Cloning of the Membrane-Bound Aldehyde Dehydrogenase Gene of Acetobacter polyoxogenes and Improvement of Acetic Acid Production by Use of the Cloned Gene

A genomic clone bank of Acetobacter polyoxogenes NBI1028 constructed in Escherichia coli by use of the expression vector pUC18 was screened with antibody raised against membrane-bound aldehyde dehydrogenase (ALDH; 75 kilodaltons [kDa]) from A. polyoxogenes NBI1028. A clone that synthesized a 41-kDa protein cross-reactive with anti-ALDH antibody was isolated. For cloning of the full-length ALDH structural gene, a cosmid gene bank was screened by Southern blot hybridization with the cloned DNA as a probe, and subcloning from the positive cosmid clone was performed with shuttle vector pMV24. Plasmid pAL25, containing the full-length ALDH structural gene, was isolated and expressed in both E. coli and Acetobacter aceti to produce a fused protein (78 kDa) with a short NH₂-terminal β-galactosidase peptide. pAL25 conferred ALDH production on a mutant of A. aceti lacking the enzyme activity. Transformation of A. aceti subsp. xylinum NBI2099 with pAL25 caused 2- and 1.4-fold increases in the production rate and in the maximum concentration of acetic acid in submerged fermentation, respectively.     

Construction of shuttle vectors derived fromAcetobacter xylinum for cellulose-producing bacteriumAcetobacter xylinum

Summary Shuttle vector pUF106 was constructed by ligation ofAcetobacter xylinum plasmid pFF6 toEscherichia coli plasmid pUC18. It had unique restriction sites suitable for insertion of a foreign DNA fragment and conferred ampicillin resistance to a host. pUF106 transformed cellulose-producingA. xylinum ATCC10245 as well asE. coli JM109.     

Spheroplast Fusion of Acetobacter aceti and Its Application to the Breeding of Strains for Vinegar Production

Spheroplasts of auxotrophic mutants derived from Acetobacter aceti subsp. aceti No. 1023 were efficiently prepared by treatment with lysozyme, using sucrose as an osmotic stabilizer, and regenerated on an agar plate containing sorbitol and gelatin. In addition, spheroplast fusion between the several auxotrophic mutants was achieved in the presence of polyethylene glycol and CaCl₂. The frequency of fusion was found to be about 5 × 10 ⁵. Spheroplast fusion between A. aceti subsp. aceti No. 2 with the ability to grow at high temperature and A. aceti subsp. xylinum NBI1002 with high resistance to acetic acid was also achieved by the same method, with a frequency of 6.0 × 10 ⁶. The fusants showed various degrees of resistance to acetic acid and ability to grow at high temperature. One of the fusants, named No. 116, could produce acetic acid from ethanol continuously under conditions under which both parent strains were unable to grow. This suggests that spheroplast fusion is applicable to the breeding of strains for vinegar production.     

Stopped-Flow Measurement of Reaction Rate of Dihydroxyfumaric Acid with 2, 6-Dichlorophenolindophenol

The proline auxotrophic strain of Acetobacter aceti No. 1023 treated with CaCl₂ solution was transformed to the Pro⁺ phenotype at a frequency of up to 10²/μg DNA using chromosomal DNA prepared from the wild type prototrophic strain. The CaCl₂-treated cells of A. aceti No. 1023 could also be rendered competent for uptake of plasmid DNA. In an attempt to produce an appropriate cloning vector for A. aceti, the restriction patterns of the cryptic plasmids, pTA5001 A (23.5 Kb) and pTA5001B (23 Kb), found in A. aceti No. 1023 were determined. A selectable marker (ampicillin resistance) was introduced onto these cryptic plasmids by fusing them to vector pACYC177 from E. coli, using their single restriction site for XhoI. The hybrid plasmids generated could replicate in and confer ampicillin resistance to both A. aceti and E. coli. The maximum transformation frequency for A. aceti No. 1023 with these vectors was 10³/μg DNA.     

