Population structure and antimicrobial resistance patterns of Salmonella Typhi and Paratyphi A amid a phased municipal vaccination campaign in Navi Mumbai, India
Kesia Esther da Silva,
Kashmira Date,
Nilma Hirani,
Christopher LeBoa,
Niniya Jayaprasad,
Priyanka Borhade,
Joshua Warren,
Rahul Shimpi,
Seth A. Hoffman,
Matthew Mikoleit,
Pankaj Bhatnagar,
Yanjia Cao,
Pradeep Haldar,
Pauline Harvey,
Chenhua Zhang,
Savita Daruwalla,
Dhanya Dharmapalan,
Jeetendra Gavhane,
Shrikrishna Joshi,
Rajesh Rai,
Varsha Rathod,
Keertana Shetty,
Divyalatha S. Warrier,
Shalini Yadav,
Debjit Chakraborty,
Sunil Bahl,
Arun Katkar,
Abhishek Kunwar,
Vijay Yewale,
Shanta Dutta,
Stephen P. Luby,
Jason R. Andrews
Affiliations
Kesia Esther da Silva
Division of Infectious Diseases and Geographic Medicine, Department of Medicine, Stanford University School of Medicine , Stanford, California, USA
Kashmira Date
Centers for Disease Control and Prevention , Atlanta, Georgia, USA
Nilma Hirani
Grant Government Medical College & Sir J J Hospital , Mumbai, Maharashtra, India
Christopher LeBoa
Division of Environmental Health Sciences, School of Public Health, University of California , Berkeley, California, USA
Niniya Jayaprasad
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Priyanka Borhade
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Joshua Warren
Yale School of Public Health, Yale University , New Haven, Connecticut, USA
Rahul Shimpi
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Seth A. Hoffman
Division of Infectious Diseases and Geographic Medicine, Department of Medicine, Stanford University School of Medicine , Stanford, California, USA
Matthew Mikoleit
Centers for Disease Control and Prevention , Atlanta, Georgia, USA
Pankaj Bhatnagar
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Yanjia Cao
Department of Geography, The University of Hong Kong , Hong Kong
Pradeep Haldar
Ministry of Health & Family Welfare, Government of India , New Delhi, India
Pauline Harvey
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Chenhua Zhang
Centers for Disease Control and Prevention , Atlanta, Georgia, USA
Savita Daruwalla
Department of Pediatrics, NMMC General Hospital , Navi Mumbai, India
Dhanya Dharmapalan
Dr. Yewale Multispecialty Hospital for Children , Navi Mumbai, India
Jeetendra Gavhane
Department of Pediatrics, MGM New Bombay Hospital, MGM Medical College , Navi Mumbai, India
Shrikrishna Joshi
Dr. Joshi’s Central Clinical Microbiology Laboratory , Navi Mumbai, India
Rajesh Rai
Department of Pediatrics & Neonatology, Dr. D.Y. Patil Medical College and Hospital , Navi Mumbai, India
Varsha Rathod
Rajmata Jijau Hospital, Airoli (NMMC) , Navi Mumbai, India
Keertana Shetty
Department of Microbiology, Dr. D.Y. Patil Medical College and Hospital , Navi Mumbai, India
Divyalatha S. Warrier
Department of Pediatrics, Mathadi Trust Hospital , Navi Mumbai, India
Shalini Yadav
Department of Microbiology, MGM New Bombay Hospital , Navi Mumbai, India
Debjit Chakraborty
National Institute of Cholera and Enteric Diseases, Indian Council of Medical Research , Kolkata, India
Sunil Bahl
World Health Organization South-East Asia Regional Office , New Delhi, India
Arun Katkar
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Abhishek Kunwar
World Health Organization-Country Office for India, National Public Health Surveillance Project , New Delhi, India
Vijay Yewale
Dr. Yewale Multispecialty Hospital for Children , Navi Mumbai, India
Shanta Dutta
National Institute of Cholera and Enteric Diseases, Indian Council of Medical Research , Kolkata, India
Stephen P. Luby
Division of Infectious Diseases and Geographic Medicine, Department of Medicine, Stanford University School of Medicine , Stanford, California, USA
Jason R. Andrews
Division of Infectious Diseases and Geographic Medicine, Department of Medicine, Stanford University School of Medicine , Stanford, California, USA
ABSTRACT We performed whole-genome sequencing of 174 Salmonella Typhi and 54 Salmonella Paratyphi A isolates collected through prospective surveillance in the context of a phased typhoid conjugate vaccine introduction in Navi Mumbai, India. We investigate the temporal and geographical patterns of emergence and spread of antimicrobial resistance. We evaluated the relationship between the spatial distance between households and genetic clustering of isolates. Most isolates were non-susceptible to fluoroquinolones, with nearly 20% containing ≥3 quinolone resistance-determining region mutations. Two H58 isolates carried an IncX3 plasmid containing blaSHV-12, associated with ceftriaxone resistance, suggesting that the ceftriaxone-resistant isolates from India independently evolved on multiple occasions. Among S. Typhi, we identified two main clades circulating (2.2 and 4.3.1 [H58]); 2.2 isolates were closely related following a single introduction around 2007, whereas H58 isolates had been introduced multiple times to the city. Increasing geographic distance between isolates was strongly associated with genetic clustering (odds ratio [OR] = 0.72 per km; 95% credible interval [CrI]: 0.66–0.79). This effect was seen for distances up to 5 km (OR = 0.65 per km; 95% CrI: 0.59–0.73) but not seen for distances beyond 5 km (OR = 1.02 per km; 95% CrI: 0.83–1.26). There was a non-significant reduction in odds of clustering for pairs of isolates in vaccination communities compared with non-vaccination communities or mixed pairs compared with non-vaccination communities. Our findings indicate that S. Typhi was repeatedly introduced into Navi Mumbai and then spread locally, with strong evidence of spatial genetic clustering. In addition to vaccination, local interventions to improve water and sanitation will be critical to interrupt transmission. IMPORTANCE Enteric fever remains a major public health concern in many low- and middle-income countries, as antimicrobial resistance (AMR) continues to emerge. Geographical patterns of typhoidal Salmonella spread, critical to monitoring AMR and planning interventions, are poorly understood. We performed whole-genome sequencing of S. Typhi and S. Paratyphi A isolates collected in Navi Mumbai, India before and after a typhoid conjugate vaccine introduction. From timed phylogenies, we found two dominant circulating lineages of S. Typhi in Navi Mumbai-lineage 2.2, which expanded following a single introduction a decade prior, and 4.3.1 (H58), which had been introduced repeatedly from other parts of India, frequently containing “triple mutations” conferring high-level ciprofloxacin resistance. Using Bayesian hierarchical statistical models, we found that spatial distance between cases was strongly associated with genetic clustering at a fine scale (<5 km). Together, these findings suggest that antimicrobial-resistant S. Typhi frequently flows between cities and then spreads highly locally, which may inform surveillance and prevention strategies.
