Cholinesterases properties

Oxime carbamates are generally applied either directly to the tilled soil or sprayed on crops. One of the advantages of oxime carbamates is their short persistence on plants. They are readily degraded into their metabolites shortly after application. However, some of these metabolites have insecticidal properties even more potent than those of the parent compound. For example, the oxidative product of aldicarb is aldicarb sulfoxide, which is observed to be 10-20 times more active as a cholinesterase inhibitor than aldicarb. Other oxime carbamates (e.g., methomyl) have degradates which show no insecticidal activity, have low to negligible ecotoxicity and mammalian toxicity relative to the parent, and are normally nondetectable in crops. Therefore, the residue definition may include the parent oxime carbamate (e.g., methomyl) or parent and metabolites (e.g., aldicarb and its sulfoxide and sulfone metabolites). The tolerance or maximum residue limit (MRL) of pesticides on any food commodity is based on the highest residue concentration detected on mature crops at harvest or the LOQ of the method submitted for enforcement purposes if no detectable residues are found. For example, the tolerances of methomyl in US food commodities range from 0.1 to 6 mg kg for food items and up to 40 mg kg for feed items. ... 

DF and its precursor, DC are organophosphonic acids. They will react with alcohols to form crude lethal nerve agents, such as crude GB. High overexposure may cause inhibition of cholinesterase activity. Although much less toxic than GB, DF and DC are toxic and corrosive materials. Because DF and DC are relatively volatile compounds, the primary route of exposure is expected to be the respiratory system. However, ingestion also results from inhalation exposures in animals and could occur in humans. DF and DC vapors have a pungent odor and may cause severe and painful irritation of the eyes, nose, throat, and lungs. Data provided is for DF only, DC has similar properties. 

The ester must in addition contain some group which will initiate the approach of the ester to the surface of the enzyme. In this connexion it should be noted that di-isopropyl phos-phorochloridate (III, X = Cl), in which the chlorine atom is chemically very reactive,3 has no toxic properties, is devoid of myotic and anti-cholinesterase activity. In this compound, the chlorine is hydrolysed very quickly in water and would probably be destroyed extremely quickly in vivo. We have shown, quite conclusively, that in non-polar solvents the phosphorochloridate... 

Cholinesterases are subdivided into acetylcholinesterase and cholinesterase, one with a narrow, the other with broad substrate specificity [109-112], Both enzymes exist in multiple molecular forms distinguishable by their subunits association (Fig. 2.4). The hydrodynamic properties of these associations have allowed globular (G) and asymmetric (A) forms to be distinguished. The G forms can be hydrophilic (water-soluble, and excreted into body fluids) or amphiphilic (membrane-bound). The homomeric class exists... 

Thioesters play a paramount biochemical role in the metabolism of fatty acids and lipids. Indeed, fatty acyl-coenzyme A thioesters are pivotal in fatty acid anabolism and catabolism, in protein acylation, and in the synthesis of triacylglycerols, phospholipids and cholesterol esters [145], It is in these reactions that the peculiar reactivity of thioesters is of such significance. Many hydrolases, and mainly mitochondrial thiolester hydrolases (EC 3.1.2), are able to cleave thioesters. In addition, cholinesterases and carboxylesterases show some activity, but this is not a constant property of these enzymes since, for example, carboxylesterases from human monocytes were found to be inactive toward some endogenous thioesters [35] [146], In contrast, allococaine benzoyl thioester was found to be a good substrate of pig liver esterase, human and mouse butyrylcholinesterase, and mouse acetylcholinesterase [147],... 

Interestingly, much work has been devoted to the development of substances in the class of cholinesterase inhibitors that have exceedingly high toxicity substances that also have properties (such as volatility and sufficient but not excessive environmental stability) that make them useful as agents of warfare. Most of those now stockpiled were first developed during World War II. Sarin and VX are perhaps the most well-known members of this class of compounds that have been especially designed to kill people. 

The classic cholinesterase inhibitor is the alkaloid physostigmine (6)/ eserine (7). It was first isolated from the calabar bean, the seeds of Physostigma venenosum. Many novel natural products with AchE-inhibifing properties have shown promise as therapeutics for AD. Some examples of such products (pure compounds/plant extracts or formulations) are briefly reviewed here. 

Choudhary MI, Nawaz SA, Zaheer-uI-Haq Lodhi MA, et al, Withanolides, a new class of natural cholinesterase inhibitors with calcium antagonistic properties, Biochem Biophys Res Comm 334 276—287, 2005. 

The pharmacological properties of ambenonium are similar to neostigmine and pyridostigmine, and it works by reversible inactivation of cholinesterase. A synonym of this drug is ambenonium. 

Individual cholinesterase inhibitors differ in their selectivity, mechanism of inhibition of acetylcholinesterase (Schneider 2001), and pharmacokinetic properties (outlined in Table 7-2). 

Although there are only few published data with antidementia drugs, the effects of cholinesterase inhibitors in healthy awake volunteers appear to be unspecific. In contrast, the REM-sleep facilitating effect of these compounds appears to be a property not shared by other psychotropic drugs. 

Irreversible cholinesterases are mostly organophosphorus compounds and combine only with esteratic site of cholinesterase and that site gets phosphorylated. The hydrolysis of phosphorylated site produces irreversible inhibition of cholinesterase. And, because, of this property, the therapeutic usefulness is very limited. Most of the compounds are used as insecticides e.g. parathion, malathion and war gases e.g. tabun, sarin, soman etc. 

Hydrolytic reactions. There are numerous different esterases responsible for the hydrolysis of esters and amides, and they occur in most species. However, the activity may vary considerably between species. For example, the insecticide malathion owes its selective toxicity to this difference. In mammals, the major route of metabolism is hydrolysis to the dicarboxylic acid, whereas in insects it is oxidation to malaoxon (Fig. 5.12). Malaoxon is a very potent cholinesterase inhibitor, and its insecticidal action is probably due to this property. The hydrolysis product has a low mammalian toxicity (see chap. 7). 

Some general methods can also be adapted to the determination of individual organophosphorus compounds. For instance, the cholinesterase-inhibiting properties of methylparathion, dimethoate and their oxygen analogues were used for their determination a known amount of enzyme is incubated with the sample, then addition of a chromogenic agent such as p-nitrobenzenediazonium fluoroborate yields a... 

The toxicity of organophosphoric esters for insects and mammals is associated with inhibition of cholinesterases. Investigations on the relation between chemical structure of organophosphoric esters and the inactivation of acetylcholinesterase (AChE) have revealed that anticholinesterase activity depends to a large extent on the chemical reactivity of the esters. As a rule, the chemical reactivity of the phosphorus atom is the single most important property which determines the anticholinesterase activity of an organophosphoric ester. 

---