Hostname: page-component-7dd5485656-bvgqh Total loading time: 0 Render date: 2025-10-21T11:19:18.590Z Has data issue: false hasContentIssue false
  • English
  • Français

Rift Valley fever seroprevalence in ruminants in Dhobley town, Lower Juba region, Somalia, in 2021

Published online by Cambridge University Press:  10 October 2025

Ahmed A. Hassan-Kadle Open the ORCID record for Ahmed A. Hassan-Kadle [Opens in a new window] ,
Aamir Muse Osman Open the ORCID record for Aamir Muse Osman [Opens in a new window] ,
Abdulkarim A. Yusuf ,
Mohamed A. Shair ,
Osman A. Hassan ,
Rachel Maluleke ,
Antoinette Van Schalkwyk ,
Marco Romito ,
Alison Lubisi  and
Abdalla M. Ibrahim
...Show all authors
Ahmed A. Hassan-Kadle*
Affiliation:
Somali One Health Centre, Abrar University , Mogadishu, Somalia Abrar Research and Training Centre, Abrar University, Mogadishu, Somalia
Aamir Muse Osman
Affiliation:
Somali One Health Centre, Abrar University , Mogadishu, Somalia Graduate Program on Veterinary Sciences, Universidade Federal do Paraná , Curitiba, Brazil Department of Animal Health and Veterinary Service, Ministry of Livestock, Forestry, and Range, Mogadishu, Somalia
Abdulkarim A. Yusuf
Affiliation:
Department of Slaughterhouse, Somali Meat Company, Mogadishu, Somalia
Mohamed A. Shair
Affiliation:
Abrar Research and Training Centre, Abrar University, Mogadishu, Somalia
Osman A. Hassan
Affiliation:
Department of Animal Health and Veterinary Service, Ministry of Livestock, Forestry, and Range, Jubaland State, Somalia
Rachel Maluleke
Affiliation:
Agricultural Research Council, Onderstepoort Veterinary Research , Pretoria, South Africa
Antoinette Van Schalkwyk
Affiliation:
Agricultural Research Council, Onderstepoort Veterinary Research , Pretoria, South Africa
Marco Romito
Affiliation:
Agricultural Research Council, Onderstepoort Veterinary Research , Pretoria, South Africa
Alison Lubisi
Affiliation:
Agricultural Research Council, Onderstepoort Veterinary Research , Pretoria, South Africa
Abdalla M. Ibrahim
Affiliation:
Somali One Health Centre, Abrar University , Mogadishu, Somalia Abrar Research and Training Centre, Abrar University, Mogadishu, Somalia
Rafael F.C. Vieira
Affiliation:
Department of Epidemiology and Community Health, The University of North Carolina at Charlotte , Charlotte, NC, USA
*
Corresponding author: Ahmed A. Hassan-Kadle; Email: akadle@abrar.edu.so
Rights & Permissions [Opens in a new window]

Abstract

This study assesses the seroprevalence of Rift Valley fever (RVF) in ruminants in Dhobley, Somalia, following a 2021 outbreak in Kenya. Among 142 ruminants sampled, 4.9% were seropositive for RVF virus (RVFV) antibody, with IgM antibodies (1.4%) indicating recent exposure, though no cases were RT-PCR-positive. Unregulated livestock movement and limited surveillance pose significant risks for future outbreaks, underscoring the need for enhanced surveillance systems and One Health strategies.

Keywords

Rift Valley FeverSeroprevalenceRuminantsOne HealthEast Africa

Information

Type
Short Paper
Information
Epidemiology & Infection , Volume 153 , 2025 , e122
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press

Introduction

Rift Valley fever (RVF) is a mosquito-borne disease caused by the Rift Valley fever virus (RVFV), which belongs to the genus Phlebovirus and the family Phenuiviridae [Reference Linthicum, Britch and Anyamba1, Reference Himeidan2]. The disease is endemic to Africa and is characterized by abortions and neonatal deaths in domestic ruminants and a range of human illnesses, from flu-like symptoms to encephalitic, ocular, or haemorrhagic syndromes [Reference Linthicum, Britch and Anyamba1, Reference Himeidan2]. RVF poses a major global threat to both human and animal health. The widespread distribution of competent mosquito vectors, along with increased international travel and livestock trade, has facilitated the spread of RVFV throughout much of Africa, including Somalia and the Middle East [Reference Himeidan2, Reference Hassan-Kadle3]. This situation underscores the growing concerns about RVFV’s pandemic potential [Reference Petrova4], leading the World Health Organization (WHO) to include RVF in its Blueprint priority diseases list for research and development [Reference Wright5].

