Nucleotide sequence of the secA gene and secA(Ts) mutations preventing protein export in Escherichia coli.

The DNA sequence of the secA gene, essential for protein export in Escherichia coli, was determined and found to encode a hydrophilic protein of 901 amino acid residues with a predicted molecular weight of 101,902, consistent with its previously determined size and subcellular location. Sequence analysis of 9 secA(Ts) mutations conferring general protein export and secA regulatory defects revealed that these mutations were clustered in three specific regions within the first 170 amino acid residues of the SecA protein and were the result of single amino acid changes predicted to be severely disruptive of protein structure and function. The DNA sequence immediately upstream of secA was shown to encode a previously inferred gene, gene X. Sequence analysis of a conditionally lethal amber mutation, am109, previously inferred to be located proximally in the secA gene, revealed that it was located distally in gene X and was conditionally lethal due to its polar effect on secA expression. This and additional evidence are presented indicating that gene X and secA are cotranscribed.     

Isolation and characterization of antisuppressor mutations in Escherichia coli.

Nonsense mutations in lacI have been shown to be useful as indicators of the efficiency of nonsense suppression. From strains containing supE and a lacI nonsense mutation, selection for LacI- mutants has resulted in the isolation of four antisuppressor mutations. Tn10 insertions linked to these mutations were isolated and used to group the four mutations into three loci. The asuA1 and asuA2 mutations are linked to trp, reduce suppression by supE approximately twofold, and affect a variety of suppressors. The asuB3 mutation was mapped by P1 cotransduction to rpsL but does not confer resistance to streptomycin. The asuC4 mutation reduced suppression by supE by 95% and was shown biochemically to result in the loss of two pseudouridine modifications from the 3' side of the anticodon stem and loop of tRNA2Gln. This mutation is linked to purF, suggesting that it is a new allele of hisT.     

prlA-mediated suppression of signal sequence mutations is modulated by the secA gene product of Escherichia coli K-12.

We studied the dependence of prlA-mediated suppression of signal sequence mutations in maltose-binding protein on cellular SecA levels in Escherichia coli. Reduction of SecA levels within the cell had strong positive and negative effects on prlA-mediated suppression, depending on the particular signal sequence mutations involved. This finding suggests that prlA and secA gene products are both components of a common export system.     

Regulation of the Escherichia coli secA gene by protein secretion defects: analysis of secA, secB, secD, and secY mutants.

SecA protein synthesis levels were elevated 10- to 20-fold when protein secretion was blocked in secA, secD, and secY mutants or in a malE-lacZ fusion-containing strain but not in a secB null mutant. An active secB gene product was not required to derepress secA, since SecA levels were elevated during protein export blocks in secB secY and secB malE-lacZ double mutants.     

Isolation and genetic analysis of mutations allowing the degradation of furans and thiophenes by Escherichia coli.

Successive mutations of Escherichia coli yielded a strain that was able to degrade a variety of heterocyclic oxygen- and sulfur-containing ring compounds. In particular, this strain could use both furan-2-carboxylic acid and thiophene-2-carboxylic acid as sole carbon and energy sources. Nitrogen-containing heterocyclic compounds were not degraded. This mutant was isolated by selecting first for oxidation of furan derivatives and then for thiophene degradation. Genetic analysis revealed that mutations in three novel genes, thdA (12 min), thdC (92 min), and thdD (98 min), were required for thiophene degradation. In addition, constitutively at both of the previously characterized fadR and atoC loci was required for efficient thiophene breakdown. The pathway of furan and thiophene degradation remains obscure, but the inability of our mutants to degrade 5-nitro- or 5-bromo-substituted furan derivatives suggests that hydroxylation at position 5 may be involved. Thiophene derivatives were toxic when they were present at concentrations of 0.1% or greater; however, addition of trace amounts of phenylalanine plus tyrosine greatly reduced this effect.     

Complementation analysis of eleven tryptophanase mutations in Escherichia coli.

Nine independent mutants deficient in tryptophanase activity were isolated. Each mutation was transferred to a specialized transducing phage that carries the tryptophanase region of the Escherichia coli chromosome. The nine phages thus produced, and a tenth carrying a previously characterized tryptophanase mutation, were used to lysogenize a bacterial strain harbouring a mutation in the tryptophanase structural gene and also a suppressor of polarity. In no case was complementation observed; we conclude that there is no closely linked positive regulatory gene for tryptophanase.     

Regulation of Escherichia coli secA mRNA translation by a secretion-responsive element.

