Cloning and analysis of the sfrB (sex factor repression) gene of Escherichia coli K-12.

The sfrB gene of Escherichia coli K-12 and the rfaH gene of Salmonella typhimurium LT2 are homologous, controlling expression of the tra operon of F and the rfa genes for lipopolysaccharide synthesis. We have determined a restriction map of the 19-kilobase ColE1 plasmid pLC14-28 which carries the sfrB gene of E. coli. After partial Sau3A digestion of pLC14-28, we cloned a 2.5-kilobase DNA fragment into the BamHI site of pBR322 to form pKZ17. pKZ17 complemented mutants of the sfrB gene of E. coli and the rfaH gene of S. typhimurium for defects of both the F tra operon and the rfa genes. pKZ17 in minicells determines an 18-kilodalton protein not determined by pBR322. A Tn5 insertion into the sfrB gene causes loss of complementing activity and loss of the 18-kilodalton protein in minicells, indicating that this protein is the sfrB gene product. These data indicate that the sfrB gene product is a regulatory element, since the single gene product elicits the expression of genes for many products for F expression and lipopolysaccharide synthesis.     

Localization of the ribosome-releasing factor gene in the Escherichia coli chromosome.

The ribosome-releasing factor (RRF) gene was localized at a position between 2 and 6 min on the Escherichia coli chromosome by measuring the gene-dosage-dependent production of RRF in various E. coli F' merozygotes. This position was confirmed and refined by using a nucleotide probe corresponding to a 16-amino-acid sequence in RRF. It was found that the RRF gene was contained in pLC 6-32 of the Clark-Carbon Gene Bank. Restriction enzyme mapping of E. coli genomic DNA with the above probe led us to conclude that the RRF gene is situated in the 4-min region, somewhere downstream (clockwise) of the elongation factor Ts gene, tsf. A pLC 6-32-derived DNA fragment which carries the RRF gene was found to contain a partial sequence of tsf. The exact location of the translational initiation site of the RRF gene was determined to be 1.1 kilobases downstream from the translational termination site of tsf. The RRF gene is designated frr.     

Dehydroquinate synthase from Escherichia coli: purification, cloning, and construction of overproducers of the enzyme

Dehydroquinate synthase has been purified 9000-fold from Escherichia coli K-12 (strain MM294). The synthase is encoded by the aroB gene, which is carried by plasmid pLC29-47 from the Carbon-Clarke library. Construction of an appropriate host bearing pLC29-47 results in a strain that produces 20 times more enzyme than strain MM294. Subcloning of the aroB gene behind a tac promoter results in E. coli transformants that produce 1000 times more enzyme than MM294: the synthase constitutes 5% of the soluble protein of the cell. A laborious isolation from 50 g of wild-type E. coli cells yields 80 micrograms of impure enzyme, whereas 50 g of cells containing the subcloned gene yields 150 mg of homogeneous enzyme in a two-column purification. Dehydroquinate synthase is a monomeric protein of Mr 40 000-44 000. The chromosomal enzyme from E. coli K-12, the cloned enzyme encoded by the plasmid pLC29-47, and the subcloned inducible enzyme encoded by pJB14 all comigrate on polyacrylamide gel electrophoresis under denaturing conditions.     

钝齿棒杆菌N-乙酰鸟氨酸转氨酶的克隆表达分析及其重组菌的精氨酸发酵

N-乙酰鸟氨酸转氨酶 (EC 2.6.1.11,ACOAT) 是钝齿棒杆菌Corynebacterium crenatum精氨酸合成途径中的第4个酶,催化底物N-乙酰谷氨酸半醛生成产物N-乙酰鸟氨酸。为研究N-乙酰鸟氨酸转氨酶在钝齿棒杆菌中精氨酸合成中的作用,考察其酶学性质,对培养基成分和发酵过程工艺条件的优化提高精氨酸产量提供依据。从精氨酸高产菌株钝齿棒杆菌SYPA 5-5染色体扩增获得ACOAT编码基因argD,全长1 176 bp,编码390个氨基酸,在Escherichia coli BL21(D     

Isolation of recombinant plasmids and phage carrying the lexA gene of Escherichia coli K-12

