Cloning of the excC and excD genes involved in the release of periplasmic proteins by Escherichia coli K12

Summary Strains of Escherichia coli K12 carrying a tolA, tolB, lky or exc mutation located at min 16.5 on the genetic map released periplasmic proteins into the extracellular medium. Wild-type genes defined by these mutations have been cloned from E. coli genomic bank made with plasmid pBR328. Subcloning experiments and complementation studies showed that lky and exc mutations were located either in the previously described tolA and tolB genes or in the newly characterized excC and excD genes. Using minicells, excC and excD gene products were identified as proteins with a molecular mass of 19 and 21 kDa, respectively.     

The E. coli cell surface: on the genetic organization of the tolPAB cluster

Summary Strongly polar mutations in the tolP AB cluster have been isolated using bacteriophage Mu. Complementation tests with these Mu-induced mutants indicated that tolP and tolA are co-transcribed in a clockwise direction, and that tolB is independently transcribed.In addition, the transduction behaviour of bacteriophage dtol-29 is described. This transducing phage appears to carry all of tolB and tolA, and terminate in tolP. With tolB and tolP recipients, dtol-29 transduced as expected (by complementation and recombination, respectively). With a tolA recipient, dtol-29 behaved anomalously. Transduction frequencies were reduced 20-fold (compared to a tolB recipient), and two distinct sizes of transduction colonies arose on the deoxycholate selection plates. Analysis of these colonies showed that all the large colonies arose by recombination-transduction, while all the small colonies arose by complementation-transduction. These observations are in agreement with the results obtained with the Mu-induced mutants; furthermore, they suggest that either a weak internal promoter exists between tolP and tolA, or that the tolA cistron on dtol-29 is under the control of gene Q.Research Fellow of the National Cancer Institute of Canada.     

Escherichia coli parA is an allele of the gyrB gene

Summary A thermosensitive (ts) parA mutant, MFT110, of Escherichia coli carried at least two ts mutations. The major ts defect, resulting from a mutation mapped originally at 95 min and complemented by pLC8-47, was most probably due to psd. A plasmid carrying the 1.6 kb BamHI-PvuII fragment recloned from pLC8-47 complemented the major ts mutation in MFT110 and psd(ts) in two mutants, but did not correct the Par phenotype of MFT110. The second ts mutation was salt-repairable and mapped at 83 min close to recF and tnaA. This mutation was linked with the Par phenotype as shown unambiguously by 4,6-diamidino-2-phenylindole stained nucleoids in parA mutant cells with the W3110 genetic background. Both salt-repairable ts and Par traits were corrected concomitantly by a plasmid carrying the chromosomal region solely for the gyrB gene. This strongly suggests that parA is an allele of gyrB.     

ore2, a mutation affecting proline biosynthesis in the yeast Saccharomyces cerevisiae, leads to a cdc phenotype

Summary We report here the isolation of temperature-sensitive mutants of the yeast Saccharomyces cerevisiae which exhibit cdc phenotypes. The recessive mutations defined four complementation groups, named ore1, ore2, ore3 and ore4. At the non-permissive temperature, strains bearing these mutations arrested in the G1 phase of the cell cycle. The wild-type allele of the gene altered in ore2 mutants was cloned. The nucleotide sequence of a fragment which can complement the mutation showed the presence of an open reading frame capable of encoding a protein with 286 amino acid residues. The deduced amino acid sequence showed 25% identity with that of the Escherichia coli 1-pyrroline-5-carboxylate reductase, an enzyme of the pathway for the biosynthesis of proline. The ore2 mutants, correspondingly, were found to be capable of growing at the non-permissive temperature on a synthetic medium supplemented with proline. In addition, the chromosomal location of the gene and its restriction map were compatible with those previously reported for the PRO3 gene which encodes the S. cerevisiae ¹-pyrroline-5-carboxylate reductase.     

