Escherichia coli thymidylate kinase: molecular cloning, nucleotide sequence, and genetic organization of the corresponding tmk locus.

Thymidylate kinase (dTMP kinase; EC 2.7.4.9) catalyzes the phosphorylation of dTMP to form dTDP in both de novo and salvage pathways of dTTP synthesis. The nucleotide sequence of the tmk gene encoding this essential Escherichia coli enzyme is the last one among all the E. coli nucleoside and nucleotide kinase genes which has not yet been reported. By subcloning the 24.0-min region where the tmk gene has been previously mapped from the lambda phage 236 (E9G1) of the Kohara E. coli genomic library (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987), we precisely located tmk between acpP and holB genes. Here we report the nucleotide sequence of tmk, including the end portion of an upstream open reading frame (ORF 340) of unknown function that may be cotranscribed with the pabC gene. The tmk gene was located clockwise of and just upstream of the holB gene. Our sequencing data allowed the filling in of the unsequenced gap between the acpP and holB genes within the 24-min region of the E. coli chromosome. Identification of this region as the E. coli tmk gene was confirmed by functional complementation of a yeast dTMP kinase temperature-sensitive mutant and by in vitro enzyme assay of the thymidylate kinase activity in cell extracts of E. coli by use of tmk-overproducing plasmids. The deduced amino acid sequence of the E. coli tmk gene showed significant similarity to the sequences of the thymidylate kinases of vertebrates, yeasts, and viruses as well as two uncharacterized proteins of bacteria belonging to Bacillus and Haemophilus species.     

Molecular analysis of the Escherichia coli phoP-phoQ operon.

The phoP-phoQ operon of Salmonella typhimurium is a member of the family of two-component regulatory systems and controls expression of the phoN gene that codes for nonspecific acid phosphatase and the genes involved in the pathogenicity of the bacterium. The phoP-phoQ operon of Escherichia coli was cloned on a plasmid vector by complementation of a phoP mutant, and the 4.1-kb nucleotide sequence, which includes the phoP-phoQ operon and its flanking regions, was determined. The phoP-phoQ operon was mapped at 25 min on the standard E. coli linkage map by hybridization with the Kohara mini set library of the E. coli chromosome (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The predicted phoP and phoQ gene products consist of 223 and 486 amino acids with estimated molecular masses of 25,534 and 55,297 Da, respectively, which correspond well with the sizes of the PhoP and PhoQ proteins identified by the maxicell method. The amino acid sequences of PhoP and PhoQ of E. coli were 93 and 86% identical, respectively, to those of S. typhimurium.     

Organic solvent tolerance and antibiotic resistance increased by overexpression of marA in Escherichia coli.

We previously reported that overexpression of the soxS or robA gene causes in several Escherichia coli strains the acquisition of higher organic solvent tolerance and also increased resistance to a number of antibiotics (H. Nakajima, K. Kobayashi, M. Kobayashi, H. Asako, and R. Aono, Appl. Environ. Microbiol. 61:2302-2307, 1995). Most E. coli strains cannot grow in the presence of cyclohexane. We isolated the marRAB genes from a Kohara lambda phage clone and cyclohexane-tolerant mutant strain OST3408. We found a substitution of serine for arginine at position 73 in the coding region of marR of OST3408 and designated the gene marR08. Our genetic analysis revealed that marR08 is responsible for the cyclohexane-tolerant phenotype. We observed that the marA gene on high-copy-number plasmids increased the organic solvent tolerance of E. coli strains. Furthermore, exposure of E. coli cells to salicylate, which activates the mar regulon genes, also raised organic solvent tolerance. Overexpression of the marA, soxS, or robA gene increased resistance to numerous antibiotics but not to hydrophilic aminoglycosides.     

Molecular genetic analysis of the Escherichia coli phoP locus.

We have cloned the Escherichia coli phoP gene, a member of the family of environmentally responsive two-component systems, and found its deduced amino acid sequence to be 93% identical to that of the Salmonella typhimurium homolog, which encodes a major virulence regulator necessary for intramacrophage survival and resistance to cationic peptides of phagocytic cells. The phoP gene was mapped to kilobase 1202 on the Kohara map (25-min region) of the E. coli genome (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987) and found to be transcribed in a counterclockwise direction. Both E. coli and S. typhimurium phoP mutants were more sensitive than their isogenic wild-type strains to the frog-derived antibacterial peptide magainin 2, suggesting a role for PhoP in the response to various stresses in both enteric species.     

麦迪霉素产生菌酮基还原酶基因在大肠杆菌中的表达

用PCR法扩增麦迪霉素产生菌酮基还原酶（MKR）基因,得到约0．8kb的DNA片段,扩增片段重组到利用依赖T7RNA聚合酶的高效表达载体pT7－7中,在大肠杆菌中表达出28．9kD的蛋白质。表达的蛋白质具有生物活性。     

Isolation and characterization of the Escherichia coli msbB gene, a multicopy suppressor of null mutations in the high-temperature requirement gene htrB.

