Background For malaria control in Africa it is crucial to characterise the dispersal of its most efficient vector, Anopheles gambiae, in order to target interventions and assess their impact spatially. Our study is, we believe, the first to present a statistical model of dispersal probability against distance from breeding habitat to human settlements for this important disease vector. Methods/Principal Findings We undertook post-hoc analyses of mosquito catches made in The Gambia to derive statistical dispersal functions for An. gambiae sensu lato collected in 48 villages at varying distances to alluvial larval habitat along the River Gambia. The proportion dispersing declined exponentially with distance, and we estimated that 90% of movements were within 1.7 km. Although a ‘heavy-tailed’ distribution is considered biologically more plausible due to active dispersal by mosquitoes seeking blood meals, there was no statistical basis for choosing it over a negative exponential distribution. Using a simple random walk model with daily survival and movements previously recorded in Burkina Faso, we were able to reproduce the dispersal probabilities observed in The Gambia. Conclusions/Significance Our results provide an important quantification of the probability of An. gambiae s.l. dispersal in a rural African setting typical of many parts of the continent. However, dispersal will be landscape specific and in order to generalise to other spatial configurations of habitat and hosts it will be necessary to produce tractable models of mosquito movements for operational use. We show that simple random walk models have potential. Consequently, there is a pressing need for new empirical studies of An. gambiae survival and movements in different settings to drive this development.
References
[1]
Bomblies A, Duchemin J-, Eltahir EAB (2009) A mechanistic approach for accurate simulation of village scale malaria transmission. Malar J 8: 223–234.
[2]
Carter R, Mendis KN, Roberts D (2000) Spatial targeting of interventions against malaria. Bull World Health Organ 78: 1401–1411.
[3]
Killeen GF, Knols BGJ, Gu WD (2003) Taking malaria transmission out of the bottle: implications of mosquito dispersal for vector-control interventions. Lancet Infect Dis 3: 297–303.
[4]
Ferguson HM, Dornhaus A, Beeche A, Borgemeister C, Gottlieb M, et al. (2010) Ecology: A prerequisite for malaria elimination and eradication. PLoS Med 7: 1–7.
[5]
Gillies MT, de Meillon B (1968) The Anophelinae of Africa South of the Sahara (Ethiopian zoogeographical region). Johannesburg: The South African Institute for Medical Research.
[6]
Service MW (1997) Mosquito (Diptera: Culcidae) dispersal - The long and short of it. J Med Entomol 36: 579–588.
[7]
B?gh C, Lindsay SW, Clarke SE, Dean A, Jawara M, et al. (2007) High spatial resolution mapping of malaria transmission risk in the Gambia, west Africa, using LANDSAT TM satellite imagery. Am J Trop Med Hyg 76: 875–881.
[8]
Paradis E, Baillie SR, Sutherland WJ (2002) Modeling large-scale dispersal distances. Ecol Modell 151: 279–292.
[9]
Costantini C, Li SG, DellaTorre A, Sagnon N, Coluzzi M, et al. (1996) Density, survival and dispersal of Anopheles gambiae complex mosquitoes in a West African Sudan savanna village. Med Vet Entomol 10: 203–219.
[10]
Takken W, Charlwood JD, Billingsley PF, Gort G (1998) Dispersal and survival of Anopheles funestus and A. gambiae s.l. (Diptera: Culicidae) during the rainy season in southeast Tanzania. Bull Entomol Res 88: 561–566.
[11]
Thomson MC, Connor SJ, Quinones ML, Jawara M, Todd J, et al. (1995) Movement of Anopheles gambiae s.l. malaria vectors between villages in The Gambia. Med Vet Entomol 9: 413–419.
[12]
Conrad KF, Willson KH, Harvey IF, Thomas CJ, Sherratt TN (1999) Dispersal characteristics of seven odonate species in an agricultural landscape. Ecography 22: 524–531.
[13]
Shaw MW (1995) Simulation of Population Expansion and Spatial Pattern When Individual Dispersal Distributions Do Not Decline Exponentially with Distance. Proc Biol Sci 259: 243–248.
[14]
Studds CE, McFarland KP, Aubry Y, Rimmer CC, Hobson KA, et al. (2012) Stable-hydrogen isotope measures of natal dispersal reflect observed population declines in a threatened migratory songbird. Diversity and Distributions 18: 919–930.
[15]
Tackenberg O (2003) Modeling long-distance dispersal of plant diaspores by wind. Ecol Monogr 73: 173–189.
[16]
Lutambi AM, Penny MA, Smith T, Chitnis N (2013) Mathematical modelling of mosquito dispersal in a heterogeneous environment. Math Biosci 241: 198–216.
[17]
Bartumeus F, da Luz MGE, Viswanathan GM, Catalan J (2005) Animal search strategies: a quantitative random-walk analysis. Ecology 86: 3078–3087.