Uvm mutants of Escherichia coli K12 deficient in UV mutagenesis

Summary Uvm mutants of Escherichia coli K12 selected for defective UV reversion induction have previously been reported to differ considerably from the UV-reversion-less recA and lexA mutants with regard to survival or mutagenic response to UV, X-rays and alkylating agents. In the present study, the phenotypic characterization of uvm mutants was extended to investigate several cellular processes which also may be related to or involved in UV mutagenesis. Like recA and lexA mutations, the uvm mutations exhibit highly reduced Weigle reactivation and normal host cell reactivation of UV irradiated phage . But unlike recA and lexA, the uvm mutations do not impair genetic recombination, UV induction of prophage or R plasmid-mediated UV resistance and mutagenesis. These phenotypical characteristics and preliminary results of genetic mapping lend further support to the assumption that the uvm site may be a novel locus affecting, apart from the recA and lexA loci, the error-prone repair pathway in E. coli.     

Pleiotropic nature of bacteriophage tolerant mutants obtained in early-blocked asporogenous mutants of Bacillus subtilis 168

Summary Bacterial mutants tolerant to bacteriophages 15 and 29 were isolated from early-blocked asporogenous mutants ofBacillus subtilis 168. These mutants are able to adsorb phages but are not killed by them.Two classes of tolerant mutants were recognized:tolA mutants which are tolerant to 15 but not 29, andtolB mutants which are tolerant to both phages. Although the parental strain (spoA12) used for the isolation of thetol mutants is a pleiotropic negative mutant, alltol mutants which have been examined have regained some wild type traits. Genetic studies have shown that thesetol mutants are neither revertants nor suppressor mutants of thespoA gene. Thesetol mutants affect bothspoA andspoB mutations. These mutants do not sporulate and they do not lyse as rapidly as the parental strain. All these results are consistent with the hypothesis that they are all cell envelope mutants.     

Genetic and physical characterization of putP, the proline carrier gene of Escherichia coli K12

Summary Two new mutants of E. coli K12, strains PT9 and PT32 were isolated, that were defective in proline transport. They had no high affinity proline transport activity, but their cytoplasmic membranes retained proline binding activity with altered sensitivity to inhibition by p-chloromercuribenzoate(pCMB). The lesion was mapped at the putP gene, which is located at min 23 on the revised E. coli genetic map (Bachmann 1983) as a composite gene in the proline utilization gene cluster, putP, putC, and putA, arranged in this order. The putC gene was shown to regulate the synthesis of proline dehydrogenase (putA gene product).Hybrid plasmids carrying the put region (Motojima et al. 1979; Wood et al. 1979) were used to construct the physical map of the put region. The possible location of the putP gene in the DNA segment was determined by subcloning the putP gene, genetic complementation, and recombination analyses using several proline transport mutants.Abbreviations pCMB p-chloromercuribenzoate - DM Davis and Mingioli - Ap ampicillin - NTG N-methyl-N-nitro-N-nitrosoguanidine - EMS ethylmethane sulfonate - Str streptomycin - Tet tetracycline - Ac l-azetidine-2-carboxylic acid - DHP 3, 4-dehydro-d,l-proline - MTT 3-(4,5-dimethyl-2)2,5-diphenyl tetrazolium bromide - Tris tris(hydroxymethyl)aminomethane - EDTA ethylenediamine tetraacetic acid - Kan kanamycin - Spc spectinomycin     

Different UmuC requirements for generation of different kinds of UV-induced mutations in Escherichia coli

