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.     

Ribosomal protein modification in Escherichia coli

Summary A mutant of Escherichia coli K12 has been isolated which shows an alteration in the ribosomal protein S18. Genetic analyses have revealed that the mutation causing this alteration maps at 99.3 min of the E. coli genetic map, between dnaC and deo. This indicated that the mutation has occurred in a gene different from the structural gene for this protein which has been located at 94 min. From the N-terminal amino acid sequence analysis it is concluded that the mutation has resulted in loss of the N-terminal acetyl group of this protein. The gene which is affected in this mutant is termed rimI that most likely specifies an enzyme acetylating the N-terminal alanine of protein S18. The mutation does not affect the acetylation of two other ribosomal proteins, S5 and L12, both of which are known to be acetylated in wild-type E. coli K12.     

Identification, cloning, nucleotide sequence and chromosomal map location of hns, the structural gene for Escherichia coli DNA-binding protein H-NS

Summary Beginning with a synthetic oligonucleotide probe derived from its amino acid sequence, we have identified, cloned and sequenced the hns gene encoding H-NS, an abundant Escherichia coli 15 kDa DNA-binding protein with a possible histone-like function. The amino acid sequence of the protein deduced from the nucleotide sequence is in full agreement with that determined for H-NS. By comparison of the restriction map of the cloned gene and of its neighboring regions with the physical map of E. coli K12 as well as by hybridization of the hns gene with restriction fragments derived from the total chromosome, we have located the hns gene oriented counterclockwise at 6.1 min on the E. coli chromosome, just before an IS30 insertion element.     

Mapping of a gene for a major outer membrane protein of Escherichia coli K12 with the aid of a newly isolated bacteriophage.

Summary A method is described for the enrichment of phages which can adsorb to a specific determinant of bacterial cell surfaces. A phage was isolated which adsorbs toE. coli cells containing the “major outer membrane” proteinc but not to strains that are lacking this protein. With the aid of this phage a gene,meoA which is responsible for the lack of proteinc was mapped at 48 min on the linkage map ofE. coli K12.     

Molecular cloning, overexpression and mapping of the slt gene encoding the soluble lytic transglycosylase of Escherichia coli

Summary The gene of the major autolysin of Escherichia coli, the soluble lytic transglycosylase (Slt), was isolated from an expression gene library. The cloned slt gene was used to determine its chromosomal map position adjacent to trpR at 99.7 min on the E. coli linkage map.     

Multisensory activation of the phosphorelay initiating sporulation in Bacillus subtilis: identification and sequence of the protein kinase of the alternate pathway

We report the characterization of the msbA gene, isolated as a multicopy suppressor of the HtrB temperature-sensitive phenotype. The msbA gene maps to 20.5 min on the Escherichia coli genetic map and encodes a protein with an estimated molecular mass of 64460 Da, with the properties of an integral membrane protein. The amino acid sequence of MsbA is very similar to those of the family of ATP-dependent translocators, which includes the haemolysin B protein of E. coli and the mammalian multidrug resistance (MDR) proteins. Mutational analysis of msbA indicates that it may form an operon with a downstream gene, orfE, and that both of these genes are essential for bacterial viability under all growth conditions tested.     

Ribosomal protein modification in Escherichia coli

Summary Among mutants of E. coli selected for temperaturesensitive growth, four were found to possess alterations in ribosomal proteins L7/L12. Of these, three apparently lack protein L7, the acetylated form of protein L12. Genetic analyses have revealed that the mutation responsible for this alteration maps at a locus around 34 min of the current E. coli genetic map, which is clearly different from the location for the structural gene for protein L7/L12 which is situated at 89 min. Hence, the gene affected in these mutants was termed rimL. Tryptic and thermolysin fingerprints of the protein L12 purified from the rimL mutants showed a profile indistinguishable from that of wild-type protein. It was found that the acetylase activity specific for protein L12 was negligible, when assayed in vitro, in the high-speed supernatant prepared from mutant cells. These results indicated that the three mutants contain mutations in the gene rimL that codes for an acetylating enzyme specific for ribosomal protein L12.Previous paper in this series is Isono and Isono (1980)     

