Frederic Laporte
Overview
Explore the profile of Frederic Laporte including associated specialties, affiliations and a list of published articles.
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Articles
17
Citations
328
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Recent Articles
1.
Zoh M, Bonneville J, Laporte F, Tutagata J, Sadia C, Fodjo B, et al.
Malar J
. 2023 Sep;
22(1):256.
PMID: 37667239
Background: The widespread use of pyrethroid insecticides in Africa has led to the development of strong resistance in Anopheles mosquitoes. Introducing new active ingredients can contribute to overcome this phenomenon...
2.
Tetreau G, Sawaya M, De Zitter E, Andreeva E, Banneville A, Schibrowsky N, et al.
Nat Commun
. 2022 Jul;
13(1):4376.
PMID: 35902572
Cry11Aa and Cry11Ba are the two most potent toxins produced by mosquitocidal Bacillus thuringiensis subsp. israelensis and jegathesan, respectively. The toxins naturally crystallize within the host; however, the crystals are...
3.
Sherpa S, Tutagata J, Gaude T, Laporte F, Kasai S, Ishak I, et al.
Mol Biol Evol
. 2022 May;
39(5).
PMID: 35574643
Climatic variation is a key driver of genetic differentiation and phenotypic traits evolution, and local adaptation to temperature is expected in widespread species. We investigated phenotypic and genomic changes in...
4.
Zoh M, Bonneville J, Tutagata J, Laporte F, Fodjo B, Mouhamadou C, et al.
Sci Rep
. 2021 Oct;
11(1):19501.
PMID: 34593941
The introduction of neonicotinoids for managing insecticide resistance in mosquitoes is of high interest as they interact with a biochemical target not previously used in public health. In this concern,...
5.
Cattel J, Haberkorn C, Laporte F, Gaude T, Cumer T, Renaud J, et al.
Evol Appl
. 2021 Apr;
14(4):1009-1022.
PMID: 33897817
By altering gene expression and creating paralogs, genomic amplifications represent a key component of short-term adaptive processes. In insects, the use of insecticides can select gene amplifications causing an increased...
6.
Tetreau G, Banneville A, Andreeva E, Brewster A, Hunter M, Sierra R, et al.
Nat Commun
. 2020 Mar;
11(1):1153.
PMID: 32123169
Cyt1Aa is the one of four crystalline protoxins produced by mosquitocidal bacterium Bacillus thuringiensis israelensis (Bti) that has been shown to delay the evolution of insect resistance in the field....
7.
Cattel J, Faucon F, Le Peron B, Sherpa S, Monchal M, Grillet L, et al.
Evol Appl
. 2020 Jan;
13(2):303-317.
PMID: 31993078
In addition to combating vector-borne diseases, studying the adaptation of mosquitoes to insecticides provides a remarkable example of evolution-in-action driving the selection of complex phenotypes. Actually, most resistant mosquito populations...
8.
Sherpa S, Gueguen M, Renaud J, Blum M, Gaude T, Laporte F, et al.
Ecol Evol
. 2019 Dec;
9(22):12658-12675.
PMID: 31788205
Invasive species can encounter environments different from their source populations, which may trigger rapid adaptive changes after introduction (niche shift hypothesis). To test this hypothesis, we investigated whether postintroduction evolution...
9.
Tetreau G, Grizard S, Patil C, Tran F, Tran Van V, Stalinski R, et al.
Parasit Vectors
. 2018 Mar;
11(1):121.
PMID: 29499735
Background: Insect microbiota is a dynamic microbial community that can actively participate in defense against pathogens. Bacillus thuringiensis (Bt) is a natural entomopathogen widely used as a bioinsecticide for pest...
10.
Stalinski R, Laporte F, Tetreau G, Despres L
Infect Genet Evol
. 2016 Jul;
44:218-227.
PMID: 27418233
Bacillus thuringiensis israelensis (Bti) toxins are increasingly used for mosquito control, but little is known about the precise mode of action of each of these toxins, and how they interact...