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Abstract

Malaria is a serious public health problem worldwide despite concerted efforts to control and eliminate it. Zoonotic malaria is emerging as a big threat to malaria elimination efforts. There is a big knowledge gap in our understanding of zoonotic malaria. It is difficult to adequately detect and identify Plasmodium species responsible for zoonotic malaria with conventional diagnostic tools. Although molecular tools have good sensitivity and specificity to diagnose zoonotic malaria, they are not readily available in resource-limited settings. There is limited data on the epidemiology of zoonotic malaria in sub-Saharan Africa. However, various reports signal for the presence of its risk lurking in the area. Therefore, organized and comprehensive studies are needed to characterize its epidemiology in sub-Saharan Africa to guide strategies of mitigating zoonotic malaria in particular and malaria in general.

Introduction

Zoonotic pathogen is a microorganism that colonizes or infects animals and can be transmitted to humans through vector or via direct contact with the animal or its products. Zoonotic disease causation in humans, usually, is accidental and not primarily for evolutionary survival [1].  An interest in potentially zoonotic malaria started after accidental infection of laboratory workers with Plasmodium cynomolgi (P. cynomolgi) via an Anopheles mosquito in 1960 [2]. Recent scientific developments show the possibility of zoonotic malaria. Various studies have reported human infection by macaque and simian malaria parasites, mainly by Plasmodium knowlesi (P. knowlesi, P. simium) and Plasmodium brasilianum (P. brasilianum) [3-6]. P. knowlesi is common in Southeast Asia [3], whereas Plasmodium simium (P. simium) and P. brasilianum are common in Latin America [5,6]. However, we lack concrete evidence on whether all human cases originate from animals or human-to-human transmission is occurring [4]. This mini review focuses on the biology, clinical pictures, diagnosis, treatment and epidemiology of zoonotic malaria in sub-Saharan Africa, and its implication for malaria elimination.

Biology and Clinical Picture
According to various experimental studies, parasites of monkeys, such as P. cynomolgi, P. brasilianum, P. eylesi, P. inui, and P. simium have been shown to infect human via mosquitoes [7, 8]. Besides, isolation of the DNAs of the Plasmodium species commonly infecting human from African anthropoid apes alarm for possibility of zoonosis [9]. However, P. knowlesi is the widely accepted Plasmodium parasite of zoonotic malaria, particularly in Southeast Asian countries, and recently became the fifth human malaria parasite [10]. Monkeys are reservoir host of knowlesi malaria [9]. Furthermore, a recent molecular study in Africa revealed zoonotic origin of the human malaria parasite P. malariae, which is known to infect chimpanzees [9,11].
Due to close similarity between P. vivax, and P. cynomolgi, various experimental studies including culturing P. cynomolgi helped to understand the life-cycle of P. vivax [12,13]. Similar to P. vivax, P. cynomolgi produces dormant liver stage hypnozoite.  It also favors infecting reticulocytes and have the Schuffner’s dot visible on infected erythrocyte membrane [14,15]. Zoonotic malaria exhibits similar symptoms of the known human malaria including myalgia, anorexia, fever, nausea and others. Human malaria caused by simian Plasmodium is often mild [9,14]. The clinical picture of malaria due to P. knowlesi infections is often uncomplicated. However, it can cause severe malaria in about 10% of patients in Malaysia [4,16,17]. The incubation period of knowlesi malaria lasts for 9-15 days [9]. The developmental cycle of P. knowlesi occurs every 24 h, and hence cause quotidian malaria in which patient fevers peak every day [7,9]. Similar to P. vivax, P. cynomolgi commonly causes asymptomatic malaria and produces dormant liver stage hypnozoite [14].

Transmission
Leucosphyrus group of Anopheline mosquitoes transmit P. knowlesi and the transmission is mainly zoonotic. This type of malaria is dominant malaria in Malaysia, where its transmission is restricted to jungle thereby putting humans entering jungle in transmission area at risk. It is quite common to see human cases of P. knowlesi in travelers returning from Southeast Asia [4].
A recent sequencing study has shown that P. simium, a malaria parasite of non-human primates (NHP), can cause zoonotic infection of human in Brazil. In fact, the study revealed that ability of the parasite to undergo genetic adaptations underscore its advantage to switch between host species [18]. An. vinckei, An. moucheti and An. marshallii serve as competent vectors of ape Laverania and non-Laverania parasites thereby mediating transmission of zoonotic malaria [19].