Molecular cloning of the Salmonella typhimurium lep gene in Escherichia coli

Summary A system is described which enabled the selection of a heterologous ep gene, encoding signal peptidase I, in Escherichia coli. It is based on complementation of an E. coli mutant, in which the synthesis of signal peptidase I can be regulated. With this system the lep gene of Salmonella typhimurium was cloned and the nucleotide sequence was determined. The S. typhimurium lep gene encodes a protein of 324 amino acids. Expression of the gene in the E. coli mutant resulted in suppression of growth inhibition and in the restoration of processing activity under conditions where synthesis of E. coli signal peptidase I was repressed. The cloned S. typhimurium signal peptidase I had an apparent molecular weight of 36000 daltons, which is in agreement with the calculated molecular weight of 35782 daltons. The system described for selection of the S. typhimurium lep gene may permit the cloning and expression of other heterologous signal peptidase I gen/es.     

Overproduction and purification of SulA fusion protein in Escherichia coli and its degradation by Lon protease in vitro

To overproduce extremely unstable SulA protein, which is the cell-division inhibitor of Escherichia coli, we fused the sulA gene to the maltose-binding protein (MBP) fusion vectors with or without the signal sequence (plasmids pMAL-p-SulA and pMAL-c-SulA respectively). The amount of the full-length fusion protein expressed from the plasmid pMAL-p-SulA (pre-MBP-SulA) in E. coli was much larger than that expressed from the plasmid pMAL-c-SulA (MBP-SulA). A major amount of the pre-MBP-SulA fusion protein was expressed in a soluble form and affinity-purified by amylose resin. Since site-specific cleavage of the fusion protein with factor Xa resulted in the precipitation of SulA protein, the pre-MBP-SulA fusion protein was used to study the degradation of SulA protein by E. coli Lon protease in vitro. It was found that only the SulA portion of the fusion protein was degraded by Lon protease in an ATP-dependent manner. This result provides direct evidence that Lon protease plays an important role in the rapid degradation of SulA protein in cells.     

The biogenesis of c-type cytochromes in Escherichia coli requires a membrane-bound protein, DipZ, with a protein disulphide isomerase-like domain

A mutant of Escherichia coli K-12, JCB606, which lacks all five c-type cytochromes synthesized during anaerobic growth in the presence of nitrite or tri-methylamine-N-oxide (TMAO), was totally defective in Nrf activity and also partially defective in TMAO reductase activity. The mutation in strain JCB606 was shown to affect expression of the tor operon, which contributes almost equally with the products of the dms operon to the rate of TMAO reduction by bacteria during anaerobic growth in the presence of TMAO. The mutation in strain JCB606, dipZ, was mapped by P1 transduction close to the mel operon at co-ordinate 4425 on the E. coli chromosome, the gene order being nrf–fdhF–mel–dipZ–ampC. Recombinant plasmids that restored Nrf activity to test-tube cultures of the mutant were isolated from a cosmid library. A 2.7 kb EcoRV–Smal fragment (co-ordinates 4443 to 4446 kb on the physical map of the E. coli chromosome) was found potentially to encode three genes arranged in at least two operons. The second gene, dipZ, was sufficient to complement the JCB606 mutation. The translated DNA sequence predicts that DipZ is a 53kDa integral membrane protein with a 37kDa N-terminal domain including at least six membrane-spanning helices and a 16kDa carboxy-terminal hydrophilic domain which includes a protein disulphide isomerase-like motif. It is suggested that DipZ is essential for maintaining cytochrome c apoproteins in the correct conformations for the covalent attachment of haem groups to the appropriate pairs of cysteine residues.     

Genetic Mapping of Cold Resistance Gene of Escherichia coli

Using cold resistant mutants, MET1 and MET2, obtained from Escherichia coli K-12, genetic mapping of the cold resistance gene(s) of E. coli was performed by the conjugation and transduction techniques. The gene(s) was confirmed to be located close to trpB at 28 min (revised chromosome linkage map, 1983) on the E. coli chromosome.     

Location of the ompT gene relative to that of appY on the physical map of the Escherichia coli chromosome

Results concerning the precise location of the ompT gene (encoding the outer membrane protease OmpT) on the Escherichia coli chromosome were obtained which disagree with published restriction sites in the gene. It is shown that the gene, together with appY, is present on a 3.075 PstI fragment, encompassing positions 596–598 of the E. coli physical map.     

