Construction ofEscherichia coli-Clostridium acetobutylicum shuttle vectors and transformation ofClostridium acetobutylicum strains

Summary SeveralE. coli-C. acetobutylicum shuttle vectors were constructed and used to transform twoC. acetobutylicum strains ATCC 824 and NCIMB 8052. Other than pSYL2, none of these vectors were able to transform ATCC 824 due to the presence of a restriction system. However, all of them could transform NCIMB 8052 with efficiencies of 8×10²–6×10³ transformants per g DNA.     

Purification of acetoacetate decarboxylase from Clostridium acetobutylicum ATCC 824 and cloning of the acetoacetate decarboxylase gene in Escherichia coli.

In Clostridium acetobutylicum ATCC 824, acetoacetate decarboxylase (EC 4.1.1.4) is essential for solvent production, catalyzing the decarboxylation of acetoacetate to acetone. We report here the purification of the enzyme from C. acetobutylicum ATCC 824 and the cloning and expression of the gene encoding the acetoacetate decarboxylase enzyme in Escherichia coli. A bacteriophage lambda EMBL3 library of C. acetobutylicum DNA was screened by plaque hybridization, using oligodeoxynucleotide probes derived from the N-terminal amino acid sequence obtained from the purified protein. Phage DNA from positive plaques was analyzed by Southern hybridization. Restriction mapping and subsequent subcloning of DNA fragments hybridizing to the probes localized the gene within an approximately 2.1 kb EcoRI/Bg/II fragment. A polypeptide with a molecular weight of approximately 28,000 corresponding to that of the purified acetoacetate decarboxylase was observed in both Western blots (immunoblots) and maxicell analysis of whole-cell extracts of E. coli harboring the clostridial gene. Although the expression of the gene is tightly regulated in C. acetobutylicum, it was well expressed in E. coli, although from a promoter sequence of clostridial origin.     

Purification of acetoacetate decarboxylase from Clostridium acetobutylicum ATCC 824 and cloning of the acetoacetate decarboxylase gene in Escherichia coli

In Clostridium acetobutylicum ATCC 824, acetoacetate decarboxylase (EC 4.1.1.4) is essential for solvent production, catalyzing the decarboxylation of acetoacetate to acetone. We report here the purification of the enzyme from C. acetobutylicum ATCC 824 and the cloning and expression of the gene encoding the acetoacetate decarboxylase enzyme in Escherichia coli. A bacteriophage lambda EMBL3 library of C. acetobutylicum DNA was screened by plaque hybridization, using oligodeoxynucleotide probes derived from the N-terminal amino acid sequence obtained from the purified protein. Phage DNA from positive plaques was analyzed by Southern hybridization. Restriction mapping and subsequent subcloning of DNA fragments hybridizing to the probes localized the gene within an approximately 2.1 kb EcoRI/Bg/II fragment. A polypeptide with a molecular weight of approximately 28,000 corresponding to that of the purified acetoacetate decarboxylase was observed in both Western blots (immunoblots) and maxicell analysis of whole-cell extracts of E. coli harboring the clostridial gene. Although the expression of the gene is tightly regulated in C. acetobutylicum, it was well expressed in E. coli, although from a promoter sequence of clostridial origin.     

Recognition sequence of a new methyl-specific restriction system from Clostridium acetobutylicum strain ABKn8

A new type II restriction endonuclease, named Cac8I was detected in Clostridium acetobutylicum strain ABKn8. Cac8I cleaved the hexanucleotide sequence [5'-GCN decreases NGC-3'] and generated blunt ends. Up to now no isoschizomer of Cac8I has been described [corrected].     

Construction and characterization of a phage-plasmid hybrid (phagemid), pCAK1, containing the replicative form of viruslike particle CAK1 isolated from Clostridium acetobutylicum NCIB 6444.

