Cloning, sequencing and expression of the xylanase gene from a Bacillus subtilis strain B10 in Escherichia coli

Bacillus subtilis strain B10 was isolated for degumming of ramie blast fibers, and a fragment of 642-bp was amplified from chromosomal DNA by using primers directed against the sequence of Bacillus subtilis xylanase gene given in GenBank. The positive clones were screened on the selected LB agar plates supplemented with xylan by Congo-red staining method. The recombinant plasmid from one positive clone was used for further analysis and DNA sequencing. The gene sequence is different from the reported xylanase gene sequence in sites of two base pairs. The recombinant plasmid was expressed in Escherichia coli, and xylanase activity was measured. The xylanase distribution in extracellular, intracellular and periplasmic fractions were about 22.4%, 28.0% and 49.6%, respectively. The xylanase had optimal activity at pH 6.0 and 50 degrees C.     

枯草芽孢杆菌Mn-SOD基因的克隆及原核表达

为了实现Mn-SOD基因在大肠杆菌(E.coli)中的可溶性表达,根据枯草芽孢杆菌(Bacillus subtilis)168sodA核酸序列设计引物,以枯草芽孢杆菌ATCC 9372基因组为模板,PCR扩增获得了Mn-SOD基因.将此基因重组至原核表达载体pET-28a,构建含Mn-SOD基因的重组表达质粒,并转化至大肠杆菌BL21(DE3).异丙基-β-D-硫代半乳糖苷(IPTG)诱导表达获得Mn-SOD,蛋白分子量约为26kD,占全菌蛋白的5.6%.改良的连苯三酚自氧化法测定SOD活力,菌体可溶性总蛋白SOD比活为51.09U·mg^-1,是对照组的.8倍.枯草芽孢杆菌ATCC 9372 Mn-SOD基因在大肠杆菌BL21(DE3)中首次成功表达,产物具有较高的可溶性和活性,为大量制备Mn-SOD奠定了基础.     

Cloning and expression of the Escherichia coli recA gene in Bacillus subtilis

By means of homopolymer dG-dC tailing, using PstI linearized pBR327 as vector, we constructed small plasmids containing the entire Escherichia coli recA gene. The 1.8-kb inserts were recloned in the Bacillus subtilis expression vector pPL608 in a B. subtilis recE4 strain. Analysis of plasmid-coded proteins showed expression of the E. coli recA gene both in minicells and whole cells of B. subtilis. Expression was under control of the bacteriophage SP02 promoter, which is part of pPL608. A recA-expressing plasmid completely abolished the transformation deficiency of the recE4 mutant as well as its sensitivity to mitomycin C (MC). The expressed recA gene also restored recombination in other B. subtilis strains lacking the recE gene product. These results indicate a high similarity between the functions of the E. coli RecA and B. subtilis RecE proteins.     

Cloning, nucleotide sequence and expression in Escherichia coli of a lipase gene from Bacillus subtilis 168.

The gene coding for an extracellular lipase of Bacillus subtilis 168 was cloned and found to be expressed in Escherichia coli. Enzyme activity measurements showed no fatty acid chain length preference. A set of Tn5 insertions which inactivate the gene were localized and used to initiate its sequencing. The nucleotide sequence was determined on two independent clones expressed in E. coli. In one of these clones, the sequence revealed a frameshift, due to the presence of an additional adenine in the N-terminal region, which caused the interruption of the open reading frame, probably allowing translation to initiate at a second ATG codon. The sequence of the wild-type lip gene from B. subtilis was confirmed on the chromosomal fragment amplified by polymerase chain reaction (PCR). When compared to other lipases sequenced to date, the enzyme described here lacks the conserved pentapeptide Gly-X-Ser-X-Gly supposed to be essential for catalysis. However, alignments of several microbial lipase sequences suggest that the pentapeptide Ala-X-Ser-X-Gly present in the lipase B. subtilis may function as the catalytic site. Homologies were found in the N-terminal protein region with lipases from different Pseudomonas species. The predicted M(r) and isoelectric point for the mature protein are 19,348 and 9.7 respectively.     

