Bacterial “Virulence” Traits and Host Demographics Predict Escherichia coli Colonization Behaviors Within Households

Background Although intestinal colonization precedes most extraintestinal Escherichia coli infections, colonization-promoting factors are incompletely understood. We compared within-household E. coli colonization patterns with host and bacterial traits. Methods Twenty-two veterans with a clinical E. coli isolate and their 46 human and animal household members underwent longitudinal fecal sampling. Distinct E. coli strains were characterized for phylogenetic background, virulence genes, antibiotic resistance, and colonization behaviors. Host and bacterial traits were assessed statistically as predictors of colonization behaviors. Results Among the 139 unique-by-household fecal E. coli strains, univariable predictors of colonization behavior included (i) host demographics, (ii) matching the index clinical isolate, and (iii) bacterial characteristics (2 phylogroups, 5 clonal lineages, 18 virulence genes, and molecular extraintestinal pathogenic E. coli status). Multivariable predictors of colonization behavior included veteran host, spouse host, matching the index clinical isolate, phylogroup F, ST73, hlyD (alpha hemolysin), hlyF (variant hemolysin), H7 fliC (flagellar variant), vat (vacuolating toxin), and iha (adhesin-siderophore). Conclusions Host demographics, multiple bacterial “virulence” traits, and matching the index clinical isolate predicted E. coli fecal colonization behaviors. Thus, certain bacterial characteristics may promote both colonization and pathogenicity. Future interventions directed toward such traits might prevent E. coli infections both directly and by disrupting antecedent colonization.

2609. Escherichia coli Clonal Lineages and Virulence Factors Predict Fecal Colonization within Households

Background Extraintestinal Escherichia coli infections are an ever-growing threat, to which specific clonal lineages and virulence factors contribute disproportionately. Despite the gut being the main reservoir for such E. coli strains, relationships between clonal lineages, virulence factors, and fecal colonization patterns are poorly understood. Accordingly, we defined E. coli fecal colonization patterns within households (HHs) and assessed specific lineages and virulence genes (VGs) as predictors of colonization behaviors. Methods Veterans with an E. coli clinical isolate (n = 22: 11 fluoroquinoline [FQ]-resistant, 11 FQ-susceptible) and their HH members provided stool samples on 2–6 occasions each. Stools were screened for total and FQ-resistant E. coli. Distinct E. coli strains were resolved by genomic profiling of 10 colonies/sample. Strains underwent molecular lineage identification, VG detection, and comparison with the veteran’s clinical isolate. Clonal lineages and VGs were assessed (Wilcoxon rank-sum test) as predictors of strains’ (i) predominance within the fecal sample, (ii) persistence across serial fecal samples, (iii) within-HH strain sharing, and (iv) overall within-HH colonization prevalence. Results From the 22 veterans and 46 HH members (27 humans, 19 pets) we recovered 139 unique-by-household fecal E. coli strains. Sixty-four traits were evaluated (16 clonal lineages, 48 VGs). Of these, 44 exhibited n ≥ 5, so could be analyzed statistically. Among these 44 traits, the proportion significantly associated with ≥ 1 outcome variable was 5/6 (83%) for clonal lineages and 18/38 (47%) for VGs. Additionally, fecal strains that matched the veteran’s clinical isolate exhibited significantly greater sharing, persistence, and overall colonization. Conclusion The studied E. coli traits – known for their associations with clinical infections –here were significantly associated with within-HH colonization behavior. These findings support that “virulence factors” may be regarded also (or perhaps best) as “colonization factors,” and “virulent lineages” as “colonizing lineages.” This suggests the possibility that future interventions that disrupt colonization behavior also could prevent E. coli infections. Disclosures All authors: No reported disclosures.

Iron effects on colonization behavior, motility, and enzymatic activity of marine bacteria

Iron availability in the ocean has been shown to affect the growth and production of phytoplankton and free-living bacteria. A large fraction of marine bacteria are specialized in colonizing and living on particles and aggregates, but the effects of iron limitation on these bacteria are not fully known. We conducted laboratory experiments to study the effects of iron availability on particle colonization behavior, motility, and enzymatic activities of 4 strains of marine bacteria. Iron depletion reduced the bacterial particle colonization rate by 1.7%–43.1%, which could be attributed to reduced swimming speeds in 2 of the 4 strains. Protease activity was not affected by iron availability. However, attached bacteria did show higher protease activities than their free counterparts. Our results suggest that iron limitation in the ocean could in some cases reduce bacteria–particle interactions by reducing bacterial motility and colonization rate.