Somalia, a country that is heavily reliant on livestock and shares porous borders with Kenya and Ethiopia, where zoonotic transboundary diseases are frequently reported [Reference Clark6, Reference Asebe7], lacks systematic vaccination programmes and comprehensive surveillance for RVFV. Limited access to laboratory infrastructure and resources leads to underreporting of outbreaks, posing significant challenges to timely detection and control. Additionally, the unregulated cross-border movement of livestock between Somalia and neighbouring countries such as Kenya, which experienced an RVF outbreak in 2021 [8], increases the risk of spillover infections in both animal and human populations in Somalia. Previous serological studies documented an RVF antibody prevalence of 1% in cattle, 5% in goats, and 2% in sheep in Somalia [Reference Hassan-Kadle3]. However, the last confirmed RVF outbreak occurred in 2007 in the southern regions of Middle Juba, Lower Juba, and Gedo, bordering Kenya, where the focal point of the outbreak was identified [Reference Nderitu9].

The recent declaration of an RVF outbreak in neighbouring Kenya in 2021 underscores the urgent need for enhanced monitoring and preventative strategies. In response to the WHO’s February 2021 announcement identifying outbreaks in Kenyan districts bordering Somalia, Abrar University, in collaboration with Somalia’s Federal and State Ministry of Livestock, Forestry, and Range, conducted an investigation in Dhobley, Jubaland State, Somalia, in April 2021 to assess the circulation of RVFV in the country.

The study

A cross-sectional study was conducted in April 2021 in Dhobley Town (0°24′38″N, 41°0′35″E), Jubaland State, Somalia. Samples were collected from 18 herds using a non-probabilistic convenience sampling method. A total of 142 ruminant blood and serum samples were obtained, comprising 100 adults and 42 young animals, with 123 females and 19 males. The sampled animals included 54 goats, 54 sheep, and 34 cattle. The study area is located near the Kenyan border, where an RVF outbreak had been declared by the Kenyan government and the WHO in February 2021 [8]. The sampled animals were managed under an extensive husbandry system, with frequent cross-border grazing. No clinical signs suggestive of RVF were recorded during sampling.

Sera were tested for the presence of anti-RVFV antibodies and IgM-specific immunoglobulins using ID Screen® Rift Valley Fever Competition Multi-species and ID Screen® Rift Valley Fever IgM Capture ELISAs, respectively (Innovative Diagnostics, Grabels, France). IgM-positive samples were further tested via RT-PCR [Reference Drosten10] at Onderstepoort Veterinary Research, South Africa, to confirm recent infection. Data were compiled and analysed using Epi Info™ software, version 7.2.3.1 (Centers for Disease Control and Prevention, CDC, USA).

Of the 142 ruminants, seven (4.9%, 95% CI: 2.0–9.9) tested seropositive for RVFV, and all seropositive animals were female. Anti-RVFV IgG seroprevalence was 4.2% (6/142), while anti-RVFV IgM prevalence was 1.4% (2/142). None of the IgM-positive samples tested positive by RT-PCR. Goats exhibited the highest RVFV seroprevalence, with 4/54 (7.4%, all adults) testing positive for anti-RVFV IgG, including one goat positive for both IgG and IgM. Among cattle, 2/34 (5.9%, both young animals) tested positive for anti-RVFV IgG, and 1/34 (2.9%) for anti-RVFV IgM. All sheep samples tested negative for both anti-RVFV IgG and IgM antibodies.

Conclusion

This study reveals a concerning prevalence of RVF in ruminants from Dhobley Town, Somalia. Although no cases were confirmed by RT-PCR, which may have been caused by the short viraemic period, the detection of anti-RVFV IgM antibodies indicates recent exposure to RVFV. The close proximity of Dhobley Town to the Kenyan border, where a recent RVF outbreak was reported, raises concerns about silent RVFV circulation. Unregulated cross-border livestock movement facilitates the spread of diseases across borders, increasing the risk of spillover infections.

Although the observed seroprevalence was low, it is crucial to recognize that these findings likely represent an underestimation of the true epidemiological situation due to the acknowledged underreporting and the absence of routine RVF surveillance systems in Somalia. A key limitation of this study is the lack of recorded clinical data, including abortion history or observable signs of illness, since such information was not collected at the time of sampling. This gap restricts the ability to correlate serological findings with clinical outcomes, which would have added value to the epidemiological interpretation.