Genetic studies of the ribosomal proteins in Escherichia coli. 7. Mapping of several ribosomal protein components by transduction experiments between different strains of Escherichia coli

Summary Two 50s (50-10 and 50-12) and two 30s (30-4 and 30-7) ribosomal proteins could be distinguished between Shigella dysenteriae Sh/s and Escherichia coli K-12 JC411 with CMC column chromatography. On the other hand, E. coli K-12 AT2472 was shown to have a 30s ribosomal protein, 30-6(AT), which is specific to this strain and distinguishable from 30-6 of other E. coli K-12 strains. Transduction experiments by phage Plkc between Sh. dysenteriae Sh/s and E. coli ATSPCO1, a spectinomycin resistant mutant derived from AT2472 in which the 30-4 protein is altered, indicated that the genes specifying the above five ribosomal protein components are located in the streptomycin region on the E. coli chromosome.The gene order for three 50s (50-8, 50-10 and 50-12) and three 30s [str (30-?), 30-4 and 30-6] ribosomal proteins on the chromosome was determined by transduction technique between Sh. dysenteriae Sh/s and E. coli ATSPC01, between E. coli ATSPC01 and E. coli ER05 (an erythromycin resistant strain in which the 50-8 protein is altered), and between Sh. dysenteriae Sh/s and E. coli ERSPC14 (str ^s spc ^r ery ^r), respectively. It was found that these protein genes are arranged on the chromosome in the order of str (30-?)-30-4-30-6-50-8-50-10-50-12.     

Replication of the mini-R1 plasmid Rsc11 and Rsc11 hybrid plasmids

Summary The DNA polymerase induced by bacteriophage T7 is composed of a phage-specified subunit, the gene 5 protein, and a host-specified subunit, the 12,000 dalton thioredoxin of Escherichia coli. tsnC mutants of E. coli B (Chamberlin, 1974) have no detectable thioredoxin, and thus cannot support the growth of phage T7, although they are killed by phage infection. A mutant of E. coli K12 affecting thioredoxin has been isolated by a modification of the procedure used by Chamberlin (1974) to isolate tsnC mutants of E. coli B. The gene affecting thioredoxin has been designated trxA. This mutant, E. coli JM109, shows the TsnC phenotype in that it is killed by, but cannot support the growth of, bacteriophage T7. T7 DNA replication does not occur in mutantinfected cells. These phenotypic expressions of the tsnC mutation have enabled us to screen recombinants for the trxA allele in HfrxF^- crosses and F-ductants in episome transfer experiments. Extracts of transductants in generalized transduction by P1 phage were screened for their ability to complement partially purified phage T7 gene 5 protein to form T7 DNA polymerase. The trxA gene is located at 84 min on the E. coli linkage map, between uvrE and metE; trxA is 34% co-transducible with metE.     

DNA sequence analysis of the Serratia marcescens ompA gene: implications for the organisation of an enterobacterial outer membrane protein

Summary The cloned ompA gene from Serratia marcescens was fully expressed in Escherichia coli and its product correctly assembled into the outer membrane. The S. marcescens polypeptide was not functionally equivalent to the E. coli OmpA protein, which serves as a phage receptor and as a component of several colincin uptake systems. DNA sequence analysis of the gene showed that three regions of the protein likely to be exposed on the cell surface not only differed extensively from the corresponding regions of the E. coli polypeptide but also from all other sequenced OmpA proteins. It is suggested that this sequence polymorphism represents a safety mechanism by which the various enterobacterial species can avoid cross-infection by noxious agents such as phages or colicins.     

Analysis of yeast prp20 mutations and functional complementation by the human homologue RCC1, a protein involved in the control of chromosome condensation

Summary A DNA fragment that codes for the 364 amino-terminal amino acid residues of a putative Bacillus subtilis SecA homologue has been cloned using the Escherichia coli SecA gene as a probe. The deduced amino acid sequence showed 58% identity to the aminoterminus of the E. coli SecA protein. A DNA fragment which codes for 275 amino-terminal amino acid residues of the B. subtilis SecA homologue was expressed in E. coli and the corresponding gene product was shown to be recognized by anti-E. coli SecA antibodies. This polypeptide, although only about 30% the size of the E. coli SecA protein, also restored growth of E. coli MM52 (secA ^ts) at the non-permissive temperature and the translocation defect of proOmpA in this mutant was relieved to a substantial extent.     

