Cloning and expression in Escherichia coli of an extremely thermostable oligo-1,6-glucosidase gene from Bacillus thermoglucosidasius.

The gene for an extremely thermostable oligo-1,6-glucosidase (dextrin-6-alpha-D-glucanohydrolase; EC 3.2.1.10) of obligately thermophilic Bacillus thermoglucosidasius KP1006 was cloned within a 4.2-kilobase HindIII-PvuII fragment of DNA by using the plasmid pUC19 as a vector and Escherichia coli C600 as a host. The gene was transcribed, presumably from its own promoter, in E. coli. E. coli with the hybrid plasmid accumulated oligo-1,6-glucosidase mainly in the cytoplasm. The level of enzyme production was comparable to that observed for B. thermoglucosidasius. The enzyme coincided absolutely with the B. thermoglucosidasius enzyme in its molecular weight (60,000), in its electrophoretic behavior on denaturing and nondenaturing polyacrylamide gels, in the temperature dependency of its stability and activity, and in its antigenic determinants.     

Isolation and characterization of the yeast 3-phosphoglycerokinase gene (PGK) by an immunological screening technique

An immunological screening technique has been used for the detection of a specific antigen-producing clone in a bank of bacterial colonies containing hybrid plasmids. This technique involves covalent attachment of antiserum to cyanogen bromide-activated paper discs, contact of this paper with lysed colonies on agar plates, and finally detection of the bound antigen with 125I-labeled antibody. Using this method, we have identified an Escherichia coli colony, containing a yeast DNA insert in plasmid ColE1, that produces antigen which combines with antibody directed against purified yeast 3-phosphoglycerate kinase. The hybrid plasmid (pYe57E2) obtained by this procedure has been shown by both biochemical and genetic methods to contain the structural gene PGK for yeast 3-phosphoglycerate kinase. The location of the PGK structural gene on pYe56E2 was determined by immunological screening of E. coli colonies bearing plasmids containing various reconstructions of the original yeast DNA insert. Examination of the expression of the cloned yeast PGK gene in both E. coli and yeast has shown that functional enzyme is synthesized from the cloned gene in yeast, but not in E. coli.     

Cloning of genes for bacterial glycosyltransferases. II. Selection of a hybrid plasmid carrying the rfah gene.

A hybrid ColE1 plasmid containing DNA from Escherichia coli K12 were identified which was capable of correcting the defect in UDP-galactose:lipopolysaccharide alpha1,3-galactosyltransferase in an rfaH mutant of Salmonella typhimurium. Expression of the gene for this enzyme was also demonstrated in several strains of E. coli by direct assay. The E. coli and S. typhimurium enzymes are similar in catalytic properties and immunologic specificity. The finding of the galactosyltransferase activity in E. coli extracts is surprising since the alpha1,3-galactosylglucose disaccharide which is the product of the enzyme-catalyzed reaction does not appear to be present in the E. coli lipopolysaccharide.     

Cloning and the expression of the hemolysin gene of Leptospira pomona pomona in Escherichia coli

The library of Leptospira pomona genes was obtained on phage vector AL 47.1. From this library a recombinant phage carrying the hemolysin gene was selected. The DNA fragment (7.7 kb) of this phage containing the hemolysin gene was subcloned on plasmid pUC19. E. coli clones with hybrid plasmid pDR7 were shown to be hemolytic, but the secretion of hemolysin by E. coli into the culture medium was not observed.     

Cloning of the gene for Escherichia coli glutamyl-tRNA synthetase

The structural gene for the glutamyl-tRNA synthetase of Escherichia coli has been cloned in E. coli strain JP1449, a thermosensitive mutant altered in this enzyme. Ampicillin-resistant and tetracycline-sensitive thermoresistant colonies were selected following the transformation of JP1449 by a bank of hybrid plasmids containing fragments from a partial Sau3A digest of chromosomal DNA inserted into the BamHI site of pBR322. One of the selected clones, HS7611, has a level of glutamyl-tRNA synthetase activity more than 20 times higher than that of a wild-type strain. The overproduced enzyme has the same molecular weight and is as thermostable as that of a wild-type strain, indicating that the complete structural gene is present in the insert. These characteristics were lost by curing this clone of its plasmid with acridine orange, and were transferred with high efficiency to the mutant strain JP1449 by transformation with the purified plasmid. A physical map of the plasmid, which contains an insert of about 2.7 kb in length, is presented.     

