A second prepilin peptidase gene in Escherichia coli K-12

Escherichia coli K-12 strains grown at 37°C or 42°C, but not at 30°C, process the precursors of the Neisseria gonorrhoeae type IV pilin PilE and the Klebsiella oxytoca type IV pseudopilin PulG in a manner reminiscent of the prepilin peptidase-dependent processing of these proteins that occurs in these bacteria. Processing of prePulG in Escherichia coli requires a glycine at position −1, as does processing by the cognate prepilin peptidase (PulO), and is unaffected by mutations that inactivate several non-specific proteases. These data suggested that E . coli K-12 has a functional prepilin peptidase, despite the fact that it does not itself appear to express either type IV pilin or pseudopilin genes under the conditions that allow prePilE and prePulG processing. The E . coli K-12 genome contains two genes encoding proteins with significant sequence similarity to prepilin peptidases: gspO at minute 74.5 and pppA (f310c) at minute 67 on the genetic map. We have previously obtained evidence that gspO encodes an active enzyme but is not transcribed. pppA was cloned and shown to code for a functional prepilin peptidase capable of processing typical prepilin peptidase substrates. Inactivation of pppA eliminated the endogenous, thermoinducible prepilin peptidase activity. PppA was able to replace PulO prepilin peptidase in a pullulanase secretion system reconstituted in E . coli when expressed from high-copy-number plasmids but not when present in a single chromosomal copy. The analysis of pppA–lacZ fusions indicated that pppA expression was very low and regulated by the growth temperature at the level of translation, in agreement with the observed temperature dependence of PppA activity. Polymerase chain reaction and Southern hybridization analyses revealed the presence of the pppA gene in 12 out of 15 E . coli isolates.     

Partial suppression of the phenotype of Escherichia coli K-12 dnaG mutants by some I-like conjugative plasmids.

Three I-like conjugative plasmids, ColIdrd1, R144drd3, and R64drd11, which are derepressed for functions involved in conjugation, were found to suppress at least partially the phenotype of temperature-sensitive dnaG mutants of Escherichia coli K-12, as judged from the kinetics of deoxyribonucleic acid synthesis at elevated temperature in newly formed and established plasmid-containing strains. In contrast, the corresponding wild-type plasmids and three F-like derepressed conjugative plasmids, F101, R100drd1, and R1drd16, all failed to suppress. Suppression is presumably caused by a different plasmid-determined function from that which promotes survival of ultraviolet-irradiated bacteria, because both the wild-type I-like plasmids and their drd mutants protected irradiated bacteria. One possible interpretation of these results is that the product of a gene carried by certain I-like plasmids can substitute for the bacterial dnaG gene product during ongoing deoxyribonucleic acid replication.     

Cloning of the Escherichia coli K-12 hemB gene.

An Escherichia coli heme-requiring, heme-permeable mutant had no detectable 5-aminolevulinate dehydratase or porphobilinogen deaminase activities. The gene which complemented this mutation was cloned to a high-copy-number plasmid, and porphobilinogen deaminase activity was restored to normal levels, but the synthesis of 5-aminolevulinate dehydratase increased 20- to 30-fold. A maxicell procedure confirmed that the gene cloned was hemB.     

Insertion mutations in the dam gene of Escherichia coli K-12

The dam gene of E. coli can be inactivated by insertion of Tn9 or Mud phage. Strains bearing these mutations are viable indicating that the dam gene product is dispensable.     

RecOR suppression of recF mutant phenotypes in Escherichia coli K-12.

