Urinary tract infections (UTIs) are one of the most common human bacterial infections. While UTIs are commonly associated with colonization by
Escherichia coli
, members of this species also have been found within the bladder of individuals with no lower urinary tract symptoms (no LUTS), also known as asymptomatic bacteriuria. Prior studies have found that both uropathogenic
E. coli
(UPEC) strains and
E. coli
isolates that are not associated with UTIs encode for virulence factors. Thus, the reason(s) why
E. coli
sometimes causes UTI-like symptoms remain(s) elusive. In this study, the genomes of 66
E. coli
isolates from adult female bladders were sequenced. These isolates were collected from four cohorts, including women: (1) without lower urinary tract symptoms, (2) overactive bladder symptoms, (3) urgency urinary incontinence, and (4) a clinical diagnosis of UTI. Comparative genomic analyses were conducted, including core and accessory genome analyses, virulence and motility gene analyses, and antibiotic resistance prediction and testing. We found that the genomic content of these 66
E. coli
isolates does not correspond with the participant’s symptom status. We thus looked beyond
the E.
coli genomes to the composition of the entire urobiome and found that the presence of
E. coli
alone was not sufficient to distinguish between the urobiomes of individuals with UTI and those with no LUTS. Because
E. coli
presence, abundance, and genomic content appear to be weak predictors of UTI status, we hypothesize that UTI symptoms associated with detection of
E. coli
are more likely the result of urobiome composition.
Prophages play a critical role in the evolution of their host species and can also contribute to the virulence and fitness of pathogenic species. Here, we conducted a comprehensive investigation of prophage sequences from 5,383 publicly available
Pseudomonas aeruginosa
genomes from human as well as environmental isolates.
Bacteriophages (phages) are vital members of the human microbiota. They are abundant even within low biomass niches of the human body, including the lower urinary tract. While several prior studies have cultured bacteria from kidney stones, this is the first study to explore phages within the kidney stone microbiota. Here we report Dobby, a temperate phage isolated from a strain of
Pseudomonas aeruginosa
cultured from a kidney stone. Dobby is capable of lysing clinical
P. aeruginosa
strains within our collection from the urinary tract. Sequencing was performed producing a 37 152 bp genome that closely resembles the temperate
P. aeruginosa
phage φCTX, a member of the P2 phage group. Dobby does not, however, encode for the cytotoxin CTX. Dobby’s genome was queried against publicly available bacterial sequences identifying 44 other φCTX-like prophages. These prophages are integrated within the genomes of
P. aeruginosa
strains from a variety of environments, including strains isolated from urine samples and other niches of the human body. Phylogenetic analysis suggests that the temperate φCTX phage species is widespread. With the isolation of Dobby, we now have evidence that phages are members of the kidney stone microbiota. Further investigation, however, is needed to determine their abundance and diversity within these communities.
Lactobacilli are dominant members of the healthy female bladder microbiota. Here, we report the complete genome sequences of six Lactobacillus gasseri and three Lactobacillus paragasseri strains isolated from catheterized urine samples. These L. paragasseri genomes are the first publicly available sequences of the species from the bladder.
Klebsiella variicola
is an opportunistic pathogen in humans. It also has been associated with bovine mastitis, which can have significant economic effects.
Recently, we isolated a temperate bacteriophage, Pseudomonas phage Dobby, from a calcium oxalate kidney stone. Here, we present the complete genome of the bacterial host harboring this phage, Pseudomonas aeruginosa UMB2738. From the analysis of the genome sequence, five additional prophage sequences were identified.
Due to its frequent association with urinary tract infections (UTIs), Escherichia coli is the best characterized constituent of the urinary microbiota (urobiome). However, uropathogenic E. coli is just one member of the urobiome. In addition to bacterial constituents, the urobiome of both healthy and symptomatic individuals is home to a diverse population of bacterial viruses (bacteriophages). A prior investigation found that most bacterial species in the urobiome are lysogens, harboring one or more phages integrated into their genome (prophages). Many of these prophages are temperate phages, capable of entering the lytic cycle and thus lysing their bacterial host. This transition from the lysogenic to lytic life cycle can impact the bacterial diversity of the urobiome. While many phages that infect E. coli (coliphages) have been studied for decades in the laboratory setting, the coliphages within the urobiome have yet to be cataloged. Here, we investigated the diversity of urinary coliphages by first identifying prophages in all publicly available urinary E. coli genomes. We detected 3,038 intact prophage sequences, representative of 1,542 unique phages. These phages include both novel species as well as species also found within the gut microbiota. Ten temperate phages were isolated from urinary E. coli strains included in our analysis, and we assessed their ability to infect and lyse urinary E. coli strains. We also included in these host range assays other urinary coliphages and laboratory coliphages. The temperate phages and other urinary coliphages were successful in lysing urinary E. coli strains. We also observed that coliphages from non-urinary sources were most efficient in killing urinary E. coli strains. The two phages, T2 and N4, were capable of lysing 83.5% (n = 86) of strains isolated from females with UTI symptoms. In conclusion, our study finds a diverse community of coliphages in the urobiome, many of which are predicted to be temperate phages, ten of which were confirmed here. Their ability to infect and lyse urinary E. coli strains suggests that urinary coliphages may play a role in modulating the E. coli strain diversity of the urobiome.
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