High temperature induction of a stringent response in the dnaK(Ts) and dnaJ(Ts) mutants of Escherichia coli

The cellular concentrations of ppGpp in the dnaK(Ts) and dnaJ(Ts) mutants of Escherichia coli were examined, since the thermosensitive RNA synthesis of these mutants is relaxed by an additional mutation in the relA gene. The results showed that ppGpp accumulated extensively in the dnaK(Ts) and dnaJ(Ts) mutants after a temperature shift up, reaching levels of 5 mM and 0.5 mM, respectively. This unusual accumulation of ppGpp was suppressed by the relA1 mutation, implying that it results from induction of a stringent response in these mutants at a nonpermissive temperature.     

Isolation and characterization of a temperature-sensitive dnaK mutant of Escherichia coli B.

A temperature-sensitive dnaK mutant (strain MT112) was isolated from Escherichia coli B strain H/r30RT by thymineless death selection at 43 degrees C. By genetic mapping, the mutation [dnaK7(Ts)] was located near the thr gene (approximately 0.2 min on the may). E. coli K-12 transductants of the mutation to temperature sensitivity were assayed for their susceptibility to transducing phage lambda carrying the dnaK and/or the dnaJ gene. All of the transductants were able to propagate phage lambda carrying the dnaK gene. When macromolecular synthesis of the mutant was assayed at 43 degrees C, it was observed that both deoxyribonucleic acid and ribonucleic acid syntheses were severely inhibited. Thus, it was suggested that the conditionally defective dnaK mutation affects both cellular deoxyribonucleic acid and ribonucleic acid syntheses at the nonpermissive temperature in addition to inability to propagate phage lambda at permissive temperature.     

Cloning and characterization of ftsN, an essential cell division gene in Escherichia coli isolated as a multicopy suppressor of ftsA12(Ts).

A new cell division gene, ftsN, was identified in Escherichia coli as a multicopy suppressor of the ftsA12(Ts) mutation. Remarkably, multicopy ftsN suppressed ftsI23(Ts) and to a lesser extent ftsQ1(Ts); however, no suppression of the ftsZ84(Ts) mutation was observed. The suppression of ftsA12(Ts), ftsI23(Ts), and ftsQ1(Ts) suggests that FtsN may interact with these gene products during cell division. The ftsN gene was located at 88.5 min on the E. coli genetic map just downstream of the cytR gene. ftsN was essential for cell division, since expression of a conditional null allele led to filamentation and cell death. DNA sequence analysis of the ftsN gene revealed an open reading frame of 319 codons which would encode a protein of 35,725 Da. The predicted gene product had a hydrophobic sequence near its amino terminus similar to the noncleavable signal sequences found in several other Fts proteins. The presumed extracellular domain was unusual in that it was rich in glutamine residues. A 36-kDa protein that was localized to the membrane fraction was detected in minicells containing plasmids with the ftsN gene, confirming that FtsN was a membrane protein.     

Increased unsaturated fatty acid production associated with a suppressor of the fabA6(Ts) mutation in Escherichia coli.

Plasmids that corrected the temperature-sensitive unsaturated fatty acid auxotrophy of strain M6 [fabA6 (Ts)] were isolated from an Escherichia coli genomic library. Subcloning and physical mapping localized the new gene (called sfa for suppressor of fabA) at 1,070 kb on the E. coli chromosome. DNA sequencing revealed the presence of a 227-bp open reading frame which directed the synthesis of a peptide of approximately 8 kDa, which correlated with the correction of the fabA6(Ts) phenotype. However, the sfa gene was an allele-specific suppressor since plasmids harboring the sfa gene corrected the growth phenotype of fabA6(Ts) mutants but did not correct the growth of fabA2(Ts) or fabB15(Ts) unsaturated fatty acid auxotrophs. Overexpression of the sfa gene in fabA6(Ts) mutants restored unsaturated fatty acid content at 42 degrees C, and overexpression in wild-type cells resulted in a substantial increase in the unsaturated fatty acid content of the membrane. Thus, the suppression of the fabA6(Ts) mutation by sfa was attributed to its ability to increase the biosynthesis of unsaturated fatty acids.     

Characterization of the Escherichia coli protein-export gene secB

The Escherichia coli secB gene product is required for normal export of envelope proteins out of the cell cytoplasm. In this report, we present the identification and nucleotide sequence of the secB coding sequence. The secB structural gene overlaps almost completely with a predicted open reading frame (ORF) that is encoded on the opposite strand. To establish the identity of the secB ORF, we characterized a secB mutation that caused total loss of secB function, based upon its phenotype. This mutation resulted from a nucleotide change that caused an ochre mutation in one ORF (the secB gene) and a silent (no amino acid change) codon change in the opposite ORF.     

Cloning and nucleotide sequence of the gene (citA) encoding a citrate carrier from Salmonella typhimurium.

