Mutations in Escherichia coli pmp and htpR genes stabilize the products of foreign gene expression

The half lives of mRNA for Escherichia coli chloramphenicol-acetyltransferase, Bacillus amyloliquefaciens alpha-amylase and human leucocyte interferon were measured in E. coli cells by molecular RNA.DNA hybridization. The effect of mutation in pnp gene, coding polynucleotide phosphorylase, on the stability of these mRNA was studied. The half life of interferon mRNA increases from 25 to 90 s in the pnp mutant, resulting in an increase of interferon accumulation. The stability of interferon in E. coli cells depends on the htpR gene, controlling the heat shock response. The yields of leucocyte interferons alpha-2, alpha I-1 and fibroblast interferon beta increase ten times in htpR mutants. Thus, by using pnp and htpR mutants it is possible to enhance considerably the eukaryotic gene expression in bacterial cells.     

sn-glycerol-3-phosphate acyltransferase tubule formation is dependent upon heat shock proteins (htpR)

Overexpression of the Escherichia coli sn-glycerol-3-phosphate (glycerol-P) acyltransferase, an integral membrane protein, causes formation of ordered arrays of the enzyme in vitro. The formation of these tubular structures did not occur in an E. coli strain bearing a mutation in the htpR gene, the regulatory gene for the heat shock response. The htpR165 mutation was shown by genetic analysis to be the lesion responsible for blockage of tubule formation. Similar amounts of glycerol-P acyltransferase were produced in isogenic htpR+ and htpR165 strains, ruling out an effect of htpR165 on expression of glycerol-P acyltransferase. Further, phospholipid metabolism was not altered in either strain after induction of glycerol-P acyltransferase synthesis. Increased glycerol-P acyltransferase synthesis caused a partial induction of the heat shock response which was dependent upon a wild type htpR gene. The heat shock proteins induced were identified as the groEL and dnaK gene products on two-dimensional gels. These two proteins have been implicated in the assembly of bacteriophage coats. These heat shock proteins appear essential for tubule formation.     

Mutations in the rpoH (htpR) gene of Escherichia coli K-12 phenotypically suppress a temperature-sensitive mutant defective in the sigma 70 subunit of RNA polymerase.

Escherichia coli K-12 strain 285c contains a mutation in rpoD, the gene encoding the sigma subunit of RNA polymerase. The 70-kilodalton sigma polypeptide encoded by this allele is unstable, and this instability leads to temperature-sensitive growth. We describe the isolation and characterization of four temperature-resistant pseudorevertants of 285c that can grow at high temperature. Each of these revertants increased the stability of the sigma 70 mutant protein. The map position of the suppressor mutations was close to that of the rpoH (htpR) gene. A multicopy plasmid containing the intact rpoH gene restored the temperature-sensitive phenotype. Marker rescue experiments established the positions of three of the alleles within the rpoH gene. One mutation has been sequenced and causes a leucine-to-tryptophan change 7 amino acids from the carboxyl terminus of the rpoH gene product.     

Thermo-regulated expression of the htpR gene under the control of the PR-promotor of bacteriophage lambda induces supersynthesis of heat shock proteins

The mechanisms of induction of heat shock protein synthesis in E. coli have been studied. For this purpose plasmids in which htpR gene expression is controlled by the PR-promoter of bacteriophage lambda and by the Trp-promoter have been constructed. An effective induction of heat shock proteins requires both an increased content of htpR protein and additional cofactors formed in the cell under heat shock conditions.     

Effect of temperature and htpR on the biosynthesis of superoxide dismutase in Escherichia coli

The synthesis of Mn- and FeSODs in response to temperature changes was examined in strains of Escherichia coli with different mutations in sod and htpR genes. Growth at or shift to elevated temperatures induced FeSOD but not MnSOD. The induction of FeSOD by heat was inhibited by chloramphenicol and was independent of the heat shock (htpR-controlled) regulon. FeSOD was more stable at 42 degrees C than was MnSOD.     

Molecular cloning and expression of a gene that controls the high-temperature regulon of Escherichia coli.

The high-temperature production (HTP) regulon of Escherichia coli consists of a set of operons that are induced coordinately by a shift to a high temperature under the control of a single chromosomal gene called htpR or hin. To identify more components of this regulon, the rates of synthesis of many polypeptides resolved on two-dimensional polyacrylamide gels were measured in various strains by pulse-labeling after a temperature shift-up. A total of 13 polypeptides were found to be heat inducible only in cells bearing a normal htpR gene on the chromosome or on a plasmid; on this basis these polypeptides were designated products of the HTP regulon. Several hybrid plasmids that contain segments of the E. coli chromosome in the 75-min region were found to carry the htpR gene. A restriction map of this region was constructed, and selected fragments were subcloned and tested for the ability to complement an htpR mutant. The polypeptides encoded by these fragments were detected by permitting expression in maxicells, minicells, and chloramphenicol-treated cells. Complementation was accompanied by production of a polypeptide having a molecular weight of approximately 33,000. This polypeptide, designated F33.4, was markedly reduced in amount in an htpR mutant expected to contain very little htpR gene product. Polypeptide F33.4 is postulated to be the product of htpR and to be an effector that controls heat induction of the HTP regulon.     

