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 and characterization of acrA and acrE genes of Escherichia coli.

The DNA fragment containing the acrA locus of the Escherichia coli chromosome has been cloned by using a complementation test. The nucleotide sequence indicates the presence of two open reading frames (ORFs). Sequence analysis suggests that the first ORF encodes a 397-residue lipoprotein with a 24-amino-acid signal peptide at its N terminus. One inactive allele of acrA from strain N43 was shown to contain an IS2 element inserted into this ORF. Therefore, this ORF was designated acrA. The second downstream ORF is predicted to encode a transmembrane protein of 1,049 amino acids and is named acrE. Genes acrA and acrE are probably located on the same operon, and both of their products are likely to affect drug susceptibilities observed in wild-type cells. The cellular localizations of these polypeptides have been analyzed by making acrA::TnphoA and acrE::TnphoA fusion proteins. Interestingly, AcrA and AcrE share 65 and 77% amino acid identity with two other E. coli polypeptides, EnvC and EnvD, respectively. Drug susceptibilities in one acrA mutant (N43) and one envCD mutant (PM61) have been determined and compared. Finally, the possible functions of these proteins are discussed.     

Molecular cloning of menaquinone biosynthetic genes of Escherichia coli K12

Summary A tranducing phage carrying some of the genes (men) defining the early stages of menaquinone biosynthesis was isolated from a pool of recombinant lambda phages that had been constructed from R.HindIII digests of E. coli DNA and the corresponding insertion vector. The lesions of menB and menC mutants were complemented by the phage but menD mutants were transduced either at low frequencies or not at all. This indicates that the transducing phage contains functional menB and menC genes but that only part of the menD gene had been cloned. The phage (G68) was accordingly disignated menCB(D). Studies with the transducing phage enabled earlier mapping data (Guest 1979) to be reinterpreted in favour of the gene order nalA.... menC..menB..menD.... purF. Restriction analyses established the presence of a bacterial DNA fragment (11.5 kb) linked by a R.HindIII target to the right arm of the genome but fused to the left arm of the vector. Hybridization studies confirmed that the cloned DNA was derived from a larger R.HindIII fragment (21 kb). A physical map of the men region was constructed and some flanking and overlapping fragments were identified.     

Molecular cloning in Escherichia coli of Erwinia chrysanthemi genes encoding multiple forms of pectate lyase.

The phytopathogenic enterobacterium Erwinia chrysanthemi excretes multiple isozymes of the plant tissue-disintegrating enzyme, pectate lyase (PL). Genes encoding PL were cloned from E. chrysanthemi CUCPB 1237 into Escherichia coli HB101 by inserting Sau3A-generated DNA fragments into the BamHI site of pBR322 and then screening recombinant transformants for the ability to sink into pectate semisolid agar. Restriction mapping of the cloned DNA in eight pectolytic transformants revealed overlapping portions of a 9.8-kilobase region of the E. chrysanthemi genome. Deletion derivatives of these plasmids were used to localize the pectolytic genotype to a 2.5-kilobase region of the cloned DNA. PL gene expression in E. coli was independent of vector promoters, repressed by glucose, and not induced by galacturonan. PL accumulated largely in the periplasmic space of E. coli. An activity stain used in conjunction with ultrathin-layer isoelectric focusing resolved the PL in E. chrysanthemi culture supernatants and shock fluids of E. coli clones into multiple forms. One isozyme with an apparent pI of 7.8 was produced at a far higher level in E. coli and was common to all of the pectolytic clones. Activity staining of renatured PL in sodium dodecyl sulfate-polyacrylamide gels revealed that this isozyme comigrated with the corresponding isozyme produced by E. chrysanthemi. The PL isozyme profiles produced by different clones and deletion derivative subclones suggest that the cloned region contains at least two PL isozyme structural genes. Pectolytic E. coli clones possessed a limited ability to macerate potato tuber tissues.     

Molecular cloning and expression of cellulase genes of alkalophilic Bacillus sp. strain N-4 in Escherichia coli.

The genes for cellulases of alkalophilic Bacillus sp. strain N-4 were cloned in Escherichia coli with pBR322. Plasmids pNK1 and pNK2 were isolated from the transformants producing carboxymethyl cellulase, and the carboxymethyl cellulase genes cloned were in 2.0- and 2.8-kilobase-pair HindIII fragments, respectively. On the DNA level, the pNK1 fragment had a different restriction map from that of the pNK2 fragment, but the genomic hybridization experiments showed partial homology among these fragments. A total of 74 and 34% of the enzyme activities were observed in the periplasmic space of E. coli carrying the plasmids pNK1 and pNK2 , respectively. The carboxymethyl cellulase thus produced had broad pH activity curves (pH of 5 to 10.9) and was stable up to 75 degrees C.     

Molecular cloning and expression in Escherichia coli of two modification methylase genes of Bacillus subtilis

Two modification methylase genes of Bacillus subtilis R were cloned in Escherichia coli by using a selection procedure which is based on the expression of these genes. Both genes code for DNA-methyltransferases which render the DNA of the cloning host E. coli HB101 insensitive to the BspRI (5'-GGCC) endonuclease of Bacillus sphaericus R. One of the cloned genes is part of the restriction-modification (RM) system BsuRI of B. subtilis R with specificity for 5'-GGCC. The other one is associated with the lysogenizing phage SP beta B and produces the methylase M.BsuP beta BI with specificity for 5'-GGCC. The fragment carrying the SP beta B-derived gene also directs the synthesis in E. coli of a third methylase activity (M.BsuP beta BII), which protects the host DNA against HpaII and MspI cleavage within the sequence 5'-CCGG. Indirect evidence suggests that the two SP beta B modification activities are encoded by the same gene. No cross-hybridization was detected either between the M.BsuRI and M.BsuP beta B genes or between these and the modification methylase gene of B. sphaericus R, which codes for the enzyme M.BspRI with 5'-GGCC specificity.     