Molecular cloning of a Bacillus subtilis xylanase gene in Escherichia coli

A gene coding for xylanase synthesis in Bacillus subtilis was isolated by direct shotgun cloning using Escherichia coli as a host. Following partial digestion of B. subtilis chromosomal DNA with PstI or EcoRI restriction enzymes, fragments ranging from 3 to 7 kb were introduced into the PstI or EcoRI sites of pBR325. Transformed colonies having lost either the ampicillin or chloramphenicol resistance markers were screened directly on 1% xylan plates. Out of 8000 transformants, ten xylanase-positive clones were identified by the clearing zone around lysozyme-treated colonies. Further characterization of one of the clones showed that the xylanase gene was present in a 3.9-kb insert within the PstI site of the plasmid pBR325. Retransformation of E. coli strain with the xylanase-positive hybrid plasmid pRH271 showed 100% transformation to xylanase production. The intracellular xylanase produced by the transformed E. coli was purified by ion exchange and gel permeation chromatography. The electrophoretic mobility of the purified xylanase indicated an Mr of 22 000.     

Cloning and expression of the Escherichia coli D-xylose isomerase gene in Bacillus subtilis

A DNA fragment containing the Escherichia coli D-xylose isomerase gene and D-xylulokinase gene had been isolated from an E. coli genomic bank constructed by Clarke and Carbon. The D-xylose isomerase gene coding for the synthesis of an important industrial enzyme, xylose isomerase, was subcloned into a Bacillus-E. coli bifunctional plasmid. It was found that the intact E. coli gene was not expressed in B. subtilis, a host traditionally used to produce industrial enzymes. An attempt was then made to express the E. coli gene in B. subtilis by fusion of the E. coli xylose isomerase structural gene downstream to the promoter of the penicillinase gene isolated from Bacillus licheniformis. Two such fused genes were constructed and they were found able to be expressed in both B. subtilis and E. coli.     

Expression of a xylanase gene of Bacillus pumilus in Escherichia coli and Bacillus subtilis

Summary A hybrid plasmid, pOXN29 (10.4 Mdal), coding the xylanase (xynA) and -xylosidase (xynB) genes of Bacillus pumilus IPO was constructed by the ligation of pBR322 and a 7.7 Mdal PstI-fragment of chromosomal DNA as reported in our previous paper (Panbangred et al. 1983). A deletion plasmid of pOXN29, pOXN293 (9.2 Mdal), which contains xynA and xynB, was ligated with pUB110 at an EcoRI site, and used to transform B. subtilis MI111. Two selected clones of B. subtilis as xylanase hyper-producers contained plasmids pOXW11 (4.2 Mdal) and pOXW12 (4.0 Mdal), both consisting of only pUB110, xynA, and its flanking regions, as the result of spontaneous deletion. These B. subtilis clones produced 2.7–3.0 times as much xylanase as B. pumilus. Escherichia coli and B. subtilis clones harbouring the hybrid plasmids synthesized xylanase and -xylosidase constitutively, whereas both enzymes were induced by xylose in B. pumilus.Xylanase synthesized by B. subtilis harbouring pOXW11 or pOXW12 was excreted into the medium like that of B. pumilus IPO, but xylanase synthesized in E. coli harbouring pOXN29, 293 or pOXW1 coding xynA was intracellular. In a previous investigation (Panbangred et al. 1983), xylanase was found to be located in the cytoplasm, not the periplasm nor the membrane fraction in E. coli cells harbouring pOXN29 derivatives. In spite of the abnormal location of xylanase synthesized in E. coli, the signal peptide was processed in the same way as in B. pumilus, with the same molecular weight and the same amino terminal sequences of xylanase prepared from E. coli cells and B. pumilus culture fluid.     

Cloning, sequencing, and expression in Escherichia coli of the Bacillus subtilis gene for phosphatidylserine synthase.

The Bacillus subtilis pss gene encoding phosphatidylserine synthase was cloned by its complementation of the temperature sensitivity of an Escherichia coli pssA1 mutant. Nucleotide sequencing of the clone indicated that the pss gene encodes a polypeptide of 177 amino acid residues (deduced molecular weight of 19,613). This value agreed with the molecular weight of approximately 18,000 observed for the maxicell product. The B. subtilis phosphatidylserine synthase showed 35% amino acid sequence homology to the yeast Saccharomyces cerevisiae phosphatidylserine synthase and had a region with a high degree of local homology to the conserved segments in some phospholipid synthases and amino alcohol phosphotransferases of E. coli and S. cerevisiae, whereas no homology was found with that of the E. coli counterpart. A hydropathy analysis revealed that the B. subtilis synthase is very hydrophobic, in contrast to the hydrophilic E. coli counterpart, consisting of several strongly hydrophobic segments that would span the membrane. A manganese-dependent phosphatidylserine synthase activity, a characteristic of the B. subtilis enzyme, was found exclusively in the membrane fraction of E. coli (pssA1) cells harboring a B. subtilis pss plasmid. Overproduction of the B. subtilis synthase in E. coli cells by a lac promoter system resulted in an unusual increase of phosphatidylethanolamine (up to 93% of the total phospholipids), in contrast to gratuitous overproduction of the E. coli counterpart. This finding suggested that the unusual cytoplasmic localization of the E. coli phosphatidylserine synthase plays a role in the regulation of the phospholipid polar headgroup composition in this organism.     