Cloning of the β-Isopropylmalate Dehydrogenase Gene from Acetobacter aceti and Its Use for Construction of a New Host-vector System for Acetobacter

The β-isopropylmalate dehydrogenase (β-IPMDH) gene of Acetobacter aceti No. 1023, which complemented the leuB mutation of Escherichia coli, was cloned and expressed in E. coli. Plasmids pCAL1 and pCAL4, carrying a 5.44 kilobase pairs (kb) HindIII-fragment in the opposite orientation, conferred the same β-IPMDH activity as that of the wild type strain of E. coli. Restriction mapping and deletion analysis indicated that the β-IPMDH gene was located on a 1.65 kb AatII-HindIII fragment. Plasmids pMVL1 and pMVL2, composing the cloned β-IPMDH gene and plasmid pMV102, a plasmid indigenous to Acetobacter, were constructed as plasmid cloning vectors which allow selection of leu⁺ transformants in an A. aceti leu^- host. The A. aceti leu^- host was obtained through the insertional inactivation occurring as a result of homologous recombination between the chromosome of A. aceti and the cloned β-IPMDH gene, which was disrupted by insertion of the kanamycin resistance gene from pACYC177 into the BamHI site in the AatII-HindIII fragment. This system constitutes a relatively simple technique for gene disruption or replacement in Acetobacter that requires a single transformation.     

Development of a Host-vector System for Gluconobacter suboxydans

A shuttle vector for Gluconobacter suboxydans and Escherichia coli was constructed by ligation of a cryptic plasmid, pMV201, found in G. suboxydans IFO 3130 to E. coli plasmid pACYC177. The chimeric plasmid named pMGlOl carries the ampicillin resistance gene derived from pACYC177 and transforms G. suboxydans var. α IFO 3254 as well as E. coli. The transformation conditions for G. suboxydansvar. α IFO 3254 were examined using pMGlOl DNA. Competent cells were induced efficiently by treatment with LiCl or RbCl CaCl₂ which induced the competency of Acetobacter was much less effective. Addition of polyethylene glycol enhanced the transformation efficiency significantly. An efficiency of approximately 10² transformants per μg DNA was finally obtained.     

Functional expression of the genes of Escherichia coli in gram-positive Corynebacterium glutamicum

Summary Hybrid plasmids were constructed by combining in vitro the Escherichia coli plasmid pGA22, which carries the genes determining resistance to kanamycin, tetracycline, chloramphenicol and ampicillin, with the cryptic plasmids, pCG1 and pCG2, of Corynebacterium glutamicum. The hybrid plasmids were introduced into C. glutamicum and E. coli and replicated in both hosts. They expressed all the E. coli resistance phenotypes except ampicillin resistance in C. glutamicum. The levels of antibiotic inactivating enzymes encoded on these plasmids were about four to ten times lower in C. glutamicum than in E. coli. Despite the lack of expression of ampicillin resistance, -lactamase activity was detected in C. glutamicum carrying hybrid plasmids.     

Construction of hybrid plasmid vectors for cloning inEscherichia coli,Bacillus subtilis,and the cyanobacteriumAnacystis nidulans

Two hybrid plasmids capable of acting as shuttle cloning vectors inAnacystis nidulans andBacillus subtilis were constructed by in vitro ligation. One construct, pMG202, consists of theB. subtilis vector pNN101 and the endogenous cyanobacterial plasmid pUH24. This 14.6 kb plasmid confers chloramphenicol resistance in both hosts and tetracycline resistance inB. subtilis. A second vector, pMG101, consists of pNN101 linked to theA. nidulans-Escherichia coli chimeric plasmid pCB4 and is 12.9 kb in size. The pCB4 portion of the vector enables pMG101 to replicate in the third host,E. coli, and confers ampicillin resistance in this bacterium as well as inA. nidulans. Both plasmids possess identical uniqueStu I sites which permit insertional inactivation of the chloramphenicol resistance gene; and, in addition, identical uniqueXho I sites are present on both vectors. Each vector also has a third unique site:Sma I on pMG101 andXba I on pMG202.     

A Host–Vector System for a Cellulose-Producing Acetobacter Strain

An indigenous plasmid, named pAH4, was detected in a cellulose-producing Acetobacter strain. This plasmid, consisting of 4002 bp, contained an AT-rich region and encoded several open reading frames, as deduced by the complete nucleotide sequence. One of the putative open reading frames showed homology with replication proteins of other plasmids. A shuttle vector of Escherichia coli and this strain was constructed by connecting pAH4 to pUC18. Electroporation of the shuttle vector into the strain yielded 1.7 × 10⁵ ampicillin resistant transformants per μg DNA. The shuttle plasmid was very stably maintained in the strain.     

