Integrating measles wastewater and clinical whole-genome sequencing enables high-resolution tracking of virus evolution and transmission

  1. Sipho Gwala
  2. Joshua I. Levy
  3. Victor Mabasa
  4. Kathleen Subramoney
  5. Nkosenhle L. Ndlovu
  6. Chris Kent
  7. Maryam Ahmadi Jeshvaghane
  8. Praneeth Gangavarapu
  9. Menzi Sikakane
  10. Natasha Singh
  11. Mantshali Motloung
  12. Lethabo Monametsi
  13. Lebohang Rabotapi
  14. Emmanuel Phalane
  15. Mokgaetji Macheke
  16. Fiona Els
  17. Chenoa Sankar
  18. Tshepo Motsamai
  19. Sibonginkosi Maposa
  20. Nishi Prabdial-Sing
  21. Joshua Quick
  22. Kristian G. Andersen
  23. Kerrigan McCarthy
  24. Mukhlid Yousif
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Abstract

Measles outbreaks have surged globally in recent years, but current surveillance systems have limited capacity to monitor measles virus (MeV) transmission and evolution at population scale. Although MeV can be detected in wastewater, the public health potential of wastewater genomic surveillance for MeV remains largely unexplored. Here, we deploy sensitive, low-cost MeV wastewater genomic surveillance combining virus concentration, whole-genome amplicon sequencing, and bioinformatic analysis alongside routine clinical genomic surveillance during the 2024-25 outbreak in South Africa. Integrated phylogenetic analyses of wastewater and clinical MeV genomes revealed previously undetected interprovincial spread and transmission links not captured by standard N450 sequencing. Our findings demonstrate that wastewater-integrated whole-genome surveillance expands the coverage and resolution of routine MeV monitoring and provides a scalable tool to advance measles control and elimination efforts.

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