Previous work established that the htrB gene of Escherichia coli is required for growth in rich media at temperatures above 32.5 degrees C but not at lower temperatures. In an effort to determine the functional role of the htrB gene product, we have isolated a multicopy suppressor of htrB, called msbB. The msbB gene has been mapped to 40.5 min on the E. coli genetic map, in a 12- to 15-kb gap of the genomic library made by Kohara et al. (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). Mapping data show that the order of genes in the region is eda-edd-zwf-pykA-msbB. The msbB gene codes for a protein of 37,410 Da whose amino acid sequence is similar to that of HtrB and, like HtrB, the protein is very basic in nature. The similarity of the HtrB and MsbB proteins could indicate that they play functionally similar roles. Mutational analysis of msbB shows that the gene is not essential for E. coli growth; however, the htrB msbB double mutant exhibits a unique morphological phenotype at 30 degrees C not seen with either of the single mutants. Analysis of both msbB and htrB mutants shows that these bacteria are resistant to four times more deoxycholate than wild-type bacteria but not to other hydrophobic substances. The addition of quaternary ammonium compounds rescues the temperature-sensitive phenotype of htrB bacteria, and this rescue is abolished by the simultaneous addition of Mg2+ or Ca2+. These results suggest that MsbB and HtrB play an important role in outer membrane structure and/or function.     

Precise mapping of the rnpB gene encoding the RNA component of RNase P in Escherichia coli K-12.

In Kohara's library derived from Escherichia coli K-12 W3110 (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987), multiple copies of chromosomal sequence are found at 68 and at 64 to 65 min (M. Umeda and E. Ohtsubo, J. Mol. Biol. 213:229-237, 1990). We have determined that the rnpB gene (previously mapped at 70 min [B. J. Bachmann, Microbiol. Rev. 54:130-197, 1990]) is located within these segments of repeated sequences as five separate copies, together with tdcA, B, C, and R (mapped at 68 min [Bachmann, 1990]) and six unidentified open reading frames. Since close linkage of rnpB and tdc is found in various strains of E. coli K-12, the rnpB gene should be mapped at 68 min rather than 70 min.     

In vitro construction of gshB::kan in Escherichia coli and use of gshB::kan in mapping the gshB locus.

The Escherichia coli structural gene for glutathione synthetase, gshB, was cloned into pBR322. Plasmids containing gshB were able to complement the glutathione requirement of a trxA gshB double mutant, and cells containing the plasmids were found to have elevated levels of glutathione synthetase. A mutant gshB allele was constructed by inserting the kan gene from pUC4K into a unique HpaI site located within gshB. The resulting plasmid-encoded allele was used to replace a genomic gshB+ by homologous recombination. The resulting strain had no detectable glutathione synthetase activity. The gshB allele containing the kan insertion was used to map gshB on the E. coli chromosome by P1 transduction. The results indicated that gshB is located at 63.4 min, between metK and speC. The allele was further localized to a region of 3,100 to 3,120 kilobase pairs on the physical map (restriction map) of E. coli by DNA-DNA hybridization to a series of lambda bacteriophages (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987).     

Cloning, sequencing, and mapping of the bacterioferritin gene (bfr) of Escherichia coli K-12.

The bacterioferritin (BFR) of Escherichia coli K-12 is an iron-storage hemoprotein, previously identified as cytochrome b1. The bacterioferritin gene (bfr) has been cloned, sequenced, and located in the E. coli linkage map. Initially a gene fusion encoding a BFR-lambda hybrid protein (Mr 21,000) was detected by immunoscreening a lambda gene bank containing Sau3A restriction fragments of E. coli DNA. The bfr gene was mapped to 73 min (the str-spc region) in the physical map of the E. coli chromosome by probing Southern blots of restriction digests of E. coli DNA with a fragment of the bfr gene. The intact bfr gene was then subcloned from the corresponding lambda phage from the gene library of Kohara et al. (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The bfr gene comprises 474 base pairs and 158 amino acid codons (including the start codon), and it encodes a polypeptide having essentially the same size (Mr 18,495) and N-terminal sequence as the purified protein. A potential promoter sequence was detected in the 5' noncoding region, but it was not associated with an "iron box" sequence (i.e., a binding site for the iron-dependent Fur repressor protein). BFR was amplified to 14% of the total protein in a bfr plasmid-containing strain. An additional unidentified gene (gen-64), encoding a relatively basic 64-residue polypeptide and having the same polarity as bfr, was detected upstream of the bfr gene.     

