Your search keyword '"Barnes, Kayla G."' showing total 3 results

1. Identification and functional validation of the novel antimalarial resistance locus PF10_0355 in Plasmodium falciparum.

Author

Van Tyne D, Park DJ, Schaffner SF, Neafsey DE, Angelino E, Cortese JF, Barnes KG, Rosen DM, Lukens AK, Daniels RF, Milner DA Jr, Johnson CA, Shlyakhter I, Grossman SR, Becker JS, Yamins D, Karlsson EK, Ndiaye D, Sarr O, Mboup S, Happi C, Furlotte NA, Eskin E, Kang HM, Hartl DL, Birren BW, Wiegand RC, Lander ES, Wirth DF, Volkman SK, and Sabeti PC

Subjects

Ethanolamines pharmacology, Fluorenes pharmacology, Gene Dosage, Gene Expression, Genetic Association Studies, Genetic Variation, Genotype, Haplotypes, Linkage Disequilibrium, Lumefantrine, Malaria, Falciparum parasitology, Malaria, Falciparum prevention & control, Mefloquine pharmacology, Phenanthrenes pharmacology, Plasmodium falciparum drug effects, Polymorphism, Single Nucleotide, Selection, Genetic, Antimalarials pharmacology, Drug Resistance genetics, Genetic Loci, Plasmodium falciparum genetics

Abstract

The Plasmodium falciparum parasite's ability to adapt to environmental pressures, such as the human immune system and antimalarial drugs, makes malaria an enduring burden to public health. Understanding the genetic basis of these adaptations is critical to intervening successfully against malaria. To that end, we created a high-density genotyping array that assays over 17,000 single nucleotide polymorphisms (∼ 1 SNP/kb), and applied it to 57 culture-adapted parasites from three continents. We characterized genome-wide genetic diversity within and between populations and identified numerous loci with signals of natural selection, suggesting their role in recent adaptation. In addition, we performed a genome-wide association study (GWAS), searching for loci correlated with resistance to thirteen antimalarials; we detected both known and novel resistance loci, including a new halofantrine resistance locus, PF10_0355. Through functional testing we demonstrated that PF10_0355 overexpression decreases sensitivity to halofantrine, mefloquine, and lumefantrine, but not to structurally unrelated antimalarials, and that increased gene copy number mediates resistance. Our GWAS and follow-on functional validation demonstrate the potential of genome-wide studies to elucidate functionally important loci in the malaria parasite genome., Competing Interests: The authors have declared that no competing interests exist.

Published

2011

2. Genomic Footprints of Selective Sweeps from Metabolic Resistance to Pyrethroids in African Malaria Vectors Are Driven by Scale up of Insecticide-Based Vector Control

Author

Barnes, Kayla G., Weedall, Gareth D., Ndula, Miranda, Irving, Helen, Mzihalowa, Themba, Hemingway, Janet, and Wondji, Charles S.

Subjects

Malawi, Insecticides, Heredity, Epidemiology, Disease Vectors, Mosquitoes, Geographical Locations, Insecticide Resistance, Cytochrome P-450 Enzyme System, Pyrethrins, Medicine and Health Sciences, qu_460, Mozambique, Phylogeny, Agriculture, Genomics, Insects, Genetic Mapping, Insect Proteins, Agrochemicals, Research Article, RM, Arthropoda, lcsh:QH426-470, Quantitative Trait Loci, wc_765, Host-Parasite Interactions, Sequence Homology, Nucleic Acid, qx_600, Anopheles, parasitic diseases, Genetics, Animals, Humans, Selection, Genetic, Evolutionary Biology, Population Biology, Base Sequence, Models, Genetic, Organisms, wa_240, Biology and Life Sciences, Genetic Variation, R1, Invertebrates, wc_750, Insect Vectors, Malaria, lcsh:Genetics, qx_650, Haplotypes, Genetic Loci, People and Places, Africa, Population Genetics, Microsatellite Repeats

