Esterase inhibitors, organophosphate

An extremely interesting area for bioassays is the group of acetylcholine-esterase inhibitors, the organophosphate and carbamate pesticides. First of all this is based on the need for rapid screening tests, allowing on-site testing of fruits and vegetables. Secondly there is the awareness that the cumulative effects... 

As will become clear, this chapter is focused on toxicants for which the receptor is a high-affinity recognition site of the type discussed in the previous paragraphs. It should be noted explicitly that other toxicants have receptors, but fall into more complex situations not appropriate for this chapter. For example, some toxicants inhibit enzymes, or are themselves enzymes. Such interesting compounds include the organophosphate and carbamate insecticides (acetylcholine esterase inhibitors) and diphtheria toxin (an enzyme). 

Techniques. In 1962, McKinley and Read (42) developed an esterase-inhibition technique for the detection of organophosphate pesticide residues on paper chromatograms. The procedure involved conversion of the thiophosphates with bromine to yield active esterase inhibitors, the inhibition by the pesticide of the esterases from a beef liver homogenate sprayed onto the chromatogram, the hydrolysis of the substrate (a-naph-thyl acetate) which was sprayed onto the paper after the liver homogenate had dried, and the development of a background color between Fast Blue RR and the hydrolysis product, a-naphthol. 

Lotti M (2002) Promotion of organophosphate induced delayed polyneuropathy by certain esterase inhibitors. Toxicology 181-182 245-248. 

Because several esterase inhibitors, including organophosphates, organophosphinates, phosphoroamidates, sulfonyl halides and carbamates have been found to exacerbate OPIDN and other axonal insults in experimental animals a search for the esterase target of promotion is progress [ 24,101,108,109],... 

Another class of acetylcholine esterase inhibitors causes irreversible inhibition of the enzyme through the transfer of an organophosphate ester group to the serine residue in the active site. This class of inhibitors has largely been used as either insecticides or nerve gases such as dyflos and parathion (see Ch. 16). 

Application of the CCM to small sets (n < 6) of enzyme inhibitors revealed correlations between the inhibitory activity and the chirality measure of the inhibitors, calculated by Eq. (26) for the entire structure or for the substructure that interacts with the enzyme (pharmacophore) [41], This was done for arylammonium inhibitors of trypsin, Di-dopamine receptor inhibitors, and organophosphate inhibitors of trypsin, acetylcholine esterase, and butyrylcholine esterase. Because the CCM values are equal for opposite enantiomers, the method had to be applied separately to the two families of enantiomers (R- and S-enantiomers). 

The mechanism of OPIDN is poorly understood, but, since all organophosphate esters that produce OPIDN are either direct cholinesterase inhibitors or are metabolically converted to cholinesterase inhibitors, inhibition of an esterase of some kind has generally been thought to be involved (Baron 1981). Certain... 

Phosphinates are a class of organophosphorus compounds, the metabolism of which has received less attention than that of phosphates (see above) or phosphorothioates and P-halidc compounds (see below). Many phosphinates are rapid but transient inhibitors of acetylcholinesterase and carboxyl-esterases. And like organophosphates and phosphonates, phosphinates are substrates of arylesterases (EC 3.1.1.2). This is exemplified by 4-nitrophen-yl ethyl(phenyl)phosphinate (9.62), whose (-)-enantiomer was hydrolyzed by rabbit serum arylesterase almost 10 times faster than the (+)-enantiomer [133],... 

Esterase activity is important in both the detoxication of organophosphates and the toxicity caused by them. Thus brain acetylcholinesterase is inhibited by organophosphates such as paraoxon and malaoxon, their oxidized metabolites (see above). This leads to toxic effects. Malathion, a widely used insecticide, is metabolized mostly by carboxylesterase in mammals, and this is a route of detoxication. However, an isomer, isomalathion, formed from malathion when solutions are inappropriately stored, is a potent inhibitor of the carboxylesterase. The consequence is that such contaminated malathion becomes highly toxic to humans because detoxication is inhibited and oxidation becomes important. This led to the poisoning of 2800 workers in Pakistan and the death of 5 (see chap. 5 for metabolism and chap. 7 for more details). 

The inhibition by other organophosphate compounds of the carboxylesterase which hydrolyzes malathion is a further example of xenobiotic interaction resulting from irreversible inhibition because, in this case, the enzyme is phosphorylated by the inhibitor. A second type of inhibition involving organophosphorus insecticides involves those containing the P=S moiety. During CYP activation to the esterase-inhibiting oxon, reactive sulfur is released that inhibits CYP isoforms by an irreversible interaction with the heme iron. As a result, these chemicals are inhibitors of the metabolism of other xenobiotics, such as carbaryl and fipronil, and are potent inhibitors of the metabolism of steroid hormones such as testosterone and estradiol. 

Figure 9.17. Organophosphate inhibitors of acetylcholinesterase. a The catalytic mechanism, shown here for diiso-propylfluorophosphate(DFP).b Stmcturesof soman and tabun. Like DFP, these were developed during world war II as nerve gases , c Stractures of the insecticides parathion and malathion, and of paraoxon, which is the achve metabolite of parathion. (Malathion likewise requires conversion to malaoxon.) The arrow above the malathione stmcture indicates the esterase cleavage sites in its leaving group esterase cleavage occurs in human plasma and renders the molecule non-toxic.

Exposure to some organophosphate cholinesterase inhibitors results in a delayed neuropathy characterized by degeneration of axons and myelin. This effect is not associated with the inhibition of acetylcholinesterase, but rather with the inhibition of an enzyme described as neuropathy target esterase (NTE) however, the exact mechanism of toxicity is not yet fully understood (Munro et al., 1994). For some organophosphate compounds, delayed neuropathy can be induced in experimental animals at relatively low exposure levels, whereas for others the effect is only seen following exposure to supralethal doses when the animal is protected from the acute toxic effects caused by cholinesterase inhibition. 

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