The lexA gene of Escherichia coli K-12 was cloned from the plasmid pLC44-14 into pBR322. Plasmids carrying lexA+ were selected by their ability to complement a recessive tsl mutation, which is believed to be a mutation in lexA. The smallest lexA+ recombinant plasmid, pJL21, contained an EcoRI-PstI fragment 2.9 kilobases (kb) in length; two larger plasmids also contained this fragment, and genetic material to one or both sides of the EcoRI-PstI fragment. Plasmids homologous to pJL21, but carrying a dominant mutation, lexA3, or one of three recessive amber mutations in lexA, termed spr, were also isolated. To clone the EcoRI-PstI fragment onto a lambda vector, the PstI end was first converted to an EcoRI end by attachment of a 100-base pair PstI-EcoRI fragment isolated from the plasmid ColE1; the resultant EcoRI fragment was then cloned into the lambda vector lambda gt4. A restriction map of pLC44-14 was obtained for nine restriction enzymes. The orientation of this map was determined relative to the E. coli genetic map by complementation of the gene ubiA+ and by comparison with restriction enzyme digests of another plasmid, pLC11-9, which carries dnaB, a gene closely linked to lexA, but does not carry lexA.     

Molecular cloning, sequencing, and mapping of the gene encoding protease I and characterization of proteinase and proteinase-defective Escherichia coli mutants.

Clones carrying the gene encoding a proteinase were isolated from Clarke and Carbon's collection, using a chromogenic substrate, N-benzyloxycarbonyl-L-phenylalanine beta-naphthyl ester. The three clones isolated, pLC6-33, pLC13-1, and pLC36-46, shared the same chromosomal DNA region. A 0.9-kb Sau3AI fragment within this region was found to be responsible for the overproduction of the proteinase, and the nucleotide sequence of the region was then determined. The proteinase was purified to homogeneity from the soluble fraction of an overproducing strain possessing the cloned gene. N-terminal amino acid sequencing of the purified protein revealed that the cloned gene is the structural gene for the protein, with the protein being synthesized in precursor form with a signal peptide. On the basis of its molecular mass (20 kDa), periplasmic localization, and substrate specificity, we conclude this protein to be protease I. By using the gene cloned on a plasmid, a deletion mutant was constructed in which the gene was replaced by the kanamycin resistance gene (Kmr) on the chromosome. The Kmr gene was mapped at 11.8 min, the gene order being dnaZ-adk-ush-Kmr-purE, which is consistent with the map position of apeA, the gene encoding protease I in Salmonella typhimurium. Therefore, the gene was named apeA. Deletion of the apeA gene, either with or without deletion of other proteinases (protease IV and aminopeptidase N), did not have any effect on cell growth in the various media tested.     

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.     

DNA sequence of the gene coding for Escherichia coli ribonuclease H

The gene for Escherichia coli ribonuclease H has been studied by use of a plasmid which contains a segment of the E. coli chromosome. The genomic DNA was subcloned from pLC28-22 to pBR322 by use of various restriction enzymes. Such subcloning limited the RNase H gene to a piece of DNA no longer than 760 base pairs. Cells bearing plasmids containing the RNase H gene produce as much as 10-15 times the normal amount of RNase H without any drastic effect on maintenance of the plasmid or cell growth. DNA sequence analysis has permitted the prediction of a protein whose molecular weight is 17,559 (155 amino acid residues). The predicted sequence was confirmed by amino acid analysis, NH2-terminal amino acid sequence, and size determination of highly purified RNase H.     

Molecular cloning and sequencing of the sppA gene and characterization of the encoded protease IV, a signal peptide peptidase, of Escherichia coli

Clones carrying a gene causing overproduction of protease IV, a signal peptide peptidase of Escherichia coli, were isolated from the Clarke and Carbon's collection. Restriction mapping analysis revealed that pLC7-10 and pLC40-13, thus isolated, shared the same chromosomal DNA region. The 2.3-kilobase RsaI-SalI fragment in this region, which was found to carry the gene, was subjected to nucleotide sequence determination. Only one long open reading frame was found. The hypothetical polypeptide sequence deduced from the DNA sequence has a molecular mass of 67,241 daltons. The putative gene was named sppA. Protease IV was purified to homogeneity from the cytoplasmic membrane of an overproducing strain harboring a sppA gene-carrying plasmid. The purified enzyme gave a single polypeptide band of 67,000-dalton molecular mass on sodium dodecyl sulfate-polyacrylamide gel. This molecular mass and the amino acid composition of the purified enzyme were consistent with the deduced primary structure of the sppA gene product. The molecular mass thus determined was almost twice as large as that previously reported by Pacaud (Pacaud, M. (1982) J. Biol. Chem. 257, 4333-4339). A cross-linking study revealed that protease IV is a tetramer of the polypeptide. From these results, we conclude that protease IV is a tetramer of the sppA gene product.     