Management of Zoonotic Malaria

Diagnosis
Microscopic examination of Giemsa stained thick and thin blood film is the routine diagnosis for malaria of humans and monkeys. However, it is difficult to differentiate between simian Plasmodium and the known human Plasmodium species solely by morphological criteria. Besides, the capacity of an extensively used malaria RDTs to sufficiently characterize simian Plasmodium species is limited [9,20].
The development of molecular methods such as polymerase chain reaction (PCR) was instrumental in the knowledge gained on zoonotic malaria [10,14]. For long time, P. knowlesi has been misdiagnosed as P. malariae. Nevertheless, PCR is now the definitive method for differentiating P. knowlesi from P. malariae and other human malaria parasites [21]. Likewise, PCR helped to differentiate between P. cynomolgi and P. vivax (14). Nevertheless, due to low prevalence (in terms of detected cases); high cost and inadequate availability of PCR, it is conceivable that zoonotic malaria is under diagnosed [20]. Generally, highly sensitive and specific tools such as PCR are critical for accurate detection of both zoonotic and human-only Plasmodium species [22].

Treatment
Chloroquine is the drug of choice for zoonotic malaria treatment regardless of resistance to the drug by other species of Plasmodium. In the case of P. knowlesi infection, a chloroquine-primaquine combination therapy is recommended [9].

Epidemiology in Sub-Saharan Africa
Various reports indicate the circulation of primate-infecting Plasmodium species in the equatorial forest region of Africa [23,24]. Despite the lack of an organized and comprehensive study, there are many reports from human and monkeys in different countries signaling for the presence of zoonotic malaria risk revolving in the continent [24-27]. A molecular study targeting cytochrome b gene conducted by Duval et al. in Cameroon showed similarity of the Plasmodium species between human and chimpanzee in which a chimpanzee Plasmodium strain was found to be genetically identical to variant Plasmodium ovale (P. ovale) type [27]. A variant P. ovale species is detected from a patient in Ghana. This parasite is highly similar to a variant P. ovale detected from Chimpanzee in Cameroon [25].
There are no reports of confirmed P. knowlesi infection in sub-Saharan Africa. The possible explanation for this absence of zoonotic malaria in the region can be absence of the common reservoir hosts (the pig-tailed and the long-tailed monkeys) and the potential misdiagnosis [26].

Factors Determining Zoonotic Malaria
According to reports of recent studies, risk factors for infection with zoonotic malaria parasites include the male sex, contact with macaque monkeys, agricultural expansion, presence of mosquito vector, human behavior, travel to forest areas and forest fragmentation [28-31]. Generally, host factors, species of the Plasmodium, social factors such as migration, environmental factors such as dense jungle and vector factors are pivotal to the risk of zoonotic malaria [32,33].

Gaps
Data on zoonotic malaria epidemiology is limited, particularly in sub-Saharan Africa. This might be partly due to low prevalence or misdiagnosis. In co-endemic settings, misdiagnosis is expected since microscopic morphological appearance of P. cynomolgi and P. knowlesi is similar to P. vivax and P. malariae, respectively [20,22,34]. A recent analysis of the P. simium genome showed a close phylogenetic relationship between P. simium and P. vivax [18]. We have limited knowledge on zoonotic malaria that can guide designing effective intervention to combat and eliminate it [33].
The five Plasmodium species that infect humans have been found in non-human primates (NHPs). This means these NHPs can potentially serve as reservoirs for transmission of malaria to humans. Besides, given evolutionary process, Plasmodium species those infecting NHPs may eventually become causes for human malaria [35,36]. Based on molecular epidemiology studies, Laverania infected apes do not currently serve as a reservoir of human infection [37,38]. Nevertheless, in depth researches are critical to resolve these discrepancies and devise interventions.

