Robert W. Gwadz scite author profile

The anopheline mosquito is the target in most malaria control programs, primarily through the use of residual insecticides. A mosquito was studied that is refractory to most species of malaria through a genetically controlled mechanism. A strain of Anopheles gambiae, which was selected for complete refractoriness to the simian malaria parasite Plasmodium cynomolgi, also has varying degrees of refractoriness to most other malaria species examined, including the human parasites P. falciparum, P. ovale, and P. vivax for which this mosquito is the principal African vector. Furthermore, the refractoriness extends to other subhuman primate malarias, to rodent malaria, and to avian malaria. Refractoriness is manifested by encapsulation of the malaria ookinete after it completes its passage through the mosquito midgut, approximately 16 to 24 hours after ingestion of an infective blood meal. Fully encapsulated ookinetes show no abnormalities in parasite organelles, suggesting that refractoriness is due to an enhanced ability of the host to recognize the living parasite rather than to a passive encapsulation of a dead or dying parasite. Production of fully refractory and fully susceptible mosquito strains was achieved through a short series of selective breeding steps. This result indicates a relatively simple genetic basis for refractoriness. In addition to the value these strains may serve in general studies of insect immune mechanisms, this finding encourages consideration of genetic manipulation of natural vector populations as a malaria control strategy.

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Chloroquine resistance not linked to mdr-like genes in a Plasmodium falciparum cross

Wellems

Panton

Gluzman

et al. 1990

Nature

515

342

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Chloroquine is thought to act against falciparum malaria by accumulating in the acid vesicles of the parasite and interfering with their function. Parasites resistant to chloroquine expel the drug rapidly in an unaltered form, thereby reducing levels of accumulation in the vesicles. The discovery that verapamil partially reverses chloroquine resistance in vitro led to the proposal that efflux may involve an ATP-driven P-glycoprotein pump similar to that in mammalian multidrug-resistant (mdr) tumor cell lines. Indeed, Plasmodium falciparum contains at least two mdr-like genes, one of which has been suggested to confer the chloroquine resistant (CQR) phenotype. To determine if either of these genes is linked to chloroquine resistance, we performed a genetic cross between CQR and chloroquine-susceptible (CQS) clones of P. falciparum. Examination of 16 independent recombinant progeny indicated that the rapid efflux phenotype is controlled by a single gene or a closely linked group of genes. But, there was no linkage between the rapid efflux, CQR phenotype and either of the mdr-like P. falciparum genes or amplification of those genes. These data indicate that the genetic locus governing chloroquine efflux and resistance is independent of the known mdr-like genes.

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Parasitic Diseases

Despommier¹,

Gwadz²,

Hotez³

1995

113

122

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Robert W. Gwadz

Genetic Selection of a Plasmodium -Refractory Strain of the Malaria Vector Anopheles gambiae

Chloroquine resistance not linked to mdr-like genes in a Plasmodium falciparum cross

Parasitic Diseases

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