Conformational ensembles in Klebsiella pneumoniae FimH impact uropathogenesis.
Edward D B LopattoJerome S PinknerDenise A SanickRobert F PotterLily X LiuJesús Bazán VillicañaKevin O TamadonfarYijun YeMaxwell I ZimmermanNathaniel C GualbertoKaren W DodsonJames W JanetkaDavid A HunstadScott J HultgrenPublished in: Proceedings of the National Academy of Sciences of the United States of America (2024)
Klebsiella pneumoniae is an important pathogen causing difficult-to-treat urinary tract infections (UTIs). Over 1.5 million women per year suffer from recurrent UTI, reducing quality of life and causing substantial morbidity and mortality, especially in the hospital setting. Uropathogenic E. coli (UPEC) is the most prevalent cause of UTI. Like UPEC, K. pneumoniae relies on type 1 pili, tipped with the mannose-binding adhesin FimH, to cause cystitis. However, K. pneumoniae FimH is a poor binder of mannose, despite a mannose-binding pocket identical to UPEC FimH. FimH is composed of two domains that are in an equilibrium between tense (low-affinity) and relaxed (high-affinity) conformations. Substantial interdomain interactions in the tense conformation yield a low-affinity, deformed mannose-binding pocket, while domain-domain interactions are broken in the relaxed state, resulting in a high-affinity binding pocket. Using crystallography, we identified the structural basis by which domain-domain interactions direct the conformational equilibrium of K. pneumoniae FimH, which is strongly shifted toward the low-affinity tense state. Removal of the pilin domain restores mannose binding to the lectin domain, thus showing that poor mannose binding by K. pneumoniae FimH is not an inherent feature of the mannose-binding pocket. Phylogenetic analyses of K. pneumoniae genomes found that FimH sequences are highly conserved. However, we surveyed a collection of K. pneumoniae isolates from patients with long-term indwelling catheters and identified isolates that possessed relaxed higher-binding FimH variants, which increased K. pneumoniae fitness in bladder infection models, suggesting that long-term residence within the urinary tract may select for higher-binding FimH variants.
Keyphrases
- klebsiella pneumoniae
- escherichia coli
- urinary tract infection
- dna binding
- multidrug resistant
- binding protein
- molecular dynamics
- molecular dynamics simulations
- healthcare
- respiratory tract
- physical activity
- transcription factor
- type diabetes
- spinal cord injury
- copy number
- body composition
- pregnant women
- structural basis
- gene expression
- machine learning
- metabolic syndrome
- deep learning
- insulin resistance
- polycystic ovary syndrome
- aqueous solution
- candida albicans
- neural network
- acute care