Molecular cloning of the Escherichia coli K-12 entACGBE genes

Abstract A 7-kb piece of Escherichia coli DNA that contains five genes ( entA, C, G, B and E ) required for the biosynthesis of the iron transport molecule enterochelin was isolated. A restriction map was constructed and proteins specified by the E. coli DNA were identified in mini- and maxicell systems. Plasmids containing portions of the entACGBE DNA generated by BAL31 digestion or restriction enzyme treatment were constructed; complementation studies done with these indicated that the five genes constitute an operon. The approximate site of the promoter was determined and the product of entE was tentatively identified as an M _r 63000 polypeptide.     

Molecular cloning of the fdhF gene of Escherichia coli K-12

Abstract The fdhF gene of Escherichia coli , coding for at least one component of benzyl viologen-linked formate dehydrogenase (FDH-BV) activity, was isolated on a ColE1- fdhF hybrid plasmid from the Clarke and Carbon colony bank.
Endonuclease restriction maps of this plasmid and its pBR322-subcloned derivative, pLW06, were constructed. Various hybrid plasmids were further obtained by deletion of endonuclease-cleaved fragments from pLW06 DNA. Their complementation pattern was analyzed after introduction into different fdhF mutant strains. The fdhF gene was shown to be located on a 5.5 kb Bam HI- Pvu II-DNA fragment, which restored FDH-BV activity to the wild-type level.     

Molecular cloning of the N-acetylneuraminate lyase gene in Escherichia coli K-12

Summary The gene for N-acetylneuraminate lyase [N-acetylneuraminate pyruvate-lyase; NPL] of Escherichia coli C600 was cloned onto pBR322 as a 9.8 kilobase HindIII fragment of chromosomal DNA and the hybrid plasmid was designated pMK2. The gene in the hybrid plasmid was subcloned in pBR322 as a 1.2 kilobase HindIII-EcoRI fragment and the resultant hybrid plasmid was designated pMK6. NPL activity level was increased more than 5-fold in the pMK6-bearing strain compared with that of the wild type, when the cells were grown on a medium containing inducer (N-acetylneuraminate: NANA). The transformants harbouring pMK6 also showed higher activity even in the absence of inducer. The NPL produced by pMK6-bearing cells was structurally and immunologically the same as that purified from E. coli C600.     

Molecular cloning and DNA sequencing of the radC gene of Escherichia coli K-12.

The radC102 mutation that sensitizes E. coli K-12 cells to ultraviolet light, ionizing radiations and alkylating agents was localized between the fpg and pyrE genes at 81.7 min on the bacterial chromosome. E. coli strain BH20 (radC+, fpg-1::KnR) has a 10.5-kb EcoRI/KpnI DNA fragment spanning the region from pyrE to the insertion mutation fpg-1::KnR. The proximity of the radC gene to this insertion mutation provided a strategy to isolate the radC+ gene based on the cloning of radC+ and fpg-1::KnR on the same DNA fragment using the resistance to kanamycin as a selector. A library of EcoRI/KpnI DNA fragments of E. coli strain BH20 was inserted into pUC19. One recombinant plasmid conferring resistance to kanamycin was selected and named pRCV10. The pRCV10 plasmid partially restores the resistance to UV-radiation when transformed into SR1187 (radC102), but sensitizes the wild-type strain to the same treatment. The radC102 complementing region was localized on a 1.2-kb BglII/BglII DNA fragment which was sequenced. The DNA sequence complementing the radC102 mutation contained an ATG translation start codon with an open reading frame of 297 base pairs which encodes a polypeptide of Mr 11,500. The order of the genes in this region of the E. coli chromosome is: fpg--rpmBG--radC--pyrE.     

