Abstract
The influence of landscape structure on anopheline mosquito density and diversity was studied in a comparison of agricultural and forested landscapes in northern Thailand. Agriculture locations had significantly higher landscape diversity, more patches, smaller mean patch sizes, and more complex patch shapes than forest locations. Mosquito collections were undertaken during both dry and wet seasons from October 1997 to December 1999. The density of two forest-associated species, Anopheles maculatus s.s. and Anopheles minimus s.l., both primary malaria vectors in Thailand, was significantly higher in forest locations in at least one season. The density of two paddy field-associated species, Anopheles aconitus and Anopheles hyrcanus group did not differ between locations. Anopheles aconitus is a secondary malaria vector and An. hyrcanus group is not considered as a vector in Thailand. The density of An. minimus s.l. was positively related to forest mean patch size, various water and paddy field landscape metrics and negatively related to landscape diversity. Anopheles hyrcanus group was also positively related to water metrics. Anopheline species diversity was negatively related to landscape diversity. Forest fragmentation resulting from human economic activities often increases landscape heterogeneity, which may result in a reduction in anopheline species diversity, as was the case in this study. There are indications that the effect of fruit orchards on anopheline diversity might be different in the dry season compared to the wet season. Fruit orchard landscape metrics affected species diversity negatively in the dry season and positively in the wet season. One reason for this could be that pesticides are typically applied in fruit orchards during the dry season. The conversion of forests to fruit orchards is a major land-use change in northern Thailand. These results show the complexity of vector status in northern Thailand and that vector and agriculture pest control are intricately interrelated. It is therefore important to include both the public health and agricultural sectors in controlling malaria vectors in the country. Our results also indicate that if landscape management should be used for malaria control in northern Thailand large-scale reduction and fragmentation of forest cover would be needed. Such drastic actions do not agree well with current global objectives concerning forest and biodiversity conservation
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ault S.K. 1994. Environmental management: a re-emerging vector control strategy. American Journal of Tropical Medicine and Hygiene 50 Suppl.: 35–59.
Baimai V., Rattanarithikul R. and Kijchalao U. 1993. Metaphase karyotypes of Anopheles of Thailand and Southeast Asia: I. The Hyrcanus Group. Journal of the American Mosquito Control Association 9: 59–67.
Beck L.R., Rodriguez M.H., Dister S.W., Rodriguez A.D., Rejmankova E., Ulloa A., Meza R.A., Roberts D.R., Paris J.F., Spanner M., Washino R.K., Hacker C. and Legters L.J. 1994. Remote sensing as a landscape epidemiological tool to identify villages at high risk for malaria transmission. American Journal of Tropical Medicine and Hygiene 51: 271–280.
Bruce-Chwatt L.J. 1985. Essential malariology. William Heinemann, London.
Bunge J. and Fitzpatrick M. 1993. Estimating the number of species: a review. Journal of the American Statistical Association 88: 364–373.
Butraporn P., Sornmani S. and Hungsapruek T. 1986. Social, behavioural, housing factors and their interactive effects associated with malaria occurrence in east Thailand. Southeast Asian Journal of Tropical Medicine and Public Health 17: 386–92.
Chao A. 1984. Non-parametric estimation of the number of classes in a population. Scandinavian Journal of Statistics 11: 265–270.
Didham R.K., Ghazoul J., Stork N.E. and Davis A.J. 1996. Insects in fragmented forests: a functional approach. Tree 11: 255–260.
Dunning J.B., Danielson B.J. and Pulliam H.R. 1992. Ecological processes that affect populations in complex landscapes. Oikos 65: 169–175.
Easton E.R. 1994. Urbanization and its effect on the ecology of mosquitoes in Macau, Southeast Asia. Journal of the American Mosquito Control Association 10: 540–544.
Eyles D.E., Wharton R.H., Cheong W.H. and McWilson W. 1964. Studies on malaria and Anopheles balabacensis in Cambodia. Bulletin of the World Health Organization 30: 7–21.
FAO. 1999. State of the World's Forests 1999. Food and Agriculture Organization, Rome, Italy.
Garcia R. and Huffaker C.B. 1979. Ecosystem management for suppression of vectors of human malaria and schistosomiasis. Agro-Ecosystems 5: 295–315.