The recF, recO, and recR genes form the recFOR epistasis group for DNA repair. recF mutants are sensitive to UV irradiation and fail to properly induce the SOS response. Using plasmid derivatives that overexpress combinations of the recO+ and recR+ genes, we tested the hypothesis that high-level expression of recO+ and recR+ (recOR) in vivo will indirectly suppress the recF mutant phenotypes mentioned above. We found that overexpression of just recR+ from the plasmid will partially suppress both phenotypes. Expression of the chromosomal recO+ gene is essential for the recR+ suppression. Hence we call this RecOR suppression of recF mutant phenotypes. RecOR suppression of SOS induction is more efficient with recO+ expression from a plasmid than with recO+ expression from the chromosome. This is not true for RecOR suppression of UV sensitivity (the two are equal). Comparison of RecOR suppression with the suppression caused by recA801 and recA803 shows that RecOR suppression of UV sensitivity is more effective than recA803 suppression and that RecOR suppression of UV sensitivity, like recA801 suppression, requires recJ+. We present a model that explains the data and proposes a function for the recFOR epistasis group in the induction of the SOS response and recombinational DNA repair.     

rhs gene family of Escherichia coli K-12.

Two additional members of a novel Escherichia coli gene family, the rhs genes, have been cloned and characterized. The structures of these loci, rhsC and rhsD, have been compared with those of rhsA and rhsB. All four loci contain a homologous 3.7-kilobase-pair core. Sequence comparison of the first 300 nucleotides of the cores showed that rhsA, rhsB, and rhsC are closely related, with only 1 to 2% sequence divergence, whereas rhsD is 18% divergent from the others. The beginning of the core coincides with the initiation of an open reading frame that extends beyond the 300 nucleotides compared. Whether a protein product is produced from this open reading frame has not been established. However, nucleotide substitutions which differentiate the cores have highly conservative effects on the predicted protein products; this suggests that products are made from the open reading frame and are under severe selection. The four rhs loci have been placed on both the genetic and restriction maps of E. coli K-12. A fifth rhs locus remains to be characterized. In terms of size, number, and sequence conservation, the rhs genes make up one of the most significant repetitions in E. coli, comparable to the rRNA operons.     

R-factor-mediated suppression of the galactose-sensitive phenotype of Escherichia coli K-12 galE mutants

Plasmids S-a and Rts1 suppress the galactose-sensitive phenotype of galE mutants of Escherichia coli K-12, giving rise to both galactose-fermenting and nonfermenting strains. Fermenting strains produce normal inducible UDP-galactose epimerase. Plasmids extracted from either a fermenting or a nonfermenting strain are indistinguishable when examined by either measurements of length of relaxed circular molecules by electron microscopy or electrophoretic pattern of restriction endonuclease digestion products. The phenomenon could be explained by reversible recombination between a plasmid-borne epimerase gene and homologous chromosomal sequences.     

Cloning and structure of the hem A gene of Escherichia coli K-12

An Escherichia coli gene, which complements two independent hemA mutants of E. coli, has been cloned onto a multi-copy plasmid and both its strands have been sequenced. Both complemented mutants produce 5-aminolevulinic acid (ALA) and display fluorescence after 24h. The cloned sequence appears to encode a 46-kDa protein, which when produced in the maxicell procedure is processed to a 41-kDa protein as determined by sodium dodecyl sulfate-polyacrylamide-gel electrophoresis. The amino acid sequence of the cloned gene product shows no significant homologies with any cloned ALA synthase, nor with any protein, in two E. coli databanks. A second cloned gene fragment, which has its coding region 34 bp away from the coding region of the gene that complements hemA, has been identified as part of protein release factor 1(RF1), thus confirming the location of hemA at min 26.7 and mapping it precisely near RF1. We have shown that E. coli utilizes the intact five-carbon chain of glutamate for the synthesis of ALA [Li et al., J Bacteriol. 171 (1989b) 2547-2552].     

Molecular cloning of the fdhF gene of Escherichia coli K-12

Abstract The fdhF gene of Escherichia coli , coding for at least one component of benzyl viologen-linked formate dehydrogenase (FDH-BV) activity, was isolated on a ColE1- fdhF hybrid plasmid from the Clarke and Carbon colony bank.
Endonuclease restriction maps of this plasmid and its pBR322-subcloned derivative, pLW06, were constructed. Various hybrid plasmids were further obtained by deletion of endonuclease-cleaved fragments from pLW06 DNA. Their complementation pattern was analyzed after introduction into different fdhF mutant strains. The fdhF gene was shown to be located on a 5.5 kb Bam HI- Pvu II-DNA fragment, which restored FDH-BV activity to the wild-type level.     

