Construction of aClostridium acetobutylicum-Escherichia coli shuttle vector

Summary A 4.1-kb cryptic plasmid, designated pCA134, has been isolated fromClostridium species. In order to develop a vector suitable for transforming saccharolytic clostridia three hybrid plasmids were constructed by inserting pCA134 into pHV32 withEcoRI, orBglII andBamHI. The newly constructed plasmids were propagated inEscherichia coli and were used to transformBacillus subtilis andClostridium acetobutylicum. One of them, pCAB32 (10.1 kb), which contains chloramphenicol acetyltransferase gene and an origin of replication derived from pCA134 was introduced intoB.subtilis andC.acetobutylicum as well asE.coli.     

A host-vector system for gene cloning in the cyanobacterium Synechocystis PCC 6803

Summary Synechocystis 6803 contains at least four cryptic plasmids of 2.27 kb (pUS1, pUS2 and pUS3) and 5.20 kb (pUS4). The 1.70 kb HpaI fragments of the related plasmids pUS2 and pUS3 were cloned into the Ap^r gene of the E. coli plasmid pACYC177, yielding the Km^r hybrid plasmids pUF12 and pUF3 respectively. pUF3 recombines in Synechocystis 6803 with a 2.27 kb plasmid giving the Km^r shuttle vector pUF311. The 1.35 kb HaeII fragment containing the Cm² gene of the E. coli plasmid pACYC184 was cloned in pUF311 generating the Cm^r Km^r shuttle vector pFCLV7. Wild-type cells of Synechocystis 6803 are transformed, albeit poorly, by the plasmids pUF3, pUF12 and pFCLV7. pFCLV7 very efficiently transforms the SUF311 strain of Synechocystis 6803 containing pUF311 as a resident plasmid. This is due to recombination between the homologous parts of pFCLV7 and pUF311. For the same reason the strain SUF311 is also efficiently transformable by E. coli plasmids, as shown for pLF8, provided that they have some homology with the E. coli part of pUF311.The combined use of Synechocystis 6803 strain SUF311 and of plasmids pFCLV7 and pLF8 generates an efficient host-vector system for gene cloning in this facultatively heterotrophic cyanobacterium.     

Thermostable tryptophan synthase ofBacillus stearothermophilus expressed inEscherichia coli

Summary The tryptophan synthase genes,trpA andtrpB, from a moderate thermophile,Bacillus stearothermophilus IFO13737, were expressed efficiently inEscherichia coli. The recombinant tryptophan synthase amounted to 22% of the soluble cellular protein, and was purified to homogeneity by three steps. The enzyme is more thermostable thanE.coli tryptophan synthase, especially the subunit. The enzyme is also more resistant to sodium dodecylsulfate and methanol thanE.coli enzyme.     

Molecular cloning of theEscherichia coli gene encoding xylose isomerase

Summary A 2.4 Kb DNA fragment restricted from a Clarke-Carbon ColEl plasmid, pLC32-9, containing the xylose isomerase gene has been inserted into the PstI site of pDB248, a shuttle plasmid between the bacteriumE. coli and the fission yeast,Schizosaccharomyces pombe. This recombinant plasmid, pDB248-XI, can genetically complement xylose isomerase deficientE. coli strains and xylose isomerase gene can be expressed inSchizosaccharomyces pombe.     

Segregational instability of pUB110-derived recombinant plasmids in Bacillus subtilis

To study plasmid instability in Bacillus subtilis the pUB110-derived hybrid plasmid pLB2 (3.6 kb) and the bifunctional replicon pLB5 (5.9 kb), able to replicate in B. subtilis and Escherichia coli, were constructed. In both vectors homologous B. subtilis, or heterologous E. coli DNA fragments of various lengths were inserted. Irrespective of the source of the cloned DNA, the segregational stability of the recombinant plasmids in B. subtilis was severely affected by the DNA inserts. In contrast, no instability was observed in E. coli. In B. subtilis a steep inverse relationship existed between the size of the inserts and the level of stability. Increased size of the pLB plasmids resulted in strongly reduced copy numbers. This seems to be the primary cause of the size-dependent segregational instability.     