Cloning and expression of the Bacillus subtilis methyltransferase gene in Escherichia coli ada- cells

DNA fragments of Bacillus subtilis were inserted into a plasmid vector that can multiply in Escherichia coli cells, and foreign genes were expressed under the control of the lac promoter. By selecting hybrid plasmids that confer an increased resistance to alkylating agents on E. coli ada- mutant cells, the B. subtilis gene dat, which encodes O6-methylguanine-DNA methyltransferase, was cloned. The Dat protein, with a molecular weight of about 20,000, could transfer the methyl group from methylated DNA to its own protein molecule. Based on the nucleotide sequence of the gene, it was deduced that the protein comprises 165 amino acids and that the molecular weight is 18,779. The presumptive amino acid sequence of Dat protein is homologous to the sequences of the E. coli Ogt protein and the C-terminal half of the Ada protein, both of which carry O6-methylguanine-DNA methyltransferase activity. The pentaamino acid sequence Pro-Cys-His-Arg-Val, the cysteine residue of which is the methyl acceptor site in Ada protein, was conserved in the 3 methyltransferase proteins. The structural similarity of these methyltransferases suggests possible evolution from a single ancestral gene.     

Cloning and expression in Escherichia coli of a xylanase gene from Bacteroides ruminicola 23.

A gene coding for xylanase activity in the ruminal bacterial strain 23, the type strain of Bacteroides ruminicola, was cloned into Escherichia coli JM83 by using plasmid pUC18. AB. ruminicola 23 genomic library was prepared in E. coli by using BamHI-digested DNA, and transformants were screened for xylanase activity on the basis of clearing areas around colonies grown on Remazol brilliant blue R-xylan plates. Six clones were identified as being xylanase positive, and all six contained the same 5.7-kilobase genomic insert. The gene was reduced to a 2.7-kilobase DNA fragment. Xylanase activity produced by the E. coli clone was found to be greater than that produced by the original B. ruminicola strain. Southern hybridization analysis of genomic DNA from the related B. ruminicola strains, D31d and H15a, by using the strain 23 xylanase gene demonstrated one hybridizing band in each DNA.     

Cloning and expression of the Clostridium thermosulfurogenes glucose isomerase gene in Escherichia coli and Bacillus subtilis.

The gene that encodes thermostable glucose isomerase in Clostridium thermosulfurogenes was cloned by complementation of glucose isomerase activity in a xylA mutant of Escherichia coli. A new assay method for thermostable glucose isomerase activity on agar plates, using a top agar mixture containing fructose, glucose oxidase, peroxidase, and benzidine, was developed. One positive clone, carrying plasmid pCGI38, was isolated from a cosmid library of C. thermosulfurogenes DNA. The plasmid was further subcloned into a Bacillus cloning vector, pTB523, to generate shuttle plasmid pMLG1, which is able to replicate in both E. coli and Bacillus subtilis. Expression of the thermostable glucose isomerase gene in both species was constitutive, whereas synthesis of the enzyme in C. thermosulfurogenes was inducible by D-xylose. B. subtilis and E. coli produced higher levels of thermostable glucose isomerase (1.54 and 0.46 U/mg of protein, respectively) than did C. thermosulfurogenes (0.29 U/mg of protein). The glucose isomerases synthesized in E. coli and B. subtilis were purified to homogeneity and displayed properties (subunit Mr, 50,000; tetrameric molecular structure; thermostability; metal ion requirement; and apparent temperature and pH optima) identical to those of the native enzyme purified from C. thermosulfurogenes. Simple heat treatment of crude extracts from E. coli and B. subtilis cells carrying the recombinant plasmid at 85 degrees C for 15 min generated 80% pure glucose isomerase. The maximum conversion yield of glucose (35%, wt/wt) to fructose with the thermostable glucose isomerase (10.8 U/g of dry substrate) was 52% at pH 7.0 and 70 degrees C.     

Cloning of the debranching-enzyme gene from Thermoanaerobium brockii into Escherichia coli and Bacillus subtilis.

