Citation: McDowell MA, Rafati S, Ramalho-Ortigao M, Ben Salah A (2011) Leishmaniasis: Middle East and North Africa Research and Development Priorities. PLoS Negl Trop Dis 5(7): e1219. doi:10.1371/journal.pntd.0001219
Editor: Serap Aksoy, Yale School of Public Health, United States of America
Published: July 26, 2011
Copyright: © 2011 McDowell et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: The sponsor is NIH. This is a manuscript that puts forth policy recommendations as a result of a scientific workshop. The organizers of NIH asked the authors to prepare and submit a manuscript outlining these policy recommendations. The funders had not role in the development of the recommendations or the preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
“Science knows no country, because knowledge belongs to humanity, and is the torch which illuminates the world.”—Louis Pasteur
Leishmaniasis remains one of the world's most devastating neglected tropical diseases, causing substantial mortality and contributing to nearly 2 million disability-adjusted life years. The true global burden of leishmaniasis, however, is unknown. The Middle East and North Africa (MENA) region is endemic for many forms of leishmanisis and has hosted many recent epidemic outbreaks. A research and policy conference, LEISHMANIA: Collaborative Research Opportunities in North Africa and the Middle East, was held in June 2009 in Tunisia to promote international collaboration between the United States (US) and the countries most affected by Old World leishmaniasis (see Table 1 for a list of participating countries). Supported by the US National Institute of Allergy and Infectious Diseases, National Institutes of Health (NIH), and hosted locally by the Institute Pasteur de Tunis, approximately 100 scientists and administrators from the US and MENA countries met to share critical information and to identify the major obstacles for translating scientific breakthroughs into innovative strategies for reducing the burden of leishmaniasis. The participants identified three crucial areas as requiring reinforcement and growth: translation of laboratory discoveries into field-applications, increased research capacity in endemic countries, and the creation of a leishmaniasis reagent repository (Figure 1). Our hope is that these recommendations will be adopted by research, funding, and policy institutions alike to have a greater impact at controlling leishmaniasis throughout the world.
Figure 1. Policy recommendations for the translation of laboratory discoveries into field applications for the control of leishmanisis.doi:10.1371/journal.pntd.0001219.g001
Leishmaniasis in the Middle East and North Africa
Leishmaniasis is a complex, multi-spectrum, sand fly–transmitted disease (Figure 2), with symptoms ranging from self-limiting cutaneous lesions to fatal visceral disease. While the species of Leishmania initiating the infection primarily dictates clinical presentation, a single Leishmania species can elicit a range of pathologies , , . The specific factors that influence clinical outcome of these infections remains to be completely elucidated, but likely is influenced by host genetics or immune responses , potentially different sand fly vector species or populations , , , and/or the presence of Leishmania spp. hybrids , .
Figure 2. MENA leishmaniasis.
Although at least 20 Leishmania spp. infect humans worldwide, the primary epidemiologically relevant species in the MENA region are L. major, L. tropica, L. infantum, and L. donovani, transmitted by approximately 25 different Phlebotomus spp. Etiological agents of visceral leishmaniasis (VL) in MENA include L. donovani, L. infantum, and occasionally L. tropica. Cutaneous leishmaniasis (CL) caused by L. major, L. tropica, and L. infantum differ slightly in lesion presentation depending on the species. As with vector species, a variety of animal hosts have been implicated as reservoirs in the transmission of zoonotic leishmaniasis, including rodents, hyraxes, and canids. For CL caused by L. major, the primary cycle is zoonotic between P. papatasi (shown) and Psammoys (shown) and Meriones rodents. Although hyraxes have been implicated as a reservoir host for L. tropica, transmission is thought to be primarily anthroponotic as is the VL agent, L. donovani. Mediterranean VL caused by L. infantum is typically zoonotic where candids are the primary reservoir and man is an accidental host; however, anthroponitic cycles also have been characterized. Regardless of species or clinical manifestation, all Leishmania species infecting humans are transmitted by the bite of an infected sand fly. During a blood meal, metacyclic promastigotes are released by the sand fly and enter the skin of the vertebrate host. Leishmania parasites infect cells of the myeloid lineage, including neutrophils, followed by macrophages and dendritic cells (shown). These parasites reside within a phagolysosome where they differentiate into a dividing, aflagellated amasitogotes. Sand flies take up parasites when feeding on an infected host. Infected host cells are lysed and amastigotes differentiate into flagellated procyclic promastigotes that attach to the midgut of the sand fly vector. Subsequent development and migration towards the anterior end of the sand fly completes the cycle. Photo Credits: P. papatasi courtesy of Tim Gathany, Center for Disease Control Photo Services; Psammomys obesus from http://commons.wikimedia.org/wiki/File:Psammomys_obesus_01.jpg; rock hyrax from http://www.marietta.edu/~biol/biomes/biome_main.htm.doi:10.1371/journal.pntd.0001219.g002
Although the World Health Organization (WHO) has designated leishmaniasis as one of the 15 most neglected tropical diseases, the global morbidity due to leishmaniasis remains underestimated due to misdiagnosis and inadequate reporting guidelines. In the MENA region alone, nearly 100,000 cases of leishmaniasis in 2008 were reported to the WHO; however, some nations only report for one of the various clinical pathologies, and other countries fail to report all together . Epidemics of leishmaniasis often are associated with war, human migration, and anthroponotic environmental change associated with agricultural practices or urbanization. The key factors driving the risk, severity, and temporal-spatial trends of disease, however, are presently unknown, and predictive tools for epidemic peaks and geographic spread of leishmanial disease are lacking .