Cloning and expression inEscherichia coli of the sucrase gene fromBacillus subtilis

Summary A recombinant cosmid carrying the sucrase gene (sacA) was obtained from a colony bank ofE. coli harboring recombinant cosmids representative of theB. subtilis genome. It was shown that thesacA gene is located in a 2 kbEcoRI fragment and that the cloned sequence is homologous to the corresponding chromosomal DNA fragment. A fragment of 2 kb containing the gene was subcloned in both orientations in the bifunctional vector pHV33 and expression was further looked for inB. subtilis andE. coli. Complementation of asacA mutation was observed in Rec⁺ and Rec^- strains ofB. subtilis. Expression of sucrase was also demonstrated inE.coli, which is normally devoid of this activity, by SDS-polyacrylamide gel electrophoresis, specific immunoprecipitation and assay of the enzyme in crude extracts. The specific activity of the enzyme depended on the orientation of the inserted fragment. The saccharolytic activity was found to be cryptic inE. coli since the presence of the recombinant plasmids did not allow the transport of [U¹⁴C] sucrose and the growth of the cells.It was shown also that the recombinant cosmid contained part of the neighboring locus (sacP) which corresponds to a component of the PEP-dependent phosphotransferase system of sucrose transport ofB. subtilis.     

Resistance of bacterial film to contamination during use as inoculum in repeated batch fermentation

Summary AnEscherichia coli strain constitutive for -galactosidase was immobilized onto cotton cloth. The resultingE.coli film was used as a resident inoculum in repeated batch fermentations for 30 days in the presence ofBrevibacterium ammoniagenes added as a contaminant. Analysis of -galactosidase production shows that contamination did not decrease the capacity of the film to generateE.coli cells, or decrease theE.coli population on the film.     

Genome sequence analyses of two isolates from the recent <Emphasis Type="Italic">Escherichia coli</Emphasis> outbreak in Germany reveal the emergence of a new pathotype: Entero-Aggregative-Haemorrhagic <Emphasis Type="Italic">Escherichia coli</Emphasis> (EAHEC)

The genome sequences of two Escherichia coli O104:H4 strains derived from two different patients of the 2011 German E. coli outbreak were determined. The two analyzed strains were designated E. coli GOS1 and GOS2 (German outbreak strain). Both isolates comprise one chromosome of approximately 5.31 Mbp and two putative plasmids. Comparisons of the 5,217 (GOS1) and 5,224 (GOS2) predicted protein-encoding genes with various E. coli strains, and a multilocus sequence typing analysis revealed that the isolates were most similar to the entero-aggregative E. coli (EAEC) strain 55989. In addition, one of the putative plasmids of the outbreak strain is similar to pAA-type plasmids of EAEC strains, which contain aggregative adhesion fimbrial operons. The second putative plasmid harbors genes for extended-spectrum β-lactamases. This type of plasmid is widely distributed in pathogenic E. coli strains. A significant difference of the E. coli GOS1 and GOS2 genomes to those of EAEC strains is the presence of a prophage encoding the Shiga toxin, which is characteristic for enterohemorrhagic E. coli (EHEC) strains. The unique combination of genomic features of the German outbreak strain, containing characteristics from pathotypes EAEC and EHEC, suggested that it represents a new pathotype Entero-Aggregative-Haemorrhagic E scherichia c oli (EAHEC).     

Construction of hybrid plasmid vectors for cloning inEscherichia coli,Bacillus subtilis,and the cyanobacteriumAnacystis nidulans

Two hybrid plasmids capable of acting as shuttle cloning vectors inAnacystis nidulans andBacillus subtilis were constructed by in vitro ligation. One construct, pMG202, consists of theB. subtilis vector pNN101 and the endogenous cyanobacterial plasmid pUH24. This 14.6 kb plasmid confers chloramphenicol resistance in both hosts and tetracycline resistance inB. subtilis. A second vector, pMG101, consists of pNN101 linked to theA. nidulans-Escherichia coli chimeric plasmid pCB4 and is 12.9 kb in size. The pCB4 portion of the vector enables pMG101 to replicate in the third host,E. coli, and confers ampicillin resistance in this bacterium as well as inA. nidulans. Both plasmids possess identical uniqueStu I sites which permit insertional inactivation of the chloramphenicol resistance gene; and, in addition, identical uniqueXho I sites are present on both vectors. Each vector also has a third unique site:Sma I on pMG101 andXba I on pMG202.     

Hydrogen production by Escherichia coli containing a cloned hydrogenase gene from Citrobacter freundii

Two hydrogenase genes of Citrobacter freundii complementing different Escherichia coli hyd mutations were cloned on the multicopy-plasmid pBR322. Recombinant plasmids pCBH2 and pCFH1 were obtained. Since hydrogenase activities of E. coli transformant HK-8 (pCBH2) and HK-7 (pCFH1) were much the same as E. coli C600 (wild type cells), the reduction in DNA size of recombinant plasmid pCBH2 (10.7 kb) was investigated. Reduced recombinant plasmids pCBH4 (6.2 kb) and pCBH6 (5.7 kb) were obtained, and a hydrogenase gene was found to be located on the 2.35 kb fragment between AvaI and EcoRI sites. Hydrogenase activity and hydrogen-evolving activity of E. coli HK-8 (pCBH4 or pCBH6) from sodium formate, sodium pyruvate or glucose were approximately 2-fold higher than those of E. coli C600 (wild type cells).On the other hand, a reduced recombinant plasmid pCBH10 (6.0 kb), which contained the adjacent DNA fragment (2.15 kb) to a hydrogenase gene, was obtained. Hydrogenase activity of E. coli C600 harboring pCBH10 was half that of E. coli C600. From these results we estimate that in plasmid pCBH2, the repressor gene suppressing the synthesis of hydrogenase might have been cloned together with a hydrogenase gene.     