These findings raise concerns about the possible silent circulation of RVFV in the region, which could lead to future outbreaks under favourable ecological conditions. The lack of recent outbreak data, coupled with limited laboratory capacity, indicates that the true burden of the disease in Somalia remains largely unknown, hindering effective preparedness and response efforts. Therefore, this study highlights the urgent need for the establishment and strengthening of a surveillance system in Somalia. This includes enhancing diagnostic capacity at the laboratory level and implementing a coordinated One Health approach that integrates animal and human health monitoring. Such measures are essential to accurately detect, effectively prevent, and rapidly control localized RVF outbreaks, thereby reducing the significant risk of escalation into a broader epidemic with detrimental impacts on both livestock livelihoods and public health security in the region.

Data availability statement

All data generated or analysed during this study are included in this article.

Acknowledgements

We are grateful to all livestock owners and keepers who agreed to take part in this study and livestock professional association and local veterinary officials for their assistance during sampling. We would also like to thank Ministry of Livestock, Forestry, and Range, Somalia, for the donation of ELISA kits.

Author contribution

AAHK and AMO designed the study. AMO collected the data. AAHK, AMO, AAY, MAS, OAH, RM, AVS, MR, BAL, AMI, and RFCV contributed to the methodology. AAHK and AMO performed the data analysis. AAHK and AMO drafted the manuscript. All authors reviewed, edited, and approved the final manuscript.

Competing interests

The authors declare no conflicts of interest.

Ethical standard

This study was approved by the Ethical Committee of Abrar University, Somalia (reference number AUEC10321). Prior to the mission, authorizations were obtained from federal and state veterinary officials. All animal owners gave consent to sample their animals.

Funding statement

The authors are grateful to Abrar University (grant no. #AURG01032021) and Agricultural Research Council (grant no. #P10000038) for financial aid and support to carry out this research.

References

Linthicum, KJ, Britch, SC and Anyamba, A (2016) Rift Valley fever: An emerging mosquito-borne disease. Annual Review of Entomology 61, 395415. https://doi.org/10.1146/annurev-ento-010715-023819.Google Scholar
Himeidan, YE, et al (2014) Recent outbreaks of rift valley fever in East Africa and the middle east. Frontiers in Public Health 2, 169. https://doi.org/10.3389/fpubh.2014.00169.Google Scholar
Hassan-Kadle, AA, et al (2021) Rift Valley fever and Brucella spp. in ruminants, Somalia. BMC Veterinary Research 17(1), 280. https://doi.org/10.1186/s12917-021-02980-0.Google Scholar
Petrova, V, et al (2020) Rift valley fever: Diagnostic challenges and investment needs for vaccine development. BMJ Global Health 5(8), e002694. https://doi.org/10.1136/bmjgh-2020-002694.Google Scholar
Wright, D, et al (2019) Rift Valley fever: Biology and epidemiology. The Journal of General Virology 100(8), 11871199. https://doi.org/10.1099/jgv.0.001296.Google Scholar
Clark, MHA, et al (2018) Systematic literature review of Rift Valley fever virus seroprevalence in livestock, wildlife and humans in Africa from 1968 to 2016. PLoS Neglected Tropical Diseases 12(7), e0006627. https://doi.org/10.1371/journal.pntd.0006627.Google Scholar
Asebe, G, et al (2020) Seroprevalence of Rift Valley fever and West Nile fever in cattle in Gambella region, south-West Ethiopia. Veterinary Medicine 19(11), 119130. https://doi.org/10.2147/VMRR.S278867.Google Scholar
World Health Organization (2021). Rift Valley Fever – Kenya. https://www.who.int/csr/don/12-february-2021-rift-valley-fever-kenya/en/ (accessed 03 July 2024).Google Scholar
Nderitu, L, et al (2011) Sequential Rift Valley fever outbreaks in eastern Africa caused by multiple lineages of the virus. The Journal of Infectious Diseases 203(5), 655665. https://doi.org/10.1093/infdis/jiq004.Google Scholar
Drosten, C, et al (2002) Rapid detection and quantification of RNA of Ebola and Marburg viruses, Lassa virus, Crimean-Congo hemorrhagic fever virus, Rift Valley fever virus, dengue virus, and yellow fever virus by real-time reverse transcription-PCR. Journal of Clinical Microbiology 40(7), 23232330. https://doi.org/10.1128/JCM.40.7.2323-2330.2002.Google Scholar