Gibbs J.P. and Stanton E.J. 2001. Habitat fragmentation and arthropod community change: carrion beetles, phoretic mites, and flies. Ecological Applications 11: 79–85.
Gingrich J.B., Weatherhead A., Sattabongkot J., Pilakasiri C., and Wirtz R.A. 1990. Hyperendemic malaria in a Thai village: dependence of year-round transmission on focal and seasonally circumscribed mosquito (Diptera: Culicidae) habitats. Journal of Medical Entomology 27: 1016–1026.
Gould D.J., Esah S. and Pranith U. 1967. Relation of Anopheles aconitus to malaria transmission in the central plain of Thailand. Transactions of the Royal Society for Tropical Medicine and Hygiene 61: 441–442.
Green C.A., Baimai V., Harrison B.A. and Andre R.G. 1985. Cytogenetic evidence for a complex of species within the taxon Anopheles maculatus (Diptera: Culicidae). Biological Journal of the Linnean Society 4: 321–328.
Green C.A., Gass R.F., Munstermann L.E. and Baimai V. 1990. Population-genetic evidence for two species in Anopheles minimus in Thailand. Medical Veterinary Entomology 4: 25–34.
Harbach R.E., Gingrich J.B. and Pang L.W. 1987. Some entomological observations on malaria transmission in a remote village in northwestern Thailand. Journal of the American Mosquito Control Association 3: 296–301.
Harrison B.A. 1980. Medical entomology studies XIII. The Myzomyia series of Anopheles (Cellia) in Thailand, with emphasis on intra-interspecific variation (Diptera:Culicidae). Contributions to the American Entomological Institute 17: 1–195.
Harrison B.A. and Scanlon J.E. 1975. Medical entomology studies II. The subgenus Anopheles in Thailand (Diptera: Culicidae). Contributions to the American Entomological Institute 12: 1–307.
Harrison B.A., Rattanarithikul R., Peyton E.L. and Mongkolpanya K. 1990. Taxonomic changes, revised occurence records and notes on the Culicidae of Thailand and neighbouring countries. Mosquito Systematics 22: 196–227.
Hii J.L.K., Smith T., Mai A., Mellor S., Lewis D., Alexander N., and Alpers M.P. 1997. Spatial and temporal variation in abundance of Anopheles (Diptera: Culicidae) in a malaria endemic area in Papua New Guinea. Journal of Medical Entomology 34: 193–205.
Ho C., Chou T.C. Ch'en T.H. and Hsueh A.T. 1962. The Anopheles hyrcanus group and its relation to malaria in east China. Chinese Medical Journal 81: 71–78.
Hoover S.R. and Parker A.J. 1991. Spatial components of biotic diversity in landscapes of Georgia, USA. Landscape Ecology 5: 125–136.
Ismail I.A., Notananda V. and Schepens J. 1975. Studies on malaria and responses of Anopheles balabacensis balabacensis and Anopheles minimus to DDT residual spraying in Thailand. Acta Tropica 32: 206–31.
Ismail I.A.H., Phinichpongse S. and Boonrasri P. 1978. Responses of Anopheles minimus to DDT residual spraying in a cleared forested foot hill area in central. Acta Tropica 35: 69–82.
Jonsen I. D. and Fahrig L. 1997. Response of generalist and specialist insect herbivores to landscape spatial structure. Landscape Ecology 12: 185–197.
Kitron U. 1987. Malaria, agriculture, and development: lessons from past campaigns. International Journal of Health Services 17: 295–326.
Klein B.C. 1989. Effects of forest fragmentation on dung and carrion beetle communities in central Amazonia. Ecology 70: 1715–1725.
Lwin M. and Htut Y. 1991. Study of the malaria situation in forested foothill and nearby plain areas of Myanmar. Southeast Asian Journal of Tropical Medicine and Public Health 22: 509–514.
Maheswary N.P., Habib M.A. and Elias M. 1992. Incrimination of Anopheles aconitus Dönitz as a vector of epidemic malaria in Bangladesh. Southeast Asian Journal of Tropical Medicine and Public Health 23: 798–801.
