Your search keyword '"Coetzer Nanette"' showing total 2 results

1. DDT and pyrethroid resistance in Anopheles arabiensis from South Africa.

Author

Nardini L, Christian RN, Coetzer N, and Koekemoer LL

Subjects

Animals, Anopheles enzymology, Anopheles genetics, Cytochrome P-450 Enzyme System genetics, Glutathione Transferase genetics, Humans, Insect Proteins genetics, Insect Vectors drug effects, Insect Vectors enzymology, Insect Vectors genetics, Malaria transmission, South Africa, Anopheles drug effects, DDT toxicity, Insecticide Resistance, Insecticides toxicity, Pyrethrins toxicity

Abstract

Background: Pyrethroid resistance has been well documented in Anopheles arabiensis, one of the major African malaria vectors, and the predominant malaria vector in South Africa., Methods: In this study, the genetic basis of pyrethroid resistance in a selected laboratory strain of An. arabiensis from South Africa was investigated using a custom-made microarray, known as the An. gambiae detoxification chip., Results: A large number of P450 genes were over-transcribed, as well as a suite of redox genes and glutathione S-transferases. The five genes that showed the highest level of gene transcription when compared with an insecticide susceptible strain were: CYP6AG2, CYPZ1, TPX2, CYPZ2 and CYP6P1., Conclusions: Permethrin resistance in South African An. arabiensis is associated with increased transcription of multiple genes, and a large proportion of these genes were also previously recorded as over-transcribed in another An. arabiensis strain selected for resistance to DDT with cross-resistance to deltamethrin. The deltamethrin resistance developed de novo in the DDT-selected strain and is most likely due to increased transcription of those genes associated with DDT resistance. However, of particular interest was the fact that the strain selected for resistance to pyrethroids did not develop de novo resistance to DDT. These differences are compared and discussed.

Published

2013

2. Detoxification enzymes associated with insecticide resistance in laboratory strains of Anopheles arabiensis of different geographic origin.

Author

Nardini L, Christian RN, Coetzer N, Ranson H, Coetzee M, and Koekemoer LL

Subjects

Animals, Demography, Female, Male, Mosquito Control, Pesticide Synergists pharmacology, Real-Time Polymerase Chain Reaction, Anopheles drug effects, Anopheles enzymology, DDT pharmacology, Insecticide Resistance, Insecticides pharmacology, Pyrethrins pharmacology

Abstract

Background: The use of insecticides to control malaria vectors is essential to reduce the prevalence of malaria and as a result, the development of insecticide resistance in vector populations is of major concern. Anopheles arabiensis is one of the main African malaria vectors and insecticide resistance in this species has been reported in a number of countries. The aim of this study was to investigate the detoxification enzymes that are involved in An. arabiensis resistance to DDT and pyrethroids., Methods: The detoxification enzyme profiles were compared between two DDT selected, insecticide resistant strains of An. arabiensis, one from South Africa and one from Sudan, using the An. gambiae detoxification chip, a boutique microarray based on the major classes of enzymes associated with metabolism and detoxification of insecticides. Synergist assays were performed in order to clarify the roles of over-transcribed detoxification genes in the observed resistance phenotypes. In addition, the presence of kdr mutations in the colonies under investigation was determined., Results: The microarray data identifies several genes over-transcribed in the insecticide selected South African strain, while in the Sudanese population, only one gene, CYP9L1, was found to be over-transcribed. The outcome of the synergist experiments indicate that the over-transcription of detoxification enzymes is linked to deltamethrin resistance, while DDT and permethrin resistance are mainly associated with the presence of the L1014F kdr mutation., Conclusions: These data emphasise the complexity associated with resistance phenotypes and suggest that specific insecticide resistance mechanisms cannot be extrapolated to different vector populations of the same species.

Published

2012