Genomic epidemiology and antibiotic susceptibility profiling of uropathogenic Escherichia coli among children in the United States.

Escherichia coli is the most common cause of urinary tract infections (UTIs) in children, and yet the underlying mechanisms of virulence and antibiotic resistance and the overall population structure of the species is poorly understood within this age group. To investigate whether uropathogenic E. coli (UPEC) from children who developed pyelonephritis carried specific genetic markers, we generated whole-genome sequence data for 96 isolates from children with UTIs. This included 57 isolates from children with either radiologically confirmed pyelonephritis or cystitis and 27 isolates belonging to the well-known multidrug-resistant sequence type ST131, selected to investigate their population structure and antibiotic resistance characteristics. We observed a UPEC population structure that is similar to those reported in adults. In comparison with prior investigations, we found that the full pap operon was more common among UPEC from pediatric cases of pyelonephritis. Further, in contrast with recent reports that the P-fimbriae adhesin-encoding papGII allele is substantially more prevalent in invasive UPEC from adults, we found papGII was common to both invasive and non-invasive UPEC from children. Among the set of ST131 isolates from children with UTIs, we found antibiotic resistance was correlated with known genetic markers of resistance, as in adults. Unexpectedly, we observed that fimH30, an allele of the fimbrial gene fimH often used as a proxy to type ST131 isolates into the most drug-resistant subclade C, was carried by some of the subclade A and subclade B isolates, suggesting that the fimH30 allele could confer a selective advantage for UPEC. IMPORTANCE Urinary tract infections (UTIs), which are most often caused by Escherichia coli, are not well studied in children. Here, we examine genetic characteristics that differentiate UTI-causing bacteria in children that either remain localized to the bladder or are involved in more serious kidney infections. We also examine patterns of antibiotic resistance among strains from children that are part of E. coli sequence type 131, a group of bacteria that commonly cause UTIs and are known to have high levels of drug resistance. This work provides new insight into the virulence and antibiotic resistance characteristics of the bacteria that cause UTIs in children.

Role of class II P fimbriae and cytokine response in the pathogenesis of Escherichia coli kidney infection in diabetic mice.

BACKGROUND: The role of class II P fimbriae (P fimbriae II) in diabetic kidney infections is uncertain, although some genetic and epidemiological studies suggest a lower prevalence of P fimbriae II genes in Escherichia coli strains isolated from diabetic patients with complicated kidney infections. METHODS: We inoculated a P fimbriae II deficient E. coli (DH5αT) or an isogenic P fimbriae II expressing transformant (DH5αTP) into the bladders of diabetic and non-diabetic BALB/C mice, and sacrificed them after 3 days. The incidence of bladder or kidney infection (≥103 CFU of E. coli per bladder or kidney), bacteremia (≥102 CFU of E. coli on blood culture plate), kidney pathological score, immunoreactive Histo-score (H-score), and corrected H-score (H-score adjusted for Log10 CFU of bacteria in the kidney) were compared among groups. RESULTS: Diabetic mice were more susceptible to bladder infection than non-diabetic mice with both transformants. The geometric mean of bacteria counts in kidneys was significantly increased only when the diabetic mice were infected with DH5αTP. Among the 4 groups of mice, diabetic mice infected with DH5αTP had the highest incidence of kidney infection and bacteremia, and the highest renal pathology scores. The IL-8 H-score and the corrected IL-6 and IL-8 H-score were significantly lower in diabetic than non-diabetic mice. CONCLUSION: We concluded that P fimbriae II contribute to the pathogenesis and severity of E. coli kidney infections in diabetic mice. An impaired cytokine response may also contribute to the increased incidence and severity of kidney infections in diabetic hosts.