A bacteriophage-plasmid hybrid (phagemid) designated pCAK1 was constructed by ligating 5-kbp Escherichia coli plasmid pAK102 (AprEmr) and the 6.6-kbp HaeIII-linearized replicative form of the CAK1 viruslike particle from Clostridium acetobutylicum NCIB 6444. Phagemid pCAK1 (11.6 kbp) replicated via the ColE1 replication origin derived from pAK102 in E. coli. Single-stranded DNA (ssDNA) molecules complexed with protein in a manner which protected ssDNA from nucleases were recovered from the supernatant of E. coli DH11S transformants containing pCAK1 in the absence of cell lysis. This suggests that the viral-strand DNA synthesis replication origin of CAK1 and associated gene expression are functional in E. coli DH11S. The single-stranded form of pCAK1 isolated from E. coli supernatant was transformed into E. coli DH5 alpha' or DH11S by electroporation. Isolation of ampicillin-resistant E. coli transformants following transformation suggests that the complementary-strand DNA synthesis replication origin of CAK1 is also functional in E. coli. The coat proteins associated with ssDNA of pCAK1 demonstrated sensitivity to proteinase K and various solvents (i.e., phenol and chloroform), similar to the results obtained previously with CAK1. Following phagemid construction in E. coli, pCAK1 was transformed into C. acetobutylicum ATCC 824 and C. perfringens 13 by intact cell electroporation. Restriction enzyme analysis of pCAK1 isolated from erythromycin-resistant transformants of both C. acetobutylicum and C. perfringens suggested that it was identical to that present in E. coli transformants.     

Introduction of plasmids into whole cells of Clostridium acetobutylicum by electroporation

Abstract A method is presented for the introduction of plasmids into Clostridium acetobutylicum ATCC 8052 by electroporation. A plasmid shuttle vector, pMTL500E, which contains the erythromycin resistance gene and replication machinery of plasmid pAMβ1, was constructed and introduced into C. acetobutylicum by electroporation. The vector was then used to introduce a 2.2 kb Cla I/ Sph I chromosomal fragment from C. pasteurianum into a leucine requiring mutant of C. acetobutylicum , SBA9, where complementation of auxotrophy was observed. Plasmid DNA indistinguishable from that introduced, on the basis of agarose gel electrophoresis, was observed in transformants containing either plasmid.     

Shuttle cloning vectors for the cyanobacterium Anacystis nidulans.

Hybrid plasmids capable of acting as shuttle cloning vectors in Escherichia coli and the cyanobacterium Anacystis nidulans R2 were constructed by in vitro ligation. DNA from the small endogenous plasmid of A. nidulans was combined with two E. coli vectors, pBR325 and pDPL13, to create vectors containing either two selectable antibiotic resistance markers or a single marker linked to a flexible multisite polylinker. Nonessential DNA was deleted from the polylinker containing plasmid pPLAN B2 to produce a small shuttle vector carrying part of the polylinker (pCB4). The two polylinker-containing shuttle vectors, pPLAN B2 and pCB4, transform both E. coli and A. nidulans efficiently and provide seven and five unique restriction enzyme sites, respectively, for the insertion of a variety of DNA fragments. The hybrid plasmid derived from pBR325 (pECAN1) also transforms both E. coli and A. nidulans, although at a lower frequency, and contains two unique restriction enzyme sites.     

Disruption of a type II endonuclease (TDE0911) enables Treponema denticola ATCC 35405 to accept an unmethylated shuttle vector

The oral spirochete Treponema denticola is associated with human periodontal disease. T. denticola ATCC 35405 and ATCC 33520 are two routinely used laboratory strains. Compared to T. denticola ATCC 33520, ATCC 35405 is more virulent but less accessible to genetic manipulations. For instance, the shuttle vectors of ATCC 33520 cannot be transformed into strain ATCC 35405. The lack of a shuttle vector has been a barrier to study the biology and virulence of T. denticola ATCC 35405. In this report, we hypothesize that T. denticola ATCC 35405 may have a unique DNA restriction-modification (R-M) system that prevents it from accepting the shuttle vectors of ATCC 33520 (e.g., the shuttle plasmid pBFC). To test this hypothesis, DNA restriction digestion, PCR, and Southern blot analyses were conducted to identify the differences between the R-M systems of these two strains. DNA restriction digestion analysis of these strains showed that only the cell extract from ATCC 35405 was able to digest pBFC. Consistently, PCR and Southern blot analyses revealed that the genome of T. denticola ATCC 35405 encodes three type II endonucleases that are absent in ATCC 33520. Among these three endonucleases, TDE0911 was predicted to cleave unmethylated double-stranded DNA and to be most likely responsible for the cleavage of unmethylated pBFC. In agreement with this prediction, the mutant of TDE0911 failed to cleave unmethylated pBFC plasmid, and it could accept the unmethylated shuttle vector. The study described here provides us with a new tool and strategy to genetically manipulate T. denticola, in particular ATCC 35405, and other strains that may carry similar endonucleases.     