Involvement of a Polyethylene glycol (PEG)-oxidizing Enzyme in the Bacterial Metabolism of PEG

Eighty-seven strains of acetic acid bacteria were surveyed for plasmids by CsCl-ethidium bromide equilibrium centrifugation of cell lysates. Twenty-seven of the 33 strains of Acetobacter were found to harbor plasmid DNA and most strains contained multiple species of low-molecular-weight plasmids. On the other hand, plasmid DNAs were detected in 23 of the 36 strains of Gluconobacter and most of them had molecular weights of more than 5 megadaltons. Of the 18 strains newly isolated from a vinegar factory, some of which were examined taxonomically, 17 contained plasmid DNA. The molecular weights of plasmids detected in this study were in the range of about one to over 17 megadaltons. The plasmids with molecular weights of less than 5 megadaltons were characterized with restriction endonucleases. The physical maps of two plasmids designated as pMV1O1 and pMV102, which were found in the isolated strains, were constructed.     

Construction of broad-host-range plasmids for the expression of heterologous genes in Acetobacter methanolicus B58

The construction of different plasmids reported here on the basis of a broad-host-range RSF1010 replicon allows an efficient expression of heterologous genes in the acidophilic methanol-assimilating bacterium Acetobacter methanolicus B58. The promoter-probe vector pRS201 was used for the identification and isolation of the promoter containing sequences derived from the DNA of the Acetobacter phage Acm1. Further, this plasmid was coupled with the Escherichia coli promoters tac and p_r creating the expression vectors pRS201tac and pRS201p_r, respectively. After the insertion of the chloramphenicol acetyltransferase (cat) gene of the cloned promoters downstream, the chloramphenicol acetyltransferase (CAT) was determined in a cell-free extract of both E. coli and A. methanolicus. Using E. coli promoters as well as promoters of the Acetobacter phage Acm1 arranged in tandem with the promoters of the heterologous genes to be expressed, the pectat lyase gene (ptlB) of Erwinia carotovora and the threonine A gene (thrA) of E. coli were successfully expressed in A. methanolicus. The stability of recombinant plasmids under various conditions in A. methanolicus strains was tested using antibiotic-free media.     

Evidence for multiple carboxymethylcellulase genes in Pseudomonas fluorescens subsp. cellulosa

Summary A genomic library of Pseudomonas fluorescens subsp. cellulosa DNA was constructed in bacteriophage 47.1 and recombinants expressing carboxymethylcellulase (CMCase) activity isolated. A 7.3 kb partial EcoRI fragment, a 9.4 kb EcoRI fragment and a 5.8 kb HindIII fragment were subcloned from three different phages into pUC18 to yield recombinant plasmids pJHH1, pJHH3 and pGJH2 respectively. Cells of Escherichia coli harbouring these plasmids expressed CMCase activity. The positions of the CMCase genes in the three plasmids were determined by subcloning and transposon mutagenesis. pJHH1 contained two distinct DNA regions encoding CMCases, which were controlled by the same promoter. All four cloned enzymes cleaved p-nitrophenyl--D-glucopyranoside, although at a very low rate, but none exhibited exoglucanase activity. In common with other extracellular enzymes cloned in E. coli, all the CMCases were exported to the periplasmic space in the enteric bacterium. The carboxymethylcellulase genes encoded by pJHH1 and pJHH3, were subject to glucose repression in E. coli.Abbreviations SSC 0.15 M NaCl, 0.015 M sodium citrate - Sm^r resistance to streptomycin - Km^r resistance to kanamycin - Ap^r resistance to ampicillin - Tc^r resistance to tetracycline - Cm^r resistance to chloramphenicol - CMCase carboxymethylcellulase     