The use of suicide substrates to select mutants of Escherichia coli lacking enzymes of alcohol fermentation

Summary Mutants of Escherichia coli resistant to chloroethanol or to chloroacetaldehyde were selected. Such mutants were found to lack the fermentative coenzyme A (CoA) linked acetaldehyde dehydrogenase activity. Most also lacked the associated fermentative enzyme alcohol dehydrogenase. Both types of mutants, those lacking acetaldehyde dehydrogenase alone or lacking both enzymes, mapped close to the regulatory adhC gene at 27 min on the E. coli genetic map. The previously described acd mutants which lack acetaldehyde dehydrogenase and which map at 63 min were shown to be pleiotropic, affecting respiration and growth on a variety of substrates. It therefore seems likely that the structural genes for both the acetaldehyde and alcohol dehydrogenases lie in the adhCE operon. This interpretation was confirmed by the isolation of temperature sensitive chloracetaldehyde-resistant mutants, some of which produced thermolabile acetaldehyde dehydrogenase and alcohol dehydrogenase and were also found to map at the adh locus. Reversion analysis indicated that mutants lacking one or both enzymes carried single mutations. The gene order in the adh region was determined by three point crosses to be trp - zch:: Tn10 - adh - galU- bglY - tyrT - chlC.     

An Escherichia coli strain deficient for both exonuclease V and deoxycytidine triphosphate deaminase shows enhanced sensitivity to ionizing radiation

An Escherichia coli mutant lacking deoxycytidine triphosphate deaminase (Dcd) activity and an unknown function encoded by a gene designated ior exhibits sensitivity to ionizing radiation whereas dcd mutants themselves are not sensitive. A DNA fragment from an E. coli genomic library that restores the wild type level of UV and gamma ray resistance to this mutant has been cloned in the multicopy vector pBR322. Comparison of its restriction map with the physical map of the E. coli chromosome revealed complete identity to the recBD genes. ior affects ATP-dependent exonuclease activity, suggesting that it is an allele of recB. This mutation alone does not confer sensitivity to UV and gamma radiation, indicating that lack of Dcd activity is also required for expression of radiation sensitivity.     

DNA sequencing of the Escherichia coli ribonuclease III gene and its mutations

Summary A 0.7 kb DNA fragment of the Escherichia coli K12 chromosome was shown to contain the structural gene for RNAse III (rnc). The DNA sequence of the gene was determined and its alteration in an RNAse III defective mutant, AB301-105, was identified. DNA sequence analysis also showed that a secondary-site suppressor of a temperature-sensitive mutation in the E. coli ribosomal protein gene, rpsL, occurred within the rnc gene, providing genetic evidence for the interaction of ribosomal proteins with RNAse III, which in turn acts on the nascent ribosomal RNA during assembly of ribosomes in E. coli.     

The ORF1 of the gentamicin-resistance operon (aac) of Pseudomonas aeruginosa encodes adenosine 5'-phosphosulphate kinase

The gentamicin-resistance operon of Pseudomonas aeruginosa (aac) contains two cistrons for which only the second gene product has an identified function. The 813bp second cistron (ORF2) encodes a protein that confers gentamicin resistance by catalysis of the transfer of an acetyl group from acetyl Coenzyme A to gentamicin. The first open reading frame (ORF1) encodes a 23.9 kDa protein that we have found, by enzyme activity and immunological reactivity, to be adenosine-5′-phosphosulphate (APS) kinase. APS kinase catalyses the transfer of the gamma phosphoryl group of ATP to the 3′-hydroxyl group of APS. The 70% sequence similarity between the Pseudomonas and Escherichia coli APS kinases suggests that the Pseudomonas enzyme may catalyse phosphoryl transfer to the 3′-hydroxyl group of other nucleotides such as dephosphocoenzyme A, as does the purified E. coli APS kinase. In extracts of pseudomonad cells we have also detected a higher molecular mass (70 kDa) protein that cross-reacts with an anti-E. coli APS kinase antibody. This cross-reactive protein is also present in Pseudomonas strains lacking the gentamicin-resistance plasmid, and apparently reflects an APS kinase analogous to the nodQ-encoded high-molecular-weight APS kinase present in Rhizobium meliloti. Production of the Pseudomonas aac APS kinase was repressed by cysteine when expressed in E. coli, as is E. coli APS kinase. However, cysteine did not repress production of the Pseudomonas enzyme when the aac ORF1 -encoded enzyme was expressed in a Pseudomonas strain, indicating differential regulation of gene expression in the two organisms.