The Escherichia coli dam gene is expressed as a distal gene of a new operon

Summary DNA containing the Escherichia coli dam gene and sequences upstream from this gene were cloned from the Clarke-Carbon plasmids pLC29-47 and pLC13-42. Promoter activity was localized using pKO expression vectors and galactokinase assays to two regions, one 1650–2100 bp and the other beyon 2400 bp upstream of the dam gene. No promoter activity was detected immediately in front of this gene; plasmid pDam118, from which the nucleotide sequence of the dam gene was determined, is shown to contain the pBR322 promoter for the primer RNA from the pBR322 rep region present on a 76 bp Sau3A fragment inserted upstream of the dam gene in the correct orientation for dam expression. The nucleotide sequence upstream of dam has been determined. An open reading frame (ORF) is present between the nearest promoter region and the dam gene. Codon usage and base frequency analysis indicate that this is expressed as a protein of predicted size 46 kDa. A protein of size close to 46 kDa is expressed from this region, detected using minicell analysis. No function has been determined for this protein, and no significant homology exist between it and sequences in the PIR protein or GenBank DNA databases. This unidentified reading frame (URF) is termed urf-74.3, since it is an URF located at 74.3 min on the E. coli chromosome. Sequence comparisons between the regions upstream of urf-74.3 and the aroB gene show that the aroB gene is located immediately upstream of urf-74.3, and that the promoter activity nearest to dam is found within the aroB structural gene. This activity is relatively weak (about 15% of that of the E. coli gal operon promoter). The promoter activity detected beyond 2400 bp upstream of dam is likely to be that of the aroB gene, and is 3 to 4 times stronger than that found within the aroB gene. Three potential DnaA binding sites, each with homology of 8 of 9 bp, are present, two in the aroB promoter region and one just upstream of the dam gene. Expression through the site adjacent to the dam gene is enhanced 2-to 4-fold in dnaA mutants at 38°C. Restriction site comparisons map these regions precisely on the Clarke-Carbon plasmids pLC13-42 and pLC29-47, and show that the E. coli ponA (mrcA) gene resides about 6 kb upstream of aroB.     

Mapping of the drug resistance genes carried by the r-determinant of the R100.1 plasmid

Summary We have cloned the EcoRI fragments of pLC1, a circular DNA element found in an Escherichia coli dnaA _ts strain integratively suppressed by R100.1 (Chandler et al., 1977a), using the plasmid vector pCR1. All the resistance genes known to be present on the r-determinant of R100.1 were found to be present on pLC1. The isolation of pCR1 derivatives carrying various EcoRI fragments of either pLC1 or R100.1 has allowed a more precise mapping of the position of the resistance genes on the R100.1 molecule.     

A gene coding for 3-deoxy-D-manno-octulosonic-acid transferase in Escherichia coli. Identification, mapping, cloning, and sequencing

An autoradiographic assay applicable to colonies immobilized on filter paper was developed for obtaining temperature-sensitive mutants of Escherichia coli defective in the transfer of 3-deoxy-D-manno-octulosonic acid (KDO) from CMP-KDO to a tetraacyldisaccharide 1,4'-bisphosphate precursor of lipid A, designated lipid IVA. Cell-free extracts from two mutants found in a population of 30,000 mutagen-treated cells showed normal KDO transferase activity when assayed at 30 degrees C, but almost no activity at 42 degrees C. The mutation was mapped by mating one of the mutants with different Hfr strains and analyzing genetic linkage of KDO transferase activity to selectable markers. The lesion was located to a position between 80 and 84 min on the E. coli chromosome. A plasmid from the Clarke and Carbon collection (Clarke, L., and Carbon, J. (1976) Cell 9, 91-99), pLC17-24, known to contain genes from the rfa region (81 min), was shown to overexpress KDO transferase activity 4-5 times and to correct the mutation when the plasmid was conjugated into the mutant strains. The KDO transferase gene, designated kdtA, was subcloned from pLC17-24 into a multicopy vector. The resulting plasmid, pCL3, overproduced transferase activity approximately 100-fold. The kdtA gene was shown to code for a 43-kDa polypeptide, as judged by radiolabeling of minicells. Its DNA sequence was determined. The results demonstrate that overexpression of this single gene product greatly stimulates the incorporation of two stereochemically distinct KDO residues during lipopolysaccharide biosynthesis in extracts of E. coli.     