Molecular cloning of Escherichia coli K-12 ggt and rapid isolation of gamma-glutamyltranspeptidase

Based on the results of mapping of ggt, eight strains were selected from a gene library of E. coli. One of the strains harboring pLC9-12 was found to show 14 times higher gamma-glutamyltranspeptidase activity per cell than the wild type strain. The ggt was subcloned to the BamHI site of pUC18 and the recombinant plasmid pSH101 was obtained. Ggt- phenotype of gamma-glutamyltranspeptidase-deficient mutants was complemented by pSH101. The specific activity of the enzyme in cells harboring pSH101 was 37-fold higher than that in the wild type cells. gamma-Glutamyltranspeptidase was isolated from the periplasmic fraction of the cells by simple two steps and crystallized.     

大肠杆菌苯丙氨酸合成途径关键酶基因pheA的克隆与表达

为了通过基因工程手段来增加苯丙氨酸的生物产量,利用ＰＣＲ方法从大肠杆菌中克隆了抗反馈抑制突变型及野生型的ｐｈｅＡ基因,进行了核苷酸序列分析,并利用高效的原核表达载体ＰＢＶ２２０对ｐｈｅＡ基因编码的突变型及野生型分支酸变位酶／预苯酸脱水酶（ＣＭ／ＰＤ）进行了表达。序列分析表明突变型基因碱基第５８０位由Ｔ变为Ｃ,相应氨基酸由Ｖａｌ变为Ａｌａ,ＳＤＳ－ＰＡＧＥ图谱扫描分析表明目的蛋白ＣＭ／ＰＤ的表达量占全菌体蛋白的４３％,占上清总蛋白的５７％。酶活性测定表明其ＣＭ和 ＰＤ活性分别提高了 １５．５和６．７倍,产酸量也有了一定的提高,为构建产苯丙氨酸的生物工程菌奠定了基础。     

Molecular cloning of the region of the terminus of Escherichia coli K-12 DNA replication.

A series of plasmids have been isolated either by ligation of defined restriction fragments to plasmid pBR325 or by screening of a cosmid bank by in situ colony hybridization. Together with one previously isolated plasmid, they spanned 86% of the 30.5- to 34-min region of the genetic map of Escherichia coli K-12. Physical analysis of these plasmids and hybridizations to Southern blots confirmed the endonuclease map of this region, with the exception of a 9.3-kilobase pair inversion.     

Molecular cloning and physical mapping of the hyd gene of Escherichia coli K-12

Abstract Passive transfer between rates of protection against cholera toxin (CT) was studied. Extracts of various organs, obtained from CT-immunized rats, were injected intravenously into non-immunized recipient rats. The ability of the extracts to inhibit CT-induced secretion in ligated jejunal loop were tested. A significant inhibition of the response to CT was achieved by extracts from hypophysis, brain and jejunal mucosa. Extracts from pancreas, spleen or adrenal glands were without effect, as were all extracts obtained from control rats. The antisecretory effects of the hypophysis extracts became intensified with increasing numbers of immunizations, and the antisecretory effect was most pronounced when the extract was injected immediately before the CT challenge. The active component of the hypophysis extract was heat-labile and negatively charged, suggesting an acidic protein as the mediator of the protective effect against CT.     

Molecular cloning of the L-phenylalanine transaminase gene from Paracoccus denitrificans in Escherichia coli K-12

The L-phenylalanine transaminase gene of Paracoccus denitrificans was cloned by a shotgun method using the Escherichia coli K-12 mutant DG30, which lacks three distinct transaminase genes. Plasmid pPAP142 was constructed by inserting a 2.2-kb fragment carrying the transaminase gene into pUC18. Strain E. coli K-12 HB101 cells harboring the plasmid produced 20-fold to 30-fold more transaminase than wild type P. denitrificans cells. The nucleotide sequence of the 2.2-kb fragment was determined, revealing that the deduced amino acid sequence of the transaminase of P. denitrificans is similar to that of other transaminases.     

