Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species

Malaria (vector: Anopheles gambiae) is a major infectious disease that kills about 1 million people each year. For the improvement of its treatment and vector control during the past decades, several issues such as high medicine cost, insecticide resistance, and lack of an effective vaccine have pr...

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Main Author: Jiang, Ying
Other Authors: Entomology
Format: Others
Published: Virginia Tech 2014
Subjects:
Online Access:http://hdl.handle.net/10919/41236
http://scholar.lib.vt.edu/theses/available/etd-02212011-004504/
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spelling ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-412362020-09-29T05:44:05Z Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species Jiang, Ying Entomology Bloomquist, Jeffrey R. Carlier, Paul R. Mullins, Donald E. neurotoxic esterase acetylcholinesterase carbamate insecticides neurotoxicity Malaria (vector: Anopheles gambiae) is a major infectious disease that kills about 1 million people each year. For the improvement of its treatment and vector control during the past decades, several issues such as high medicine cost, insecticide resistance, and lack of an effective vaccine have prevented adequate control of malaria. Additionally, the low selectivity of malaria vector insecticides also presents a public health problem. The purpose of developing novel carbamate insecticides in our laboratory is to offer effective and selective insecticide options to achieve the ultimate goal of malaria control. First, 50% inhibition concentration (IC50) data was collected from three mammalian AChEs with eight commercial carbamate insecticides by using the Ellman assay. The IC50 values varied from 57 nM to 7358 nM. The AChE sensitivity pattern and level were shown to be similar between the recombinant mouse and ICR male mouse brain cortex homogenate (slope = 0.99, R2 = 0.96). Then eight novel carbamate insecticides that are possible malaria vector control agents were selected for further neurotoxicity testing in non-target organisms. For commercial carbamate insecticides, the IC50 varied from 9.1 nM to 2,094 nM. For the novel carbamate insecticides, it varied from 58 nM to 388,800 nM. Based on IC50 data from previous work on A. gambiae, the selectivity index (IC50 of non-target species / IC50 A. gambiae) ranged from 0.17 to 5.64 and from 0.47 to 19,587 for commercial and novel carbamate insecticides, respectively. Subsequently, the AChE protein sequence alignment comparison and cladogram were used to compare the genetic and evolutionary relationship among five different organisms. The alignment score ranged from 88 for mouse vs. human to 54 for hen vs. T. californica. The evolutionary relationships among species was obtained from the cladogram. Recombinant mouse vs. recombinant human was shown to have the most similar inhibitor potency profiles (alignment score = 88, closest taxa position on cladogram, similar AChE sensitivity pattern [R2 = 0.81] and level [P > 0.05] to the novel carbamates). Neurotoxic esterase (NTE) assay showed that the novel carbamates did not significantly inhibit NTE, inhibition of which underlies a significant hazard for anticholinesterases, especially organophosphates, in several nontarget vertebrate organisms. The NTE activity in the presence of novel carbamate insecticides ranged from 93% to 116% of the control, while in the commercial group, bendiocarb significantly inhibited NTE, leaving only 76.5% of the initial reactivity at 1 mM inhibitor concentration. Further in vivo bioassay using Daphnia magna was conducted to compare the aquatic toxicity of commercial and novel carbamates. The data showed that except for PRC331 (3-tert-butylphenylmethylcarbamate), all novel carbamates were of similar potency as bendiocarb (LC50 = 611 nM) for aquatic toxicity, and their LC50 values ranged from 172 nM (PRC331) to 1109 nM. In conclusion, the novel carbamate insecticides would appear to be an improvement over commercial carbamate insecticides because of greater selectivity, negligible NTE inhibition capacity, but in some cases with potent in vivo toxicity to Daphnia magna. However, since the envisioned usage of these compounds is in bednets or as indoor residual sprays (IRS), any environmental exposures to nontarget aquatic organisms are expected to be minimal. Master of Science 2014-03-14T21:30:03Z 2014-03-14T21:30:03Z 2011-01-17 2011-02-21 2011-03-03 2011-03-03 Thesis etd-02212011-004504 http://hdl.handle.net/10919/41236 http://scholar.lib.vt.edu/theses/available/etd-02212011-004504/ Jiang_Ying_T_2011.pdf In Copyright http://rightsstatements.org/vocab/InC/1.0/ application/pdf Virginia Tech
