J. Hubáček

Transfer of liposome-encapsulated plasmid DNA toBacillus subtilis protoplasts and calcium-treatedEscherichia coli cells

Protoplasts ofBacillus subtilis 168trpC2 str and cells ofEscherichia coli SK1590 after treatment with calcium chloride were transformed to tetracycline resistance with the recombinant plasmid pUN82 entrapped in the reverse phase evaporation hposomes. Frequency of transfer was 4×10-4 % inB. subtilis and 8×10-6 % inE. coli.

Curing effect of clorobiocin on Escherichia coli plasmids

SummaryClorobiocin, an inhibitor of the gyrB subunit of DNA gyrase, was used for the curing of some Escherichia coli plasmids. Of the plasmids studied, ampicillin resistant R28K and a miniplasmid derived from R1 drd-19 were effectively eliminated. We also succeeded in eliminating the ColA factor from E. coli strain B834 (pBS103), which was resistant to the effect of currently used curing agents. Although a derivative of ColE1-pBR322 was effectively cured by clorobiocin, the ColE1-plasmid was resistant to its effect. The ColV plasmid determining virulence was effectively eliminated.

Stability of the hybrid plasmid pIM138 and its curing by some eliminating agents.

Hybrid plasmid pIM138 was constructed by insertion of a chromosomal fragment with the threonme operon fromEscherichia coli into the pBR322 vector. Molar mass of pIM138 was 2.8 Mg/mol. Heteroduplexes between pBR322 vector and pIM138 hybrid DNA molecules were prepared. The hybrid plasmid shows a high stability against the curing effect of rifampicin and clorobiocm inE. coli SK1590thr host.

Mutation in the specificity polypeptide of the type I restriction endonuclease R · EcoK that affects subunit assembly

We describe the isolation and characterization of a temperature-sensitive mutation within the hsdS gene of the type I restriction and modification system EcoK. This mutation appears to affect the ability of the HsdR subunit to interact with the HsdS subunit when forming an active endonuclease. We discuss the possibility that this mutant, together with another mutation described previously, may define a discontinuous domain, involved in protein-protein interactions, within the HsdS polypeptide.

Functional analysis of second-step host specificity mutations in unstable Escherichia coli heterozygotes.

SUMMARY: From an Escherichia coli strain ki2 carrying a temperature-sensitive hostspecific modification (hsm) mutation, second-step mutants have been isolated that are completely deficient in modification and restriction. Complementation analysis has revealed that one group of these mutants is impaired in the specificity gene hss, while in the other group of mutant strains both mutations, i.e. the first-step temperature-sensitive and the second-step which impairs restriction and modification completely, are located in hsm. Analysis of the heterozygotes used in the complementation experiments suggested a cis- and tandem arrangement of the hs and leu genes in haploid, segregating exconjugants; however, the attachment of these genes to a cryptic plasmid was not excluded.

A mutation that converts serine340 of the HsdSK polypeptide to phenylalanine and its effects on restriction and modification in Escherichia coli K-12

A hybrid hsdS gene, encoding the HsdSts + d polypeptide, was constructed by joining the proximal region of the wild-type (wt) hsdS sequence with the distal region of the hsdSts + d sequence, at the hsdS BglII site. The hybrid hsdS-Sts + d gene exerts a trans-dominant effect on restriction and modification, which points to the location of the temperature-sensitive (ts) trans-dominant (+ d) mutation in the gene hsdSts + d distal region. Sequencing of the region downstream from the HindIII target in the Escherichia coli K-12 hsdSts + d mutant was carried out. It is identical to the wt hsdS sequence (GenBank/EMBL accession number ECHSDK LV00288), except for a single base-pair transition C1245----T. The results obtained support the idea that the trans-dominant effect of the ts mutation described earlier is related to the single base-pair transition in the nonhomologous region of the hsdSts + d sequence.

Expression of the threonine operon fromEscherichia coli inBrevibacterium flavum andCorynebacterium glutamicum

SummaryThe threonine operon fromEscherichia coli was cloned in plasmid pBR322, subcloned into the shuttle vector pCEM300 and the resulting recombinant plasmid was transferred intoBrevibacterium flavum andCorynebacterium glutamicum. The expression ofE. coli threonine genes in these coryneform bacteria was demonstrated by complementing thethrA andthrB mutations and by assaying homoserine dehydrogenase activity.

Transfer of plasmids from Escherichia coli and Pseudomonas aeruginosa to methylotrophic bacteria and their detection in the new hosts.

Several plasmids of incompatibility group P were transferred fromEscherichia coli andPseudomonas aeruginosa strains toMethylophilus methylotrophus and two other methylotrophs to test their recipient ability. The presence of plasmids in transconjugants was confirmed by electrophoretic analysis. Optimal conditions for detection of plasmid DNA in the strains tested based on alkaline lysis of cells at elevated temperature were established. Special behaviour of plasmids carrying the Mu phage in methylotrophic hosts is described.

Biological function of DNA methylation

Structural and functional properties of prokaryotic DNA methyltransferases are summarized. The different aspects of the role of DNA methylation which influences DNA-protein interaction in restriction and modification of DNA and in mismatch repair, DNA replication and gene expression are discussed.

Physical characterization of the plasmid pON5300

SummaryThe antibiotic resistance plasmid Rldrd19Km-which has spontaneously lost its kanamycin resistance marker, and its derivative pON5300, were analysed using the restriction endonucleases SalI, BamHI, HindIII and EcoRI. The fragment patterns were compared with that of the Rldrd19 and the fragments responsible for kanamycin resistance were found to be missing in Rldrd19Km− and pON5300. In these plasmids a 7 Mg/mol EcoRI fragment was observed instead of the D (6.3 Mg/mol) fragment of Rldrd19. Further a new 6 Mg/mol EcoRI restriction fragment was observed in pON5300. Using double digestions it was shown that the new fragment does not carry restriction sites for HindIII, BamHI and SalI endonucleases. The non-homology of the analysed plasmid was proved electron microscopically by heteroduplex techniques. The possibility of amplification in the regulatory region for the expression of R-determinants in pON5300 is discussed.