Abstract

Insecticide resistance in mosquito populations threatens recent successes in malaria prevention. Elucidating patterns of genetic structure in malaria vectors to predict the speed and direction of the spread of resistance is essential to get ahead of the ‘resistance curve’ and to avert a public health catastrophe. Here, applying a combination of microsatellite analysis, whole genome sequencing and targeted sequencing of a resistance locus, we elucidated the continent-wide population structure of a major African malaria vector, Anopheles funestus. We identified a major selective sweep in a genomic region controlling cytochrome P450-based metabolic resistance conferring high resistance to pyrethroids. This selective sweep occurred since 2002, likely as a direct consequence of scaled up vector control as revealed by whole genome and fine-scale sequencing of pre- and post-intervention populations. Fine-scaled analysis of the pyrethroid resistance locus revealed that a resistance-associated allele of the cytochrome P450 monooxygenase CYP6P9a has swept through southern Africa to near fixation, in contrast to high polymorphism levels before interventions, conferring high levels of pyrethroid resistance linked to control failure. Population structure analysis revealed a barrier to gene flow between southern Africa and other areas, which may prevent or slow the spread of the southern mechanism of pyrethroid resistance to other regions. By identifying a genetic signature of pyrethroid-based interventions, we have demonstrated the intense selective pressure that control interventions exert on mosquito populations. If this level of selection and spread of resistance continues unabated, our ability to control malaria with current interventions will be compromised., Author Summary Malaria control currently relies heavily on insecticide-based vector control interventions. Unfortunately, resistance to insecticides threatens the continued effectiveness of these measures. Metabolic resistance, caused by increased detoxification of insecticides, presents the greatest threat to vector control, yet it remains unclear how these mechanisms are linked to underlying genetic changes driven by the massive selection pressure from these interventions, such as the widespread use of Long Lasting Insecticide Nets (LLINs) across Africa. Therefore, understanding the direction and speed at which this operationally important form of resistance spreads through mosquito populations is essential if we are to get ahead of the ‘resistance curve’ and avert a public health catastrophe. Here, using microsatellite markers, whole genome sequencing and fine-scale sequencing at a major resistance locus, we elucidated the Africa-wide population structure of Anopheles funestus, a major African malaria vector, and detected a strong selective sweep occurring in a genomic region controlling cytochrome P450-based metabolic pyrethroid resistance in this species. Furthermore, we demonstrated that this selective sweep is driven by the scale-up of insecticide-based malaria control in Africa, highlighting the risk that if this level of selection and spread of resistance continues unabated, our ability to control malaria with current interventions will be compromised.

Published

2017

3. Widespread Pyrethroid and DDT Resistance in the Major Malaria Vector Anopheles funestus in East Africa Is Driven by Metabolic Resistance Mechanisms.

Author

Mulamba, Charles, Riveron, Jacob M., Ibrahim, Sulaiman S., Irving, Helen, Barnes, Kayla G., Mukwaya, Louis G., Birungi, Josephine, and Wondji, Charles S.

Subjects

MALARIA prevention, ANOPHELES funestus, PROTOZOAN diseases, PYRETHROIDS, CYTOCHROMES

Abstract

Background: Establishing the extent, geographical distribution and mechanisms of insecticide resistance in malaria vectors is a prerequisite for resistance management. Here, we report a widespread distribution of insecticide resistance in the major malaria vector An. funestus across Uganda and western Kenya under the control of metabolic resistance mechanisms. Methodology/Principal Findings: Female An. funestus collected throughout Uganda and western Kenya exhibited a Plasmodium infection rate between 4.2 to 10.4%. Widespread resistance against both type I (permethrin) and II (deltamethrin) pyrethroids and DDT was observed across Uganda and western Kenya. All populations remain highly susceptible to carbamate, organophosphate and dieldrin insecticides. Knockdown resistance plays no role in the pyrethroid and DDT resistance as no kdr mutation associated with resistance was detected despite the presence of a F1021C replacement. Additionally, no signature of selection was observed on the sodium channel gene. Synergist assays and qRT-PCR indicated that metabolic resistance plays a major role notably through elevated expression of cytochrome P450s. DDT resistance mechanisms differ from West Africa as the L119F-GSTe2 mutation only explains a small proportion of the genetic variance to DDT resistance. Conclusion: The extensive distribution of pyrethroid and DDT resistance in East African An. funestus populations represents a challenge to the control of this vector. However, the observed carbamate and organophosphate susceptibility offers alternative solutions for resistance management. [ABSTRACT FROM AUTHOR]

Published

2014