Rotavirus group A genotype circulation patterns across Kenya before and after nationwide vaccine introduction, 2010–2018

Mike J. Mwanga; Betty E. Owor; John B. Ochieng; Mwanajuma H. Ngama; Billy Ogwel; Clayton Onyango; Jane Juma; Regina Njeru; Elijah Gicheru; Grieven P. Otieno; Sammy Khagayi; Charles N. Agoti; Godfrey M. Bigogo; Richard Omore; O. Yaw Addo; Seheri Mapaseka; Jacqueline E. Tate; Umesh D. Parashar; Elizabeth Hunsperger; Jennifer R. Verani; Robert F. Breiman; D. James Nokes

doi:10.1186/s12879-020-05230-0

BMC Infectious Diseases (Jul 2020)

Rotavirus group A genotype circulation patterns across Kenya before and after nationwide vaccine introduction, 2010–2018

Mike J. Mwanga,
Betty E. Owor,
John B. Ochieng,
Mwanajuma H. Ngama,
Billy Ogwel,
Clayton Onyango,
Jane Juma,
Regina Njeru,
Elijah Gicheru,
Grieven P. Otieno,
Sammy Khagayi,
Charles N. Agoti,
Godfrey M. Bigogo,
Richard Omore,
O. Yaw Addo,
Seheri Mapaseka,
Jacqueline E. Tate,
Umesh D. Parashar,
Elizabeth Hunsperger,
Jennifer R. Verani,
Robert F. Breiman,
D. James Nokes

Affiliations

Mike J. Mwanga: Wellcome Trust Research Programme, Kenya Medical Research Institute
Betty E. Owor: Wellcome Trust Research Programme, Kenya Medical Research Institute
John B. Ochieng: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
Mwanajuma H. Ngama: Wellcome Trust Research Programme, Kenya Medical Research Institute
Billy Ogwel: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
Clayton Onyango: Division of Global Health Protection, US Centers for Disease Control and Prevention
Jane Juma: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
Regina Njeru: Wellcome Trust Research Programme, Kenya Medical Research Institute
Elijah Gicheru: Wellcome Trust Research Programme, Kenya Medical Research Institute
Grieven P. Otieno: Wellcome Trust Research Programme, Kenya Medical Research Institute
Sammy Khagayi: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
Charles N. Agoti: Wellcome Trust Research Programme, Kenya Medical Research Institute
Godfrey M. Bigogo: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
Richard Omore: Kenya Medical Research Institute, Center for Global Health Research (KEMRI-CGHR)
O. Yaw Addo: Global Health Institute, Emory University
Seheri Mapaseka: Department of Virology, South African Medical Research Council/Diarrheal Pathogens Research Unit, Sefako Makgatho Health Sciences University
Jacqueline E. Tate: Division of Viral Diseases, US Centers for Disease Control and Prevention
Umesh D. Parashar: Division of Viral Diseases, US Centers for Disease Control and Prevention
Elizabeth Hunsperger: Division of Global Health Protection, US Centers for Disease Control and Prevention
Jennifer R. Verani: Division of Global Health Protection, US Centers for Disease Control and Prevention
Robert F. Breiman: Global Health Institute, Emory University
D. James Nokes: Wellcome Trust Research Programme, Kenya Medical Research Institute

DOI: https://doi.org/10.1186/s12879-020-05230-0
Journal volume & issue: Vol. 20, no. 1
pp. 1 – 12

Abstract

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Abstract Background Kenya introduced the monovalent G1P [8] Rotarix® vaccine into the infant immunization schedule in July 2014. We examined trends in rotavirus group A (RVA) genotype distribution pre- (January 2010–June 2014) and post- (July 2014–December 2018) RVA vaccine introduction. Methods Stool samples were collected from children aged < 13 years from four surveillance sites across Kenya: Kilifi County Hospital, Tabitha Clinic Nairobi, Lwak Mission Hospital, and Siaya County Referral Hospital (children aged < 5 years only). Samples were screened for RVA using enzyme linked immunosorbent assay (ELISA) and VP7 and VP4 genes sequenced to infer genotypes. Results We genotyped 614 samples in pre-vaccine and 261 in post-vaccine introduction periods. During the pre-vaccine introduction period, the most frequent RVA genotypes were G1P [8] (45.8%), G8P [4] (15.8%), G9P [8] (13.2%), G2P [4] (7.0%) and G3P [6] (3.1%). In the post-vaccine introduction period, the most frequent genotypes were G1P [8] (52.1%), G2P [4] (20.7%) and G3P [8] (16.1%). Predominant genotypes varied by year and site in both pre and post-vaccine periods. Temporal genotype patterns showed an increase in prevalence of vaccine heterotypic genotypes, such as the commonly DS-1-like G2P [4] (7.0 to 20.7%, P < .001) and G3P [8] (1.3 to 16.1%, P < .001) genotypes in the post-vaccine introduction period. Additionally, we observed a decline in prevalence of genotypes G8P [4] (15.8 to 0.4%, P < .001) and G9P [8] (13.2 to 5.4%, P < .001) in the post-vaccine introduction period. Phylogenetic analysis of genotype G1P [8], revealed circulation of strains of lineages G1-I, G1-II and P [8]-1, P [8]-III and P [8]-IV. Considerable genetic diversity was observed between the pre and post-vaccine strains, evidenced by distinct clusters. Conclusion Genotype prevalence varied from before to after vaccine introduction. Such observations emphasize the need for long-term surveillance to monitor vaccine impact. These changes may represent natural secular variation or possible immuno-epidemiological changes arising from the introduction of the vaccine. Full genome sequencing could provide insights into post-vaccine evolutionary pressures and antigenic diversity.

Published in BMC Infectious Diseases

ISSN: 1471-2334 (Online)
Publisher: BMC
Country of publisher: United Kingdom
LCC subjects: Medicine: Internal medicine: Infectious and parasitic diseases
Website: https://bmcinfectdis.biomedcentral.com

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