Regulation of proteolytic processes using antisense RNA genes htpR and lon of Escherichia coli in hetero- and homologous genetic systems

Possibility of correction of proteolytic processes in cells of Escherichia coli and Pseudomonas aeruginosa has been studied. For this purpose recombinant plasmids directing the synthesis of antisense RNAs were constructed. In Ps. aeruginosa the synthesis of htpR antisense RNA resulted in 2.5-fold reduction of the intensity of degradation of 3H-puromycin polypeptides under heat shock conditions. An antisense RNA complementary to the 5'- end of E. coli lon gene decreased the same index to the level observed in lon- mutants. Genes homologous to htpR and lon genes of E. coli were found in Pseudomonas: bacteria in hybridisation experiments. This finding suggests that the genetic system of heat shock in these microorganisms is organized in a similar manner.     

Mutants of Escherichia coli K-12 with increased resistance to ionizing radiation. VI. Increased radioresistance and heat shock proteins

By means of one-dimensional electrophoresis, it is shown that in radiation-resistant Gamr444 and Gamr445 mutants of Escherichia coli K-12 high-molecular weight heat shock proteins are hyperproduced at 32-37 degrees C and are induced more intensively during heat shock (in comparison to the parental wild-type strain AB1157). When the missense htpR15 mutation of the positive regulatory htpR gene for heat shock proteins was introduced by transduction into the genome of the Gamr444 mutant, its enhanced radiation-resistance disappeared but could be restored upon introduction of pKV3 plasmid bearing the htpR+ gene. These data show that heat shock proteins are participating in the enhanced radioresistance of Gamr mutants.     

Directed mutagenesis of chromosomal genes of Escherichia coli in vivo: construction of RecA- and HtpR- mutants

The deletions in Escherichia coli chromosomal genes recA and htpR were constructed using the site-directed mutagenesis techniques. The obtained RecA- mutants are UV-sensitive and have a phenotype defective for the homologous DNA recombination. HtpR- mutant is temperature sensitive for growth and deficient in intracellular proteolysis. As a result a HtpR- mutant seems to be a preferable candidate for attempting to synthesize efficiently any alien protein in Escherichia coli cells.     

lon gene product of Escherichia coli is a heat-shock protein

The product of the pleiotropic gene lon is a protein with protease activity and has been tentatively identified as protein H94.0 on the reference two-dimensional gel of Escherichia coli proteins. Purified Lon protease migrated with the prominent cellular protein H94.0 in E. coli K-12 strains. Peptide map patterns of Lon protease and H94.0 were identical. A mutant form of the protease had altered mobility during gel electrophoresis. An E. coli B/r strain that is known to be defective in Lon function contained no detectable H94.0 protein under normal growth conditions. Upon a shift to 42 degrees C, however, the Lon protease was induced to high levels in K-12 strains and a small amount of protein became detectable at the H94.0 location in strain B/r. Heat induction of Lon protease was dependent on the normal allele of the regulatory gene, htpR, establishing lon as a member of the high-temperature-production regulon of E. coli.     

High-level expression of a proteolytically sensitive diphtheria toxin fragment in Escherichia coli.

ABM508 is a recombinant fusion protein consisting of the N-terminal 485 amino acids of diphtheria toxin joined to alpha-melanocyte-stimulating hormone. When expressed in Escherichia coli under the control of the tox promoter and signal sequence, ABM508 is severely degraded. When overexpressed from a thermoinducible lambda pR promoter fusion, ABM508 is largely insoluble. We compared the expression of ABM508 (501 amino acids) to a full-length mutant form of the toxin (CRM197; 535 amino acids) and found that CRM197 showed minimal proteolysis. Thus, the removal of the C-terminal 50 amino acids of the toxin destabilizes the protein, making it a target for proteases. Proteolysis of ABM508 could be reduced by removal of the tox signal sequence (thereby directing the protein to the cytoplasm) and growth in lon and htpR mutant strains of E. coli. We also showed that the solubility of tox gene products expressed in E. coli was directly related to the growth temperature of the culture. Thus, a fragment A fusion protein (223 amino acids), ABM508, and CRM197 were found in soluble extracts when expressed at 30 degrees C but could not be released by the same procedures after growth at 42 degrees C. On the basis of these observations, we fused the coding sequences for mature ABM508 to the trc promoter (inducible at 30 degrees C by isopropyl-beta-D-thiogalactoside) and expressed this construct in a lon htpR strain of E. coli. This plasmid made 10 mg of soluble tox protein per liter of culture (7.7% of the total cell protein) or 14 times more than our previous maximal level. Extracts from lon htpR cells harboring this plasmid had high levels of ADP-ribosyltransferase activity, and although proteolysis still occurred, the major tox product corresponded to full-length ABM508.     

Properties of thermostable HtpR-mutant of Escherichia coli

A thermoresistant htpR mutant having a decreased level of proteolytic activity has been selected in E. coli strain K802 after the directed mutagenesis in vivo. The mutation results in the bacteriophage T7 RNA-polymerase stability, aminoglycosidephosphotransferase stability as well as in the decrease in the rate of proteolytic degradation of cytoplasmic proteins during the heat shock. The obtained mutant strain can, probably be used as a host for alien polypeptides production.