The gene for an enzyme with single or dual specificity on complex carbohydrates has been transferred from its native host (Thermoanaerobium brockii), a thermophilic anaerobe, into Escherichia coli and Bacillus subtilis. Most of the gene coding region is in a 2.2-kilobase PstI fragment that is common to the E. coli and B. subtilis chimeric vectors pCPC902 and pCPC903, respectively. Although the T. brockii debranching enzyme secreted from B. subtilis was unglycosylated and had less thermostability, more enzyme was secreted from B. subtilis (0.80 to 1.0 U/ml) than from T. brockii (0.23 U/ml). E. coli did not export any measurable enzyme. From the fermentation broth of B. subtilis containing pCPC903, three active species of the debranching enzyme were separated; two species are possibly protease digestion products of the larger protein (105,000 molecular weight). Whereas the enzyme can cleave all of the alpha-1----6 glucosidic linkages (and none of the alpha-1----4 bonds) in pullulan, it hydrolyzed mostly alpha-1----4 and very few of the alpha-1----6 linkages in starch. Upon hydrolysis of pullulan by the enzyme, only maltotriose was produced, while starch was digested to various-sized oligomers.     

Cloning of the Bacillus subtilis DLG beta-1,4-glucanase gene and its expression in Escherichia coli and B. subtilis.

The gene encoding beta-1,4-glucanase in Bacillus subtilis DLG was cloned into both Escherichia coli C600SF8 and B. subtilis PSL1, which does not naturally produce beta-1,4-glucanase, with the shuttle vector pPL1202. This enzyme is capable of degrading both carboxymethyl cellulose and trinitrophenyl carboxymethyl cellulose, but not more crystalline cellulosic substrates (L. M. Robson and G. H. Chambliss, Appl. Environ. Microbiol. 47:1039-1046, 1984). The beta-1,4-glucanase gene was localized to a 2-kilobase (kb) EcoRI-HindIII fragment contained within a 3-kb EcoRI chromosomal DNA fragment of B. subtilis DLG. Recombinant plasmids pLG4000, pLG4001a, pLG4001b, and pLG4002, carrying this 2-kb DNA fragment, were stably maintained in both hosts, and the beta-1,4-glucanase gene was expressed in both. The 3-kb EcoRI fragment apparently contained the beta-1,4-glucanase gene promoter, since transformed strains of B. subtilis PSL1 produced the enzyme in the same temporal fashion as the natural host B. subtilis DLG. B. subtilis DLG produced a 35,200-dalton exocellular beta-1,4-glucanase; intracellular beta-1,4-glucanase was undetectable. E. coli C600SF8 transformants carrying any of the four recombinant plasmids produced two active forms of beta-1,4-glucanase, an intracellular form (51,000 +/- 900 daltons) and a cell-associated form (39,000 +/- 400 daltons). Free exocellular enzyme was negligible. In contrast, B. subtilis PSL1 transformed with recombinant plasmid pLG4001b produced three distinct sizes of active exocellular beta-1,4-glucanase: approximately 36,000, approximately 35,200, and approximately 33,500 daltons. Additionally, B. subtilis PSL1(pLG4001b) transformants contained a small amount (5% or less) of active intracellular beta-1,4-glucanase of three distinct sizes: approximately 50,500, approximately 38,500 and approximately 36,000 daltons. The largest form of beta-1,4-glucanase seen in both transformants may be the primary, unprocessed translation product of the gene.     

Cloning of a xylanase gene from Aspergillus usamii and its expression in Escherichia coli

The complete gene xyn// that encodes endo-1,4-beta-xylanase secreted by Aspergillus usamii E001 was cloned and sequenced. The coding region of the gene is separated by only one intron. It encodes 184 amino acid residues of a protein with a calculated molecular weight of 19.8kDa plus a signal peptide of 27 amino acids. The amino acid sequence of the xyn// gene has higher similarity with those of family 11 of glycosyl hydrolases reported from other microorganisms. The mature peptide encoding cDNA was subcloned into pET-28a(+) expression vector. The recombinant plasmid was expressed in Escherichia coli BL21-CodonPlus (DE3)-RIL, and xylanase activity was measured. The expressed fusion protein was analyzed by SDS-PAGE and a new specific band with molecular weight of about 20kDa was found when induced by IPTG. Enzyme activity assay verified the recombinant protein as a xylanase. A maximum activity of 49.6Umg(-1) was obtained from cellular extract of E. coli BL21-CodonPlus (DE3)-RIL harboring pET-28a-xyn//. The xylanase had optimal activity at pH 4.6 and 50 degrees C. This is the first report on the cloning of a xylanase gene from A. usamii.     