Bifunctional cosmid vector forStreptomyces

Summary AnEscherichia coli/Streptomyces bifunctional cosmid vector, pJP3, which selects for clones with insert size 23–33 kilobase pairs (kb), has been constructed. A genomic DNA library fromS. kanamyceticus has been stably maintained inE. coli using pJP3. This recombinant DNA can be transferred intoS. lividans with increased efficiency by utilizing heat treatment during protoplast formation.     

Expression of genes from the marine bacteriumAlteromonas haloplanktis 214 inEscherichia coli K-12

DNA from the marine bacteriumAlteromonas haloplanktis 214 was partially digested withSau 3A and inserted into theBam HI site of the cloning vector pBR322. The ligation mixture was used to transformEscherichia coli HB101. The gene bank plasmid preparation obtained was used to transformEscherichia coli K-12 strain EO2717, an organism auxotrophic for histidine, arginine, adenine, uracil and thiamin. Prototrophic transformants for each of the five metabolites were isolated using appropriate minimal media for selection. Plasmids isolated from each of the transformants were shown by hybridization to containA. haloplanktis DNA and to be capable of complementing the appropriate mutation inE. coli EO2717. Restriction maps showed that each of the plasmids was different.     

High level extracellular secretion of thermostable α-amylase ofBacillus stearothermophilus inEscherichia coli

Summary Bacillus stearothermophilus BR135 (ATCC 29609)amy gene was cloned in pBR322 from its plasmid DNA and was subcloned in a vector useful both forB. subtilis andE. coli.E.coli HB101 harboring the plasmid pSS099 when grown in L medium in presence of 5. g/ml chloramphenicol produces 70 units/ml of extracellular -amylase. This is nearly twice that ofE.coli cells harboring pSSO76, a plasmid havingamy ofB.stearothermophilus BR135 atHindIII site of pBR322. Characteristically the protein was a 58 kd protein and cross reacted with antiserum developed against purified -amylase of BR135.     

Generating In Vivo Cloning Vectors for Parallel Cloning of Large Gene Clusters by Homologous Recombination

A robust method for the in vivo cloning of large gene clusters was developed based on homologous recombination (HR), requiring only the transformation of PCR products into Escherichia coli cells harboring a receiver plasmid. Positive clones were selected by an acquired antibiotic resistance, which was activated by the recruitment of a short ribosome-binding site plus start codon sequence from the PCR products to the upstream position of a silent antibiotic resistance gene in receiver plasmids. This selection was highly stringent and thus the cloning efficiency of the GFPuv gene (size: 0.7 kb) was comparable to that of the conventional restriction-ligation method, reaching up to 4.3 × 10⁴ positive clones per μg of DNA. When we attempted parallel cloning of GFPuv fusion genes (size: 2.0 kb) and carotenoid biosynthesis pathway clusters (sizes: 4 kb, 6 kb, and 10 kb), the cloning efficiency was similarly high regardless of the DNA size, demonstrating that this would be useful for the cloning of large DNA sequences carrying multiple open reading frames. However, restriction analyses of the obtained plasmids showed that the selected cells may contain significant amounts of receiver plasmids without the inserts. To minimize the amount of empty plasmid in the positive selections, the sacB gene encoding a levansucrase was introduced as a counter selection marker in receiver plasmid as it converts sucrose to a toxic levan in the E. coli cells. Consequently, this method yielded completely homogeneous plasmids containing the inserts via the direct transformation of PCR products into E. coli cells.     

Cloning of two protease genes fromRhodocyclus gelatinosa APR 3-2 and their expression inEscherichia coli

Two different protease genes were cloned fromRhodocyclus gelatinosa APR 3-2 inEscherichia coli HB 101/ with pBR329 or its derivatives. The recombinant plasmids designated as pRP100 and pRP300 contained 11.2 and 10.6 kb DNA fragments, respectively. The differences of both plasmids in restriction enzyme maps indicate that these plasmids contained different protease genes. DNA fragments coding for protease, 6.4 kb and 4.5 kb from pRP100 and pRP300, were subcloned into pRP329 and designated as pRP101 and pRP301, respectively. The two cloned proteases were excreted in culture medium ofE. coli, and ß-lactamase ofE. coli, which was originally localized in periplasmic space, was also excreted in the medium.     