Cloning of the adenylate cyclase gene of Escherichia coli K-12

The adenylate cyclase gene of Escherichia coli has been cloned on the plasmid vector pBR325. The hybrid plasmid pTH4 obtained has a molecular weight of 6,4 megadalton and represents pBR325 plasmid with the insertion of 2,8 megadalton in the Pst1 site. The cya mutant bacteria carrying pTH4 recover their ability to utilize mannitol, lactose and other carbohydrates as carbon sources, and lose this ability again in the case of rare spontaneous excision of the DNA insert from the Pst1 site. The phenotypical effect of pTH4 in cya mutants can be only seen in the crp+ genome. The strains carrying pTH4 are also characterized by the ability of beta-galactosidase induction under conditions of catabolite repression. Besides, the bacteria containing cya+ allele on the plasmid do not grow on glycerol, which seems to be caused by toxic concentrations of methylglyoxal formed as a result of the increased intracellular level of cyclic adenosine monophosphate.     

Partial characterization of a lysU mutant of Escherichia coli K-12.

The Escherichia coli K-12 strain GNB10181 shows no inducible lysyl-tRNA synthetase (LysRS) activity. Two-dimensional gel electrophoretic analysis of the polypeptides synthesized by this strain indicates that the normal lysU gene product, LysU, is absent. When both GNB10181 and its parent, MC4100, were grown at elevated temperatures (42 to 45 degrees C) no significant difference between their growth rates was observed. The lysU mutation was transferred to other E. coli K-12 backgrounds by using P1 transduction. The lysU transductants behaved comparably to their lysU+ parents at different growth temperatures. Therefore, the LysU proteins does not appear to be essential for growth at high temperatures, at least under the conditions examined here. In addition, lysU transductants were found to be defective for inducible lysine decarboxylase, (LDC), inducible arginine decarboxylase (ADI), and melibiose utilization (Mel), which are all missing in GNB10181. Complementation of the above missing functions was achieved by using the Clarke-Carbon plasmids pLC4-5 (LysU LDC) and pLC17-38 (LysU Mel ADI). From these experiments, it appears that GNB10181 has suffered a chromosomal deletion between 93.4 and 93.7 min, which includes the lysU gene. By using plasmid pLC17-38, the position of ADI on two-dimensional gels was identified. Finally, lysS delta lysU double mutants were constructed which can potentially be used as positive selection agents for the isolation of LysRS genes from other sources.     

Dominance of Ultraviolet Radiation Resistance in Partial Diploids of Escherichia coli K-12

Although an F'13 capR(+)/capR9 strain is nonmucoid and an F'13 capR9/capR(+) strain is mucoid, both strains are ultraviolet (UV)-resistant. In contrast, haploid capR9 strains are UV-sensitive. Therefore, UV resistance is dominant to UV sensitivity, regardless of whether the capR(+) allele is on the chromosome or on the F'13 episome.     

Molecular cloning of the N-acetylneuraminate lyase gene in Escherichia coli K-12

Summary The gene for N-acetylneuraminate lyase [N-acetylneuraminate pyruvate-lyase; NPL] of Escherichia coli C600 was cloned onto pBR322 as a 9.8 kilobase HindIII fragment of chromosomal DNA and the hybrid plasmid was designated pMK2. The gene in the hybrid plasmid was subcloned in pBR322 as a 1.2 kilobase HindIII-EcoRI fragment and the resultant hybrid plasmid was designated pMK6. NPL activity level was increased more than 5-fold in the pMK6-bearing strain compared with that of the wild type, when the cells were grown on a medium containing inducer (N-acetylneuraminate: NANA). The transformants harbouring pMK6 also showed higher activity even in the absence of inducer. The NPL produced by pMK6-bearing cells was structurally and immunologically the same as that purified from E. coli C600.     