An Escherichia coli strain bearing the dnaQ49 mutation, which results in a defective s subunit of DNA polymerase III, and carrying the lexA71 mutation, which causes derepression of the SOS regulon, is totally unable to maintain high-copy-number plasmids containing the umuDC operon. The strain is also unable to maintain the pAN4 plasmid containing a partial deletion of the umuD gene but retaining the wild-type umuC gene. These results suggest that a high cellular level of UmuC is exceptionally harmful to the defective DNA polymerase III of the dnaQ49 mutant. We have used this finding as a basis for selection of new plasmid umuC mutants. The properties of two such mutants, bearing the umuC61 or umuC95 mutation, are described in detail. In the umuC122:: Tn 5 strain harbouring the mutant plasmids, UV-induced mutagenesis is severely decreased compared to that observed with the parental umuDC ⁺ plasmid. Interestingly, while the frequency of UV-induced GC AT transitions is greatly reduced, the frequency of AT TA transversions is not affected. Both mutant plasmids bear frameshift mutations within the same run of seven A residues present in umuC ⁺; in umuC61 the run is shortened to six A whereas in umuC95 is lengthened to eight A. We have found in both umuC61 and umuC95 that translation is partially restored to the proper reading frame. We propose that under conditions of limiting amounts of UmuC, the protein preferentially facilitates processing of only some kinds of UV-induced lesions.     

Mutations conferring lincomycin, spectinomycin, and streptomycin resistance in Solanum nigrum are located in three different chloroplast genes

A number of Solanum nigrum mutants resistant to the antibiotics spectinomycin, streptomycin and lincomycin have been isolated from regenerating leaf strips after mutagenesis with nitroso-methylurea. Selection of streptomycin- and spectinomycin-resistant mutants has been described earlier. Lincomycin-resistant mutants show resistance to higher levels of the antibiotic than used in the initial selection, and in the most resistant mutant (Ll7A1) maternal inheritance of the trait was demonstrated. The lincomycin-resistant mutant L17A1 and a streptomycin plus spectinomycin resistant double mutant (StSpl) were chosen for detailed molecular characterisation. Regions of the plastid DNA, within the genes encoding 16S and 23S rRNA and rps12 (3) were sequenced. For spectinomycin and lincomycin resistance, base changes identical to those in similar Nicotiana mutants were identified. Streptomycin resistance is associated with an A C change at codon 87 of rps 12 (converting a lysine into a glutamine), three codons upstream from a mutation earlier reported for Nicotiana. This site has not previously been implicated in streptomycin resistance mutations of higher plants, but has been found in Escherichia coli. The value of these mutants for studies on plastid genetics is discussed.     

Round-cell mutants of Salmonella typhimurium produced by transposition mutagenesis: Lethality of rodA and mre mutations

Summary Thirty-three insertions of transposon Tn10l6l7 into genes involved in the control of rod cell shape were isolated in Salmonella typhimurium by the characteristic glossy appearance of colonies composed of spherical cells. Genetic tests demonstrated that 25 (76%) were insertions in the rodA gene, 7 (21 %) were mre mutants, and 1 (3%) was a divD mutant. No insertion in the pbpA gene were found. Insertions in cell shape genes only appeared when strains displaying resistance to mecillinam (not caused by -lactamase production) were employed. Neither rodA nor mre insertions could be transduced to wild-type strains but they were normally accepted by mecillinam-resistant derivatives and by cya and crp mutants, which, unlike the corresponding Escherichia coli strains, did not display resistance to mecillinam. On the other hand, the divD insertion could be efficiently transduced to any strain. It is concluded that the rodA, mre, and divD genes are involved in the control of rod cell shape but, in addition, the RodA and Mre products perform some function(s) that is essential for wild-type cells but dispensable for some mecillinam-resistant strains, and for cya and crp mutants.     

A general method for the construction of Escherichia coli mutants by homologous recombination and plasmid segregation

Summary A technique is presented by which mutations can be introduced into the Escherichia coli chromosome by gene replacement between the chromosome and a plasmid carrying the mutant gene. The segregational instability of plasmids in E. coli is used with high efficiency to isolate E. coli mutants. The method should be applicable to construction of mutants for any E. coli chromosomal gene provided it is dispensable, and for any E. coli strain provided it is capable of homologous recombination. The use of the method was demonstrated by constructing E. coli mutants for the glycogen branching enzyme gene (glgB) and the -galactosidase gene (lacZ). The results show that recombination occurs via a reciprocal mechanism indicating that the method should, in a slightly modified form, also be useful in transferring chromosomal mutations onto multicopy plasmids in vivo.     

