Influence of environmental characteristics on the habitat of and behavioural interactions between anopheles species in South Africa

Date
2016
Authors
Davies, Craig
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Abstract
This project explored the ecological conditions of aquatic breeding sites of Anopheles gambiae sensu lato immatures in the Lowveld region of eastern Mpumalanga Province, South Africa. The aim was to determine the environmental conditions influencing anopheline abundance as well as abiotic parameters which associated with vector productivity. In addition to this, the levels of insecticide resistance to the three dominant compounds used in vector control in the region were assessed. Taking into account the sympatric occurrence of the major malaria vector in South Africa (An. arabiensis Patton) and its sibling, non-vector species (An. quadriannulatus Theobald), a laboratory study was devised which investigated the outcome of intra- and inter-specific competition under constant and fluctuating temperature regimes. There was a heterogenous distribution of anophelines across aquatic habitats in Mpumalanga with small-scale variation in salinity and Total Dissolved Solids (TDS) influencing species composition and Anopheles arabiensis was found in all sites surveyed with low numbers occurring where salinity levels were elevated. Anopheles merus associated with high salinity and TDS (Pearson’s Product Moment, r = 0.922, p < 0.05) whilst An. quadriannulatus dominated in breeding sites within 50m of a building or road. Anopheles gambiae complex members were susceptible to the insecticides tested with possible resistance (97%) to DDT in An. merus. Under laboratory conditions, temperature and competitive scenarios affected the life-history traits of both species studied here. The treatment 18 - 35°C generally reduced survivorship except for An. arabiensis in mixed, larval species treatments where it was similar to values reported for 25°C. Survivorship of both species at 20 - 30°C was not significantly impacted and the adult production was high across species treatments. The development rates at 25°C and 20 - 30°C were significantly different between species when reared alone and in mixed species treatments from larvae and from eggs. The effect of temperature was more pronounced at 18 - 35°C with An. arabiensis developing faster under both competitive scenarios and An. quadriannulatus slower, notably when in the presence of its competitor (p < 0.05). In the field component of this study, Anopheles arabiensis exploited all the habitats surveyed. It is therefore recommended that larval control operations should include all available breeding sites, focusing efforts during the dry season when these sites are limited and discreet within the landscape. In the laboratory component, it was possible to test whether or not community composition of anophelines at the adult stage was regulated by different temperature and competitive conditions at the larval stage to better understand the ecological conditions that determine anopheline composition and relative abundance. Taken together, the results of each component emphasize the need for local scale studies, especially under conditions of changing temperatures and rainfall patterns. The results of responses to temperatures and biotic interactions are necessary data for use in models predicting the impact of climate change on malaria vector mosquitoes.
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A dissertation submitted to the Faculty of Health Sciences, University of the Witwatersrand, South Africa in fulfilment of the requirements for the degree of Master of Science. 2016
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