Characterization of amplification core and esterase B1 gene responsible for insecticide resistance in Culex.

Abstract: Organophosphorus insecticide (OP) resistance in several Culex species is associated with increased esterase activity resulting from amplification of the corresponding structural gene. In Culex pipiens quinquefasciatus, high levels of OP resistance (=800 times) are due to the esterase Bi gene, which is amplified at least 250-fold. This gene has now been sequenced, and the structure of the amplification unit (amplicon) encompassing the structural gene has been partially characterized. The inferred amino acid seq… Show more

“…Because of the shared ancestral origin, similarities between genes could have resulted in similar amplification processes in response to selective pressures from exposure to organophosphate insecticides in both insects. The Type I gene appeared to have a relatively low copy number in the resistant individuals compared with EstB1 1 of Culex mosquitoes (Mouchès et al, 1990) but similar to that estimated in M. persicae .…”

Amplification and methylation of an esterase gene associated with insecticide-resistance in greenbugs, Schizaphis graminum (Rondani) (Homoptera: Aphididae)

“…Because of the shared ancestral origin, similarities between genes could have resulted in similar amplification processes in response to selective pressures from exposure to organophosphate insecticides in both insects. The Type I gene appeared to have a relatively low copy number in the resistant individuals compared with EstB1 1 of Culex mosquitoes (Mouchès et al, 1990) but similar to that estimated in M. persicae .…”

Amplification and methylation of an esterase gene associated with insecticide-resistance in greenbugs, Schizaphis graminum (Rondani) (Homoptera: Aphididae)

“…In glutactin, a 1,023-amino acid residue glycoprotein located in basement membranes of Drosophila, it is the N-terminal segment that is homologous to esterases. Although the sequence identity of these three nonhydrolytic proteins with other proteins in this Shimada et al, 1990Shimada et al, 1989Kawaguchi et al, 1989Longhi et al, 1992Schumacher et al, 1986Sikorav et al, 1987Rachinsky et al, 1990Doctor et al, 1990Soreq et al, 1990Hall and Spierer, 1986Hall and Malcolm, 1991Lockridge et al, 1987Rachinsky et al, 1990Jbilo and Chatonnet, 1990Robbi et al, 1990Munger et al, 1992Long et al, 1991Korza and Ozols, 1988Ozols, 1989Ovnic et al, 1991Long et al, 1988Takagi et al, 1988Oakeshott et al, 1987Collet et al, 1990Hanzlik et al, 1989Mouches et al, 1990Han et al, 1987Kissel et al, 1989 Hui andKissel, 1990;Nilsson et al, 1990;Baba et al, 1991Kyger et al, 1989Rubino et al, 1989Bomblies et al, 1990 de la Escalera et al ., 1990Olson et al, 1990Mercken et al, 1985 family is within 16-28%, there is no evolutionary pressure to maintain the geometry of the active site. One may, therefore, predict that their 3D structures will show more divergence from GCL and TcAChE than other proteins in this group.…”

“…Even within AChEs this loop varies in length by 4 residues. Only two sequences lack these cysteines: Culex esterase B1 (Mouches et al, 1990) and Heliothis juvenile hormone esterase (Hanzlik et al, 1989). Although this disulfide bridge is highly conserved, its role and importance are not apparent from the 3D structure alone.…”

Relationship between sequence conservation and three‐dimensional structure in a large family of esterases, lipases, and related proteins

“…In Diptera, they occur as a gene cluster on the same chromosome (26,27). Individual members of the gene cluster may be modified in instances of insecticide resistance, for example, by changing a single amino acid that converts the specificity of an esterase to an insecticide hydrolase (28) or by existing as multiple-gene copies that are amplified in resistant insects (the best studied examples are the B1 [29] and A2-B2 [30] amplicons in Culex pipiens and C. quinquefasciatus).…”

Insecticide Resistance and Vector Control