Cloning the Escherichia coli K-12 argD gene specifying acetylornithine delta-transaminase

The argD gene of Escherichia coli was shown to be present in plasmids pLC2-28 and pLC3-11 of the collection of Clarke and Carbon [Cell 9 (1976) 91-99]. The gene was cloned into pBR322 as a 6.3-kb BamHI fragment. Enzyme determination showed that the cloned DNA contains the structural gene for acetylornithine delta-transaminase. The argD DNA was used as a probe in hybridization experiments which indicated that the argM gene resides in a duplicated portion of E. coli DNA that is highly similar to the argD region.     

On the enthalpy of formation of Escherichia coli K-12 cells

An examination is made of five methods for obtaining values of the enthalpy of formation of a unit mass of living Escherichia coli K-12 cells. The values obtained by these methods ranged from -88.95 kJ to -99.55 kJ, the gross average being 96.01 kJ, per unit carbon formula weight equivalent of living, hydrated cells. Although theoretically the growth of this organism in a microcalorimeter should provide the best value, the value obtained by this method (-88.95 kJ per UCFW equivalent) is not in close agreement with those of the other four methods, the values from which form a cluster averaging -97.8 +/- 1.0 kJ (-23.4 +/- 0.2 kcal)/UCFW equivalent. Calculations using this value indicate that the enthalpy change accompanying anabolism (as this is represented) is zero, or very nearly so, and that the heat of growth is that from catabolism alone.     

Penetration of nalidixic acid into Escherichia coli K-12 cells

Transport of nalidixic acid (NAL) into Escherichia coli cells subjected to osmotic shock, permeabilised with toluene or treated with DNP, CCCP or EDTA, was studied. It was found that osmotic shock and protonophores do not inhibit the transport of [3H]NAL, however, the transport of [3H]DAP and [3H]glucose is reduced. EDTA and toluene enhance penetration of [3H]NAL. This effect is, however, abolished in the presence of Mg++ ions. It is suggested that NAL penetrates into the cell by simple or facilitated diffusion and that the outer membrane of E. coli is the penetration barrier for the drug.     

Lysophospholipase L1 from Escherichia coli K-12 overproducer

After screening 900 E. coli strains of the Clarke and Carbon collection for by lysophospholipase L1 activities, we isolated a clone bearing the plasmid pLC6-34, which showed an increased level of lysophospholipase L1 activity. Strains bearing the plasmid pC124, a subclone of pLC6-34 in plasmid vector pUC8, showed approximately 11.4 times higher lysophospholipase L1 activity than that of the parental strain. Starting from those overproducing strains, the lysophospholipase L1 was purified to near homogeneity by sequential use of ammonium sulfate fractionation, Sephacryl S-300, DEAE-cellulose, hydroxyapatite and Sephacryl S-200 column chromatographies. The apparent molecular weight of the purified lysophospholipase L1 was estimated to be 20,500-22,000 both by SDS-polyacrylamide gel electrophoresis and by gel permeation chromatography. The specific activity of the homogeneous lysophospholipase L1 was 10,400 nmol/min/mg protein when 1-acyl-sn-glycero-3-phosphoethanolamine was used as the substrate. The amino acid sequence of the amino-terminal portion of purified lysophospholipase L1 was determined and was different from that of lysophospholipase L2, which had previously been purified from the envelope fraction of E. coli strains bearing its cloned structural gene, pldB [Karasawa, K., Kudo, I., Kobayashi, T., Sa-eki, T., Inoue, K., & Nojima, S. (1985) J. Biochem, 98, 1117-1125]. The gene responsible for overproduction of lysophospholipase L1 activity was designated as pldC (phospholipid degradation C). Its restriction enzyme map was also different from that of cloned pldB. These results further confirmed that, in E. coli, there are two lysophospholipases with distinct characteristics.