Long-term study of Chlamydophilosis in Slovenia.

Immune reactivity for Chlamydophila (C.) psittaci in Slovenia was monitored in parrots, canaries, finches and nine species of recently captured free-living birds (house sparrows, Eurasian goldfinches, tree sparrows, chaffinches, European greenfinches, European serines, Eurasian siskins, Eurasian linnets and Eurasian bullfinches) in the period from 1991 to 2001. In subsequent years, specific IgG antibodies were found using immunofluorescence in parrots (0.7-53.6%), canaries (0.0-3.5%), finches (0.0-5.7%) and in captured free-living birds (33.3% of Eurasian goldfinches in 1994). An experimental infection with C psittaci was performed in order to study clinical signs and pathological changes in canaries and finches. The C. psittaci strain used for experimental infection was isolated from a cockatiel (Nymphicus hollandicus). Chlamydial DNA was extracted from clinical material followed by RFLP-PCR analysis. Infection of canaries and finches was confirmed in organ smears by direct immunofluorescence and a modified Gimenez staining method. In addition, serological tests of indirect immunofluorescence and complement fixation were applied. However, in spite of positive immunological reaction there were no clinical signs three weeks after infection. The present study includes results of a serological survey of persons belonging to the most important risk groups (breeders, pet shopkeepers and veterinarians). The results of microimmunofluorescence to identify the presence of specific antibodies and correlation between appearance of infection in birds and important risk groups are presented. Out of 143 persons belonging to the high-risk group we found 10 (7%) persons who were immunologically positive. Testing of two successive samples was used to demonstrate an increase in IgG and IgA titres in human sera. However, IgM, which is indicative of acute infection, could not be detected.

Progressive loss of lambda prophage recombinogenicity in UV-irradiated Escherichia coli: the role of RecBCD enzyme.

RecBCD enzyme is involved in the radiation-induced process known as prophage inactivation. The process leads to the inability of lambda prophage to excise itself from the Escherichia coli chromosome via site-specific recombination. In this work we sought to further characterize the role of RecBCD enzyme in this process. In addition, we examined the ability of irradiated prophage to recombine with the infecting homologous phage. We used several E. coli mutants differentially altered in RecBCD's activities. The results showed that in the mutants carrying either recB2109 or recD1903, which do not exhibit significant nuclease activities, the prophage progressively loses its capacity for both site-specific and general recombination. In the recB268 null mutant, however, prophage recombinogenicity remained fully preserved. We also showed that the prophage unable to recombine retained its ability to complement the mutant infecting phage and that the recombination frequencies in phage x phage crosses were not affected by postirradiation incubation. Our results suggest that the helicase activity of RecBCD is responsible for the progressive loss of prophage recombinogenicity. This loss is most probably a consequence of the unsuccessful RecBCD-dependent recombinational repair of double-stranded breaks in the cell chromosome, during which some structures unsuitable for further recombination reactions may be produced.

Mismatch repair in xenopus egg extracts is not strand-directed by DNA methylation.

The efficiency of Xenopus laevis egg extract to repair T:G and A:C mismatched base pairs in unmethylated, hemimethylated and fullymethylated heteroduplexes was investigated. Filamentous phage M13mp18 and its derivative M13mp18/MP-1 (C changed to T inside the sequence dCC*C GGG, at the position 6248) were used for heteroduplexes construction. The three origins of mismatched base-pairs in the eukaryotic DNA are mimicked by in vitro methylation: hemimethylated DNA (me-/me+) for replication errors; unmethylated (me-/me-) and fully methylated DNA (me+/me+) for recombination heteroduplexes, and fullymethylated also for locally, spontaneously deaminated 5-methylcytosine (5meC) to T, generating the exclusively T:G mismatch. The methylations were in CpG dinucleotides, mostly characteristic ofeukaryotic cells [5, 24]. In vitro methylation was done by HpaII methylase which methylate central C of dCCGG sequence in the manner of eukaryotic methylation. The position of mismatched bases was chosen so that correction of mismatched bases in any strand would create the sequence for one of the "diagnostic" restriction endonucleases, either BstNI or MspI. Correction efficiency was about 10(8) repair events per egg equivalent. Correction in favor of C:G base pair restoration occurred regardless of the T:G or C:A mispairs, with almost equal efficiency. Repair of T:G to T:A was up to 10 times less efficient comparing to C:G, and repair of C:A to T:A was in our experimental system undetectable. No significant difference in repair efficiency of mismatched bases situated in unmethylated, hemimethylated or fullymethylated heteroduplexes indicate methylation-independent repair of mismatched bases in X. laevis oocite extracts.

Chromosome segregation and cell division defects in recBC sbcBC ruvC mutants of Escherichia coli.

The RuvC protein is important for DNA recombination and repair in Escherichia coli. The present work shows that a ruvC null mutation introduced into a recBC sbcBC background causes severe defects in chromosome segregation and cell division. Both defects were found to result from abortive recombination initiated by the RecA protein.