Correlation of a subset of the pLC plasmids to the physical map of Escherichia coli K-12.

We determined map positions of the Escherichia coli K-12 portions of a subset of the hybrid E. coli-ColE1 plasmids constructed by Clarke and Carbon. The probe DNA of pLC plasmids was labeled with digoxigenine-dUTP, hybridized to the 476 phage clones of the E. coli ordered clone bank miniset, which was adsorbed on a strip of nylon membrane filters, and detected by enzyme-linked immunoassay and a subsequent enzyme-catalyzed color reaction. The total number of Clarke-Carbon plasmids we analyzed was 518, for which chromosomal locations of 297 clones were newly determined in the present study. Another 180 plasmids gave results that agreed with those reported previously, and the remaining 41 plasmids gave map positions different from those described in the previous report. A chromosome map of E. coli which shows the locations of 518 pLC plasmids on it is presented, as well as a table which correlates the pLC plasmids with the clones of the E. coli ordered clone bank miniset on the basis of the hybridization data. We estimate that approximately one-half of the entire genome of E. coli was covered by the pLC plasmids used in this study.     

Cloning and expression of the pepD gene of Escherichia coli

Peptidase D of Escherichia coli, cleaving the unusual dipeptide carnosine, was found to be encoded by the ColE1 hybrid plasmid pLC44-11. From this plasmid the pepD gene was subcloned into small vectors. As shown by successive reduction of the flanking sequences of genomic DNA, the order of genes in the region at 6 min of the E. coli K12 map is phoE, pepD, in the clockwise orientation. Insertional inactivation of the pepD gene and expression of recombinant plasmids in maxicells allowed the identification of the pepD product as a 52 kDa protein. Comparison with the 100 kDa protein molecular mass determined by gel filtration suggests that active peptidase D is probably a dimer.     

Searching for potential Z-DNA in genomic Escherichia coli DNA

The Clarke-Carbon library with Escherichia coli DNA cloned into plasmid ColE1 was partially screened for Z-DNA with the monoclonal antibody Z-D11 using the retardation of the covalently closed circular DNA-protein complex by nitrocellulose filters. About 85% of the plasmids tested at "natural" supercoil density bound to the filter. Together with binding studies of the iodinated antibody, one Z-DNA segment per about 18,000 base-pairs of E. coli DNA is observed. One clone containing the region around the lactose operon, pLC20-30, was studied in detail. Subcloning a partial Sau3A digest and selection with antibodies gave three different Z-forming sites. They were mapped to within about +/- 20 base-pairs by preparing unidirectional deletion clones, selection of protein binding plasmids on nitrocellulose filters and subsequent sizing on agarose gels. The size of the Z-DNA-forming segments was estimated from two-dimensional gels of topoisomer mixtures. Together with results from sequencing of the plasmid DNA using exonuclease III to create single-stranded templates, stretches of alternating purine-pyrimidine tracts of 12 to 15 base-pairs were found to be responsible for Z-DNA formation. One of the sites was found in the middle of the lacZ gene, where it might be an obstacle for RNA polymerase. The methods used here should also be helpful for studying other DNA-protein sites, especially if they exist only in supercoiled DNA.     

Isolation and characterization of an Escherichia coli clone overproducing prolipoprotein signal peptidase

Based on the rationale that Escherichia coli cells containing increased levels of prolipoprotein signal peptidase would be highly resistant to globomycin, a specific inhibitor of the prolipoprotein signal peptidase, we have isolated a clone from the Carbon-Clarke collection, plasmid pLC3-13, which is globomycin-resistant and contains an increased level of prolipoprotein signal peptidase activity. The plasmid pMT521, a subclone of pLC3-13 in pBR322, conferred on its host cells approximately 20 times overproduction of prolipoprotein signal peptidase and an extremely high level of resistance against globomycin. The overproduced prolipoprotein signal peptidase was completely inhibited by the presence of globomycin in the in vitro assay, and the overproduced activity was found in the cell envelope fraction. Several lines of biochemical and genetic evidence suggest that the gene contained in pLC3-13 and its derivative clones is most likely the structure gene (lsp) for prolipoprotein signal peptidase.