Cloning and expression in Escherichia coli of a xylanase gene from Bacteroides ruminicola 23

A gene coding for xylanase activity in the ruminal bacterial strain 23, the type strain of Bacteroides ruminicola, was cloned into Escherichia coli JM83 by using plasmid pUC18. AB. ruminicola 23 genomic library was prepared in E. coli by using BamHI-digested DNA, and transformants were screened for xylanase activity on the basis of clearing areas around colonies grown on Remazol brilliant blue R-xylan plates. Six clones were identified as being xylanase positive, and all six contained the same 5.7-kilobase genomic insert. The gene was reduced to a 2.7-kilobase DNA fragment. Xylanase activity produced by the E. coli clone was found to be greater than that produced by the original B. ruminicola strain. Southern hybridization analysis of genomic DNA from the related B. ruminicola strains, D31d and H15a, by using the strain 23 xylanase gene demonstrated one hybridizing band in each DNA.     

Cloning and expression of the Clostridium thermosulfurogenes glucose isomerase gene in Escherichia coli and Bacillus subtilis

The gene that encodes thermostable glucose isomerase in Clostridium thermosulfurogenes was cloned by complementation of glucose isomerase activity in a xylA mutant of Escherichia coli. A new assay method for thermostable glucose isomerase activity on agar plates, using a top agar mixture containing fructose, glucose oxidase, peroxidase, and benzidine, was developed. One positive clone, carrying plasmid pCGI38, was isolated from a cosmid library of C. thermosulfurogenes DNA. The plasmid was further subcloned into a Bacillus cloning vector, pTB523, to generate shuttle plasmid pMLG1, which is able to replicate in both E. coli and Bacillus subtilis. Expression of the thermostable glucose isomerase gene in both species was constitutive, whereas synthesis of the enzyme in C. thermosulfurogenes was inducible by D-xylose. B. subtilis and E. coli produced higher levels of thermostable glucose isomerase (1.54 and 0.46 U/mg of protein, respectively) than did C. thermosulfurogenes (0.29 U/mg of protein). The glucose isomerases synthesized in E. coli and B. subtilis were purified to homogeneity and displayed properties (subunit Mr, 50,000; tetrameric molecular structure; thermostability; metal ion requirement; and apparent temperature and pH optima) identical to those of the native enzyme purified from C. thermosulfurogenes. Simple heat treatment of crude extracts from E. coli and B. subtilis cells carrying the recombinant plasmid at 85 degrees C for 15 min generated 80% pure glucose isomerase. The maximum conversion yield of glucose (35%, wt/wt) to fructose with the thermostable glucose isomerase (10.8 U/g of dry substrate) was 52% at pH 7.0 and 70 degrees C.     

Cloning and expression of Bacillus subtilis phage DNA methyltransferase genes in Escherichia coli and B. subtilis

The DNA methyltransferase (Mtase) genes of the temperate Bacillus subtilis phages SPR (wild type and various mutants), phi 3T, rho 11 and SP beta have been cloned and expressed in Escherichia coli and B. subtilis host-plasmid vector systems. Mtase activity has been quantitated in these clones by performing in vitro methylation assays of cell-free extracts. The four-phage Mtase genes differ in the amount of Mtase synthesized when transcribed from their genuine promoters. In B. subtilis as well as in E. coli the SPR Mtase is always produced in smaller amounts than the other phage Mtases. Expression levels of the SPR Mtase are dependent on the strength of the upstream vector promoter sequences. Overproduction of the SPR wild-type and mutant enzymes was achieved in E. coli (inducible expression) by fusions to the lambda pL or the tac promoter and in B. subtilis (constitutive expression) by means of the phage SP02 promoter.     

Cloning of a thermostable α-amylase gene from Bacillus licheniformis and its expression in Escherichia coli and Bacillus subtilis

Abstract The gene coding for the thermostable α-amylase Bacillus licheniformis has been isolated from a direct shotgun in Escherichia coli using the bacteriophage lambda as a vector. The fragment containing the α-amylase gene has been sub-cloned in pBR322 and its restriction map determined. The α-amylase produced by the E. coli clones retained the thermostability of the B. licheniformis enzyme. Expression and properties of the gene product in E. coli and Bacillus subtilis have been examined.