Genetic organization ofAcetobacter for acetic acid fermentation

Plasmid vectors for the acetic acid-producing strains ofAcetobacter andGluconobacter were constructed from their cryptic plasmids and the efficient transformation conditions were established. The systems allowed to reveal the genetic background of the strains used in the acetic acid fermentation. Genes encoding indispensable components in the acetic acid fermentation, such as alcohol dehydrogenase, aldehyde dehydrogenase and terminal oxidase, were cloned and characterized. Spontaneous mutations at high frequencies in the acetic acid bacteria to cause the deficiency in ethanol oxidation were analyzed. A new insertion sequence element, IS1380, was identified as a major factor of the genetic instability, which causes insertional inactivation of the gene encoding cytochromec, an essential component of the functional alcohol dehydrogenase complex. Several genes including the citrate synthase gene ofA. aceti were identified to confer acetic acid resistance, and the histidinolphosphate aminotransferase gene was cloned as a multicopy suppressor of an ethanol sensitive mutant. Improvement of the acetic acid productivity of anA. aceti strain was achieved through amplification of the aldehyde dehydrogenase gene with a multicopy vector. In addition, spheroplast fusion of theAcetobacter strains was developed and applied to improve their properties. ADH membrane-bound alcohol dehydrogenase - ALDH membrane-bound aldehyde dehydrogenase - IS insertion sequence - NTG N-methyl-N-nitro-N-nitrosoguanidine - PQQ pyrroloquinoline quinone     

Construction of a recombinant plasmid composed of B. subtilis leucine genes and a B. subtilis (natto) plasmid: its use as cloning vehicle in B. subtilis 168.

Summary Recombinant plasmids composed of Bacillus subtilis 168 leucine genes and a B. subtilis (natto) plasmid have been constructed in a recombination deficient (recE4) mutant of Bacillus subtilis 168. The process involved EcoRI fragmentation and ligation of a B. subtilis (natto) plasmid and a composite plasmid RSF2124-B · leu in which B. subtilis 168 leucine genes are linked to the R-factor RSF2124. A constructed plasmid (pLS102) was found to be composed of an EcoRI fragment derived from the vector plasmid and two tandemly repeated EcoRI fragments carrying the leucine genes. A derivative plasmid (pLS101 or pLS103) consisting of one molecule each of the EcoRI fragments was obtained by in vivo intramolecular recombination between the repeated leucine gene fragments in pLS102. pLS103 was cleaved once with BamNI, SmaI and HpaI. Insertion of foreign DNA (Escherichia coli plasmid pBR322) into the BamNI site inactivated leuA but not the leuC function which thus can serve as selective marker if the plasmid is used as vector in molecular cloning. The penicillin resistance carried in pBR322 was not functionally expressed in B. subtilis cells. By partial digestion of pLS103 with HindIII followed by ligation with T4-induced ligase, pLS107 was obtained which contained only one EcoRI site. However, insertion of exogenous DNA (pBR322) into this EcoRI site inactivated both leuA and leuC functions.     

Nocardioform arsenic resistance plasmids and construction of Rhodococcus cloning vectors

One of a number of large nocardioform plasmids previously obtained by a primarily genetic approach was reduced in size to about ˜ 11 kb. This smaller plasmid possessed determinants for resistance to sodium arsenate and sodium arsenite, as well as immunity to nocardiophage Q4. It was joined to an Escherichia coli-positive selection vector constructed by M. Zabeau and colleagues, which had the EcoR1 endonuclease gene placed under the control of the P_R promoter of λ as well as a bla determinant. The resulting shuttle vector of about 14.6 kb was maintained in E. coli and in several strains of Rhodococcus. The vector was efficient in cloning DNA without prior alkaline phosphatase treatment, as a result of the presence of the positive selection function. This function was not significantly expressed in Rhodococcus, and the presence of the nocardioform resistance determinants led to no increase in arsenate or arsenite resistance in E. coli. The presence of the bla gene resulted in an increase of about threefold in ampicillin resistance in Rhodococcus strains.     

Vectors for cloning in cyanobacteria: construction and characterization of two recombinant plasmids capable of transformation of Escherichia coli K12 and Anacystis nidulans R2

Summary Two plasmids were constructed consisting of the E. coli vector pACYC184 and the cyanobacterial plasmid pUC1. These recombinants, designated pUC104 and pUC105, can be transformed to E. coli K12 as well as to the cyanobacterium Anacystis nidulans R2 and in both hosts they express their antibiotic markers. pUC104 and pUC105 differ with respect to the location and the orientation of the pACYC184 segment in pUC1. pUC104 was found to be stable under all circumstances. Transformation of pUC105 to A. nidulans R2 gave intact plasmids when chloramphenicol was the selective agent, but upon ampicillin selection a deletion derivative was produced identical to pUC1. Further characteristics of pUC104 and pUC105 are described and their usefulness as cloning vectors is discussed.     