Malaria Division. 1998. Annual report of Ministry of Public Health. Ministry of Public Health, Thai Government, Bangkok, Thailand.
Martens M., Martens H. and Wold S. 1983. Preference of cauliflower related to sensory descriptive variables by Partial Least Squares (PLS) regression. Journal of the Science of Food and Agriculture 34: 715–724.
McGarigal K. and Marks B.J. 1995. FRAGSTATS: spatial pattern analysis for quantifying landscape structure. General Technical Report PNW-GTR-351. US Department of Agriculture, Forest Service, Pacific Northwest Research Station, Portland, Oregon, USA.
Meteorological Department. 1999. Yearly Records, January 1977-1999 (21 issues). Meteorological Department, Climatology Division, Bangkok, Thailand.
Muirhead Thomson R.C. 1940. Studies on the behaviour of Anopheles minimus. Journal of the Malaria Institute of India 3: 265–325.
Myo P., Tun Lin W. and Sebastian A.A. 1988. Behaviour of Anopheles minimus (Theobald) in relation to its role as vector of malaria in a forested foothill area of Burma. Tropical Biomedicine 5: 161–166.
Overgaard H.J., Tsuda Y., Suwonkerd W. and Takagi M. 2002. Characteristics of Anopheles minimus Theobald (Diptera: Culicidae) larval habitats in northern Thailand. Environmental Entomology 31: 134–141.
Peyton E.L. and Harrison B.A. 1979. Anopheles (Cellia) dirus, a new species of the Leucophyrus Group from Thailand (Diptera: Culicidae). Mosquito Systematics 11: 40–52.
Peyton E.L. and Scanlon J.E. 1966. Illustrated key to the female Anopheles mosquitoes of Thailand. U.S. Army Medical Component, South East Asia Treaty Organization, Bangkok, Thailand.
Poolsuwan S. 1995. Malaria in prehistoric southeastern Asia. Southeast Asian Journal of Tropical Medicine and Public Health 26: 3–22.
Prakash A., Bhattacharyya D.R., Mohapatra P.K. and Mahanta J. 1997. Breeding and day resting habitats of Anopheles dirus in Assam, India. Southeast Asian Journal of Tropical Medicine and Public Health 28: 610–614.
Preston F.W. 1948. The commonness and rarity of species. Ecology 29: 254–283.
Rao T.R. 1984. The Anophelines of India. Indian Council of Medical Research, New Dehli, India.
Rattanarithikul R. and Green C.A. 1986. Formal recognition of the species of the Anopheles maculatus group (Diptera:Culicidae) occurring in Thailand, including the descriptions of two new species and a preliminary key to females. Mosquito Systematics 18: 246–278.
Rattanarithikul R. and Harrison B.A. 1973. An illustrated key to the Anopheles larvae of Thailand. U.S. Army Medical Component, South East Asia Treaty Organization, Bangkok, Thailand.
Rattanarithikul R. and Panthusiri P. 1994. Illustrated keys to the medical important mosquitos of Thailand. Southeast Asian Journal of Tropical Medicine and Public Health 25: 1–66.
Reid J.A. 1968. Anopheline mosquitoes of Malaya and Borneo. Studies of the Institute of Medical Research Malaysia 31: 1–520.
Rodriguez A.D., Rodriguez M.H., Hernandez J.E., Dister S.W., Beck L.R., Rejmankova E. and Roberts D.R. 1996. Landscape surrounding human settlements and Anopheles albimanus (Diptera: Culicidae) abundance in southern Chiapas, Mexico. Journal of Medical Entomology 33: 39–48.
Rosenberg R., Andre R.G. and Somchit L. 1990. Highly efficient dry season transmission of malaria in Thailand. Transactions of the Royal Society for Tropical Medicine and Hygiene 84: 22–28.
SAS. 1996. SAS/STAT: user's guide, version 6th ed. SAS Institute, Cary, North Carolina, USA.
Sawadwongporn P. 1972. Pictorial key of Anopheles in Thailand. Malaria Center Region 2, Thai Government, Chiang Mai, Thailand.
Singhanetra-Renard A. 1993. Malaria and mobility in Thailand. Social Science and Medicine 37: 1147-1154.