Molecular cloning of the Pseudomonas putida glyoxalase I gene in Escherichia coli

The glyoxalase I gene of Pseudomonas putida was cloned onto a vector plasmid pBR 322 as a 7.5 kilobase Sau 3AI fragment of chromosomal DNA and the hybrid plasmid was designated pGI 318. The gene responsible for the glyoxalase I activity in pGI 318 was recloned in pBR 322 as a 2.2 kilobase Hin dIII fragment and was designated pGI 423. The P. putida glyoxalase I gene on pGI 318 and pGI 423 was highly expressed in E. coli cells and the glyoxalase I activity level was increased more than 150 fold in the pGI 423 bearing strain compared with that of E. coli cells without pGI 423. The E. coli transformants harboring pGI 318 or pGI 423 could grow normally in the presence of methylglyoxal, although the E. coli cells without plasmid were inhibited to grow and showed the extremely elongated cell shape.     

Cloning the Gene for the Malolactic Fermentation of Wine from Lactobacillus delbrueckii in Escherichia coli and Yeasts

The gene responsible for the malolactic fermentation of wine was cloned from the bacterium Lactobacillus delbrueckii into Escherichia coli and the yeast Saccharomyces cerevisiae. This gene codes for the malolactic enzyme which catalyzes the conversion of l-malate to l-lactate. A genetically engineered yeast strain with this enzymatic capability would be of considerable value to winemakers. L. delbrueckii DNA was cloned in E. coli on the plasmid pBR322, and two E. coll clones able to convert l-malate to l-lactate were selected. Both clones contained the same 5-kilobase segment of L. delbrueckii DNA. The DNA segment was transferred to E. coli-yeast shuttle vectors, and gene expression was analyzed in both hosts by using enzymatic assays for l-lactate and l-malate. When grown nonaerobically for 5 days, E. coli cells harboring the malolactic gene converted about 10% of the l-malate in the medium to l-lactate. The best expression in S. cerevisiae was attained by transfer of the gene to a shuttle vector containing both a yeast 2-mum plasmid and yeast chromosomal origin of DNA replication. When yeast cells harboring this plasmid were grown nonaerobically for 5 days, ca. 1.0% of the l-malate present in the medium was converted to l-lactate. The L. delbrueckii controls grown under these same conditions converted about 25%. A laboratory yeast strain containing the cloned malolactic gene was used to make wine in a trial fermentation, and about 1.5% of the l-malate in the grape must was converted to l-lactate. Increased expression of the malolactic gene in wine yeast will be required for its use in winemaking. This will require an increased understanding of the factors governing the expression of this gene in yeasts.     

Dihydroorotase from Escherichia coli. Cloning the pyrC gene and production of tryptic peptide maps

We have inserted a 1.7-kilobase pair Escherichia coli DNA fragment containing the 1-kilobase pair pyrC gene into the high copy number plasmid pKC16. Dihydroorotase expressed by the pyrC plasmid in E. coli constituted 6.3% of the soluble protein in frozen cell paste. Pure dihydroorotase derived from this frozen cell paste was compared with pure enzyme derived from an E. coli strain lacking the pyrC plasmid: tryptic peptide maps from the two dihydroorotase preparations, produced using reverse-phase high performance liquid chromatography, were indistinguishable. We conclude that the entire pyrC gene is present on the hybrid plasmid and that the dihydroorotase produced from this plasmid is identical to the wild type.     

Identification, purification, and characterization of Escherichia coli virus T1 DNA methyltransferase

An Escherichia coli virus T1-induced DNA methyltransferase was identified by activity gel analysis in homogenates of infected E. coli DNA-adenine-methylation-deficient strains. Although the Mr of this protein (31,000) is in the same range as that of the E. coli DNA adenine methyltransferase, the two proteins are not closely related; the E. coli dam gene does not hybridize with T1 DNA. Selective conditions for measurement of the T1 activity were developed, and the enzyme was purified to functional homogeneity, as shown by activity analysis in polyacrylamide gels. Requirements for optimal activity of the viral enzyme were determined to be pH 6.9, ionic strengths below 0.1 M KCl, and a temperature between 40 and 43 degrees C. The Km for S-adenosyl-L-methionine is 4.9 microM. The purified T1 DNA methyltransferase is capable of methylating adenine in 5'-GATC-3' sites in vitro.     