Localization of his genes on the Rhizobium trifolii RS800 linkage map

Summary We have studied N-methyl-N-nitro-N-nitrosoguanidine (NTG)- and Tn5-induced histidine auxotrophic mutants in Rhizobium trifolii. HisGE, hisD and hisH mutants have been characterized. Using the Kemper's equation we have located them on the R. trifolii linkage map. The hisGE and hisD genes are clustered in the same region and are closely linked to the spectinomycin marker. The hisH gene is located in another region equidistant from the streptomycin and rifampicin markers. The two regions carrying his genes are separated by a distance approximately one-third of the length of the chromosome.     

Salmonella typhimurium LT2 metF operator mutations

Summary Using an Escherichia coli lac deletion strain lysogenized with lambda phage carrying a metF-lacZ gene fusion (Flac), in which -galactosidase levels are dependent on metF gene expression, cis-acting mutations were isolated that affect regulation of the Salmonella typhimurium metF gene. The mutations were located in a region previously defined as the metF operator by its similarity to the E. coli metF operator sequence. Regulation of the metF gene was examined by measuring -galactosidase levels in E. coli strains lysogenized with the wild-type Flac phage and mutant Flac phage. The results suggest that the mutations disrupt the methionine control system mediated by the metJ gene product, but not the vitamin B₁₂ control system mediated by the metH gene product. The results also demonstrate that negative control of the metF gene by the metH gene product and vitamin B₁₂ is dependent on a functional metJ gene product.Abbreviations Ap ampicillin - dNTP deoxyribonucleoside triphosphates - GM glucose minimal - Km kanamycin - L-agar Luria agar - LM lactose minimal - SAM s-adenosyl-L-methionine - TPEG phenylethyl -D-thiogalactoside - X-gal 5-bromo-4-chloro-3-indolyl -D-galactopyranoside - [] designates plasmid-carrier state - :: novel joint     

Molecular cloning of the fnr gene of Escherichia coli K12

Summary Mutations in the fnr gene of Escherichia coli have pleiotropic effects leading to deficiencies in the reduction of fumarate and nitrate, hydrogen production and the ability to grow anaerobically with fumarate or nitrate as terminal electron acceptors. Transducing phages (fnr) carrying the wild-type fnr gene were isolated from populations of artificially-constructed recombinant lambda phages by their ability to complement the lesions of fnr mutants. The fnr phages restored anaerobic growth with fumarate and nitrate as electron acceptors and, as prophages, they promoted normal synthesis of fumarate reductase, nitrate reductase and hydrogenase in fnr mutants. Five independently-isolated fnr phages each contained a R.HindIII fragment (11.5 kilobases) that possessed three internal R.EcoRI targets and had inserted with the same orientation relative to the phage. A physical map of the fnr region was constructed by restriction analysis and flanking fragments were identified by DNA:DNA hybridization.     

Characterization of an Azospirillum brasilense Sp7 gene homologous to Alcaligenes eutropbus pbbB and to Rbizobium meliloti nodG

Summary A 4 kb SalI fragment from Azospirillum brasilense Sp7 that shares homology with a 6.8 kb EcoRI fragment carrying nodGEFH and part of nodP of Rhizobium meliloti 41 was cloned in pUC18 to yield pAB503. The nucleotide sequence of a 2 kb SalI-SmaI fragment of the pAB503 insert revealed an open reading frame, named ORF3, encoding a polypeptide sharing 40% identity with R. mehloti NodG. The deduced polypeptide also shared 60% identity with the Alcaligenes eutrophus NADPH-dependent acetoacetyl-CoA (AA-CoA) reductase, encoded by the pbbB gene and involved in poly--hydroxybutyrate (PHB) synthesis. Northern blot analysis and promoter extension mapping indicated that ORF3 is expressed as a monocistronic operon from a promoter that resembles the Escherichia coli ⁷⁰ consensus promoter. An ORF3-lacZ translational fusion was constructed and was very poorly expressed in E. coli, but was functional and constitutively expressed in Azospirillum. Tn5-Mob insertions in ORF3 did not affect growth, nitrogen fixation, PHB synthesis or NAD(P)H-linked AA-CoA reductase activity. An ORF3 DNA sequence was used to probe total DNA of several Azospirillum strains. No ORF3 homologues were found in A. irakense, A. amazonense, A. halopraeferens or in several A. lipoferum strains.     