Phytase activity in some groups of bacteria. Search for and cloning of genes for bacterial phytases

A search for phytase genes in 9 Bacillus strains from the collection of IMGAN was implemented. The growth optimum of strains IX-22, IX-12B, K17-2, K18, IMG I, IMG II, M4 and M8 was 50-60 degrees C; the optimal growth temperature for Bacillus sp. 790 was 45-47 degrees C. According to the sequence data of 16S RNA genes, Bacillus sp. 790 belongs to the B. subtilis/amyloliquefaciens group. The other 8 strains were identified as B. licheniformis. Selection of Bacillus strains, potentially containing the phytase genes, was performed via PCR with primers designed on the basis of the conserved sequence regions of the phyA gene from B. amyloliquefaciens FZB45 with chromosomal DNA being used as the template. The nucleotide sequences of all PCR fragments showed a high level of homology to the known Bacillus phytase genes. The gene libraries of B. licheniformis M8 and B. amyloliquefaciens 790 in E. coli were constructed and phytase-containing clones were selected from them. Twenty-four Pseudomonas strains of different species, 5 Xanthomonas maltophilia strains and 1 Xanthomonas malvacearum (all from the mentioned collection) were tested for phytase activity. Such activity was found in 13 Pseudomonas strains and in 6 Xanthomonas strains. The accumulation of phytase in Pseudomonas was shown to take place at later (over 2 days') growth stages. The optimum pH for phytase from 3 Pseudomonas strains were established. The enzymes were found to be most active at pH 5.5.     

Ⅱ型志贺毒素单克隆抗体可变区基因克隆及单链抗体的表达和功能鉴定

目的从分泌抗肠出血性大肠埃希菌Ⅱ型志贺毒素中和单克隆抗体杂交瘤细胞株S2C4中克隆抗体可变区基因,构建单链抗体（ScFv）,进行原核表达,并对其功能进行鉴定。方法从杂交瘤细胞株S2C4中提取总RNA,逆转录成cDNA。在cDNA3’-OH末端添加poly．G。PCR扩增包括5’非翻译区和信号肽序列在内的抗体重、轻链可变区基因VH和VL,PCR产物装入T—A载体测序。根据测序结果,设计引物分别扩增VH和VL编码区,再通过重叠PCR,在VH和VL．编码区基因之间引入连接链,构建Scn基因,并克隆到表达载体pComb3xSS中。重组载体导入E．coliTop10F’进行表达,重组蛋白经纯化后,分别用ELISA和动物保护性实验鉴定其生物学活性。结果VH和VL编码区基因全长分别为396bp和378bp,ScFv基因能在大肠埃希菌中高效表达,表达产物的分子量为34000,用NiSO4亲和层析柱成功纯化。功能性实验表明纯化的重组蛋白可以与Stx2毒素有效结合,能保护动物抵御毒素分子的攻击。结论成功地克隆S2C4单抗可变区基因,并构建、表达其单链抗体ScFv,为下一步进行该抗体人源化奠定实验基础。     

NotI genomic cleavage map of Escherichia coli K-12 strain MG1655.

Several approaches were used to construct a complete NotI restriction enzyme cleavage map of the genome of Escherichia coli MG1655. The approaches included use of transposable element insertions that created auxotrophic mutations and introduced a NotI site into the genome, hybridization of NotI fragments to the ordered lambda library constructed by Kohara et al. (BioTechniques 10:474-477, 1991), Southern blotting of NotI digests with cloned genes as probes, and analysis of the known E. coli DNA sequence for NotI sites. In all, 22 NotI cleavage sites were mapped along with 26 transposon insertions. These sites were localized to clones in the lambda library and, when possible, sequenced genes. The map was compared with that of strain EMG2, a wild-type E. coli K-12 strain, and several differences were found, including a region of about 600 kb with an altered restriction pattern and an additional fragment in MG1655. Comparison of MG1655 with other strains revealed minor differences but indicated that this map was representative of that for many commonly used E. coli K-12 strains.     

Mapping of sequenced genes (700 kbp) in the restriction map of the Escherichia coli chromosome

This paper describes software (written in Pascal and running on Macintosh computers) allowing localization of unknown DNA fragments from the Escherichia coli chromosome on the restriction map established by Kohara et al. (1987). The program identifies the segment's map position using a restriction pattern analysis obtained with all, or some, of the eight enzymes used by Kohara et al. (1987). Therefore, the sequenced genes available in the EMBL library may be localized on the E. coli chromosome restriction map. This allowed correction of the map (mainly by introducing missing sites in the published maps) at the corresponding positions. Analysis of the data indicates that there is only a very low level of polymorphism, at the nucleotide level, between the E. coli K12 strains used by the various laboratories involved in DNA sequencing. The program is versatile enough to be used with other genomes.