A Col E1 hybrid plasmid containing Escherichia coli genes complementing d-xylose negative mutants of Escherichia coli and Salmonella typhimurium

The Clarke and Carbon bank of Col El - Escherichia coli DNa hybrid plasmids was screened for complementation of d-xylose negative mutants of E. coli. Of several obtained, the smallest, pRM10, was chosen for detailed study. Its size was 16 kilobases (kb) and that of the insert was 9.7 kg. By transformation or F'-mediated conjugation this plasmid complemented mutants of E. coli defective in either D-xylose isomerase or D-xylulose kinase activity, or both. The activity of D-xylulose kinase in E. coli transformants which bear an intact chromosomal gene for this enzyme was greater than that for the host, due to a gene dosage effect. The plasmid also complemented D-xylose negative mutants of Salmonella typhimurium by F'-mediated conjugation between E. coli and S. typhimurium. Salmonella typhimurium mutants complemented were those for D-xylose isomerase and for D-xylulose kinase in addition to pleiotropic D-xylose mutants which were defective in a regulatory gene of the D-xylose operon. In addition, the plasmid complemented the glyS mutation in E. coli and S. typhimurium. The glyS mutant of E. coli was temperature sensitive, indicating that the plasmid carried the structural gene for glycine synthetase. The glyS mutation in E. coli maps at 79 min, as do the xyl genes. The behaviour of the plasmid is consistent with the existence of a d-xylose operon in E. coli. The data also suggest that the plasmid carries three of the genes of this operon, specifically those for D-xylose isomerase, D-xylulose kinase, and a regulatory gene.     

Cloning and expression in Escherichia coli of a Klebsiella ozaenae plasmid-borne gene encoding a nitrilase specific for the herbicide bromoxynil.

An enzyme (nitrilase) that converts the herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) to its metabolite 3,5-dibromo-4-hydroxybenzoic acid was shown to be plasmid encoded in the natural soil isolate Klebsiella ozaenae. The bromoxynil-specific nitrilase was expressed in Escherichia coli by direct transfer and stable maintenance in E. coli of a naturally occurring 82-kilobase K. ozaenae plasmid. Irreversible loss of the ability to metabolize bromoxynil both in E. coli and K. ozaenae was associated with the conversion of the 82-kilobase plasmid to a 68-kilobase species. In E. coli this conversion was the result of a host recA+-dependent recombinational event. A gene, designated bxn, encoding the bromoxynil-specific nitrilase was constitutively expressed in K. ozaenae and E. coli and subcloned on a 2.6-kilobase PstI DNA segment. The polarity and the location of the gene were determined by assaying hybrid constructs of the bromoxynil-specific nitrilase gene fused with the heterologous lac promoter.     

Amplification of the respiratory NADH dehydrogenase of Escherichia coli by gene cloning.

A relatively simple method has been used to clone the gene coding for the respiratory NADH dehydrogenase (NADH-ubiquinone oxidoreductase) of Escherichia coli from unfractionated chromosomal DNA. The restriction endonucleases EcoRI, BamI and HindIII were used to construct three hybrid plasmid pools from total E. coli DNA and the amplifiable plasmids pSF2124 and pGM706. Three different restriction endonucleases were used to increase the chances of cloning the ndh gene intact. Mobilization by the plasmid F was used to transfer the hybrid plasmids into ndh mutants and selection was made for Apr and complementation of ndh. DNA fragments complementing ndh were isolated from both the EcoRI and HindIII hybrid plasmid pools. The strain carrying the hybrid plasmid constructed with EcoRI produced about 8--10 times the normal level of the respiratory NADH dehydrogenase in the cytoplasmic membrane. Treating the cells with chloramphenicol to increase the plasmid copy number allowed the level of NADH dehydrogenase in the membrane to be increased to 50--60 times the level in the wild type. The results indicate the potential of gene cloning for the specific amplification of particular proteins prior to their purification.     

右旋糖酐蔗糖酶工程菌株的构建及其培养条件的研究

[目的]右旋糖酐蔗糖酶是一种以蔗糖为底物,催化转移D-葡萄糖基生成α-葡聚糖或低聚糖的葡萄糖基转移酶.[方法]利用PCR扩增技术,将已获得的右旋糖酐蔗糖酶基因dexYG亚克隆到表达载体PET28a( )上,转化E.coli BL21(DE3),经过卡那霉素抗性筛选和酶切验证后,得到右旋糖酐蔗糖酶工程菌株BL21(DE3)/pET28-dexYG.[结果]经IPTG诱导该基因在E.coli BL21(DE3)中能有效表达,在诱导过程中菌体生长受到抑制.通过对培养时间、IPTG浓度、培养温度、菌浓(OD600)和pH值等产酶因素的优化考察,得到最佳培养条件为:培养时间5h、IPTG浓度0.5mmol/L、25℃、OD600值1.0和pH6.0.酶活力由最初的5.39U/mL提高到35.62U/mL,其中pH值对产酶活力影响最大,在pH6.0时的最高产酶活力是LB原始pH条件下最高酶活的3.5倍,并且pH值也是导致在诱导后期酶活迅速下降的主要原因之一.[结论]酶的表达和酶活的研究结果表明,构建的工程菌株能够异源高效表达右旋糖酐蔗糖酶,并且表现出较高的酶活力.     

