Molecular cloning and functional expression of a Talaromyces emersonii derived alpha-amylase encoding genetic determinant in a human cell line

Summary A cDNA fragment encoding a Talaromyces emersonii acid stable alpha-amylase has been cloned into a mammalian cell expression vector system. When human HeLa cells were transformed with this DNA, functional enzyme could be detected in extracellular media and cell lysates derived from stable transformants. Expression of the T. emersonii derived cDNA was verified by northern dot blotting hybridisation analysis of mRNA extracted from transformants, using the labelled amylase encoding cDNA determinant as a probe. Results obtained suggest that expression of the fungus derived alpha-amylase in the transformed HeLa cells is glucocorticoid dependent.     

Cloning and expression of raw-starch-digesting alpha-amylase gene from Bacillus circulans F-2 in Escherichia coli

The raw potato-starch-digesting alpha-amylase gene of Bacillus circulans F-2 was cloned for the first time in Escherichia coli C600, using plasmid pYEJ001. The recombinant plasmid, named pYKA3, has a 5.4 kb insert from a chromosome of the donor bacterium. Subcloning of this amylase gene gave plasmid pHA300 which carried 3.15 kb of the inserted DNA. The transformed bacterium, E. coli C600 (pYKA3), produced the amylase in the periplasmic space, whereas it is secreted outside the cell in the donor bacterium. The cloned raw-starch-digesting alpha-amylase has a molecular weight of 93,000 on SDS-PAGE, and its action pattern was absolutely the same as that of the potent raw-starch-digestible amylase produced by B. circulans F-2. The periplasmic amylase produced by the transformed E. coli (pHA300) could digest raw starch granules such as potato, corn and barley raw starch granules, indicating that the raw-starch-digesting amylase is active in E. coli. Furthermore, this amylase crossreacted with the rabbit antiserum raised against the raw potato-digesting alpha-amylase of B. circulans F-2. From these results it was concluded that the cloned amylase is the same amylase protein as B. circulans F-2 amylase, which has a potent raw-starch digestibility. Thus, this paper is to our knowledge the first describing the molecular cloning of raw-starch-digesting alpha-amylase from Bacillus species and its successful expression in E. coli.     

Cloning and expression of the gene for neutral protease of Bacillus amyloliquefaciens in Bacillus subtilis

A Bacillus amyloliquefaciens neutral protease gene was cloned and expressed in Bacillus subtilis.The chromosomal DNA of B. amyloliquefaciens strain F was partially digested with restriction endonuclease Sau3AI, and 2 to 9 kb fragments isolated were ligated into the BamHI site of plasmid pUB110. Then, B. subtilis strain 1A289 was transformed with the hybrid plasmids by the method of protoplast transformation and kanamycin-resistant transformants were screened for the formation of large halo on a casein plate. A transformant that produced a large amount of an extracellular neutral protease harbored a plasmid, designated as pNP150, which contained a 1.7 kb insert.The secreted neutral protease of the transformant was found to be indistinguishable from that of DNA donor strain B. amyloliquefaciens by double immunodiffusion test and SDS-polyacrylamide gel electrophoresis.The amount of the neutral protease activity excreted into culture medium by the B. subtilis transformed with pNP150 was about 50-fold higher than that secreted by B. amyloliquefaciens. The production of the neutral protease in the transformant was partially repressed by addition of glucose to the medium.     

Protoplast transformation in coryneform bacteria and introduction of an alpha-amylase gene from Bacillus amyloliquefaciens into Brevibacterium lactofermentum.

The goal of this study was to investigate the likelihood of developing useful transformation systems for coryneform bacteria. Two species of coryneform bacteria, Brevibacterium lactofermentum and Corynebacterium lilium, were transformed with chimeras constructed from pUB110 and a cryptic coryneform plasmid (pGX1901). C. lilium protoplasts were also efficiently transfected with phage CS1 DNA. High transformation and transfection frequencies were obtained after only 2 min of lysozyme treatment of lysozyme-sensitive mutants. A series of experiments was also conducted to determine whether DNA from other species of important industrial microbes from the genus Bacillus could be expressed in coryneform bacteria. Evidence of restriction of Bacillus subtilis DNA by B. lactofermentum was observed but could be overcome. A Bacillus amyloliquefaciens alpha-amylase gene (amyEBamP) was subcloned onto a plasmid able to replicate in B. lactofermentum. B. lactofermentum transformants for this plasmid expressed amylase activity and produced material cross-reactive to amylase antibody.     

