An international collaborative study has revealed groundbreaking findings in the realm of tick-borne pathogens, marking the first molecular detection of Rickettsia species within ticks collected from domestic dogs in Malawi. This research addresses a critical gap in the epidemiological understanding of zoonotic diseases in southeastern Africa, a region where such data has historically been sparse. By identifying the presence of pathogen-carrying ticks associated with one of the most common domestic animals, the study shines a spotlight on the intersection of animal health and public safety in Malawi.
The investigative efforts were spearheaded by a consortium of scientists from Hokkaido University in Japan alongside researchers from Lilongwe University of Agriculture and Natural Resources in Malawi. Through their meticulous work, three distinct species of the obligate intracellular bacteria Rickettsia were molecularly identified. These bacteria, known causative agents of human rickettsioses, including various forms of spotted fevers, have now been confirmed in tick populations infesting dogs throughout Malawi, thereby expanding current knowledge about their geographic distribution.
Prior to this investigation, countries bordering Malawi—such as Tanzania, Mozambique, and Kenya—had reported human incidences of spotted fever group rickettsioses. However, no comprehensive molecular investigation had been carried out within Malawi itself. This dearth of diagnostic data has limited the ability of public health authorities and epidemiologists to evaluate the true risk posed by rickettsial infections within the country, underscoring the critical importance of this new research.
The study employed an integrative approach combining extensive field collection, molecular diagnostics, and phylogenetic analyses conducted over samples collected between 2019 and 2020. Researchers amassed 209 canine blood samples and 259 tick specimens from four geographically distinct districts in Malawi. By utilizing polymerase chain reaction (PCR) amplification targeting rickettsial DNA sequences coupled with advanced sequencing techniques, they were able to detect and classify the bacteria and map their genetic relatedness with previously characterized strains from other regions.
Interestingly, despite thorough testing, no Rickettsia DNA was detected within the dog blood samples themselves. In stark contrast, the investigation revealed infection rates of 2.5% among Rhipicephalus linnaei ticks and 6.3% among Haemaphysalis elliptica ticks. These findings suggest that while dogs may not harbor systemic rickettsial infections, their attached ticks serve as important reservoirs and vectors for these pathogens, potentially facilitating zoonotic transmission.
Three rickettsial species were identified, each presenting varying levels of pathogenicity and public health concern. The most clinically significant among them is Rickettsia conorii subspecies conorii, the etiological agent of Mediterranean spotted fever, a potentially severe illness in humans characterized by fever, rash, and in some cases, fatality if untreated. Secondly, Rickettsia massiliae, which has been linked to mild to moderate spotted fever symptoms, was detected, marking its first molecular identification within southern Africa. Lastly, Rickettsia rhipicephali was found, although its pathogenic potential in humans remains poorly characterized, warranting further investigation.
The discovery of R. massiliae and R. rhipicephali in Malawi is particularly momentous given their previous absence from southern African pathogen surveillance, indicating either recent geographic expansion or a previously unrecognized endemic presence. This underscores the dynamic and evolving nature of tick-borne pathogen ecology, emphasizing the importance of sustained monitoring in various ecological niches to preempt zoonotic outbreaks.
The complex relationship between dogs and humans in Malawi provides a critical context for interpreting these findings. Dogs in many Malawian households function beyond companionship; they are actively engaged in security and pest control within homestead environments. Their frequent and close contact with humans, coupled with overlapping environmental exposures, positions dogs as sentinel species for assessing risks to human health from vector-borne diseases.
Seasonal trends emerged as a pivotal factor influencing tick infection dynamics. The majority of Rickettsia-infected ticks were collected during Malawi’s rainy season, spanning December through March, coinciding with peak tick populations. This seasonality contributes to heightened risks for pathogen transmission during specific periods, necessitating targeted intervention strategies aligned with environmental conditions to mitigate human infections.
Furthermore, urbanization appears to impact tick infestation rates among canine populations. The study noted a notably higher prevalence of tick infestations among urban dogs compared to their rural counterparts. This disparity is hypothesized to stem from differences in animal husbandry practices, environmental modifications, and microclimatic factors prevalent within urban settings, all of which may create favorable conditions for tick proliferation and survival.
Adopting a One Health approach, which integrates human, animal, and environmental health perspectives, the research provides a holistic understanding of rickettsial disease ecology in Malawi. This interdisciplinary framework is particularly effective for zoonotic diseases where pathogen transmission bridges multiple hosts and vectors, offering actionable insights into surveillance, diagnosis, and prevention.
The data strongly suggest that dog-associated ticks constitute a significant ecological niche for maintenance and transmission of rickettsial pathogens with zoonotic potential. This highlights an urgent need for developing integrated surveillance systems that encompass vectors, animal hosts, and human populations to facilitate early detection, risk assessment, and implementation of control measures aimed at minimizing public health impacts.
Conclusively, this pioneering molecular evidence of zoonotic Rickettsia species in dog-attached ticks in Malawi reshapes the current understanding of rickettsial disease epidemiology in southern Africa. It underscores the nexus between pet animal management, vector ecology, and human health risks, thereby advocating for collaborative cross-sectoral efforts to address emerging infectious diseases in resource-constrained settings.
In light of these findings, future research should prioritize elucidating the pathogenic potential of R. rhipicephali, assessing dog-to-human transmission dynamics, and evaluating the efficacy of integrated tick control programs. Such initiatives will be crucial in bolstering public health defenses against tick-borne rickettsial diseases that may otherwise go unnoticed and unmanaged in vulnerable populations.
—
Subject of Research: Molecular detection and characterization of zoonotic Rickettsia species in ticks infesting domestic dogs in Malawi.
Article Title: Investigation of potentially zoonotic Rickettsia species in dogs and their attached ticks in Malawi through the lens of One Health
News Publication Date: 18-Sep-2025
Web References: http://dx.doi.org/10.1016/j.soh.2025.100122
Keywords: Zoonotic diseases, Rickettsia, tick-borne pathogens, domestic dogs, Malawi, One Health, Mediterranean spotted fever, Rhipicephalus linnaei, Haemaphysalis elliptica, molecular diagnostics, phylogenetics, vector-borne infections
Tags: domestic dog health and safetyemerging zoonotic pathogensepidemiological research in Malawigeographic distribution of Rickettsiainternational collaboration in infectious disease researchmolecular detection of Rickettsiapublic health threat from animal ticksRickettsia species in Malawispotted fever group rickettsiosestick-borne pathogens in dogsveterinary public health in Africazoonotic diseases in southeastern Africa