Molecular cloning of the Escherichia coli B L-fucose-D-arabinose gene cluster.

To metabolize the uncommon pentose D-arabinose, enteric bacteria often recruit the enzymes of the L-fucose pathway by a regulatory mutation. However, Escherichia coli B can grow on D-arabinose without the requirement of a mutation, using some of the L-fucose enzymes and a D-ribulokinase that is distinct from the L-fuculokinase of the L-fucose pathway. To study this naturally occurring D-arabinose pathway, we cloned and partially characterized the E. coli B L-fucose-D-arabinose gene cluster and compared it with the L-fucose gene cluster of E. coli K-12. The order of the fucA, -P, -I, and -K genes was the same in the two E. coli strains. However, the E. coli B gene cluster contained a 5.2-kb segment located between the fucA and fucP genes that was not present in E. coli K-12. This segment carried the darK gene, which encodes the D-ribulokinase needed for growth on D-arabinose by E. coli B. The darK gene was not homologous with any of the L-fucose genes or with chromosomal DNA from other D-arabinose-utilizing bacteria. D-Ribulokinase and L-fuculokinase were purified to apparent homogeneity and partially characterized. The molecular weights, substrate specificities, and kinetic parameters of these two enzymes were very dissimilar, which together with DNA hybridization analysis, suggested that these enzymes are not related. D-Arabinose metabolism by E. coli B appears to be the result of acquisitive evolution, but the source of the darK gene has not been determined.     

Molecular cloning of the ecotin gene in Escherichia coli

The nucleotide sequence of a 876 bp region in E. coli chromosome that encodes Ecotin was determined. The proposed coding sequence for Ecotin is 486 nucleotides long, which would encode a protein consisting of 162 amino acids with a calculated molecular weight of 18,192 Da. The deduced primary sequence of Ecotin includes a 20-residue signal sequence, cleavage of which would give rise to a mature protein with a molecular weight of 16,099 Da. Ecotin does not contain any consensus reactive site sequences of known serine protease inhibitor families, suggesting that Ecotin is a novel inhibitor.     

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.     

Molecular cloning and expression of perhydrolase genes from Pseudomonas aeruginosa and Burkholderia cepacia in Escherichia coli

Two bacterial perhydrolase genes, perPA and perBC, were cloned from Pseudomonas aeruginosa and Burkholderia cepacia, respectively, using PCR amplification with primers designed to be specific for conserved amino acid sequences of the already-known perhydrolases. The amino acid sequence of PerPA was identical to a putative perhydrolase of P. aeruginosa PAO1 genome sequences, whereas PerBC of B. cepacia was a novel bacterial perhydrolase showing similarity of less than 80% with all other existing perhydrolases. Most importantly, the perPA gene was expressed as a soluble intracellular form to an extent of more than 50% of the total protein content in Escherichia coli. Two perhydrolase enzymes were confirmed to exhibit the halogenation activity towards Phenol Red and monochlorodimedone. These results suggested that we successfully obtained the newly identified members of the bacterial perhydrolase family, expanding the pool of available perhydrolases.     

Ordering tryptophan synthase genes of Pseudomonas aeruginosa by cloning in Escherichia coli.

The Pseudomonas aeruginosa tryptophan synthase genes, trpA and trpB, which are induced by their substrate indoleglycerol phosphate, were cloned along with their controlling region into the BamHI site of pBR322 to produce the 10.7-megadalton plasmid pZAZ5. SalI partial digestion and ligation yielded a smaller plasmid, pZAZ167, with the chromosomal insert reduced in size from 8.1 to 3.4 megadaltons. Both pZAZ5 and pZAZ167 display Pseudomonas-like regulation of the trpA and trpB genes. Deletion of an EcoRI fragment or a BglII fragment from pZAZ167 yielded plasmids pZAZ168 and pZAZ169; the former expresses trpB but not trpA, and the latter has lost both activities. A deleted form of pZAZ5 designated pZAZ101 was obtained by excising a BglII-BamHI segment and religating the trip gene segment in the opposite orientation. This plasmid expresses trpA and trpB constitutively. The physical maps of these plasmids establish the gene order: promoter-trpB-trpA.     

Ligation-independent cloning of glutathione S-transferase fusion genes for expression in Escherichia coli.

A plasmid vector has been constructed that allows the ligation-independent cloning of cDNAs in any reading frame and directs their synthesis in Escherichia coli as glutathione S-transferase-linked fusion proteins. The cloning procedure does not require restriction enzyme digestion of the target sequence and does not introduce any additional sequences between the thrombin cleavage site and the foreign protein. Extended single-stranded tails complementary between the vector and insert, generated by the (3'----5') exonuclease activity of T4 DNA polymerase, obviate the need for in vitro ligation prior to bacterial transformation. This cloning procedure is rapid and highly efficient, and has been used successfully to construct a series of fusion proteins to investigate the sequence requirements for efficient thrombin cleavage.