Electrotransformation ofClostridium thermosaccharolyticum

Transformation of the thermophileClostridium thermosaccharolyticum ATCC 31960 was achieved using plasmid pCTC1 and electroporation. Evidence supporting transformation was provided by Southern blots, detection of the plasmid in 10 out of 10 erythromycin-resistant clones, retransformation ofE. coli andC. thermosaccharolyticum with plasmid DNA isolated fromC. thermosaccharolyticum, and a proportional relationship between the number of transformants and the amount of DNA added. Transformation efficiencies were very low for plasmid DNA prepared fromE. coli (0.6 transformants mg^–1 DNA), although somewhat higher for plasmid DNA prepared fromC. thermosaccharolyticum (52 transformants mg^–1 DNA). Transformation-dependent erythromycin resistance indicates that an adenosine methylase gene originating fromEnterococcus faecalis, a mesophile, is expressed inC. thermosaccharolyticum. The plasmid pCTC1 appears to be replicated independently of the chromosome, as indicated by visualization of recovered plasmid on gels, and retransformation using recovered plasmid. pCTC1 is maintained inC. thermosaccharolyticum at both 45 and 60°C. Restriction analysis showed little or no rearrangement occurred upon passage through the thermophile.     

The restriction-modification system in Streptomyces flavopersicus

To clone bifunctional vectors in streptomycetes, it was necessary to define the restriction-modification system ofStreptomyces flavopersicus. Plasmid DNA from bifunctional vectors pIJ699 and pXED3-13, isolated fromE. coli strains with different methylation systems:E. coli DH5α (dam ⁺ dcm ⁺),E. coli MB5386(dam dcm), E. coli CB51 (dam dcm ⁺),E. coli NM544 (dam ⁺ dcm), was used for transformation of protoplasts from strainS. flavopersicus. Restriction ofdcm-methylated DNA fromS. flavopersicus was established. As a host in the intermediate cloning strainE. coli NM544 (dam ⁺ dcm) should be used, as thedcm-transmethylase-dependent strainS. flavopersicus does not process DNA from this strain.     

DNA sequence analysis of the recA genes from Proteus vulgaris, Erwinia carotovora, Shigella flexneri and Escherichia coli B/r

Summary The complete nucleotide sequences of therecA genes fromEscherichia coli B/r,Shigella flexneri, Erwinia carotovora andProteus vulgaris were determined. The DNA sequence of the coding region of theE. coli B/r gene contained a single nucleotide change compared with theE. coli K12 gene sequence whereas theS. flexneri gene differed at 7 residues. In both cases, the predicted proteins were identical in primary structure to theE. coli K12 RecA protein. The DNA sequences of the recA genes fromE. carotovora andP. vulgaris were 80% and 74% homologous, respectively, to theE. coli K12 gene. The predicted amino acid sequences of theE. carotovora andP. vulgaris RecA proteins were 91% and 85% identical respectively, to that ofE. coli K12. The RecA proteins from bothP. vulgaris andE. carotovora diverged significantly in sequence in the last 50 residues whereas they showed striking conservation throughout the first 300 amino acids which include an ATP-binding region and a subunit interaction domain. A putative LexA repressor binding site was localized upstream of each of the heterologous genes.     

Cloning of the gene coding for aromatic amino acid aminotransferase from anE. Coli B strain

Summary AnE. coli B strain showing high activity in the transamination of phenylpyruvate to phenylalanine was used as the DNA source for the construction of a cosmid library inE. coli DG30, a strain which is known to be defective in all three major transaminase genes (aspC, ilvE andtyrB). By complementation analysis, cosmid clones could be identified with inserts carrying atyrB gene. The DNA inserts were further subcloned into pAT153 and thetyrB gene fromE. coli B was found to be similar to the gene reported forE. coli K12. Plasmids containing theE. coli BtyrB gene were transformed into the originalE. coli B strain and the recombinant strains assayed for transaminase activity and plasmid stability.Dedicated to Prof. Dr. Heinz Harnisch on the occasion of his 60th birthday.     