[18]
Midega JT, Smith DL, Olotu A, Mwangangi JM, Nzovu JG, et al. (2012) Wind direction and proximity to larval sites determines malaria risk in Kilifi District in Kenya. Nat Commun 3: 674.
[19]
Yakob L, Yan G (2010) A network population model of the dynamics and control of African malaria vectors. Trans R Soc Trop Med Hyg 104: 669–675.
[20]
Thomas CJ, Lindsay SW (2000) Local-scale variation in malaria infection amongst rural Gambian children estimated by satellite remote sensing. Trans R Soc Trop Med Hyg 94: 159–163.
[21]
B?gh C, Clarke SE, Jawara M, Thomas CJ, Lindsay SW (2003) Localised breeding of Anopheles gambiae complex mosquitoes along the River Gambia, West Africa. Bull Entomol Res 93: 279–287.
[22]
Majambere S, Fillinger U, Sayer DR, Green C, Lindsay SW (2008) Spatial distribution of mosquito larvae and the potential for targeted larval control in The Gambia. Am J Trop Med Hyg 79: 19–27.
[23]
Fillinger U, Sombroek H, Majambere S, van Loon E, Takken W, et al. (2009) Identifying the most productive breeding sites for malaria mosquitoes in The Gambia. Malar J 8: 62.
[24]
Gillies MT, Wilkes TJ (1972) The range of attraction of animal baits and carbon dioxide for mosquitoes. Studies in a freshwater area of West Africa. Bull Entom Res 61: 389–404.
[25]
Cummins B, Cortez R, Foppa IM, Walbeck J, Hyman JM (2012) A spatial model of mosquito host-seeking behavior. PLoS Comput Biol 8: e1002500.
[26]
Gillies MT (1961) Studies on the dispersion and survival of Anopheles gambiae Giles in East Africa, by means of marking and release experiments. Bull Entomol Res 52: 99–127.
[27]
Reiter P, Amador M, Anderson R, Clark G (1995) Short Report: Dispersal Of Aedes aegypti In An Urban Area After Blood Feeding As Demonstrated By Rubidium-Marked Eggs. Am J Trop Med Hyg 52: 177–179.
[28]
Midega JT, Mbogo CM, Mwambi H, Wilson MD, Ojwang G, et al. (2007) Estimating dispersal and survival of Anopheles gambiae and Anopheles funestus along the Kenyan Coast by using mark-release-recapture methods. J Med Entomol 44: 923.
[29]
Lindsay SW, Alonso PL, Armstrong SJ, Hemingway J, Thomas PJ, et al. (1993) A malaria control trial using insecticide-treated bed nets and targeted chemoprophylaxis in a rural area of The Gambia, West Africa. 3. Entomological characteristics of the study area. Trans R Soc Trop Med Hyg 87: 19–23.
[30]
Directorate of Overseas Surveys, UK (1975) Map: The Gambia, 4th edition. Banjul, The Gambia.
[31]
Snow WF, Milligan PJM (1999) Land use changes in relation to tsetse distribution. Unpublished report NRI R6434.
[32]
Marks M, Adams S (1992) Aerial photo interpretation in The Gambia. USAID/IRG Washington.
[33]
Rangel TF, Diniz-Filho JAF, Bini LM (2010) SAM: a comprehensive application for Spatial Analysis in Macroecology. Ecography 33: 46–50.
[34]
Burnham KP, Anderson DR, Burnham KPMSAI (2002) Model selection and multimodel inference: a practical information-theoretic approach. New York: Springer.
[35]
Estep LK, Burkett-Cadena ND, Hill GE, Unnasch RS, Unnasch TR (2010) Estimation of dispersal distances of Culex erraticus in a focus of Eastern Equine Encephalitis Virus in the Southeastern United States. J Med Entomol 47: 977–986.
[36]
Honório NA, Castro MG, Barros FSM, Magalh?es MAFM, Sabroza PC (2009) The spatial distribution of Aedes aegypti and Aedes albopictus in a transition zone, Rio de Janeiro, Brazil. Cadernos de Saúde Pública 25: 1203–1214.
[37]
Meats A, Smallridge CJ (2007) Short- and long-range dispersal of medfly, Ceratitis capitata (Dipt., Tephritidae), and its invasive potential. J Appl Entomol 131: 518–523.
[38]
Service MW (1993) Mosquito Ecology: Field sampling methods. London: Elsevier Applied Science.
[39]
Ray N, Lehmann A, Joly P (2002) Modeling spatial distribution of amphibian populations: a GIS approach based on habitat matrix permeability. Biodivers Conserv 11: 2143–2165.
[40]
Gillies MT, Wilkes TJ (1978) The effect of high fences on the dispersal of some West African mosquitoes (Diptera: Culicidae). Bull. Entomol. Res 68: 401–408.