Two versatile shuttle vectors for Thermus thermophilus-Escherichia coli containing multiple cloning sites, lacZα gene and kanamycin or hygromycin resistance marker

Two versatile shuttle vectors for Thermus thermophilus and Escherichia coli were developed on the basis of the T. thermophilus cryptic plasmid pTT8 and E. coli vector pUC13. These shuttle vectors, pTRK1T and pTRH1T, carry a gene encoding a protein homologous to replication protein derived from pTT8, a replicon for E. coli, new multiple cloning sites and a lacZα gene from E. coli vector pUC13, and also have a gene encoding a thermostable protein that confers resistance to kanamycin or hygromycin, which can be used as a selection marker in T. thermophilus. These shuttle vectors are useful to develop enzymes and proteins of biotechnological interest. We also constructed a plasmid, pUC13T, which carries the same multiple cloning sites of pTRK1T and pTRH1T. These vectors should facilitate cloning procedures both in E. coli and T. thermophilus.     

Development of Thermus-Escherichia shuttle vectors and their use for expression of the Clostridium thermocellum celA gene in Thermus thermophilus.

We describe the self-selection of replication origins of undescribed cryptic plasmids from Thermus aquaticus Y-VII-51B (ATCC 25105) and a Thermus sp. strain (ATCC 27737) by random insertion of a thermostable kanamycin adenyltransferase cartridge. Once selected, these autonomous replication origins were cloned into the Escherichia coli vector pUC9 or pUC19. The bifunctional plasmids were analyzed for their sizes, relationships, and properties as shuttle vectors for Thermus-Escherichia cloning. Seven different vectors with diverse kanamycin resistance levels, stabilities, transformation efficiencies, and copy numbers were obtained. As a general rule, those from T. aquaticus (pLU1 to pLU4) were more stable than those from the Thermus sp. (pMY1 to pMY3). To probe their usefulness, we used one of the plasmids (pMY1) to clone in E. coli a modified form of the cellulase gene (celA) from Clostridium thermocellum in which the native signal peptide was replaced in vitro by that from the S-layer gene of T. thermophilus HB8. The hybrid product was expressed and exported by E. coli. When the gene was transferred by transformation into T. thermophilus, the cellulase protein was also expressed and secreted at 70 degrees C.     

丁醇合成途径关键酶基因在大肠杆菌中的克隆和表达

【目的】克隆丙酮丁醇梭状芽胞杆菌(Clostridium acetobutylicum)ATCC824丁醇合成途径关键酶基因,构建产丁醇的工程大肠杆菌。【方法】以C.acetobutylicum ATCC824基因组为模板,分别扩增丁醇合成途径关键酶基因thil,adhE2和BCS operon(crt-bcd-etfB-etfA-hbd)基因序列,构建BCS operon-adhE2-thil/pTrc99a/MG1655(pBAT)。重组菌E.coli pBAT采用0.1 mmol异丙基-β-硫代半乳糖苷(IPTG)诱导5 h,测定乙酰基转移酶(THL)、3-羟基丁酰辅酶A脱氢酶(HBD)、3-羟基丁酰辅酶A脱水酶(CRT)、丁酰辅酶A脱氢酶(BCD)、醛醇脱氢酶(BYDH/BDH)的酶活。并以该基因工程菌作为发酵菌种,采用好氧、厌氧和微好氧三种培养方式,检测丁醇产量。【结果】酶活测定结果显示:THL酶活达到0.160 U/mg protein,酶活力提高了近30倍;HBD酶活力提高了近5倍;CRT酶活达到1.53 U/mg protein,野生菌株无此酶活;BCD酶活力提高了32倍;BYDH/BDH酶活力无显著提高。3种发酵培养结果显示在微好氧和厌氧条件下,均有丁醇产生,且丁醇的最大产量约为84 mg/L。【结论】本实验通过构建产丁醇基因工程大肠杆菌,实现了丁醇关键酶基因在大肠杆菌中的活性表达以及发酵产丁醇,为发酵法生产丁醇开辟了一条新的途径。     