Protoplast transformation in coryneform bacteria and introduction of an alpha-amylase gene from Bacillus amyloliquefaciens into Brevibacterium lactofermentum

The goal of this study was to investigate the likelihood of developing useful transformation systems for coryneform bacteria. Two species of coryneform bacteria, Brevibacterium lactofermentum and Corynebacterium lilium, were transformed with chimeras constructed from pUB110 and a cryptic coryneform plasmid (pGX1901). C. lilium protoplasts were also efficiently transfected with phage CS1 DNA. High transformation and transfection frequencies were obtained after only 2 min of lysozyme treatment of lysozyme-sensitive mutants. A series of experiments was also conducted to determine whether DNA from other species of important industrial microbes from the genus Bacillus could be expressed in coryneform bacteria. Evidence of restriction of Bacillus subtilis DNA by B. lactofermentum was observed but could be overcome. A Bacillus amyloliquefaciens alpha-amylase gene (amyEBamP) was subcloned onto a plasmid able to replicate in B. lactofermentum. B. lactofermentum transformants for this plasmid expressed amylase activity and produced material cross-reactive to amylase antibody.     

Molecular cloning of the ADE1 gene of Saccharomyces cerevisiae and stability of the transformants

Plasmid YEp(ADE1)1a, containing a 2.7-kb Sau3A fragment of Saccharomyces cerevisiae DNA inserted at the BamHI site of the yeast shuttle vector pBTI-1 (Morris et al., 1981), results in high frequency, unstable transformation of ade1 yeast strains. A second plasmid, YRp(ADE1)2, containing adjacent 0.5-kb and 3.0-kb BamHI fragments in pBR322 gave three types of yeast transformants: (1) transformants carrying extrachromosomal copies of the plasmid which indicate the presence of a functional ars sequence, (2) transformants indistinguishable from ade1 strains by hybridization analyis, and (3) a transformant carrying a multimeric form of YRp(ADE1)2. Cells transformed with either of the plasmids are free of the red pigment characteristic of ade1 mutants and indicate potential for direct colour-based selection of yeast transformants using ADE1 plasmids.     

Functional expression of cloned yeast DNA in Escherichia coli: specific complementation of argininosuccinate lyase (argH) mutations.

Segments of yeast (Saccharomyces cerevisiae) DNA cloned on various plasmid vectors in Escherichia coli can be functionally expressed to produce active enzymes. We have identified several ColE1-DNA(yeast) plasmids capable of complementing argH mutations, including deletions, in E. coli. Variants of the original transformants that grow faster on selective media and contain higher levels of the complementing enzyme activity (argininosuccinate lyase) can be readily isolated. The genetic alterations leading to increased expression of the yeast gene are associated with the cloned yeast DNA segment, rather than the host genome. The yeast DNA segment cloned in these plasmids also specifies a suppressor of the leuB6 mutation in E. coli. The argH and leuB6 complementing activities are expressed from discrete regions of the cloned yeast DNA segment, since the two genetic functions can be separated on individual recloned restriction fragments. The ease with which the bacterial cell can achieve functional high-level gene expression from cloned yeast DNA indicates that there are no significant barriers preventing expression of many yeast genes in E. coli.     

Designed gene amplification on the Bacillus subtilis chromosome

We previously reported the cloning of a 1.6 kb HindIII fragment (containing the junction of the repeating unit) from chromosomal DNA of Bacillus subtilis strain B7 in which tandem amplification of a 16 kb region occurred, and the induction of B7-type gene amplification by competence transformation with this cloned fragment. Based on this result, we designed, on the B. subtilis chromosome, a gene amplification of the 22 kb repeating unit containing the alpha-amylase structural gene (amyE), the tunicamycin-resistance gene (tmrB) and the shikimate kinase structural gene (aroI). We cloned only two short DNA fragments from both termini of the 22 kb region, constructed a junction structure of the designed repeating unit on pBR327 and transformed a B. subtilis wild-type strain by this constructed plasmid. As a result, we succeeded in obtaining tunicamycin-resistant (Tmr) transformants in which the designed gene amplification of 22 kb occurred on the chromosome. The Tmr transformants showed high productivity of alpha-amylase and shikimate kinase. The copy number of the repeating unit was estimated to be 10-20. This system may provide an effective means of amplifying long (greater than 20 kb) DNA regions on the chromosome.     

