Effect of ciprofloxacin exposure on DNA repair mechanisms in Campylobacter jejuni.

Ciprofloxacin resistance is common both among animal and human Campylobacter jejuni isolates. Resistant isolates are shown to persist even without selection pressure. To obtain further insight on effects of ciprofloxacin exposure on C. jejuni we compared transcriptional responses of both C. jejuni wild-type strain 81-176 (ciprofloxacin MIC 0.125 mg l(-1)) and its intermediate ciprofloxacin-resistant variant P3 (Asp90→Asn in GyrA) in the absence and presence of ciprofloxacin. Further, we sequenced the genome of P3 and compared the sequence with that of wild-type 81-176. One hour of exposure to 8 mg l(-1) of ciprofloxacin did not decrease the viability of the parent strain 81-176. Transcriptional analysis revealed that ciprofloxacin exposure caused changes in the expression of genes involved in DNA replication and repair. While in the wild-type the exposure caused downregulation of several genes involved in the control of DNA replication and recombination, the genes controlling nucleotide excision repair and DNA modification were upregulated in both the wild-type and P3. In addition, we observed that ciprofloxacin exposure caused upregulation of genes responsible for damage recognition in base excision repair in P3. In contrast, without ciprofloxacin exposure, DNA repair mechanisms were substantially downregulated in P3. The genome sequence of P3 compared to that of the 81-176 parental strain had three non-synonymous substitutions and a deletion, revealing that the resistant variant had maintained genetic integrity. In conclusion, enhanced DNA repair mechanisms under ciprofloxacin exposure might explain maintenance of genomic integrity in ciprofloxacin-resistant variant P3.

Role of YadA, Ail, and Lipopolysaccharide in Serum Resistance of Yersinia enterocolitica Serotype O:3.

Complement attack is a host strategy leading to elimination of pathogens. Yersinia enterocolitica expresses several potential complement resistance factors: the outer membrane proteins YadA and Ail as well as lipopolysaccharide (LPS). To study the contribution of these factors to the survival of Y. enterocolitica serotype O:3 in nonimmune human serum, we constructed 23 mutant strains of Y. enterocolitica O:3 expressing different combinations of YadA, Ail, LPS O antigen, and LPS outer core. Survival of bacteria was analyzed in normal serum (with functional classical, lectin, and alternative complement activation pathways) and EGTA-Mg-treated serum (only alternative pathway functional). Kinetic killing tests revealed that the most potent single-serum resistance factor needed for long-term survival was YadA; Ail was also indispensable, but it provided short-term survival and delayed the bacterial killing. On the contrary, the LPS O antigen and outer core, when in combination with YadA, Ail, or both, had a minor and often negative effect on serum resistance. Bacteria in the exponential phase of growth were more resistant to serum killing than stationary-phase bacteria. After exposing bacteria to EGTA-Mg-treated serum, O antigen could prevent deposition of covalently bound C3b on bacteria at 3 min of incubation, even as a single factor. At later time points (15 and 30 min) it had to be accompanied by YadA, Ail, and outer core. In normal serum, the bacteria were less resistant to C3b deposition. However, no direct correlation between the C3 deposition pattern and bacterial resistance was observed.

Functional characterization of Gne (UDP-N-acetylglucosamine-4-epimerase), Wzz (chain length determinant), and Wzy (O-antigen polymerase) of Yersinia enterocolitica serotype O:8.

The lipopolysaccharide (LPS) O-antigen of Yersinia enterocolitica serotype O:8 is formed by branched pentasaccharide repeat units that contain N-acetylgalactosamine (GalNAc), L-fucose (Fuc), D-galactose (Gal), D-mannose (Man), and 6-deoxy-D-gulose (6d-Gul). Its biosynthesis requires at least enzymes for the synthesis of each nucleoside diphosphate-activated sugar precursor; five glycosyltransferases, one for each sugar residue; a flippase (Wzx); and an O-antigen polymerase (Wzy). As this LPS shows a characteristic preferred O-antigen chain length, the presence of a chain length determinant protein (Wzz) is also expected. By targeted mutagenesis, we identify within the O-antigen gene cluster the genes encoding Wzy and Wzz. We also present genetic and biochemical evidence showing that the gene previously called galE encodes a UDP-N-acetylglucosamine-4-epimerase (EC 5.1.3.7) required for the biosynthesis of the first sugar of the O-unit. Accordingly, the gene was renamed gne. Gne also has some UDP-glucose-4-epimerase (EC 5.1.3.2) activity, as it restores the core production of an Escherichia coli K-12 galE mutant. The three-dimensional structure of Gne was modeled based on the crystal structure of E. coli GalE. Detailed structural comparison of the active sites of Gne and GalE revealed that additional space is required to accommodate the N-acetyl group in Gne and that this space is occupied by two Tyr residues in GalE whereas the corresponding residues present in Gne are Leu136 and Cys297. The Gne Leu136Tyr and Cys297Tyr variants completely lost the UDP-N-acetylglucosamine-4-epimerase activity while retaining the ability to complement the LPS phenotype of the E. coli galE mutant. Finally, we report that Yersinia Wzx has relaxed specificity for the translocated oligosaccharide, contrary to Wzy, which is strictly specific for the O-unit to be polymerized.