The cloning of the Escherichia coli K-12 deoxyribonucleoside operon

A 6.1-kb EcoRI DNA fragment containing the four structural genes (deoC, deoA, deoB, deoD) of the deoxyribonucleoside operon has been cloned into the plasmid pMFS53. By use of a unique, asymmetrically positioned HindIII site on the 6.1 kb insert, plasmids containing the deoC,deoA genes (pMFS50) or the deoB,deoD genes (pMFS55) have been constructed. Enzyme assays performed on extracts prepared from clones harboring pMFS53, pMFS50 or pMFS55 revealed that each clone possessed amplified deo enzyme levels and that the spectrum of enzyme amplification corresponded to the genetic composition of the plasmids carried by each clone. A plasmid (pMFS50l) having functional deoA, deoB and deoD genes but devoid of the deo regulatory region and a portion of the deoC structural gene has been isolated following treatment of BamHI cleaved pMFS53 and BAL31 nuclease. Comparison of the deo enzyme levels for clones harboring pMFS53 and pMFS501 suggest that plasmid pMFS53 possesses a functional deo regulatory region in addition to the four structural genes of the operon.     

Molecular cloning and DNA sequencing of the Escherichia coli K-12 ald gene encoding aldehyde dehydrogenase.

The gene ald, encoding aldehyde dehydrogenase, has been cloned from a genomic library of Escherichia coli K-12 constructed with plasmid pBR322 by complementing an aldehyde dehydrogenase-deficient mutant. The ald region was sequenced, and a single open reading frame of 479 codons specifying the subunit of the aldehyde dehydrogenase enzyme complex was identified. Determination of the N-terminal amino acid sequence of the enzyme protein unambiguously established the identity and the start codon of the ald gene. Analysis of the 5'- and 3'-flanking sequences indicated that the ald gene is an operon. The deduced amino acid sequence of the ald gene displayed homology with sequences of several aldehyde dehydrogenases of eukaryotic origin but not with microbial glyceraldehyde-3-phosphate dehydrogenase.     

Molecular cloning and characterization of genes required for ribose transport and utilization in Escherichia coli K-12.

We isolated spontaneous and transposon insertion mutants of Escherichia coli K-12 that were specifically defective in utilization or in high-affinity transport of D-ribose (or in both). Cotransduction studies located all of the mutations near ilv, at the same position as previously identified mutations causing defects in ribokinase ( rbsK ) or ribose transport ( rbsP ). Plasmids that complemented the rbs mutations were isolated from the collection of ColE1 hybrid plasmids constructed by Clarke and Carbon. Analysis of those plasmids as well as of fragments cloned into pBR322 and pACYC184 allowed definition of the rbs region. Products of rbs genes were identified by examination of the proteins produced in minicells containing various rbs plasmids. We identified four rbs genes: rbsB , which codes for the 29-kilodalton ribose-binding protein; rbsK , which codes for the 34-kilodalton ribokinase ; rbsA , which codes for a 50-kilodalton protein required for high-affinity transport; and rbsC , which codes for a 27-kilodalton protein likely to be a transport system component. Our studies showed that these genes are transcribed from a common promoter in the order rbsA rbsC rbsB rbsK . It appears that the high-affinity transport system for ribose consists of the three components, ribose-binding protein, the 50-kilodalton RbsA protein, and the 27-kilodalton RbsC protein, although a fourth, unidentified component could exist. Mutants defective in this transport system, but normal for ribokinase , are able to grow normally on high concentrations of the sugar, indicating that there is at least a second, low-affinity transport system for ribose in E. coli K-12.     

Cadmium uptake in Escherichia coli K-12.

109Cd2+ uptake by Escherichia coli occurred by means of an active transport system which has a Km of 2.1 microM Cd2+ and a Vmax of 0.83 mumol/min X g (dry weight) in uptake buffer. 109Cd2+ accumulation was both energy dependent and temperature sensitive. The addition of 20 microM Cd2+ or Zn2+ (but not Mn2+) to the cell suspensions preloaded with 109Cd2+ caused the exchange of Cd2+. 109Cd2+ (0.1 microM) uptake by cells was inhibited by the addition of 20 microM Zn2+ but not Mn2+. Zn2+ was a competitive inhibitor of 109Cd2+ uptake with an apparent Ki of 4.6 microM Zn2+. Although Mn2+ did not inhibit 109Cd2+ uptake, the addition of either 20 microM Cd2+ or Zn2+ prevented the uptake of 0.1 microM 54Mn2+, which apparently occurs by a separate transport system. The inhibition of 54Mn2+ accumulation by Cd2+ or Zn2+ did not follow Michaelis-Menten kinetics and had no defined Ki values. Co2+ was a competitive inhibitor of Mn2+ uptake with an apparent Ki of 34 microM Co2+. We were unable to demonstrate an active transport system for 65Zn2+ in E. coli.     