[41]
Smith T, Charlwood JD, Takken W, Tanner M, Speigelhalter DJ (1995) Mapping the densities of malaria vectors within a single village. Acta Trop 59: 1–18.
[42]
Russell TL, Lwetoijera DW, Knols BG, Takken W, Killeen GF, et al. (2013) Geographic coincidence of increased malaria transmission hazard and vulnerability occurring at the periphery of two Tanzanian villages. Malar J 12: 24.
[43]
Lindsay SW, Armstrong JRM, Schellenberg J, Zeiler HA, Daly RJ, et al. (1995) Exposure to Gambian Children to Anopheles gambiae Malaria Vectors in an Irrigated Rice Production Area. Med Vet Entomol 9: 50–58.
[44]
Garrett-Jones C (1950) A dispersion of mosquitoes by wind. Nature 4190: 285.
[45]
Kay BH, Farrow RA (2000) Mosquito (Diptera: Culcidae) dispersal: Implications for the epidemiology of Japanese and Murray Valley encephalitis viruses in Australia. J Med Entomol37: 797–801.
[46]
Gillies MT (1988) Anopheline mosquitoes: vector behaviour and bionomics. In: Wernsdofer WH&MI, editors. Malaria: principles and practice of malariology. Edinburgh: Churchill Livingstone.
[47]
Taylor C, Touré YT, Carnahan J, Norris DE, Dolo G, et al. (2001) Gene flow among populations of the malaria vector, Anopheles gambiae, in Mali, West Africa. Genetics 157: 743–750.
[48]
De Silva PM, Marshall JM (2012) Factors contributing to urban malaria transmission in sub-Saharan Africa: a systematic review. J Trop Med 2012: 819563.
[49]
Machault V, Gadiaga L, Vignolles C, Jarjaval F, Bouzid S, et al. (2009) Highly focused anopheline breeding sites and malaria transmission in Dakar. Malar J 8: 138.
[50]
Trape J-F, Lefebvre-Zante E, Legros F, Ndiaye G, Bouganali H, et al. (1992) Vector density gradients and the epidemiology of urban malaria in Dakar, Senegal. Am J Trop Med Hyg 47: 181–189.
[51]
Balls MJ, Bodker R, Thomas CJ, Kisinza W, Msangeni HA, et al. (2004) Effect of topography on the risk of malaria infection in the Usambara Mountains, Tanzania. Trans R Soc Trop Med Hyg 98: 400–408.
[52]
Smith MW, Macklin MG, Thomas CJ (2013) Hydrological and geomorphological controls of malaria transmission. Earth-Science Reviews 116: 109–127.
[53]
Bryan JH, Foley DH, Geary M, Carven CTJ (1991) Anopheles annulipes Walker (Diptera, Culicidae) at Griffith, New South Wales. 3. Dispersal of Two Sibling Species. Aust J Entomol 30: 119–121.
[54]
Baber I, Keita M, Sogoba N, Konate M, Diallo M, et al. (2010) Population size and migration of Anopheles gambiae in the Bancoumana Region of Mali and their significance for efficient vector control. PLoS One 5: e10270.
[55]
Zhou G, Githeko AK, Minakawa N, Yan G (2010) Community-wide benefits of targeted indoor residual spray for malaria control in the western Kenya highland. Malar J 9: 67.
[56]
Lacroix R, McKemey AR, Raduan N, Kwee Wee L, Hong Ming W, et al. (2012) Open field release of genetically engineered sterile male Aedes aegypti in Malaysia. PLoS One 7: e42771.
[57]
Gu W, Regens JL, Beier JC, Novak RJ (2006) Source reduction of mosquito larval habitats has unexpected consequences on malaria transmission. Proc Natl Acad Sci U S A 103: 17560–17563.
[58]
Charlwood JD, Mendis C, Thompson R, Begtrup K, Cuamba N, et al. (1998) Cordon Sanitaire or Laissez Faire: differential dispersal of young and old females of the malaria vector Anopheles funestus Giles (Diptera: Culicidae) in southern Mozambique. Afr Entomol 6: 1–6.
[59]
Utzinger J, Tanner M, Kammen DM, Killeen GF, Singer BH (2002) Integrated programme is key to malaria control. Nature 419: 431.
[60]
Fillinger U, Lindsay SW (2011) Larval source management for malaria control in Africa: myths and reality. Malar J 10: 353.
[61]
Kweka EJ, Zhou G, Munga S, Lee MC, Atieli HE, et al. (2012) Anopheline larval habitats seasonality and species distribution: a prerequisite for effective targeted larval habitats control programmes. PLoS One 7: e52084.
[62]
Hamer GL, Donovan DJ, Hood-Nowotny R, Kaufman MG, Goldberg TL, et al. (2012) Evaluation of a stable isotope method to mark naturally-breeding larval mosquitoes for adult dispersal studies. J Med Entomol 49(1): 61–70.