Mapping of three plasmids from Lactobacillus helveticus ATCC 15009

A 1.4 kb DNA fragment from the chromosomal DNA of Penicillium nalgiovense was isolated which confers proteolytic activity to E. coli DH5α cells when cloned under the control of the E. coli lacZ promoter. The protein was excreted by the cells as was shown by the formation of a clearing zone in skim milk medium. A retransformation of the plasmid carrying the protease gene into P. nalgiovense leads to transformants with both increased and with nearly no proteolytic activity under neutral conditions. Southern blotting experiments revealed that the transforming plasmid had apparently integrated into the homologous locus and thereby inactivated the residual gene.     

Haemophilus influenzae immunoglobulin A1 protease genes: cloning by plasmid integration-excision, comparative analyses, and localization of secretion determinants.

Many bacteria which establish infections after invasion at human mucosal surfaces produce enzymes which cleave immunoglobulin A (IgA), the primary immunoglobulin involved with protection at these sites. Bacterial species such as Haemophilus influenzae which produce IgA1 proteases secrete this enzyme into their environment. However, when the gene encoding this protein was isolated from H. influenzae serotype d and introduced into Escherichia coli, the activity was not secreted into the medium but was localized in the periplasmic space. In this study, the IgA1 protease gene (iga) from an H. influenzae serotype c strain was isolated and the gene from the serotype d strain was reisolated. The IgA1 proteases produced in E. coli from these genes were secreted into the growth medium. A sequence linked to the carboxyl terminus of the iga gene but not present in the original clone was shown to be necessary to achieve normal secretion. Tn5 mutagenesis of the additional carboxyl-terminal region was used to define a 75- to 100-kilodalton coding region required for complete secretion of IgA1 protease but nonessential for protease activity. The iga genes were isolated by a plasmid integration-excision procedure. In this method a derivative of plasmid pBR322 containing a portion of the protease gene and the kanamycin resistance determinant of Tn5 was introduced into H. influenzae by transformation. The kanamycin resistance gene was expressed in H. influenzae, but since pBR322 derivatives are unable to replicate in this organism, kanamycin-resistant transformants arose by integration of the plasmid into the Haemophilus chromosome by homologous recombination. The plasmid, together with the adjoining DNA encoding IgA1 protease, was then excised from the chromosome with DNA restriction enzymes, religated, and reintroduced into E. coli. Comparisons between the H. influenzae protease genes were initiated which are useful in locating functional domains of these enzymes.     

DNA primase of plasmid ColIb is involved in conjugal DnA synthesis in donor and recipient bacteria.

The sog gene of the IncI alpha group plasmid ColIb is known to encode a DNA primase that can substitute for defective host primase in dnaG mutants of Escherichia coli during discontinuous DNA replication. The biological significance of this enzyme was investigated by using sog mutants, constructed from a derivative of ColIb by in vivo recombination of previously defined mutations in a cloned sog gene. The resultant Sog- plasmids failed to specify detectable primase activity and were unable to suppress a dnaG lesion. These mutants were maintained stably in E. coli, implying that the enzyme is not involved in vegetative replication of ColIb. However, the Sog- plasmids were partially transfer deficient in E. coli and Salmonella typhimurium matings, consistent with the hypothesis that the normal physiological role of this enzyme is in conjugation. This was confirmed by measurements of conjugal DNA synthesis. Studies of recipient cells have indicated that plasmid primase is required to initiate efficient synthesis of DNA complementary to the transferred strand, with the protein being supplied by the donor parent and probably transmitted between the mating cells. Primase specified by the dnaG gene of the recipient can substitute partially for the mutant enzyme, thus providing an explanation for the partial transfer proficiency of the mutant plasmids. Conjugal DNA synthesis in dnaB donor cells was deficient in the absence of plasmid primase, implying that the enzyme also initiates synthesis of DNA to replace the transferred material.     