Galactofuranose biosynthesis in Escherichia coli K-12: identification and cloning of UDP-galactopyranose mutase.

We have cloned two open reading frames (orf6 and orf8) from the Escherichia coli K-12 rfb region. The genes were expressed in E. coli under control of the T7lac promoter, producing large quantities of recombinant protein, most of which accumulated in insoluble inclusion bodies. Sufficient soluble protein was obtained, however, for use in a radiometric assay designed to detect UDP-galactopyranose mutase activity (the conversion of UDP-galactopyranose to UDP-galactofuranose). The assay is based upon high-pressure liquid chromatography separation of sugar phosphates released from both forms of UDP-galactose by phosphodiesterase treatment. The crude orf6 gene product converted UDP-[alpha-D-U-14C]-galactopyranose to a product which upon phosphodiesterase treatment gave a compound with a retention time identical to that of synthetic alpha-galactofuranose-1-phosphate. No mutase activity was detected in extracts from cells lacking the orf6 expression plasmid or from orf8-expressing cells. The orf6 gene product was purified by anion-exchange chromatography and hydrophobic interaction chromatography. Both the crude extract and the purified protein converted 6 to 9% of the UDP-galactopyranose to the furanose form. The enzyme was also shown to catalyze the reverse reaction; in this case an approximately 86% furanose-to-pyranose conversion was observed. These observations strongly suggest that orf6 encodes UDP-galactopyranose mutase (EC 5.4.99.9), and we propose that the gene be designated glf accordingly. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of purified UDP-galactopyranose mutase revealed one major band, and analysis by electrospray mass spectrometry indicated a single major species with a molecular weight of 42,960 +/- 8, in accordance with that calculated for the Glf protein. N-terminal sequencing revealed that the first 15 amino acids of the recombinant protein corresponded to those expected from the published sequence. UV-visible spectra of purified recombinant enzyme indicated that the protein contains a flavin cofactor, which we have identified as flavin adenine dinucleotide.     

Molecular cloning of a maltose transport gene from Bacillus stearothermophilus and its expression in Escherichia coli K-12

Genes responsible for maltose utilization from Bacillus stearothermophilus ATCC7953 were cloned in the plasmid vector pBR325 and functionally expressed in Escherichia coli. The 4.2 kb Bacillus DNA insert in clone pAM1750 suppressed the growth defects on maltose caused by mutations in E. coli maltose transport genes (malE, malK or complete malB deletion) but not mutations in genes affecting intracellular maltose metabolism (malA region). Transport studies in E. coli and B. stearothermophilus suggested that pAM1750 codes for a high affinity transport system, probably one of two maltose uptake systems found in B. stearothermophilus ATCC7953. Nucleotide sequence analysis of a 3.6 kb fragment of pAM 1750 revealed three open reading frames (ORFs). One of the ORFs, malA, encoded a putative hydrophobic protein with 12 potential transmembrane segments. MalA showed amino acid sequence similarity to proteins in the superfamily containing LacY lactose permease and also some similarity to MaIG protein, a member of a binding protein-dependent transport system in E. coli. The products of two other ORFs were not hydrophobic, did not show similarity to other known sequences and were found not to be essential for maltose utilization in transport-defective E. coli mutants. Hence MalA protein was the only protein necessary for maltose transport, but despite giving a detectable but low level of transport function in E. coli, the protein was very poorly expressed and could not be identified.