Cellular localization and export of the soluble haemolysin of Vibrio cholerae El Tor

Summary The cellular location of the haemolysin of Vibrio cholerae El Tor strain 017 has been analyzed. This protein is found both in the periplasmic space and the extracellular medium in Vibrio cholerae. However, when the cloned gene, present on plasmid pPM431, is introduced into E. coli K-12 this protein remains localized predominantly in the periplasmic space with no activity detected in the extracellular medium. Mutants of E. coli K-12 (tolA and tolB) which leak periplasmic proteins mimic excretion and release the haemolysin into the growth medium. Secretion of haemolysin into the periplasm is independent of perA (envZ) and in fact, mutants in perA (envZ) harbouring pPM431 show hyperproduction of periplasmic haemolysin. These results in conjunction with those for other V. cholerae extracellular proteins suggest that although E. coli K-12 can secrete these proteins into the periplasm, it lacks a specific excretion mechanism, present in V. cholerae, for the release of soluble proteins into the growth medium.     

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of -galactosidase with symmetric variants of - and -centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the -centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the -centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. AI80, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for -centered trp operator variants with exchanges in positions 3, 4 and 5.     

The excC gene of Escherichia coli K-12 required for cell envelope integrity encodes the peptidoglycan-associated lipoprotein (PAL)

The excC mutants of Escherichia coli are hypersensitive to drugs such as cholic acid and release periplasmic proteins Into the extracellular medium. A 1884 bp fragment carrying the excC gene was isolated and sequenced. It contains the 3′ end of the tolB gene which maps at min 17 on the E. coll map and an open reading frame which encodes the 18748 Da ExcC protein. The protein is composed of a hydrophobic region of 22 residues and displayed an overall hydrophilic configuration. It was shown that the ExcC protein is indeed the PAL (peptidoglycan-associated lipoprotein) described by Mizuno (1979). The pal gene had not yet been characterized on the E. coli linkage map since no obvious phenotype could be identified for mutations in this gene. A topologic analysis of the PAL protein using PAL–PhoA translational fusions showed that PAL is associated with the outer membrane only by its N-terminal moiety. The carboxy-terminal part of the protein is necessary for correct interaction of PAL with the peptidoglycan layer.     

AICAR is not an endogenous mutagen in Escherichia coli

A number of observations in the Escherichia coli and Salmonella typhimurium literature could be explained by the hypothesis that a particular purine ribonucleotide precursor can be converted to the corresponding deoxyribonucleotide triphosphate, thereby becoming a base-analogue mutagen. The metabolite in question, AICAR (5-amino-4-carboxamide imidazole riboside 5-phosphate), is also a by-product of histidine biosynthesis, and its (ribo)triphosphate derivative, ZTP, has been detected in E. coli. We constructed E. coli tester strains that had either a normal AICAR pool (pur ⁺ his ⁺ strains cultivated without purines or histidine) or no AICAR pool (purF hisG mutant strains, lacking the first enzyme of each pathway and cultivated in the presence of adenine and histidine). Using a set of lacZ mutations, each of which can revert to Lac⁺ only by a specific substitution mutation, we found that no base substitution event occurs at a higher frequency in the presence of an AICAR pool. We conclude that the normal AICAR pool in E. coli is not a significant source of spontaneous base substitution mutagenesis.