Impact of Zoonotic Malaria on Elimination Efforts
Considering the recent malaria outbreaks of P. knowlesi in Southeast Asia and P. simium in Brazil, it is conceivable that intensified human intervention on the natural forest might increase the risk of zoonotic malaria [37]. The deletion of Duffy binding protein (DBP1) gene in P. simium may facilitate invasion of human red blood cells thereby facilitating zoonotic infection, which in turn sustains malaria transmission [18].
If we do not have clear knowledge on zoonotic malaria with its epidemiology in time and space, we might not be in better position to mitigate it. Moreover, it could eventually complicate efforts to eliminate malaria [1]. In the presence of continued human contact with the monkey reservoir and the presence of competent mosquito vectors, zoonotic malaria will not be eliminated by current intervention that mainly focused at human-only Plasmodium species [17]. Following decline in the prevalence of human-only malaria due to intensified elimination efforts, zoonotic malaria could become prominent public health problem in co-endemic settings. Besides, if areas approaching elimination use molecular surveillance, the previously misdiagnosed zoonotic malaria by conventional tools might persist and delay the achievement of elimination [34,39]. 

Conclusion and Recommendation

Zoonotic malaria is becoming public health problem by threatening malaria elimination efforts. There is a big knowledge gap in our understanding of zoonotic malaria. There is paucity of data on the epidemiology of zoonotic malaria in sub-Saharan Africa. Admirable advancements of molecular techniques with their promising application in epidemiology can fine-tune our understanding on zoonotic malaria. That knowledge will prompt discovery of mitigation tools and intervention strategies to mitigate zoonotic malaria in particular and keep us on the track to eradicate malaria in general.
A concerted effort is needed on basic science to understand the biology of simian Plasmodium species with zoonotic potential. An integrated control program including ecological approach is required to mitigate the eminent public health threat from zoonotic malaria. Considering zoonotic malaria into mitigation efforts is key to consolidate gains and advance towards malaria elimination.

Author Contributions

Author Contributions
Aklilu Alemayehu has conceived, made online search of relevant articles, and wrote the first draft. Then, he critically reviewed, wrote the final draft, read and approved it for this submission.

Funding
This research received no external funding.

Acronyms and Abbreviations
DBP:        Duffy binding protein
NHP:        Non-human primates
PCR:         Polymerase Chain Reaction
RDT:        Rapid Diagnostic Test