Cloning of Corticium rolfsii glucoamylase cDNA and its expression in Saccharomyces cerevisiae

A cDNA coding for the glucoamylase of Corticium rolfsii AHU 9627 was cloned using synthetic oligonucleotide probes that code for inner amino acid sequences of the purified enzyme. This clone (CG 15) is 1900 base pairs long and contains the entire coding region for a polypeptide of 579 residues. Comparison with amino acid sequences of other fungal glucoamylases showed homologies of 35%–56%, and most homology with that of Aspergillus niger. The expression plasmid pACG 115 was constructed by introduction of the coding region of CG 15 into a yeast expression vector pAAH 5, containing the promoter and terminator of alcohol dehydrogenase (ADH1). Saccharomyces cerevisiae AH 22, containing the recombinant plasmid pACG 115, acquired starch-saccharifying ability.     

Alpha-factor-directed synthesis of Bacillus stearothermophilus alpha-amylase in Saccharomyces cerevisiae

Promoter and leader sequence of Bacillus stearothermophilus alpha-amylase gene were removed and the gene was joined in-frame to sequences encoding the leader region of Saccharomyces cerevisiae mating pheromone alpha-factor on plasmid p69A (a hybrid of pBR322 and S. cerevisiae 2-microns plasmid). S. cerevisiae cells were transformed with plasmids containing the hybrid genes, obtaining yeast transformants which exhibit a significant extra-cellular amylolytic activity in solid medium, but not in liquid medium. Levels of alpha-amylase activity in solid medium were found to depend on the mode of fusion of the alpha-amylase gene to the alpha-factor leader region.     

Molecular cloning of the SUF2 frameshift suppressor gene from Saccharomyces cerevisiae

A genetic approach to the molecular cloning of frameshift suppressor genes from yeast is described. These suppressors act by suppressing +1 G:C base-pair insertion mutations in glycine or proline codons. The cloning regimen involves an indirect screen for yeast transformants which harbor a functional suppressor gene inserted into the autonomously replicating “shuttle” vector YEp13, followed by transfer of the hybrid plasmid from yeast into Escherichia coli. Using this procedure a 10.7-kb DNA fragment carrying the SUF2 frameshift suppressor gene has been isolated. This suppressor acts specifically on +1 G:C insertions in proline codons. When inserted into an integrative vehicle and reintroduced into yeast by transformation, this fragment integrates by homologous recombination in the region of the SUF2 locus on chromosome III. A large proportion of the fragment overlaps with another cloned DNA segment which carries the closely linked CDC10 gene. The SUF2 fragment carries at least two tRNA genes. The SUF2 gene and one of the tRNA genes are located on a 0.85-kb restriction fragment within the 10.7-kb segment. A method is also described for the isolation of DNA fragments carrying alternative alleles of the SUF2 locus. Using this procedure, the wild-type suf2⁺ allele has been cloned.     

Cloning of α-amylase gene fromSchwanniomyces occidentalis and expression inSaccharomyces cerevisiae

The cloning of α-amylase gene ofS. occidentalis and the construction of starch digestible strain of yeast,S. cerevisiae AS. 2. 1364 with ethanol-tolerance and without auxotrophic markers used in fermentation industry were studied. The yeast/E.coli shuttle plasmid YCEp1 partial library ofS. occidentalis DNA was constructed and α-amylase gene was screened in S.cerevisiae by amylolytic activity. Several transformants with amylolysis were obtained and one of the fusion plasmids had an about 5.0 kb inserted DNA fragment, containing the upstream and downstream sequences of α-amylase gene fromS. occidentalis. It was further confirmed by PCR and sequence determination that this 5.0 kb DNA fragment contains the whole coding sequence of α-amylase. The amylolytic test showed that when this transformant was incubated on plate of YPDS medium containing 1 % glum and 1 % starch at 30°C for 48 h starch degradation zones could be visualized by staining with iodine vapour. α-amylase activity of the culture filtratate is 740–780 mU/mL and PAGE shows that the yeast harboring fusion plasmids efficiently secreted α-amylase into the medium, and the amount of the recombinant α-amylase is more than 12% of the total proteins in the culture filtrate. These results showed that α-amylase gene can be highly expressed and efficiently secreted inS. cerevisiae AS. 2.1364, and the promotor and the terminator of α-amylase gene fromS. occidentalis work well inS. cercvisiac AS. 2.1364.     