A high molecular weight plasmid ofZymomonas mobilis harbours genes for HgCl2 resistance

Summary Plasmids fromZ. mobilis could be stably maintained inE. coli HB101 in which the expression of various drug resistance markers could be monitored. A large molecular weight plasmid (5.2 kbp) ofZ. mobilis was found to harbour the genes for mercuric chloride degradation and to confer uponE. coli, resistance to a higher mercuric chloride concentration as compared toZ. mobilis. The introduction of this plamsid madeE. coli sensitive to concentrations of cadmium acetate which were originally non-inhibitory to it.     

The minimal replicon of the Streptomyces ghanaensis plasmid pSG5 identified by subcloning and Tn5 mutagenesis

Summary The cryptic plasmid pSG5 of Streptomyces ghanaensis 5/1B (DSM 2932) was characterized to have a molecular size of 12.7 kb and an approximate copy number of 20–50 per chromosome. A bifunctional derivative, designated pSW344E, consisting of pSG5 and an Escherichia coli vector plasmid was constructed. Following Tn5 mutagenesis in E. coli, the replication functions of the mutagenized pSW344E plasmids were analysed in S. lividans. A 2 kb DNA fragment of the pSG5 replicon was found to carry replication functions. Subcloning of pSG5 DNA into various replication probe vectors resulted in the identification of the pSG5 minimal replicon, identical to the above mentioned 2 kb DNA region. Several small bifunctional plasmids, able to replicate in E. coli as well as in Streptomyces, were generated during subcloning. Some of these plasmids were found to be useful shuttle vectors.     

The effect of restriction on shotgun cloning and plasmid stability in Bacillus subtilis Marburg

Summary Using the bifunctional cloning vehicle pHP13, which carries the replication functions of the cryptic Bacillus subtilis plasmid pTA1060, the effects of BsuM restriction on the efficiency of shotgun cloning of heterologous Escherichia coli DNA were studied. In a restriction-deficient but modification-proficient mutant of B. subtilis, clones were obtained at a high frequency, comparable to frequencies normally obtained in E. coli (10⁴ clones per g target DNA). Large inserts were relatively abundant (26% of the clones contained inserts in the range of 6 to 15 kb), which resulted in a high average insert length (3.6 kb). In the restriction-proficient B. subtilis strain, the class of large inserts was underrepresented. Transformation of B. subtilis with E. coli-derived individual recombinant plasmids was affected by BsuM restriction in two ways. First, the transforming activities of recombinant plasmids carrying inserts larger than 4 kb, were, in comparison with the vector pHP13, reduced to varying degrees in the restricting host. The levels of the reduction increased with insert length, resulting in a 7800-fold reduction for the largest plasmid used (pC23; insert length 16 kb). Second, more than 80% of the pC23 transformants in the restricting strain contained a deleted plasmid. In the non-restricting strain, the transforming activities of the plasmids were fairly constant as a function of insert length (in the range of 0–16 kb), and no structural instability was observed. It is concluded that for shotgun cloning in B. subtilis, the use of restriction-deficient strains is highly preferable. Evidence is presented that in addition to XhoI other sequences are involved in BsuM restriction. It is postulated that AsuII sites are additional target sites for BsuM restriction.     

Identification of the Multi-Resistance Gene cfr in Escherichia coli Isolates of Animal Origin

Previous study indicated that the multi-resistance gene cfr was mainly found in gram-positive bacteria, such as Staphylococcus and Enterococcus, and was sporadically detected in Escherichia coli. Little is known about the prevalence and transmission mechanism of cfr in E. coli. In this study, the presence of cfr in E. coli isolates collected during 2010–2012 from food-producing animals in Guangdong Province of China was investigated, and the cfr-positive E. coli isolates were characterized by PFGE, plasmid profiling, and genetic environment analysis. Of the 839 E. coli isolates, 10 isolates from pig were cfr positive. All the cfr-positive isolates presented a multi-resistance phenotype and were genetically divergent as determined by PFGE. In 8 out of the 10 strains, the cfr gene was located on plasmids of ∼30 kb. Restriction digestion of the plasmids with EcoRI and sequence hybridization with a cfr-specific probe revealed that the cfr-harboring fragments ranged from 6 to 23 kb and a ∼18 kb cfr-carrying fragment was common for the plasmids that were ∼30 kb. Four different genetic environments of cfr were detected, in which cfr is flanked by two identical copies of IS26, which may loop out the intervening sequence through homologous recombination. Among the 8 plasmids of ∼30 kb, 7 plasmids shared the same genetic environment. These results demonstrate plasmid-carried cfr in E. coli and suggest that transposition and homologous recombination mediated by IS26 might have played a rule in the transfer of the cfr gene in E. coli.