References

1. Blaser MJ, Dolin R, Bennett JE. Mandell, Douglas, and Bennett’s (2020), Principles and Practice of Infectious Diseases. 9th ed. Philadelphia: Elsevier.
   View at Publisher | View at Google Scholar
2. Eyles, Don E., G. Robert Coatney, and Morton E. Getz. "Vivax- type malaria parasite of macaques transmissible to man." Science 131, no. 3416 (1960): 1812-1813.
   View at Publisher | View at Google Scholar
3. Lubis, Inke ND, Hendri Wijaya, Munar Lubis, Chairuddin P. Lubis, Paul CS Divis, Khalid B. Beshir, and Colin J. Sutherland. "Contribution of Plasmodium knowlesi to multispecies human malaria infections in North Sumatera, Indonesia." The Journal of infectious diseases 215, no. 7 (2017): 1148-1155.
   View at Publisher | View at Google Scholar
4. Millar, S. B., and Janet Cox-Singh. "Human infections with Plasmodium knowlesi—zoonotic malaria." Clinical Microbiology and Infection 21, no. 7 (2015): 640-648.
   View at Publisher | View at Google Scholar
5. Brasil, Patrícia, Mariano Gustavo Zalis, Anielle de Pina-Costa, Andre Machado Siqueira, Cesare Bianco Júnior, Sidnei Silva, Marcelo Pelajo-Machado et al. "Outbreak of human malaria caused by Plasmodium simium in the Atlantic Forest in Rio de Janeiro: a molecular epidemiological investigation." The Lancet Global Health 5, no. 10 (2017): e1038-e1046.
   View at Publisher | View at Google Scholar
6. Lalremruata, Albert, Magda Magris, Sarai Vivas-Martínez, Maike Koehler, Meral Esen, Prakasha Kempaiah, Sankarganesh Jeyaraj, Douglas Jay Perkins, Benjamin Mordmüller, and Wolfram G. Metzger. "Natural infection of Plasmodium brasilianum in humans: man and monkey share quartan malaria parasites in the Venezuelan Amazon." EBioMedicine 2, no. 9 (2015): 1186-1192.
   View at Publisher | View at Google Scholar
7. Encyclopedia of Malaria. New York: Springer; 2013.
   View at Publisher | View at Google Scholar
8. Coatneyi G, Collins W, Warren M, Contacos P. (1971), The Primate Malarias. Department of Health Education and Welfare.
   View at Publisher | View at Google Scholar
9. Bauerfeind R, Graevenitz Av, Kimmig P, Schiefer HG, Schwarz T, Slenczka W, et al. (2016), Zoonoses Infectious Diseases Transmissible Between Animals and Humans. 4th ed. Washington: ASM Press.
   View at Publisher | View at Google Scholar
10. Singh, Balbir, Lee Kim Sung, Asmad Matusop, Anand Radhakrishnan, Sunita SG Shamsul, Janet Cox-Singh, Alan Thomas, and David J. Conway. "A large focus of naturally acquired Plasmodium knowlesi infections in human beings." The Lancet 363, no. 9414 (2004): 1017-1024.
    View at Publisher | View at Google Scholar
11. Plenderleith, Lindsey J., Weimin Liu, Yingying Li, Dorothy E. Loy, Ewan Mollison, Jesse Connell, Ahidjo Ayouba et al. "Zoonotic origin of the human malaria parasite Plasmodium malariae from African apes." Nature Communications 13, no. 1 (2022): 1868.
    View at Publisher | View at Google Scholar
12. Cornejo, Omar E., and Ananias A. Escalante. "The origin and age of Plasmodium vivax." Trends in parasitology 22, no. 12 (2006): 558-563.
    View at Publisher | View at Google Scholar
13. Voorberg-van der Wel, Annemarie, Anne-Marie Zeeman, Sandra M. van Amsterdam, Alexander Van den Berg, Els J. Klooster, Shiroh Iwanaga, Chris J. Janse et al. "Transgenic fluorescent Plasmodium cynomolgi liver stages enable live imaging and purification of Malaria hypnozoite-forms." PloS one 8, no. 1 (2013): e54888.
    View at Publisher | View at Google Scholar
14. Bykersma, Alexander. "The new zoonotic malaria: Plasmodium cynomolgi." Tropical medicine and infectious disease 6, no. 2 (2021): 46.
    View at Publisher | View at Google Scholar
15. Pasini, Erica M., Ulrike Böhme, Gavin G. Rutledge, Annemarie Voorberg-Van der Wel, Mandy Sanders, Matt Berriman, Clemens HM Kocken, and Thomas Dan Otto. "An improved Plasmodium cynomolgi genome assembly reveals an unexpected methyltransferase gene expansion." Wellcome open research 2 (2017): 42.
