Pathogenesis of Gram-Negative Bacteremia: Shared and Unique Virulence Mechanisms Across Key Species
This review dissects the three-phase pathogenesis of Gram-negative bacteremia (colonization, dissemination, bloodstream survival) across E. coli, K. pneumoniae, P. aeruginosa, and A. baumannii. Capsule production, adhesins, and metabolic flexibility emerge as common virulence mediators, while toxin utilization varies by species. Understanding these mechanisms informs diagnostic target selection for molecular panels and helps explain differential blood culture recovery rates among Gram-negative pathogens.
The original study
Pathogenesis of Gram-Negative Bacteremia.
- Authors
- Holmes CL, Anderson MT, Mobley HLT, Bachman MA
- Journal
- Clinical microbiology reviews
- Type
- Journal Article, Research Support, N.I.H., Extramural, Review
- PMID
- 33692149
Original abstract
Gram-negative bacteremia is a devastating public health threat, with high mortality in vulnerable populations and significant costs to the global economy. Concerningly, rates of both Gram-negative bacteremia and antimicrobial resistance in the causative species are increasing. Gram-negative bacteremia develops in three phases. First, bacteria invade or colonize initial sites of infection. Second, bacteria overcome host barriers, such as immune responses, and disseminate from initial body sites to the bloodstream. Third, bacteria adapt to survive in the blood and blood-filtering organs. To develop new therapies, it is critical to define species-specific and multispecies fitness factors required for bacteremia in model systems that are relevant to human infection. A small subset of species is responsible for the majority of Gram-negative bacteremia cases, including Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa, and Acinetobacter baumannii The few bacteremia fitness factors identified in these prominent Gram-negative species demonstrate shared and unique pathogenic mechanisms at each phase of bacteremia progression. Capsule production, adhesins, and metabolic flexibility are common mediators, whereas only some species utilize toxins. This review provides an overview of Gram-negative bacteremia, compares animal models for bacteremia, and discusses prevalent Gram-negative bacteremia species.