Ultra-Low Background DNA Cloning System

Yeast-based in vivo cloning is useful for cloning DNA fragments into plasmid vectors and is based on the ability of yeast to recombine the DNA fragments by homologous recombination. Although this method is efficient, it produces some by-products. We have developed an “ultra-low background DNA cloning system” on the basis of yeast-based in vivo cloning, by almost completely eliminating the generation of by-products and applying the method to commonly used Escherichia coli vectors, particularly those lacking yeast replication origins and carrying an ampicillin resistance gene (Amp^r). First, we constructed a conversion cassette containing the DNA sequences in the following order: an Amp^r 5′ UTR (untranslated region) and coding region, an autonomous replication sequence and a centromere sequence from yeast, a TRP1 yeast selectable marker, and an Amp^r 3′ UTR. This cassette allowed conversion of the Amp^r-containing vector into the yeast/E. coli shuttle vector through use of the Amp^r sequence by homologous recombination. Furthermore, simultaneous transformation of the desired DNA fragment into yeast allowed cloning of this DNA fragment into the same vector. We rescued the plasmid vectors from all yeast transformants, and by-products containing the E. coli replication origin disappeared. Next, the rescued vectors were transformed into E. coli and the by-products containing the yeast replication origin disappeared. Thus, our method used yeast- and E. coli-specific “origins of replication” to eliminate the generation of by-products. Finally, we successfully cloned the DNA fragment into the vector with almost 100% efficiency.     

Molecular cloning and expression ofBacillus subtilis bglS gene inSaccharomyces cerevisiae

A 2.7-kb EcoRI DNA fragment carrying aBacillus subtilis endo--1,3-1,4-glucanase gene (bglS) from theE. coli plasmid pFG1 was cloned into anEscherichia coli/yeast shuttle vector to construct a hybrid plasmid YCSH. The hybrid plasmid was used to transformSaccharomyces cerevisiae, and thebglS gene was expressed. Variation between levels ofbglS gene expression inS. cerevisiae was about 2.3-fold, depending on the orientation of the 2.7-kb DNA fragment. Assay of substrate specificity and optimal pH of the enzyme demonstrated that the enzyme encoded by YCSH (bglS) was identical with that found inB. subtilis, but the expression level ofbglS gene inS. cerevisiae (YCSH) was much lower than that inE. coli (YCSH).     

Complete nucleotide sequence of a gene coding for heat- and pH-stable alpha-amylase of Bacillus licheniformis: comparison of the amino acid sequences of three bacterial liquefying alpha-amylases deduced from the DNA sequences

The gene coding for the heat-stable and pH-stable alpha-amylase of Bacillus licheniformis 584 (ATCC 27811) was cloned in Escherichia coli and the nucleotide sequence of a DNA fragment of 1,948 base pairs containing the entire amylase gene was determined. As inferred from the DNA sequence, the B. licheniformis alpha-amylase had a signal peptide of 29 amino acid residues and the mature enzyme comprised 483 amino acid residues, giving a molecular weight of 55,200. The amino acid sequence of B. licheniformis alpha-amylase showed 65.4% and 80.3% homology with those of heat-stable Bacillus stearothermophilus alpha-amylase and relatively heat-unstable Bacillus amyloliquefaciens alpha-amylase, respectively. Nevertheless, several regions of the alpha-amylases appeared to be clearly distinct from one another when their hydropathy profiles were compared.     

双功能枯草杆菌诱导型高效表达分泌载体的构建与鉴定

利用大肠杆菌质粒pSP72和枯草杆菌质粒pUB18共整合得到双功能克隆载体pSB。在pSB多克隆位点依次引入枯草杆菌果聚糖蔗糖酶基因启动子-信号肽序列sacBp.s.、地衣芽孢杆菌淀粉酶基因终止子序列α-amyT和短小芽孢杆菌增强子基因degQ,最终构建了双功能枯草杆菌诱导型高效表达分泌载体pSBPTQ。将VasostatinⅠ基因作为靶基因检测sacBp.s.、α-amyT和degQ在pSBPTQ进行外源基因表达时的功能,结果表明,在蔗糖诱导下,sacB启动子有效启动了Vasostatin I基因的表达和分泌,α-amy T提高了VasostatinⅠ基因的转录效率,而degQ明显增强了VasostatinⅠ基因的表达水平。VasostatinⅠ基因在蔗糖诱导下成功表达并分泌到枯草杆菌细胞外,蛋白质分泌效率达到90%左右。质粒稳定性试验结果表明,经过40个世代之后,质粒pSBPTQ在枯草杆菌DB1342中仍旧保持在83%以上。