Translation of Laboratory Discoveries into Field Applications
“Science and the applications of science bound together as the fruit of the tree which bears it.” —Louis Pasteur
Science is in the midst of a technological explosion, and the next wave of scientific progress will involve translating these advancements into practical implementation policies in disease-endemic regions. Many novel techniques are furthering our understanding of various aspects of Leishmania transmission, disease, and sand fly biology, tools that hold promise for bridging the bench to the bedside. Unfortunately, this revolution has not translated into meaningful control measures. Advancement in three major priority areas, molecular diagnostics, clinical research, and knowledge sharing and standardization, is necessary to push the leishmaniasis field towards translational results (Table 2).
Table 2. Leishmaniasis: Road to Translation.doi:10.1371/journal.pntd.0001219.t002
Specific parasite identification methods are essential if the complexities of leishmanial disease manifestation are to be elucidated; to effectively impact epidemiological studies as well as clinical treatment, these diagnostic tools must be reliable, inexpensive, easy to use, and provide quick results. Comparative genome analyses of completed Leishmania genomes will greatly enhance development of novel molecular approaches to identify different Leishmania species and strains, and as next generation sequencing methods become more affordable, genome sequence information will be more easily obtainable for clinical isolates. Bolstering genomics research in general and increasing genomics capacity in regional environments is crucial if we hope to unravel the complex dynamics of leishmaniasis.
Molecular tool development also is essential to produce a complete epidemiological picture of vector distributions and how these species correlate with the current state of leishmaniasis in the MENA region. New insights concerning sand fly biology will likely be provided with the completion of the ongoing genome projects of two sand fly species, Phlebotomus papatasi and Lutzomyia longipalpis.
Development of a vaccine to prevent leishmaniasis has been motivated by the observation that a cured infection protects against re-infection. While laboratory studies and anecdotal evidence indicate that “natural infection” protects from severe disease, true validation in the field is necessary, as cases of re-infection have been reported , . Model systems certainly can provide critical information, but they never truly mimic the disease dynamics in nature. Although delineating the mechanisms that lead to parasite establishment and tissue-specific immunity in humans remains an ethical challenge, clinical research in leishmaniasis-endemic regions needs to be expanded. In addition to the evaluation of vaccine trials and anti-leishmanial drugs, implementation of large, longitudinal, cohort studies will improve the understanding of that natural history of Leishmania infection and its transmission dynamics, as well as the parameters that lead to the wide disease spectrum.
Regulatory bottlenecks due to inadequate administrative frameworks often hinder clinical research activity in disease-endemic countries. The international research community could bridge this infrastructure gap by facilitating clear and coordinated international human subjects' research protection (HRP) policy conformity through streamlined procedures for establishing and registering Institutional Review Boards and Federalwide Assurance compliance in all nations. Furthermore, research institutions and private industry should be encouraged to establish policies for the ease of executing material transfer agreements (MTA) and non-disclosure arrangements (NDA) in low- and middle-income countries.
Knowledge Sharing and Standardization
Rapid advances are being made in the leishmaniasis field, some of which are opening new avenues for investigation and hold promise for translational application. For these breakthroughs to be effective, however, technology needs to be efficiently transferred to regional scientists. Not only is knowledge sharing essential between scientists of resource-rich and low- and middle-income nations, there also is a dire necessity for assay standardization between the entire leishmaniasis research community. Clear guidelines and best practices should be created for assessing vaccine efficacy and validating chemotherapies.