Overexpression of the ATP-dependent helicase RecG improves resistance to weak organic acids in<Emphasis Type="Italic"> Escherichia coli</Emphasis>

Increased resistance to several weak organic acids was conferred on Escherichia coli by overexpression of the ATP-dependent helicase RecG and, to a lesser extent, by overexpressing the helicase RuvAB. This property of helicases was identified by reproducible selection of recG-bearing clones from genomic libraries of the acetate-resistant species Acetobacter aceti and Staphylococcus capitis. We show that overexpression of RecG from both species, but also from E. coli, increased the maximum biomass concentration attained by E. coli cultures that were grown in the presence of various weak organic acids and uncouplers. Furthermore, overexpression of RecG from A. aceti significantly improved the maximum growth rates of E. coli under weak organic acid challenge. Based on the known role of RecG in DNA replication/repair, our data provide a first indication that weak organic acids negatively affect DNA replication and/or repair, and that these negative effects may be counteracted by helicase activity.     

DNA sequence analysis of endoglucanase genes fromPseudomonas fluorescens subsp.cellulosa andPseudomonas sp. NCIB 8634

Summary The DNA of two previously isolated recombinant clones, one fromPseudomonas sp. NCIB 8634 (=Cellvibrio mixtus) (pPC71) and another fromPseudomonas fluorescens subsp.cellulosa (pPFC4) that express endoglucanase activity inE. coli was sequenced. Plasmid pPC71 had three open reading frames, two of which include portions of plasmid pBR322. The third open reading frame occurs entirely within thePseudomonas DNA insert and encodes a protein with a molecular mass of 5845 Da. The DNA insert in pPFC4 was found to contain an open reading frame (PFC-ORF) that encodes a protein of 32189 Da. The major endoglucanase produced inE. coli cells carrying pPFC4 is about 30000 Da [26]. It is concluded that PFC-ORF encodes this endoglucanase. Both ribosome and catabolite gene activator protein binding sites lie upstream from the initiating codon of PFC-ORF. An interesting feature of the PFC-ORF protein is the presence of amino acid motifs Val-Ser-Ser-Ser-Ser and Val-Val-Ser-Ser-Ser-Ser-Ser that occur within a 25 amino acid span.     

Overexpression of the gene forN-acylamino acid racemase fromAmycolatopsis sp. TS-1-60 inEscherichia coli and continuous production of optically active methionine by a bioreactor

A DNA sequence encodingN-acylamino acid racemase (AAR) was inserted downstream from the T7 promoter in pET3c. The recombinant plasmid was introduced intoEscherichia coli MM194 lysogenized with a bacteriophage having a T7 RNA polymerase gene. The amount of AAR produced by theE. coli transformant was 1100-fold more than that produced byAmycolatopsis sp. TS-1-60, the DNA donor strain. The AAR was purified to homogeneity from the crude extract of theE. coli transformant by two steps: heat treatment and Butyl-Toyopearl column chromatography. Bioreactors for the production of optically active amino acids were constructed with DEAE-Toyopearl-immobilized AAR andd- orl-aminoacylase.d- orl-methionine was continuously produced with a high yield fromN-acetyl-dc-methionine by the bioreactor.     

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.     

Tributyltin-resistant marine bacteria: a summary of recent work

Summary A tributyltin chloride (TBTCl)-resistant bacterium,Alteromonas sp. M-1, was isolated from coastal seawater. This bacterium grew in medium containing 125 M TBTCl. TBTCl added to the medium was taken up by this bacterium, however, the amount of TBTCl in the cellular fraction was low after the logarithmic phase, suggesting the existence of a TBTCl-efflux system. A genetic library was constructed using plasmid vector pUC 19. Three positive clones were obtained, by whichE. coli was transformed to TBTCl resistance. Of the three clones, the shortest fragment fromHindIII-library was analyzed. This fragment was 1.8 kb long and contained one complete open reading frame. The predicted amino acid sequence of this open reading frame had a homologous domain to transglycosylases of bacteriophage andE. coli. TBTCl-tolerant marine bacteria other thanAlteromonas sp. M-1 were obtained from natural seawater to which TBTCl was added. DNA-DNA hybridization was performed between the three cloned fragments fromAlteromonas sp. M-1 and chromosomal DNA of the TBTCl-tolerant bacteria. Some strains hybridized with the fragments and some did not, suggesting that several genes are responsible for TBTCl tolerance.     