地衣芽孢杆菌普鲁兰酶编码基因的鉴定

对地衣芽孢杆菌基因组序列分析显示。其中标注为amyX的基因可能编码普鲁兰酶。以PCR方法,从地衣芽孢杆菌染色体DNA中扩增出amyX基因蛋白编码区,插入大肠杆菌表达载体pET28aT7启动予下游。含重组质粒的大肠杆菌BL21（DE3）在IPTG诱导下表达出有活性的普鲁兰酶。酶学性质初步分析表明,重组普鲁兰酶最适反应温度为40℃,最适pH值为6．0。     

A T4 DNA fragment containing genes for the baseplate central plug: Endonuclease restriction, gene expression and cell wall changes

Summary A fragment of Escherichia coli bacteriophage T4D DNA, containing 6.1 Kbp which included the six genes (genes 25, 26, 51, 27, 28 and 29) coding for the tail baseplate central plug has been partially characterized. This DNA fragment was obtained originally by Wilson et al. (1977) by the action of the restriction enzyme EcoRI on a modified form of T4 DNA and was inserted in the pBR322 plasmid and then incorporated into an E. coli K12 strain called RRI. This plasmid containing the phage DNA fragment has now been reisolated and screened for cleavage sites for various restriction endonucleases. Restriction enzymes Bgl 11 and Xbal each attacked one restriction site and the enzyme Hpa 1 attacked two restriction sites on this fragment. The combined digestion of the hybrid plasmid containing the T4 EcoRI DNA fragment conjugated to the pBR322 plasmid with one of these enzymes plus Bam H1 restriction enzyme resulted in the localization of the restriction site for Bgl 11, Xba 1 and Hpa 1. Escherichia coli strain B cells were transformed with this hybrid plasmid and found to have some unexpected properties. E. coli B cells, which are normally restrictive for T4 amber mutants and for T4 temperature sensitive mutants (at 44°) after transformation, were permissive for 25am, 26am and 26^Ts, 51am, and 51^Ts, 27^Ts, and 28^Ts T4 mutants. Extracts from the transformed E. coli cells were found in complementation experiments to contain the gene 29 product, as well as the gene 26 product, the gene 51 product, and the gene 27 product. The complementation experiments and the permissiveness of the transformed E. coli B cells to the various conditional lethal mutants clearly showed that the six T4 genes were producing all six gene products in these transformed cells. However, these cells were not permissive for T4 amber mutants in genes 27, 28, and 29. The transformed E. coli B cells, as compared to untransformed cells, were found to have altered outer cell walls which made them highly labile to osmotic shock and to an increased rate of killing by wild type T4 and all T4 amber mutants except for T4 am29. The change in cell walls of the transformed cells has been found to be due to the T4 baseplate genes on the hybrid plasmid, since E. coli B transformed by the pBR322 plasmid alone does not show the increase in osmotic sensitivity.     

Cloning and expression of the Escherichia coli glgC gene from a mutant containing an ADPglucose pyrophosphorylase with altered allosteric properties.

A mutant strain of Escherichia coli K-12, designated 618, accumulates glycogen at a faster rate than wild-type strain 356. The mutation affects the ADPglucose pyrophosphorylase regulatory properties (N. Creuzat-Sigal, M. Latil-Damotte, J. Cattaneo, and J. Puig, p. 647-680, in R. Piras and H. G. Pontis, ed., Biochemistry of the Glycocide Linkage, 1972). The enzyme is less dependent on the activator, fructose 1,6 bis-phosphate for activity and is less sensitive to inhibition by the inhibitor, 5'-AMP. The structural gene, glgC, for this allosteric mutant enzyme was cloned into the bacterial plasmid pBR322 by inserting the chromosomal DNA at the PstI site. The glycogen biosynthetic genes were selected by cotransformation of the neighboring asd gene into an E. coli mutant also defective in branching enzyme (glgB) activity. Two recombinant plasmids, pEBL1 and pEBL3, that had PstI chromosomal DNA inserts containing glgC and glgB were isolated. Branching enzyme and ADPglucose pyrophosphorylase activities were increased 240- and 40-fold, respectively, in the asd glgB mutant, E. coli K-12 6281. The E. coli K-12 618 mutant glgC gene product was characterized after transformation of an E. coli B ADPglucose pyrophosphorylase mutant with the recombinant plasmid pEBL3. The kinetic properties of the cloned ADPglucose pyrophosphorylase were similar to those of the E. coli K-12 618 enzyme. The inserted DNA in pEBL1 was arranged in opposite orientation to that in pEBL3.