    View at Publisher | View at Google Scholar
16. Rajahram, Giri S., Bridget E. Barber, Timothy William, Matthew J. Grigg, Jayaram Menon, Tsin W. Yeo, and Nicholas M. Anstey. "Falling Plasmodium knowlesi malaria death rate among adults despite rising incidence, Sabah, Malaysia, 2010–2014." Emerging infectious diseases 22, no. 1 (2016): 41.
    View at Publisher | View at Google Scholar
17. Grigg, Matthew J., Timothy William, Bridget E. Barber, Giri S. Rajahram, Jayaram Menon, Emma Schimann, Kim Piera et al. "Age-related clinical spectrum of Plasmodium knowlesi malaria and predictors of severity." Clinical infectious diseases 67, no. 3 (2018): 350-359.
    View at Publisher | View at Google Scholar
18. Mourier, Tobias, Denise Anete Madureira de Alvarenga, Abhinav Kaushik, Anielle de Pina-Costa, Olga Douvropoulou, Qingtian Guan, Francisco J. Guzmán-Vega et al. "The genome of the zoonotic malaria parasite Plasmodium simium reveals adaptations to host switching." BMC biology 19 (2021): 1-17.
    View at Publisher | View at Google Scholar
19. Makanga, Boris, Patrick Yangari, Nil Rahola, Virginie Rougeron, Eric Elguero, Larson Boundenga, Nancy Diamella Moukodoum et al. "Ape malaria transmission and potential for ape-to-human transfers in Africa." Proceedings of the National Academy of Sciences 113, no. 19 (2016): 5329-5334.
    View at Publisher | View at Google Scholar
20. Anstey, Nicholas M., and Matthew J. Grigg. "Zoonotic malaria: the better you look, the more you find." The Journal of infectious diseases 219, no. 5 (2019): 679-681.
    View at Publisher | View at Google Scholar
21. Ramasamy, Ranjan. "Zoonotic malaria–global overview and research and policy needs." Frontiers in public health 2 (2014): 123.
    View at Publisher | View at Google Scholar
22. Imwong, Mallika, Wanassanan Madmanee, Kanokon Suwannasin, Chanon Kunasol, Thomas J. Peto, Rupam Tripura, Lorenz Von Seidlein et al. "Asymptomatic natural human infections with the simian malaria parasites Plasmodium cynomolgi and Plasmodium knowlesi." The Journal of infectious diseases 219, no. 5 (2019): 695-702.
    View at Publisher | View at Google Scholar
23. Antonio-Nkondjio, Christophe, Cyrille Ndo, Flobert Njiokou, Jude D. Bigoga, Parfait Awono-Ambene, Josiane Etang, Albert Same Ekobo, and Charles S. Wondji. "Review of malaria situation in Cameroon: technical viewpoint on challenges and prospects for disease elimination." Parasites & vectors 12 (2019): 1-23.
    View at Publisher | View at Google Scholar
24. Antinori, Spinello, Laura Galimberti, Laura Milazzo, and Mario Corbellino. "Biology of human malaria plasmodia including Plasmodium knowlesi." Mediterranean journal of hematology and infectious diseases 4, no. 1 (2012): e2012013.
    View at Publisher | View at Google Scholar
25. Tordrup, David, Jakob Virenfeldt, Felicie F. Andersen, and Eskild Petersen. "Variant Plasmodium ovale isolated from a patient infected in Ghana." Malaria Journal 10 (2011): 1-5.
    View at Publisher | View at Google Scholar
26. Onyedibe, Kenneth Ikenna, Michael O. Iroezindu, Emmanuel Tumininu Obishakin, Mark Okolo Ojogba, Emmanuel Olushola Shobowale, Ita Okokon Ita, Ubong Aniefiok Udoh, Samson Ejiji Isa, and Daniel Z. Egah. "Plasmodium knowlesi Infection: Should Africa be Prepared for a New Human Malaria Threat." Int. J. Trop. Dis. Health 19 (2016): 1-12.
    View at Publisher | View at Google Scholar
27. Duval, Linda, Eric Nerrienet, Dominique Rousset, Serge Alain Sadeuh Mba, Sandrine Houze, Mathieu Fourment, Jacques Le Bras, Vincent Robert, and Frederic Ariey. "Chimpanzee malaria parasites related to Plasmodium ovale in Africa." PLoS One 4, no. 5 (2009): e5520.
    View at Publisher | View at Google Scholar