Also essential is the generation of guidelines for the development and implementation of field-based studies and clinical trials. Standardization of experimental design, reporting statistics, and clinical protocols will be required across nations to adequately derive conclusions from multiple investigations. Furthermore, development of protocols to assess pertinence, effectiveness, and robustness of surveillance programs are desperately needed.
Successful implementation of these clinical studies will only advance the leishmaniasis field if critical information is shared among researchers, policy makers, and practitioners. Timely information dissemination will be required as the leishmaniasis field continues to expand; such exchange could appear in public digital libraries, through development of secure Web sites for clinical data, or by implementation of smaller regional meetings that foster interaction between scientists, clinicians, and government personnel.
Increased investments in research, availability of laboratory facilities, and close collaboration among scientists would greatly advance the leishmaniasis field. Strengthening the connections between education, research, and society are essential factors and require certain building blocks to assure its proper structure. However, in resource-poor locations it is difficult to establish and sustain such cooperative enterprises. This arduous task requires global capacity building in science and technology, and active participation of the international scientific community could have tremendous effects.
The persistent loss of national scientific talent is an important issue that low- and middle-income countries are facing and is a major obstacle to the proper establishment of research activities in endemic countries. In order to be successful, scientific institutions need access to infrastructure, technical support, and trained scientists. By creating a thriving scientific atmosphere, researchers will be retained and motivated. In order to increase scientific capacity in the MENA region, focused efforts in the following areas are necessary:
- Long-term partnerships between scientists and institutions, including both academic and public health organizations, must be fostered and supported by funding agencies, governments, and private and public institutions. Proactive actions should to be taken to develop mutually advantageous collaborative projects through directed seed funding.
- Development of institutional partnerships with lasting student and faculty exchange programs. Sandwich training of PhD students is particularly useful at bringing and retaining regional scientists.
- The organization of training workshops and courses can serve as a mechanism of active collaboration among different institutes. These training modules should be located in leishmaniasis-endemic countries for greater accessibility to scientists from these areas.
- Creation of Web sites where subject-specific teaching materials and assay protocols are easily accessed.
- Availability of visiting lectureships and travel grants for participation in international scientific meetings to scientists, post-graduate students, and technicians from disease-endemic countries should be increased.
- Establishment and support of local and international scientific associations that meet on a regular basis would increase information sharing among endemic scientists and policy makers.
Creation of a Leishmania/Sand Fly Reagent Repository
Another priority area that will increase the research capacity in leishmaniasis-endemic countries is the creation of a centralized leishmaniasis reagent repository. An enterprise such as the Malaria Research and Reference Reagent Resource Center (MR4) housed at the American Type Culture Collection (ATCC) would greatly enhance the availability of leishmanisis reagents to resource-poor nations. Genomic databases, like TriTypDB (http://tritrypdb.org/) for kinetoplastid organisms, EuPathDB (http://eupathdb.org/) for eukaryotic pathogens, and VectorBase (http://www.vectorbase.org/) for arthropod vectors of disease, that manage genmic data and support centralized bioinformatics tools have already provided essential resources to researchers from disease-endemic countries. The next critical step, however, is for the genomic reagents connected to genome projects to be readily accessible to the international research community. In addition to genomic tools, a depot stocking Leishmania strains and mutants, clinical isolates, tissue samples, and other leishmaniasis research reagents would improve the access of such materials to scientists worldwide. One obstacle to effectively controlling leishmaniasis is an inadequate picture of the sand fly strains that can transmit Leishmania parasites. As molecular systematics is a rapidly evolving field, type specimens for future analysis also could be stored and distributed by a leishmaniasis reagent center.
In addition to increased access of reagents to international scientists, an added benefit of a leishmaniasis repository would be the availability of Leishmania strains and other reagents for verification by multiple laboratories and additional experimental platforms. Moreover, easy access of materials might encourage scientists from other disciplines to apply their expertise to the leishmaniasis field, bringing fresh ideas and approaches to controlling these destructive diseases.
There are currently limited Leishmania repositories in the United Kingdom, France, and Brazil, as well as sand fly collections housed by universities and museums in different nations. However, no centralized location exists that curates, stores, and distributes these resources to the entire international research community. As leishmaniasis research continues to expand, the financial cost to these smaller storage facilities may become too much of a burden. International collaborative leishmaniasis research would be greatly strengthened if a sustained leishmaniasis repository was created and ease the cost and difficulty of the distribution of scientific samples across international borders. Clearly, such an enterprise would require oversight and funding, and strict guidelines for sample submission and quality control must be implemented. Like MR4, which is supported by NIH and serves the malaria community, such a facility could be funded by a collection of public and private agencies and would be best developed through a competitive bid process.