A cryptic citrate transport gene (citA) from Salmonella typhimurium chromosome was cloned and its nucleotide sequence was determined. The cloned plasmid conferred citrate-utilizing ability on wild-type Escherichia coli, which cannot grow on citrate as the sole source of carbon. The resultant E. coli transformant was able to transport citrate. A 1,302-base-pair open reading frame with a preceding ribosomal binding site was found in the cloned DNA fragment. The 434-amino-acid protein that could be translated from this open reading frame is highly hydrophobic (69% nonpolar amino acid residues), consistent with the fact that the transport protein is an intrinsic membrane protein. The molecular weight of this protein was calculated to be 47,188. The gene sequence determined is highly homologous to those of Cit+ plasmid-mediated citrate transport gene, citA, from E. coli, the chromosomal citA gene from Citrobacter amalonaticus and the chromosomal cit+ gene from Klebsiella pneumoniae. The hydropathy profile of the deduced amino acid sequence suggests that this carrier has 12 hydrophobic segments, which may span the membrane lipid bilayer.     

Nucleotide sequence and deduced amino acid sequence of Escherichia coli pyruvate oxidase, a lipid-activated flavoprotein.

The entire nucleotide sequence of the poxB (pyruvate oxidase) gene of Escherichia coli K-12 has been determined by the dideoxynucleotide (Sanger) sequencing of fragments of the gene cloned into a phage M13 vector. The gene is 1716 nucleotides in length and has an open reading frame which encodes a protein of Mr 62,018. This open reading frame was shown to encode pyruvate oxidase by alignment of the amino acid sequences deduced for the amino and carboxy termini and several internal segments of the mature protein with sequences obtained by amino acid sequence analysis. The deduced amino acid sequence of the oxidase was not unusually rich in hydrophobic sequences despite the peripheral membrane location and lipid binding properties of the protein. The codon usage of the oxidase gene was typical of a moderately expressed protein. The deduced amino acid sequence shares homology with the large subunits of the acetohydroxy acid synthase isozymes I, II, and III, encoded by the ilvB, ilvG, and ilvI genes of E. coli.     

Nucleotide sequence of the gene ompA coding the outer membrane protein II of Escherichia coli K-12.

A nucleotide sequence of 2271 basepairs has been determined from cloned E. coli DNA which contains ompA. Withing that sequence, starting at nucleotide 1037, an open translational reading frame encodes a protein of 367 amino acids which starting with amino acid 22 agrees with the primary structure of protein II. The preceeding 21 amino acids constitute a typical signal sequence. There is a non-translated region of 360 nucleotides in front of the translational start. The insertion point of an IS1 element 110 nucleotides upstream from the start codon and an amber codon at the position of amino acid residue 28 have been localized in the DNA from two ompA mutants.     

The dnaK protein modulates the heat-shock response of Escherichia coli

E. coli bacteria respond to a sudden upward shift in temperature by transiently overproducing a small subset of their proteins, one of which is the product of the dnaK gene. Mutations in dnaK have been previously shown to affect both DNA and RNA synthesis in E. coli. Bacteria carrying the dnaK756 mutation fail to turn off the heat-shock response at 43 degrees C. Instead, they continue to synthesize the heat-shock proteins in large amounts and underproduce other proteins. Both reversion and P1 transduction analyses have shown that the failure to turn off the heat-shock response is the result of the dnaK756 mutation. In addition, bacteria that overproduce the dnaK protein at all temperatures undergo a drastically reduced heat-shock response at high temperature. We conclude that the dnaK protein is an inhibitor of the heat-shock response in E. coli.     

UTP: alpha-D-glucose-1-phosphate uridylyltransferase of Escherichia coli: isolation and DNA sequence of the galU gene and purification of the enzyme.

The galU gene of Escherichia coli, thought to encode the enzyme UTP:alpha-D-glucose-1-phosphate uridylyltransferase, had previously been mapped to the 27-min region of the chromosome (J. A. Shapiro, J. Bacteriol. 92:518-520, 1966). By complementation of the membrane-derived oligosaccharide biosynthetic defect of strains with a galU mutation, we have now identified a plasmid containing the galU gene and have determined the nucleotide sequence of this gene. The galU gene is located immediately downstream of the hns gene, and its open reading frame would be transcribed in the direction opposite that of the hns gene (i.e., clockwise on the E. coli chromosome). The nucleotide sequences of five galU mutations were also determined. The enzyme UTP:alpha-D-glucose-1-phosphate uridylyltransferase was purified from a strain containing the galU gene on a multicopy plasmid. The amino-terminal amino acid sequence (10 residues) of the purified enzyme was identical to the predicted amino acid sequence (after the initiating methionine) of the galU-encoded open reading frame. The functional enzyme appears to be a tetramer of the galU gene product.