The host specificity system inEscherichia coli SK

E. coli SK has its own enzyme system providing DNA host specificity which differs from the known types of specificity inE. coli K12 andE. coli B. Modification and restriction are observed when the PBVI or PBV3 phages are transferred fromE. coli SK toE. coli B or K12 (and back).A methylase has been isolated fromE. coli SK cells and partly purified. This methylase catalyzesin vitro transfer of the labelled methyl groups from S-adenosylmethionine (SAM) to DNA of both phage and tissue origin which gives rise to 5-methylcytosine (5MC) and 6-methylaminopurine (6MAP). The methylase preparations isolated from the cells at the stationary growth have proved to be 1.5–1.7 times as active as the enzyme from the cells at the logarithmic growth stage. The extract ofE. coli SK cells infected with the phage S_D cannot methylate DNAin vitro. This fact is due tode novo synthesis of the enzyme which disintegrates SAM down to 5-methylthioadenosine (5MTA) and homoserine (HS). This enzyme is not found in the cells infected with the S_D phage in the presence of chloroamphenicole. The activity of the enzyme which disintegrates SAM is the highest between the 4th and the 5th minutes of infection. Thus it may be assumed that this enzyme, most probably, is an early virus specific protein and preventsin vivo methylation of the phage DNA.     

Cloning,production and secretion of β-galactosidase inAcetobacter pasteurianus

The gene coding for β-galactosidase fromEscherichia coli was cloned into plasmid pACT71 containing the replicon from plasmid pAC1 fromAcetobacter pasteurianus. E. coli MC4100,E. coli JM105,E. coli LE392.23 andA. pasteurianus 3614 were transformed with the recombinant plasmid pACB815. Cells were cultivated in LB, YPG and M media supplemented with glucose, glycerol, lactose or ethanol and β-galactosidase activity was detected in the cells and in the cultivation medium. The best substrate for production of β-galactosidase was lactose. To release β-galactosidase fromA. pasteurianus cells amino acids were added to the cultivation medium. The highest secretory activity was achieved using 1.5% glycine after 36 h of cultivation in the M medium.     

Conjugal Transfer of Plasmid DNA fromEscherichia colito Enterococci: A Method to Make Insertion Mutations

Shuttle vector pAT18 was transferred by conjugation fromEscherichia coliS17-1 toEnterococcus faecalisOG1RF andEnterococcus faeciumSE34. Transfer was mediated by the transfer functions of plasmid RK2 inE. coliS17-1 and the origin of conjugal transfer (oriT) located on pAT18. TheoriTsequence was then inserted into two plasmids to generate vectors pTEX5235 and pTEX5236. These two vectors cannot replicate in gram-positive bacteria and can be used to make insertion mutants in gram-positive bacteria. An internal sequence from an autolysin gene ofE. faecalisOG1RF was cloned into pTEX5235 and transferred by conjugation fromE. coliS17-1 toE. faecalisOG1RF. The plasmid was found to integrate into the chromosome of OG1RF by a single crossover event, resulting in a disrupted autolysin gene. A cosmid carrying the pyrimidine gene cluster fromE. faecalis,with a transposon insertion inpyrC,was also transferred fromE. coliS17-1 toE. faecalisOG1RF. After selection for the transposon, it was found to have recombined into the recipient chromosome by a double crossover between the cosmid and the chromosome of OG1RF. This resulted in apyrCknockout mutant showing an auxotrophic phenotype.     

Construction of a sequencedClostridium perfringens-Escherichia coli shuttle plasmid

A newClostridium perfringens-Escherichia coli shuttle plasmid has been constructed and its complete DNA sequence compiled. The vector, pJIR418, contains the replication regions from theC. perfringens replicon pIP404 and theE. coli vector pUC18. The multiple cloning site and lacZ gene from pUC18 are also present, which means that X-gal screening can be used to select recombinants inE. coli. Both chloramphenicol and erythromycin resistance can be selected inC. perfringens andE. coli since pJIR418 carries theC. perfringens catP and ermBP genes. Insertional inactivation of either the catP or ermBP genes can also be used to directly screen recombinants in both organisms. The versatility of pJIR418 and its applicability for the cloning of toxin genes fromC. perfringens have been demonstrated by the manipulation of a cloned gene encoding the production of phospholipase C.     

