of that an elaboration of gene cloning methods in Bacillus subtilis cells is of great significance both from scientific and practical point of view. It was found hybrid plasmids constructed by ligation of pE3692 and pE3692-9 staphylococcal plasmids with pBR322 vector can be integrated with B. subtilis chromosome. Selection of cells in the presence of erythromycin at 50 degrees C allows to isolate clones containing exclusively integrated plasmids. Growth rate of cells containing these plasmids in the selective medium is the same or slightly higher at 50 degrees C than at 37 degrees C. It seems that hybrid plasmid tested pBE4 and pBE91 after appropriate reconstruction in vitro could serve as vectors for B. subtilis gene cloning.     

Physiological consequences of mutations in Escherichia coli heat shock dnaK and dnaJ genes.

Mutations in the heat shock genes, dnaK and dnaJ, cause severe defects of several cellular functions. Null dnaJ and dnaKdnaJ mutations can be transduced in a restricted range of temperature. The efficiency of transformation with three unrelated plasmids, viz pACYC184, pBR322 and pSC101, is two times lower in dnaK mutants while the dnaJ mutant is characterized by slightly impaired transformation with pSC101 only. The lack of DnaJ function negatively influences the stability of pSC101 at 42 degrees C, and this plasmid cannot be stably maintained at 30 degrees C in the delta dnaKdnaJ mutant. The double deletion mutant, delta dbaKdnaJ, is characterized by impaired osmoadaptation. The galactokinase content is lower in both mutants tested compared with wild-type strains even at 30 degrees C. The efficient complementation of some of these defects by the wild-type alleles present on low-copy number plasmid was achieved.