Jozef Grones

Construction of shuttle vectors for cloning inEscherichia coli andAcetobacter pasteurianus

New cloning vectors were prepared with the aid of a large plasmid isolated fromAcetobacter pasteurianus and from plasmids pBR322 and pUC4-KAPA. Of the prepared cloning vectors, pACK5 contains a gene coding for kanamycin resistance, pACT7 and pACT71 contain a gene coding for tetracycline resistance and vector pACG3 with a gene coding for both kanamycin and tetracycline resistance. The vectors prepared only contained the beginning of replication from the pAC1 plasmid and possessed the ability to replicate withinE. coli andA. pasteurianus. The vectors are highly stable in both strains and during the 5-d cultivation under nonselective conditions are not eliminated.

The Rep20 replication initiator from the pAG20 plasmid of Acetobacter aceti.

In the previously isolated pAG20 plasmid from the Acetobacteraceti CCM3610 strain, the Rep20 protein was characterized as a main replication initiator. The pAG20 plasmid origin was localized in the vicinity of the rep20 gene and contained two 21-nucleotide-long iteron sequences, two 13-nucleotide-long direct repeats, and a DnaA-binding site. Electrophoretic mobility shift assay and nonradioactive fragment analysis confirmed that the Rep20 protein interacted with two direct repeats (5′-TCCAAATTTGGAT′-3′) and their requirement during plasmid replication was verified by mutagenesis. Although the association could not be validated of the DnaA protein of from the host cells of Escherichia coli with the plasmid-encoded replication initiator that usually occurs during replication initiation, Rep20 was able to form dimeric structures by which it could bind the sequence of the rep20 gene and autoregulate its own expression. Targeted mutagenesis of the Rep20 protein revealed the importance of the third α-helix and 63Lys, specifically during DNA binding. The second, closely adjacent β-sheet also took part in this process in which 52Asn played a significant role.

Molecular analysis of 16S–23S spacer regions ofAcetobacter species

Abstract16S–23S rDNA internal transcribed spacer regions (ITS) similarities were determined in 8Acetobacter and 1Gluconacetobacter strains. ITS-PCR amplification of the 16S–23S spacers showed 2 products of similar size in 7 strains; only 1 product of similar size was found in the 2 remaining strains. Analysis of the PCR products using restriction endonucleasesHaeIII,HpaII andAluI revealed 3 different restriction groups ofA. pasteurianus forAluI andHaeIII, and 4 restriction groups forHpaII. ITS nucleotide sequences of all studied strains exhibited a 52–98% similarity.

Nucleotide sequence analysis of small cryptic plasmid pGP2 from Acetobacter estunensis

Complete nucleotide sequence of plasmid pGP2 from Acetobacter estunensis GP2 was identified after initial cloning of EcoRI fragment followed by preparation of deletion derivatives. Its size was defined to 2,797 bp and several sites for several restriction enzymes were revealed by DNA sequencing. Sequence analysis predicts three putative open reading frames (ORFs). ORF1 shows significant identity with the bacterial excinuclease α-subunit, ORF2 is a putative replication protein with low similarity with other Acetobacter plasmid’s replication proteins, and ORF3 encodes a class B acid phosphatase/phosphotransferase. The replication module comprises a DnaA box like sequence, direct repeats, a potential prokaryotic promoter and a rep gene. The rep module is similar with several θ-replicating, iteron-containing modules from plasmids, suggesting pGP2 replication may follow the same course. Any phenotypic character determinant gene is absent in pGP2, suggesting this plasmid to be cryptic. However, a pGP2 derivative plasmid, containing the putative pGP2 rep region, can replicate and is stably maintained in Acetobacter and Escherichia coli strains; it can also carry foreign DNA fragments. Thus, pGP2-X could serve as a cloning shuttle vector between these bacteria. Prepared deletion derivatives of plasmid pGP2 suggested that Rep protein is essential for plasmid replication in host bacteria. In its natural host, A. estunensis GP2, pGP2 maintains a four-times lower copy number than in E. coli.

Euglena gracilis as a supplementary test organism for detecting biologically active compounds

The mutagenic activity of more than 120 antimicrobial agents and protective components was investigated. Only Kathon showed a consistent increase in revertant counts in the Ames test onSalmonella typhimurium. The hereditary bleaching test onEuglena gracilis used for detecting extranuclear mutations, showed positive results for Kathon, triethanolamine and diamine silver tetraborate.

Protective effect of ascorbic acid on bleaching activity of N-methyl-N'-nitro-N-nitrosoguanidine and furazolidone

Exposure of autotrophic cells ofEuglena gracilis to MNNG and furazolidone results in an irreversible loss of chloroplasts leading to a production of white mutants (permanent bleaching). Induction of the white mutants is significantly decreased by ascorbic acid, especially during the first stages of this mutation process.

Escherichia coli strain with a deletion of the chromosomalampC gene marked with TcR, suitable for production of penicillin G acylase

Escherichia coli strain which contains a marker of tetracycline resistance gene (TcR) placed by P1 transduction beside the chromosomal deletion, ofampC gene (ΔampC) coding for β-lactamase was constructed. Such introduction of TcR marker permits a fast and simple selection for the transfer of ΔampC by P1 transduction into industrialE. coli strains. This approach was used for constructing anE. coli strain suitable for penicillin acylase production.

Cloning, production and secretion of β-galactosidase inAcetobacter pasteurianus

The gene coding for β-galactosidase fromEscherichia coli was cloned into plasmid pACT71 containing the replicon from plasmid pAC1 fromAcetobacter pasteurianus. E. coli MC4100,E. coli JM105,E. coli LE392.23 andA. pasteurianus 3614 were transformed with the recombinant plasmid pACB815. Cells were cultivated in LB, YPG and M media supplemented with glucose, glycerol, lactose or ethanol and β-galactosidase activity was detected in the cells and in the cultivation medium. The best substrate for production of β-galactosidase was lactose. To release β-galactosidase fromA. pasteurianus cells amino acids were added to the cultivation medium. The highest secretory activity was achieved using 1.5% glycine after 36 h of cultivation in the M medium.

Isolation of a new restriction enzyme,ApaCI, an isoschizomer ofBamHI produced byAcetobacter pasteurianus

A new Type II restriction endonucleaseApaCI purified fromAcetobacter pasteurianus is an isoschizomer ofBamHI that cleaves at the nucleotide sequence 5′-G/GATCC-3′ of double-stranded DNA. The single restriction activity present in this strain permits rapidly purified 30 000 units of cleavage activity from 10 g of freshly harvested cells. The resultingApaCI preparation is free of contaminant nuclease activities that might interfere within vitro manipulation of DNA.

Protein–protein association and cellular localization of four essential gene products encoded by tellurite resistance-conferring cluster “ ter” from pathogenic Escherichia coli

Gene cluster “ter” conferring high tellurite resistance has been identified in various pathogenic bacteria including Escherichia coli O157:H7. However, the precise mechanism as well as the molecular function of the respective gene products is unclear. Here we describe protein–protein association and localization analyses of four essential Ter proteins encoded by minimal resistance-conferring fragment (terBCDE) by means of recombinant expression. By using a two-plasmid complementation system we show that the overproduced single Ter proteins are not able to mediate tellurite resistance, but all Ter members play an irreplaceable role within the cluster. We identified several types of homotypic and heterotypic protein–protein associations among the Ter proteins by in vitro and in vivo pull-down assays and determined their cellular localization by cytosol/membrane fractionation. Our results strongly suggest that Ter proteins function involves their mutual association, which probably happens at the interface of the inner plasma membrane and the cytosol.