The Escherichia coli secA gene, whose translation is responsive to the proficiency of protein export within the cell, is the second gene in a three-gene operon and is flanked by gene X and mutT. By using gene fusion and oligonucleotide-directed mutagenesis techniques, we have localized this translationally regulated site to a region at the end of gene X and the beginning of secA. This region has been shown to bind SecA protein in vitro. These studies open the way for a direct investigation of the mechanism of secA regulation and its coupling to the protein secretion capability of the cell.     

Competition between ribosome and SecA binding promotes Escherichia coli secA translational regulation.

SecA protein, the protein translocation ATPase of Escherichia coli, autogenously regulates its translation during normal protein secretion by binding to a secretion-responsive element located near the 5' end of its gene on geneX-secA mRNA. In order to characterize this autoregulation further, RNA footprinting and primerextension inhibition (toeprinting) studies were carried out with a segment of geneX-secA RNA, 30S ribosomal subunits and tRNAfMet along with purified SecA protein. The results show that ribosome and SecA-binding sites overlap, indicating that a simple competition for binding of geneX-secA mRNA presumably governs the translation initiation step. Further analysis showed that SecA protein was able to specifically dissociate a preformed 30S-tRNAfMet-geneX-secA RNA ternary complex as indicated by the disappearance of its characteristic toeprint after SecA addition. These findings are consistent with secA autoregulation, and they suggest a novel mechanism for the autoregulatory behavior of this complex protein.     

Genetic analysis of acrA and lir mutations of Escherichia coli.

An analysis of acrA (acriflavine- and methylene blue-sensitive) and lir (lincomycin- and erythromycin-sensitive) mutants of Escherichia coli indicated that these mutations are probably within the same gene.     

Membrane biogenesis in Escherichia coli: effects of a secA mutation

In Escherichia coli K-12, temperature-sensitive mutations in the secA gene have been shown to interfere with protein export. Here we show that the effect of a secA mutation is strongly pleiotropic on membrane biogenesis. Freeze-fracture experiments as well as cryosections of the cells revealed the appearance of intracytoplasmic membranes upon induction of the SecA phenotype. The permeability barrier of the outer membrane to detergents was lost. Two alterations in the outer membrane may be responsible for this effect, namely the reduced amounts of outer membrane proteins, or the reduction of the length of the core oligosaccharide of the lipopolysaccharide, which was observed in phage-sensitivity experiments and by SDS-polyacrylamide gel electrophoresis. Phospholipid analysis of the secA mutant, grown under restrictive conditions, revealed a lower content of the negatively charged phospholipid cardiolipin and of 18:1 fatty acid compared to those of the parental strain grown under identical conditions. These results are in line with the hypothesis that protein export and lipid metabolism are coupled.     

Tiamulin resistance mutations in Escherichia coli.

Forty "two-step" and 13 "three-step" tiamulin-resistant mutants of Escherichia coli PR11 were isolated and tested for alteration of ribosomal proteins. Mutants with altered ribosomal proteins S10, S19, L3, and L4 were detected. The S19, L3, and L4 mutants were studied in detail. The L3 and L4 mutations did not segregate from the resistance character in transductional crosses and therefore seem to be responsible for the resistance. Extracts of these mutants also exhibited an increased in vitro resistance to tiamulin in the polyuridylic acid and phage R17 RNA-dependent polypeptide synthesis systems, and it was demonstrated that this was a property of the 50S subunit. In the case of the S19 mutant, genetic analysis showed segregation between resistance and the S19 alteration and therefore indicated that mutation of a protein other than S19 was responsible for the resistance phenotype. The isolated ribosomes of the S19, L3, and L4 mutants bound radioactive tiamulin with a considerably reduced strength when compared with those of wild-type cells. The association constants were lower by factors ranging from approximately 20 to 200. When heated in the presence of ammonium chloride, these ribosomes partially regained their avidity for tiamulin.     

Fluctuation analysis of mutations to nalidixic acid resistance in Escherichia coli.

Mutations of Escherichia coli from sensitivity to nalidixic acid resistance were studied by fluctuation analysis. The mutant distributions in replicate cultures were not significantly affected either by the age of the carbon-starved preculture used for inocula or by the inoculum size. The data from 23 fluctuation tests (48 cultures each) were pooled. The mean number of mutations per culture was estimated to be 0.71 from the fraction of cultures without mutants or 0.74 and 0.77 by maximum-likelihood estimation based on the two models under consideration. When the pooled data were compared with the theoretical expectations, the fits were unsatisfactory (P < 0.005). The lack of fit was caused mainly by too high a frequency of cultures with between 17 and 32 mutants and too high a frequency of cultures with more than 128 mutants. Possible reasons for the lack of fit and its implications with respect to estimation of mutation rates from fluctuation tests are discussed.     