collection NDLTD
format Others
sources NDLTD
topic neurotoxic esterase
acetylcholinesterase
carbamate insecticides
neurotoxicity
spellingShingle neurotoxic esterase
acetylcholinesterase
carbamate insecticides
neurotoxicity
Jiang, Ying
Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
description Malaria (vector: Anopheles gambiae) is a major infectious disease that kills about 1 million people each year. For the improvement of its treatment and vector control during the past decades, several issues such as high medicine cost, insecticide resistance, and lack of an effective vaccine have prevented adequate control of malaria. Additionally, the low selectivity of malaria vector insecticides also presents a public health problem. The purpose of developing novel carbamate insecticides in our laboratory is to offer effective and selective insecticide options to achieve the ultimate goal of malaria control. First, 50% inhibition concentration (IC50) data was collected from three mammalian AChEs with eight commercial carbamate insecticides by using the Ellman assay. The IC50 values varied from 57 nM to 7358 nM. The AChE sensitivity pattern and level were shown to be similar between the recombinant mouse and ICR male mouse brain cortex homogenate (slope = 0.99, R2 = 0.96). Then eight novel carbamate insecticides that are possible malaria vector control agents were selected for further neurotoxicity testing in non-target organisms. For commercial carbamate insecticides, the IC50 varied from 9.1 nM to 2,094 nM. For the novel carbamate insecticides, it varied from 58 nM to 388,800 nM. Based on IC50 data from previous work on A. gambiae, the selectivity index (IC50 of non-target species / IC50 A. gambiae) ranged from 0.17 to 5.64 and from 0.47 to 19,587 for commercial and novel carbamate insecticides, respectively. Subsequently, the AChE protein sequence alignment comparison and cladogram were used to compare the genetic and evolutionary relationship among five different organisms. The alignment score ranged from 88 for mouse vs. human to 54 for hen vs. T. californica. The evolutionary relationships among species was obtained from the cladogram. Recombinant mouse vs. recombinant human was shown to have the most similar inhibitor potency profiles (alignment score = 88, closest taxa position on cladogram, similar AChE sensitivity pattern [R2 = 0.81] and level [P > 0.05] to the novel carbamates). Neurotoxic esterase (NTE) assay showed that the novel carbamates did not significantly inhibit NTE, inhibition of which underlies a significant hazard for anticholinesterases, especially organophosphates, in several nontarget vertebrate organisms. The NTE activity in the presence of novel carbamate insecticides ranged from 93% to 116% of the control, while in the commercial group, bendiocarb significantly inhibited NTE, leaving only 76.5% of the initial reactivity at 1 mM inhibitor concentration. Further in vivo bioassay using Daphnia magna was conducted to compare the aquatic toxicity of commercial and novel carbamates. The data showed that except for PRC331 (3-tert-butylphenylmethylcarbamate), all novel carbamates were of similar potency as bendiocarb (LC50 = 611 nM) for aquatic toxicity, and their LC50 values ranged from 172 nM (PRC331) to 1109 nM. In conclusion, the novel carbamate insecticides would appear to be an improvement over commercial carbamate insecticides because of greater selectivity, negligible NTE inhibition capacity, but in some cases with potent in vivo toxicity to Daphnia magna. However, since the envisioned usage of these compounds is in bednets or as indoor residual sprays (IRS), any environmental exposures to nontarget aquatic organisms are expected to be minimal. === Master of Science
author2 Entomology
author_facet Entomology
Jiang, Ying
author Jiang, Ying
author_sort Jiang, Ying
title Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
title_short Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
title_full Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
title_fullStr Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
title_full_unstemmed Evaluation of Novel Carbamate Insecticides for Neurotoxicity to Non-Target Species
title_sort evaluation of novel carbamate insecticides for neurotoxicity to non-target species
publisher Virginia Tech
publishDate 2014
url http://hdl.handle.net/10919/41236
http://scholar.lib.vt.edu/theses/available/etd-02212011-004504/
work_keys_str_mv AT jiangying evaluationofnovelcarbamateinsecticidesforneurotoxicitytonontargetspecies
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