Using Genomic and Traditional Epidemiologic Approaches to Define Complex Transmission Pathways of Klebsiella pneumoniae Infection in a Neonatal Unit in Botswana, 2022–2023

  1. Jonathan Strysko
  2. Weiming Hu
  3. Kagiso Mochankana
  4. Janet John-Thubuka
  5. Tshiamo Zankere
  6. Boingotlo Gopolang
  7. Erin Theiller
  8. Steven M. Jones
  9. Chimwemwe Viola Tembo
  10. Tlhalefo Dudu Ntereke
  11. Teresia Gatonye
  12. Kwana Lechiile
  13. Tapoloso Keatholetswe
  14. Colleen Bianco
  15. Susan E Coffin
  16. Carolyn McGann
  17. Kyle Bittinger
  18. Ebbing Lautenbach
  19. Naledi Mannathoko
  20. Margaret Mokomane
  21. Mosepele Mosepele
  22. Melissa Richard-Greenblatt
  23. Britt Nakstad
  24. David M. Goldfarb
  25. Paul Planet
  26. Ahmed M. Moustafa
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Abstract

Background

Klebsiella pneumoniae ( Kpn ) is a major cause of infant mortality worldwide, with most transmission occurring among hospitalized neonates in low-and middle-income countries where infections caused by multidrug-resistant Kpn (MDR- Kpn ) are increasingly common. We hypothesized that integrating laboratory surveillance for neonatal colonization and infection, real-time epidemiologic investigations, and whole-genome sequencing (WGS) could identify transmission pathways to guide targeted infection prevention and control (IPC) strategies.

Methods and Findings

We conducted Kpn surveillance in a 36-bed neonatal unit in Botswana over 12 months (2022–2023). WGS was performed on Kpn isolates from bloodstream infections (BSIs), and MDR- Kpn isolates collected from environmental sampling during outbreaks and twice-monthly colonization screenings (skin and perirectal swabs) using culture media selective for MDR- Kpn (CHROMagar Extended-spectrum beta-lactamase [ESBL]/SuperCarba). WGS data were analyzed using multilocus sequence typing (MLST), pangenome and reference-based single-nucleotide polymorphism (SNP) analyses, and Bayesian phylogenetics.

We identified 55 Kpn BSIs during the 12-month surveillance period and the median prevalence of MDR- Kpn colonization was 28%. Kpn was recovered from multi-use intravenous (IV) fluid bags during a Kpn outbreak (41 BSIs, 10 deaths), which was controlled by implementing a 24-hour discard policy for IV medications. Among 270 Kpn isolates available (28 BSI, 232 colonizing, 10 environmental [six IV fluid, four sink drain]), WGS confirmed over half of BSI genomes (n=17) were ST1414, a clone susceptible to third-generation cephalosporins not detected during MDR- Kpn colonization screening, but closely related (<25 SNPs) to six Kpn isolates from contaminated IV fluids.

Conclusions

This study reinforces the value of integrating WGS with real-time epidemiologic investigations to understand transmission dynamics and guide IPC. Colonization surveillance focused solely on MDR- Kpn may overlook drug-susceptible but outbreak-prone strains.

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  1. Version published to 10.1101/2025.11.06.25339637 on medRxiv