Isolation and characterization of amber mutations in the lexA gene of Escherichia coli K-12.

We describe the isolation and characterization of amber mutations in the lexA gene of Escherichia coli K-12. These mutations, designated spr(Am), were isolated and characterized in a lexA tif sfi genetic background. They abolished the sensitivity of the strain to UV light and resulted in high rates of synthesis of recA protein. Phage lambda+ failed to lysogenize the strains as observed with similar strains carrying non-amber spr mutations described previously, thereby indicating a constitutive expression of the phage induction pathway. Introduction of an amber suppressor mutation into a strain bearing the spr(Am) mutation restored expression of the LexA mutant phenotype. We conclude that spr mutations either inactivate or prevent synthesis of the lexA gene product and that loss of this product results in constitutive expression of the E. coli induction system in the tif sfi genetic background.     

A new Escherichia coli gene,fdrA, identified by suppression analysis of dominant negative FtsH mutations

An Escherichia coli membrane protein, FtsH, has been implicated in several cellular processes, including integration of membrane proteins, translocation of secreted proteins, and degradation of some unstable proteins. However, how it takes part in such diverse cellular events is largely unknown. We previously isolated dominant negative ftsH mutations and proposed that FtsH functions in association with some other cellular factor(s). To test this proposal we isolated multicopy suppressors of dominant negative ftsH mutations. One of the multicopy suppressor clones contained an N-terminally truncated version of a new gene that was designated fdrA. The FdrA fragment suppressed both of the phenotypes — increased abnormal translocation of a normally cytoplasmic domain of a model membrane protein and retardation of protein export — caused by dominant negative FtsH proteins. The intact fdrA gene (11.9 min on the chromosome) directed the synthesis of a 60 kDa protein in vitro.     

Isolation of temperature-sensitive McrA and McrB mutations and complementation analysis of the McrBC region of Escherichia coli K-12.

We isolated temperature-sensitive mcrA and mcrBC mutants of Escherichia coli. At 42 degrees C, they were unable to restrict the T-even bacteriophages T6gt and T4gt or plasmids encoding cloned DNA methylase genes whose specificities confer sensitivity to the McrA and McrBC nucleases. Complementation analysis of the McrBC region (mcrB251) with the complete cloned McrBC system or a derivative with mcrB alone indicated that the mutation shows an absolute defect for the restriction of DNA containing hydroxymethylcytosine and a thermosensitive defect for the restriction of DNA containing methylcytosine. The properties of the McrA temperature-sensitive mutants suggest that some of these mutations can also influence the restriction of DNA containing hydroxymethylcytosine or methylcytosine residues.     

Mutations conferring resistance to azide in Escherichia coli occur primarily in the secA gene.

Mutant strains of Escherichia coli were screened for the ability to grow on L agar plates containing 3.4 or 4.6 mM sodium azide. Most mutants had mutations located in the leucine region, presumably at the azi locus. Two of these mutants were found to have a mutation in the secA gene, but expression of the resistance phenotype also required the presence of upstream gene X. While a plasmid carrying the X-secA mutant gene pair was able to confer azide resistance to a sensitive host, a similar plasmid harboring the wild-type secA allele rendered a resistant strain sensitive to azide, indicating codominance of the two alleles. That azide inhibits SecA is consistent with the fact that SecA has ATPase activity, an activity that is often prone to inhibition by azide.     

Isolation of Haemophilus influenzae genes that suppress Escherichia coli polA mutations

Haemophilus influenzae was found to produce a DNA polymerase that was similar to polymerase I of Escherichia coli. E. coli polA mutants were used as backgrounds for the selection of H. influenzae polA suppressor genes. Six different H. influenzae fragments were isolated that could suppress E. coli polA mutations. None of the suppressors appeared to encode the H. influenzae equivalent of the E. coli polA gene. One type of clone, represented by pGW41, caused a polymerase I activity to appear in a suppressed polA1 mutant. Plasmids from the pGW41 class contained two genes (pol-2 and pol-3) that were both required for polA suppression. Mutated nonsuppressing derivatives of the pGW41 class were used to create H. influenzae mutants that were deficient in polymerase I.