The US-MENA Leishmaniasis conference provided an unprecedented opportunity for scientists to interact and focus on leishmaniasis research issues specific to the MENA region and resulted in several successful grant proposals funded through the Civilian Research and Development Foundation. The collaborations that arose from this conference will certainly influence leishmaniasis control in the MENA region specifically; moreover, the discussions and recommendations also have implications for the leishmaniasis field as a whole.
Special acknowledgement goes to Martha Jane Coury, Shaden Kamhawi, Jesus Valenzuela, and Adriana Costero for their infinite enthusiasm and countless hours spent organizing the meeting. In addition, we thank The Dixon Group, specifically Stuart Ruff and his colleagues, for overseeing all of the travel arrangements and accommodations. We are particularly appreciative to Drs. Riadh Ben-Ismail and Jose Postigo from WHO-EMRO for sharing the 2008 Leishmaniasis data from the MENA region. We also are grateful to all of the participants that attended the meeting, generously providing their time, data, and ideas.
- 1. Abbas K, Musatafa MA, Abass S, Kheir MM, Mukhtar M, et al. (2009) Mucosal leishmaniasis in a Sudanese patient. Am J Trop Med Hyg 80: 935–938.
- 2. Elamin EM, Guizani I, Guerbouj S, Gramiccia M, El Hassan AM, et al. (2008) Identification of Leishmania donovani as a cause of cutaneous leishmaniasis in Sudan. Trans R Soc Trop Med Hyg 102: 54–57.
- 3. Khalil EA, Musa AM, Elgawi SH, Meshasha A, Gamar Eldawla I, et al. (2008) Revival of a focus of visceral leishmaniasis in central Sudan. Ann Trop Med Parasitol 102: 79–80.
- 4. Sakthianandeswaren A, Foote SJ, Handman E (2009) The role of host genetics in leishmaniasis. Trends Parasitol 25: 383–391.
- 5. Ben Hadj Ahmed S, Chelbi I, Kaabi B, Cherni S, Derbali M, et al. Differences in the salivary effects of wild-caught versus colonized Phlebotomus papatasi (Diptera: Psychodidae) on the development of zoonotic cutaneous leishmaniasis in BALB/c mice. J Med Entomol 47: 74–79.
- 6. Laurenti MD, Silveira VM, Secundino NF, Corbett CE, Pimenta PP (2009) Saliva of laboratory-reared Lutzomyia longipalpis exacerbates Leishmania (Leishmania) amazonensis infection more potently than saliva of wild-caught Lutzomyia longipalpis. Parasitol Int 58: 220–226.
- 7. Yin H, Norris DE, Lanzaro GC (2000) Sibling species in the Llutzomyia longipalpis complex differ in levels of mRNA expression for the salivary peptide, maxadilan. Insect Mol Biol 9: 309–314.
- 8. Volf P, Benkova I, Myskova J, Sadlova J, Campino L, et al. (2007) Increased transmission potential of Leishmania major/Leishmania infantum hybrids. Int J Parasitol 37: 589–593.
- 9. Ravel C, Cortes S, Pratlong F, Morio F, Dedet JP, et al. (2006) First report of genetic hybrids between two very divergent Leishmania species: Leishmania infantum and Leishmania major. Int J Parasitol 36: 1383–1388.
- 10. World Health Organization (2011) WHO Regional Office for the Eastern Mediterranean (EMRO). Available: http://www.emro.who.int. Accessed 28 June 2011.
- 11. Ready PD (2008) Leishmaniasis emergence and climate change. Rev Sci Tech 27: 399–412.
- 12. Killick-Kendrick R, Bryceson AD, Peters W, Evans DA, Leaney AJ, et al. (1985) Zoonotic cutaneous leishmaniasis in Saudi Arabia: lesions healing naturally in man followed by a second infection with the same zymodeme of Leishmania major. Trans R Soc Trop Med Hyg 79: 363–365.
- 13. Salah AB, Kamarianakis Y, Chlif S, Alaya NB, Prastacos P (2007) Zoonotic cutaneous leishmaniasis in central Tunisia: spatio temporal dynamics. Int J Epidemiol 36: 991–1000.