Singhasivanon P., Thimasarn K., Yimsamran S., Linthicum K., Nualchawee K., Dawreang D., Kongrod S., Premmanisakul N., Maneeboonyang W. and Salazar N. 1999. Malaria in tree crop plantations in south-eastern and western provinces of Thailand. Southeast Asian Journal of Tropical Medicine and Public Health 30: 399–404.
Smith T., Charlwood J.D., Takken W., Tanner M. and Spiegelhalter D.J. 1995. Mapping the densities of malaria vectors within a single village. Acta Tropica 59: 1–18.
Somboon P., Aramrattana A., Lines J. and Webber R. 1998. Entomological and epidemiological investigations of malaria transmission in relation to population movements in forest areas of north-west Thailand. Southeast Asian Journal of Tropical Medicine and Public Health 29: 3–9.
Suwonkerd W., Overgaard H.J., Tsuda Y., Prajakwong S. and Takagi M. 2002. Malaria vector densities in transmission and non-transmission areas during 23 years and land use in Chiang Mai province, Northern Thailand. Basic and Applied Ecology 3: 197–207.
Takagi M., Suwonkerd W., Tsuda Y., Kamboonruang C., Chipralop U., Nakazawa S., Kanbara H. and Wada Y. 1995. Seasonal density and malaria vector competence of Anopheles minimus and other anophelines at a shallow valley in north Thailand. Japanese Journal of Tropical Medicine and Hygiene 23: 177–182.
Thies C. and Tscharntke T. 1999. Landscape structure and biological control in agroecosystems. Science 285: 893–5.
Thomson M.C., Connor S.J., Milligan P.J. and Flasse S.P. 1996. The ecology of malaria-as seen from Earth-observation satellites. Annual Tropical Medicine and Parasitology 90: 243–64.
Turner M.G. 1989. Landscape ecology: the effect of pattern on process. Annual Review of Ecology and Systematics 20: 171–197.
Turner M.G. and Gardner R.H. (eds), 1990. Quantitative methods in landscape ecology: the analysis and interpretation of landscape heterogeneity. Ecological Studies Series Volume 82.
Umetri. 1994. User's guide to Simca-S, version 5.1. Umetri AB, Umeå, Sweden.
Upatham E. S., Prasittisuk C., Ratanatham S., Green C.A., Rojanasunan W., Setakana P., Therasilp N., Tremongkol A., Vryanant V., Pantuwatana S., and Andre R.G. 1988. Bionomics of Anopheles maculatus complex and their role in malaria transmission in Thailand. Southeast Asian Journal of Tropical Medicine and Public Health 19: 259–269.
Wehner R. 2000. Ecological effects of herbicide use on the weed flora in lychee orchards in the highlands of northern Thailand. M.S. thesis in Biology. Institut für Landschafts-und Planzenökologie, Universität Hohenheim, Stuttgart, Germany.
Weibull A-C., Bengtsson J. and Nohlgren E. 2000. Diversity of butterflies in the agricultural landscape: the role of farming system and landscape heterogeneity. Ecography 23: 743–750.
WHO. 1975. Manual on Practical Entomology in Malaria, Part II. World Health Organisation, Geneva, Switzerland.
Wiens J.A. 1976. Population response to patchy environments. Annual Review of Ecology and Systematics 7: 81–129.
Wilkinson R.N., Gould D.J., Boonyakanist P. and Segal H.E. 1978. Observations on Anopheles balabacensis (Diptera: Culicidae) in Thailand. Journal of Medical Entomology 14: 666–671.
Wold H. 1984. PLS regression. Encyclopedia of Statistical Sciences 6: 581–591.
Wood B.L., Beck L., Washino R.K., Hibbard K.A. and Salute J. 1992. Estimating high and mosquito-producing rice using spectral and spatial data. International Journal of Remote Sensing 13: 2813–2826.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Overgaard, H.J., Ekbom, B., Suwonkerd, W. et al. Effect of landscape structure on anopheline mosquito density and diversity in northern Thailand: Implications for malaria transmission and control. Landscape Ecology 18, 605–619 (2003). https://doi.org/10.1023/A:1026074910038
Issue Date:
DOI: https://doi.org/10.1023/A:1026074910038