Kazuyo Yuri

THE PRESENCE OF THE VIRULENCE ISLAND CONTAINING THE USP GENE IN UROPATHOGENIC ESCHERICHIA COLI IS ASSOCIATED WITH URINARY TRACT INFECTION IN AN EXPERIMENTAL MOUSE MODEL

PURPOSE A putative virulence island commonly noted in the genome of uropathogenic Escherichia coli strains has recently been reported. We have observed that the island includes a gene consisting of a protein designated uropathogenic specific protein (usp) and 3 small open reading frames (orfU1-3). In our current study we assessed the importance of the genes located in the putative virulence island in the pathogenesis of urinary tract infection using a mouse pyelonephritis model. MATERIALS AND METHODS A total of 427 E. coli strains isolated from the urine of 194, 76 and 107 subjects suffering from cystitis, pyelonephritis and prostatitis, respectively, and 50 isolates from the feces of healthy individuals were examined for genotypes and serotypes. In addition, several recombinant E. coli strains possessing usp and/or orfU1 to 3 were constructed for evaluating the significance of these genes using an experimental pyelonephritis mouse model. RESULTS The usp was significantly more often associated with uropathogenic E. coli strains (79.4% from cystitis, 93.4% from pyelonephritis and 88.8% from prostatitis) than with fecal E. coli strains from healthy individuals (24%). Furthermore, usp was frequently associated with all common serotypes of uropathogenic E. coli (71.7% to 100%). In challenge experiments using the mouse urinary tract infection model the vector possessing usp significantly enhanced the infectibility of the E. coli host cell, whereas the 3 small proteins at the downstream of usp failed to show the effect. CONCLUSION Our results indicate that usp may contribute to the causation of urinary tract infection and may be considered a major virulence determinant of uropathogenic E. coli.

Distribution of the usp gene in uropathogenic Escherichia coli isolated from companion animals and correlation with serotypes and size-variations of the pathogenicity island.

Uncomplicated urinary tract infection (UTI) caused by uropathogenic Escherichia coli (UPEC) is a serious problem not only among humans but also in companion animals such as dogs and cats. The uropathogenic specific protein gene (usp) is preferentially distributed in UPEC isolates from dogs and cats compared with the distribution of usp in E. coli strains from feces of healthy dogs and cats and this pattern of distribution resembles that observed in human UPEC strains. The UPEC strains from companion animals share common O serotypes like O1, O2, O4, O6, O16, O18, O22, O25 and O75 as those reported for human UPEC. The size variation of the pathogenicity island that includes usp in UPEC from dogs and cats was almost similar to those seen in human UPEC. We propose that dogs and cats are the alternative reservoirs for UPEC strains that are associated with human UTI.

Assessment of the Significance of Virulence Factors of Uropathogenic Escherichia coli in Experimental Urinary Tract Infection in Mice

Four Escherichia coli strains, isolated from cystitis patients, belonging to serotype O2:H− and possessing different combinations of urovirulence factors were examined in an experimental pyelonephritis mouse model to assess the relative importance of virulence factors in causation of urinary tract infections (UTI). The results suggest not only that the each virulence factor has a role in causation of UTI but also that the presence of P fimbriae and production of hemolysin significantly reduced the LD50 and ID50 of the strains in the mouse model. The results also demonstrate that the presence of additional virulence factors acts in an additive or synergetic fashion enhancing the cumulative impact of the strain.

Differentiation of vaccine virus from field isolates of feline panleukopenia virus by polymerase chain reaction and restriction fragment length polymorphism analysis

In an attempt to distinguish feline panleukopenia virus (FPLV) live vaccine strains from FPLV field isolates in Japan, we compared restriction fragment length polymorphisms (RFLP) of polymerase chain reaction (PCR)-amplified fragments of live FPLV vaccine strains with those of FPLV Japanese field isolates. On the basis of nucleotide sequence differences between PLI-IV, a live vaccine strain, and FPV-483, a recent field isolate, two restriction enzymes, Dra I and Afa I, were selected for PCR-RFLP analysis of nucleotide (nt) differences at nt 3695 and 4508, respectively. Three live vaccine strains including the PLI-IV strain could be distinguished from the Japanese field isolates by their PCR-RFLP patterns by Afa I, but one live vaccine strain was indistinguishable from the Japanese isolates when Dra I and Afa I were used. The Japanese field isolates were divided into two groups by the profile of PCR-RFLP patterns generated by Dra I and Afa I, suggesting that PCR-RFLP analysis using several enzymes provides a good genetic estimate of strain differentiation. No isolate that shows a Dra I-negative/Afa I-negative pattern has emerged in Japan, indicating the possibility that the live vaccine viruses with a Dra I-negative/Afa I-negative pattern, such as the PLI-Iv strain, are candidates for use as live FPLV vaccine strain in Japan where they can be genetically distinguished from field strains.