Yeast shuttle and integrative vectors with multiple cloning sites suitable for construction of lacZ fusions

We report yeast/Escherichia coli shuttle vectors suitable for fusing yeast promoter and coding sequences to the lacZ gene of E. coli. The vectors contain a region of multiple unique restriction sites including EcoRI, KpnI, SmaI, BamHI, XbaI, SalI, PstI, SphI and HindIII. The region with the unique cloning sites has been introduced in both orientations with respect to lacZ and occurs proximal to the eighth codon of the gene. All the restriction sites have been phased to three different reading frames. Two series of vectors have been constructed. The first series (YEp) has two origins of replication (ori), i.e., of the yeast 2 mu circle and of the ColE1 plasmid of E. coli, and can therefore replicate autonomously in both organisms. These shuttle vectors also have the ApR gene of E. coli and either the yeast LEU2 or URA3 genes to allow for selection of both E. coli and yeast transformants. The second series of vectors (YIp) are identical in all respects to the YEp vectors except that they lack the 2 mu ori. The YIp vectors can be used to integrate lacZ fusions into yeast chromosomal DNA. None of the vectors express beta-galactosidase (beta Gal) in yeast or E. coli in the absence of inserted yeast promoter sequences. The 5'-nontranslated sequences and parts of the coding sequences of various yeast genes have been cloned into representative lacZ fusion vectors. In-frame gene fusions can be detected by beta Gal activity when either yeast or E. coli clones are plated on media containing XGal indicator. Quantitative determinations of promoter activity were made by colorimetric assay of beta Gal activity in whole cells. Fusion of the yeast CYC1 gene to lacZ in one of the vectors allowed detection of regulated expression of this gene when cells were grown under conditions of catabolite repression or derepression.     

Development and characterization of a gene expression reporter system for Clostridium acetobutylicum ATCC 824.

A gene expression reporter system (pHT3) for Clostridium acetobutylicum ATCC 824 was developed by using the lacZ gene from Thermoanaerobacterium thermosulfurogenes EM1 as the reporter gene. In order to test the reporter system, promoters of three key metabolic pathway genes, ptb (coding for phosphotransbutyrylase), thl (coding for thiolase), and adc (coding for acetoacetate decarboxylase), were cloned upstream of the reporter gene in pHT3 in order to construct vectors pHT4, pHT5, and pHTA, respectively. Detection of beta-galactosidase activity in time course studies performed with strains ATCC 824(pHT4), ATCC 824(pHT5), and ATCC 824(pHTA) demonstrated that the reporter gene produced a functional beta-galactosidase in C. acetobutylicum. In addition, time course studies revealed differences in the beta-galactosidase specific activity profiles of strains ATCC 824(pHT4), ATCC 824(pHT5), and ATCC 824(pHTA), suggesting that the reporter system developed in this study is able to effectively distinguish between different promoters. The stability of the beta-galactosidase produced by the reporter gene was also examined with strains ATCC 824(pHT4) and ATCC 824(pHT5) by using chloramphenicol treatment to inhibit protein synthesis. The data indicated that the beta-galactosidase produced by the lacZ gene from T. thermosulfurogenes EM1 was stable in the exponential phase of growth. In pH-controlled fermentations of ATCC 824(pHT4), the kinetics of beta-galactosidase formation from the ptb promoter and phosphotransbutyrylase formation from its own autologous promoter were found to be similar.     

The restriction endonucleases in Bacillus amyloliquefaciens N strain. Substrate specificities.

Two species of restriction endonuclease were isolated by gel filtration and DEAE-cellulose chromatography from a cell-free extract of Bacillus amyloliquefaciens (B. subtilits) N strain; a lower molecular weight endonuclease (endonuclease R.BamNI) and a higher molecular-weight one (endonuclease R.BamNx). Both of them required only Mg2+ for their activities. Endonuclease R.BamNx introduced a larger number of site-specific scissions in Excherchia coli phage lambda DNA that endonuclease R.BamNI did. Endonuclease R.BamNx cleaved Bacillus phage phi 105C DNA at the specific sites which are classified into two groups: one type of sites is modified by B. amyloliquefaciens H strain in vivo while the other is not affected. It was also active on DNA'S OF E. coli phage T7, lambdadvl, Simian virus 40 (SV40) and colicinogenic factor ColEI and was inactive on DNAs of Bacillus phages phi 29 and M2. Endonuclease R.BamHI isolated from H strain by Wilson and Young. This endonuclease was active on DNAs of phage lambda, lambdadvl and SV40, adn was inactive on DNAs of phages phi 105C, phi 29, M2 and T7, and ColEI DNA.     