28. Fornace, Kimberly M., Paddy M. Brock, Tommy R. Abidin, Lynn Grignard, Lou S. Herman, Tock H. Chua, Sylvia Daim et al. "Environmental risk factors and exposure to the zoonotic malaria parasite Plasmodium knowlesi across northern Sabah, Malaysia: a population-based cross-sectional survey." The Lancet Planetary Health 3, no. 4 (2019): e179-e186.
    View at Publisher | View at Google Scholar
29. Protopopoff, Natacha, Wim Van Bortel, Niko Speybroeck, Jean-Pierre Van Geertruyden, Dismas Baza, Umberto D'Alessandro, and Marc Coosemans. "Ranking malaria risk factors to guide malaria control efforts in African highlands." PloS one 4, no. 11 (2009): e8022.
    View at Publisher | View at Google Scholar
30. Grignard, Lynn, Sonal Shah, Tock H. Chua, Timothy William, Chris J. Drakeley, and Kimberly M. Fornace. "Natural human infections with Plasmodium cynomolgi and other malaria species in an elimination setting in Sabah, Malaysia." The Journal of infectious diseases 220, no. 12 (2019): 1946-1949.
    View at Publisher | View at Google Scholar
31. Brock, Patrick M., Kimberly M. Fornace, Matthew J. Grigg, Nicholas M. Anstey, Timothy William, Jon Cox, Chris J. Drakeley, Heather M. Ferguson, and Rowland R. Kao. "Predictive analysis across spatial scales links zoonotic malaria to deforestation." Proceedings of the Royal Society B 286, no. 1894 (2019): 20182351.
    View at Publisher | View at Google Scholar
32. Naserrudin, Nurul Athirah, April Monroe, Richard Culleton, Rozita Hod, Muhammad Saffree Jeffree, Kamruddin Ahmed, and Mohd Rohaizat Hassan. "Reimagining zoonotic malaria control in communities exposed to Plasmodium knowlesi infection." Journal of Physiological Anthropology 41, no. 1 (2022): 14.
    View at Publisher | View at Google Scholar
33. Chin, Abraham Zefong, Marilyn Charlene Montini Maluda, Jenarun Jelip, Muhammad Saffree Bin Jeffree, Richard Culleton, and Kamruddin Ahmed. "Malaria elimination in Malaysia and the rising threat of Plasmodium knowlesi." Journal of physiological anthropology 39 (2020): 1-9.
    View at Publisher | View at Google Scholar
34. Barber, Bridget E., Timothy William, Matthew J. Grigg, Tsin W. Yeo, and Nicholas M. Anstey. "Limitations of microscopy to differentiate Plasmodium species in a region co-endemic for Plasmodium falciparum, Plasmodium vivax and Plasmodium knowlesi." Malaria journal 12 (2013): 1-6.
    View at Publisher | View at Google Scholar
35. Su, Xin-zhuan, and Jian Wu. "Zoonotic transmissions and host switches of malaria parasites." Zoonoses (Burlington, Mass.) 1, no. 1 (2021): 11.
    View at Publisher | View at Google Scholar
36. Medeiros-Sousa, Antônio Ralph, Gabriel Zorello Laporta, Renato Mendes Coutinho, Luis Filipe Mucci, and Mauro Toledo Marrelli. "A mathematical model for zoonotic transmission of malaria in the Atlantic Forest: Exploring the effects of variations in vector abundance and acrodendrophily." PLoS neglected tropical diseases 15, no. 2 (2021): e0008736.
    View at Publisher | View at Google Scholar
37. Sharp, Paul M., Lindsey J. Plenderleith, and Beatrice H. Hahn. "Ape origins of human malaria." Annual review of microbiology 74, no. 1 (2020): 39-63.
    View at Publisher | View at Google Scholar
38. Sundararaman, Sesh A., Weimin Liu, Brandon F. Keele, Gerald H. Learn, Kyle Bittinger, Fatima Mouacha, Steve Ahuka- Mundeke et al. "Plasmodium falciparum-like parasites infecting wild apes in southern Cameroon do not represent a recurrent source of human malaria." Proceedings of the National Academy of Sciences 110, no. 17 (2013): 7020-7025.
    View at Publisher | View at Google Scholar
39. Herdiana, Herdiana, Chris Cotter, Farah N. Coutrier, Iska Zarlinda, Brittany W. Zelman, Yusrifar Kharisma Tirta, Bryan Greenhouse et al. "Malaria risk factor assessment using active and passive surveillance data from Aceh Besar, Indonesia, a low endemic, malaria elimination setting with Plasmodium knowlesi, Plasmodium vivax, and Plasmodium falciparum." Malaria journal 15 (2016): 1-15.
    View at Publisher | View at Google Scholar