Development of a Plasmid Vector for Easy Selection of Strong Promoters

A promoter vector pACPR33 for Escherichia coli based on the promotorless ampicillin-resistance gene from pBR322 has been constructed. The promoter of the ampicillin-resistance gene was deleted and replaced by a suitable multiple cloning site. Molecular cloning of promoters into the polylinker resulted in activation of the ampicillin resistance in E. coli. The plasmid contains a functional origin of DNA replication and a tetracycline resistance gene for E. coli, and a chloramphenicol resistance gene for S. aureus. The vector permitted direct detection of promoter activity, especially strong promoters, by easy iodometric determination of β-lactamase activity in liquid or solid media. Received: 26 July 1999 / Accepted: 22 November 1999     

Construction of a colony bank of E. coli containing hybrid plasmids representative of the Bacillus subtilis 168 genome. Expression of functions harbored by the recombinant plasmids in B. subtilis.

Summary A collection of about 2500 clones containing hybrid plasmids representative of nearly the entire genome of B. subtilis 168 was established in E. coli SK1592 by using the poly(dA)·poly(dT) joining method with randomly sheared DNA fragments and plasmid pHV33, a bifunctional vector which can replicate in both E. coli and B. subtilis. Detection of cloned recombinant DNA molecules was based on the insertional inactivation of the Tc gene occurring at the unique BamHI cleavage site present in the vector plasmid.Thirty individual clones of the collection were shown to hybridize specifically with a B. subtilis rRNA probe. CCC-recombinant plasmids extracted from E. coli were pooled in lots of 100 and used to transform auxotrophic mutants of B. subtilis 168. Complementation of these auxotrophic mutations was observed for several markers such as thr, leuA, hisA, glyB and purB. In several cases, markers carried by the recombinant plasmids were lost from the plasmid and integrated into the chromosomal DNA. Loss of genetic markers from the hybrid plasmids did not occur when a rec ^- recipient strain of B. subtilis was used.Abbreviations Ap^R resistance to ampicillin - Tc^R resistance to tetracycline - Cm^R resistance to chloramphenicol - CCC covalently closed circular duplex - Mdal magadalton     

Direction of transcription affects the replication mode of lambda in an in vitro system

Summary pMV158 is a 5.4 kb broad host range multicopy plasmid specifying tetracycline resistance. This plasmid and two of its derivatives, pLS1 and pLS5, are stably mantained and express their genetic information in gram-positive and gram-negative hosts. The in vitro replication of plasmid pMV158 and its derivatives was studied in extracts prepared from plasmid-free Escherichia coli cells and the replicative characteristics of the streptococcal plasmids were compared to those of the E. coli replicons, ColE1 and the mini-R1 derivative pKN182. The optimal replicative activity of the E. coli extracts was found at a cellular phase of growth that corresponded to 2 g wet weight of cells per litre. Maximal synthesis of streptococcal plasmid DNA occurred after 90 min of incubation and at a temperature of 30° C. The optimal concentration of template DNA was 40 g/ml. Higher plasmid DNA concentrations resulted in a decrease in the incorporation of dTMP, indicating that competition of specific replication factor(s) for functional plasmid origins may occur. In vitro replication of plasmid pMV158 and its serivatives required the host RNA polymerase and de novo protein synthesis. The final products of the streptococcal plasmid DNAs replicated in the E. coli in vitro system were monomeric supercoiled DNA forms that had completed at least one round of replication, although a set of putative replicative intermediates could also be found. The results suggest that a specific plasmid-encoded factor is needed for the replication of the streptococcal plasmids.     

Construction of a Chimeric Plasmid in Bacillus subtilis

Staphylococcal plasmids pTP4 (2.7 megadaltons encoding resistance to chloramphenicol) and pTP5 (2.6 megadaltons encoding resistance to tetracycline), which replicate and express resistance in B. subtilis, were found to cut by HindIII endonuclease respectively at a single site and three sites. A chimeric plasmid pTA1245 (4.1 megadaltons) was constructed from pTP4 and pTP5 by HindIII digestion and ligation with E. coli DNA ligase. pTA1245 expresses resistances to chloramphenicol and tetracycline in B. subtilis, and pTA1245 is amplified in the presence of tetracycline. A physical map of pTA1245 was constructed.