Restriction of two-replicon shuttle Escherichia coli-Streptomyces plasmids in Streptomyces lividans strain 66

The shuttle Escherichia coli - Streptomyces plasmids were used to transform S. lividans 66. Plasmid DNAs isolated from this strain transform it 10-1000-fold more efficiently than DNAs from E. coli. Rare transformant cured from most restricted plasmid is more efficient recipient of plasmid DNA from E. coli and has the property of R +/- M+ mutant. Restriction in S. lividans 66 correlates with the appearance in DNA from E. coli of the sites susceptible to Scg2I restriction endonuclease. The latter was isolated earlier from recombinant strain Rcg2, a hybrid between S. griseus Kr. 15 and S. coelicolor A3(2). Scg2I possesses the recognition sequence CCTAGG, like EcoRII, MvaI and Eco dcm methylase. The DNA resistant to Scg2I cleavage retained this ability after in vitro modification by EcoRII methylase. So, the resistance of DNA to Scg2I cleavage is not connected with methylation at 4th and 5th position of second cytosine in the recognition sequence. Neither restriction of plasmid DNA in S. lividans 66 is dependent on dcm modification in E. coli, though its dependence on dam modification is not excluded. It is assumed that the restriction in S. lividans 66 is specified by endonuclease analogous to Scg2I.     

Evidence that Escherichia coli virus T1 induces a DNA methyltransferase

DNA of Escherichia coli virus T1 is resistant to MboI cleavage and appears to be heavily methylated. Analysis of methylation by the isoschizomeric restriction enzymes Sau3AI and DpnI revealed that recognition sites for E. coli DNA adenine methylase (dam methylase) are methylated. The same methylation pattern was found for virus T1 DNA grown on an E. coli dam host, indicating a T1-specific DNA methyltransferase.     

Cloning and expression of Clostridium acetobutylicum ATCC 824 acetoacetyl-coenzyme A:acetate/butyrate:coenzyme A-transferase in Escherichia coli

Coenzyme A (CoA)-transferase (acetoacetyl-CoA:acetate/butyrate:CoA-transferase [butyrate-acetoacetate CoA-transferase] [EC 2.8.3.9]) of Clostridium acetobutylicum ATCC 824 is an important enzyme in the metabolic shift between the acid-producing and solvent-forming states of this organism. The purification and properties of the enzyme have recently been described (D. P. Weisenborn, F. B. Rudolph, and E. T. Papoutsakis, Appl. Environ. Microbiol. 55:323-329, 1989). The genes encoding the two subunits of this enzyme have been cloned by using synthetic oligodeoxynucleotide probes designed from amino-terminal sequencing data from each subunit of the CoA-transferase. A bacteriophage lambda EMBL3 library of C. acetobutylicum DNA was prepared and screened by using these probes. Subsequent subcloning experiments established the position of the structural genes for CoA-transferase. Complementation of Escherichia coli ato mutants with the recombinant plasmid pCoAT4 (pUC19 carrying a 1.8-kilobase insert of C. acetobutylicum DNA encoding CoA-transferase activity) enabled the transformants to grow on butyrate as a sole carbon source. Despite the ability of CoA-transferase to complement the ato defect in E. coli mutants, Southern blot and Western blot (immunoblot) analyses showed that neither the C. acetobutylicum genes encoding CoA-transferase nor the enzyme itself shared any apparent homology with its E. coli counterpart. Polypeptides of Mr of the purified CoA-transferase subunits were observed by Western blot and maxicell analysis of whole-cell extracts of E. coli harboring pCoAT4. The proximity and orientation of the genes suggest that the genes encoding the two subunits of CoA-transferase may form an operon similar to that found in E. coli.(ABSTRACT TRUNCATED AT 250 WORDS)