Electrophoretic resolution of microheterogeneity inVibrio cholerae lipopolysaccharide

Lipopolysaccharide (LPS) fromVibrio cholerae has been analysed by sodium dodecyl sulfate-potyacrylamide gel electrophoresis. Under normal conditions of electrophoresis which resolveEscherichia coli LPS, V.cholerae LPS shows two diffuse and unresolved bands. However, on long gels at low concentration it can be resolved into two major band types. There are at least 10 slow moving, discrete bands of regular periodicity and three fast moving bands. Comparison with LPS fromE. coli indicates that the heterogeneity occurs over a much smaller range of molecular weight in V.cholerae LPS, with the entire spectrum of discrete bands being contained within the space of fourE. coli repeating units.     

Transformation of a glucose negative mutant ofPachysolen tannophilus with a plasmid carrying the cloned hexokinase PII gene fromSaccharomyces cerevisiae

Lithium treated cells of the yeastPachysolen tannophilus have been transformed with a plasmid carrying the gene encoding for the hexokinase PII enzyme fromSaccharomyces cerevisiae. The gene was expressed and the presence of the enzyme within the cell was demonstrated by DEAE-cellulose chromatography of cell-free extracts. Plasmid DNA from the transformants was used to transformE. coli HB101. Plasmid DNA from the bacterial transformants had the same mobility on an agarose gel as the original plasmid.     

Partial characterization ofPseudomonas fluorescens subsp.cellulosa endoglucanase activity produced inEscherichia coli

Summary The recombinant plasmid, pPFC4, which carriesPseudomonas fluorescens subsp.cellulosa chromosomal DNA was previously isolated on the basis of its ability to direct the expression of endoglucanase inEscherichia coli. In the present study, some physical and chemical properties of this activity were characterized. The major portion (78.4%) of the endoglucanase activity is found in the periplasmic space ofE. coli. This plasmid-encoded endoglucanase has a pH optimum of approximately 6.0 and a temperature optimum of approximately 50°C. With carboxymethylcellulose-zymograms, after polyacrylamide gel electrophoresis, periplasmic extracts fromE. coli carrying pPFC4 show six distinct bands with endoglucanase activity. The molecular mass of the major endoglucanase band is approximately 29 kDa while the remaining bands with endoglucanase activity range from 48 to 100 kDa. Although the basis of this heterogeneity is not known, the DNA insert of pPFC4 that encodes endoglucanase activity is not large enough to contain six separate genes; hence, the observed array of endoglucanases may result from post-translational modification of one or two primary gene products.     

Construction of a new host-vector system inArthrobacter sp. and cloning of the lipase gene

Arthrobacter sp. strain MIS38 was transformed with a shuttle vector containing the kanamycin resistant genekan (derived from Tn5) by an electroporation method. This shuttle vector is fromBrevibacterium lactofermentum andEscherichia coli, pULRS8: - The following optimal condition of electroporation was determined. A square wave pulse of 1 kV/cm electric field strength for 0.5 ms duration yielded 3 × 10⁵ transformants/,g plasmid DNA. The number of transformants increased with the amount of DNA over the range 0.01-5 g. This host-vector system was then used successfully to clone and express a lipase gene fromArthrobacter sp. strain MIS38 into bothArthrobacter sp. MIS38 and E. coli JM109.     

Subcloning and functional analysis of aBacillus subtilis β-1,3-1,4-glucanase gene (bglS) inEscherichia coli

This article describes a 7.1kb EcoRI DNA fragment carrying aBacillus subtilis -1,3-1,4-glucanase gene (bglS). By subcloning, a 1.5kb EcoRI-PstI DNA fragment was inserted into the polylinker cloning sites of the plasmid pUC19 and transferred toEscherichia coli JM101. The fragment directed the synthesis inE. coli of a-1,3-1,4-glucanase that specifically degrades barley glucan and lichenan. The largest proportion (>50%) of the total enzyme activity was cellular enzyme; 25% of the-1,3-1,4-glucanse activity was present in the extracellular fractions. Through enzyme analysis, the enzymes purified fromE. coli or fromBacillus subtilis 1.88 were proved to be identical.