Toxicological and biochemical characterizations of AChE in phosalone-susceptible and resistant populations of the common pistachio psyllid, Agonoscena pistaciae

The toxicological and biochemical characteristics of acetylcholinesterases (AChE) in nine populations of the common pistachio psyllid, Agonoscena pistaciae Burckhardt and Lauterer (Hemiptera: Psyllidae), were investigated in Kerman Province, Iran. Nine A. pistaciae populations were collected from pistachio orchards, Pistacia vera L. (Sapindales: Anacardiaceae), located in Rafsanjan, Anar, Bam, Kerman, Shahrbabak, Herat, Sirjan, Pariz, and Paghaleh regions of Kerman province. The previous bioassay results showed these populations were susceptible or resistant to phosalone, and the Rafsanjan population was most resistant, with a resistance ratio of 11.3. The specific activity of AChE in the Rafsanjan population was significantly higher than in the susceptible population (Bam). The affinity (K(M)) and hydrolyzing efficiency (Vmax) of AChE on acetylthiocholine iodide, butyrylthiocholine iodide, and propionylthiocholine odide as artificial substrates were clearly lower in the Bam population than that in the Rafsanjan population. These results indicated that the AChE of the Rafsanjan population had lower affinity to these substrates than that of the susceptible population. The higher Vmax value in the Rafsanjan population compared to the susceptible population suggests a possible over expression of AChE in the Rafsanjan population. The in vitro inhibitory effect of several organophosphates and carbamates on AChE of the Rafsanjan and Bam populations was determined. Based on I50, the results showed that the ratios of AChE insensitivity of the resistant to susceptible populations were 23 and 21.7-fold to monocrotophos and phosphamidon, respectively. Whereas, the insensitivity ratios for Rafsanjan population were 0.86, 0.8, 0.78, 0.46, and 0.43 for carbaryl, eserine, propoxur, m-tolyl methyl carbamate, and carbofuran, respectively, suggesting negatively correlated sensitivity to organophosphate-insensitive AChE. Therefore, AChE from the Rafsanjan population showed negatively correlated sensitivity, being insensitive to phosphamidon and monocrotophos and sensitive to N-methyl carbamates.

Bivalve esterases as biomarker: identification and characterization in European cockles (Cerastoderma edule)

This study characterized esterase activity in Cerastoderma edule tissues using different substrates and specific inhibitors and identified the tissue distribution of esterases in this species. Synthetic thiocholines and thioacetate esters and specific inhibitors (eserine, BW284C51 and iso-OMPA) were used to identify and quantify cholines and carboxyl esterases. The results demonstrated the presence of a non-specific propionyl thiocholine (PrSCh)-cleaving cholinesterase (ChE) and a large amount of carboxylesterases (CaE). For further studies using C. edule esterases as biomarkers, our results suggest that the adductor muscle, with PrSCh (5 mM) as substrate should be used to analyze ChE, and for CaE analyses, phenyl thioacetate should be used in digestive gland extracts (PSA, 5 mM).

Development of Au nanoparticles dispersed carbon nanotube-based biosensor for the detection of paraoxon

A disposable and sensitive biosensor has been fabricated for the detection of the organophosphorous (OP) compound paraoxon using an amperometric technique. For the measurements, gold nanoparticles dispersed on the outer surface of multiwalled carbon nanotubes (Au-MWNTs) has been used as the electrode material, as it possesses high electron transfer rates and provides large immobilization sites for the bioenzymes, which combines with the high electrocatalytic activity of MWNTs for thiocholine oxidation at low potential. Au-MWNTs have been synthesized by chemically reducing Au salt over functionalized MWNTs, and the same has been characterized by X-ray diffraction (XRD), transmission electron microscopy (TEM) and high resolution transmission electron microscopic (HRTEM) techniques. The ability of the Au-MWNTs nanocomposite-based biosensor has been demonstrated to reliably measure the concentration of paraoxon in the nanomolar range.

Cholinesterase activities as potential biomarkers: characterization in two freshwater snails, Potamopyrgus antipodarum (Mollusca, Hydrobiidae, Smith 1889) and Valvata piscinalis (Mollusca, Valvatidae, Müller 1774)

Anti-cholinesterase insecticides constitute a major portion of modern synthetic pesticides and the assessment of cholinesterase (ChE) inhibition is widely used as a specific biomarker for evaluating the exposure of non-target organisms to these pollutants. However, most studies on this biomarker were developed on vertebrates and among invertebrates, gastropod mollusks are rarely used. Gastropods are important members of aquatic habitats and therefore present a high ecological relevance for freshwater ecosystems. In this context, ChE activities were characterized in two freshwater gastropod mollusks, Potamopyrgus antipodarum and Valvata piscinalis, in order to ascertain their value as sentinel species. Firstly, characterization of ChE activities was performed using different substrates (acetylcholine iodide, butyrylcholine iodide and propionylcholine iodide) and specific inhibitors (eserine, iso-OMPA and BW284c51). Secondly, in vivo effect of a widely used organophosphate insecticide, chlorpyrifos, was tested on ChE activity in both species. Results suggested that P. antipodarum possesses two isoforms of cholinesterases, one isoform which properties are intermediate between an acetyl and a propionyl ChE, and one minor isoform which correspond to a butyryl ChE, while V. piscinalis seems to possess only one isoform which displays typical properties of an acetyl ChE. Chlorpyrifos induced no effect on V. piscinalis ChE. In contrast, P. antipodarum activity was significantly decreased by environmental realistic chlorpyrifos concentrations (2.86 and 14.2 nM) after seven days of contact. The present study suggests that P. antipodarum may be employed as a biological indicator for assessing pesticide contamination.

Characterization of trimeric acetylcholinesterase from a legume plant, Macroptilium atropurpureum Urb

We recently identified plant acetylcholinesterases (E.C.3.1.1.7; AChEs) homologous to the AChE purified from a monocotyledon, maize, that are distinct from the animal AChE family. In this study, we purified, cloned and characterized an AChE from a dicotyledon, siratro. The full-length cDNA of siratro AChE is 1,441 nucleotides, encoding a 382-residue protein that includes a signal peptide. This AChE is a disulfide-linked 125-kDa homotrimer consisting of 41-42 kDa subunits, in contrast to the maize AChE, which exists as a mixture of disulfide and non-covalently linked 88-kDa homodimers. The plant AChEs apparently consist of various quaternary structures, depending on the plant species, similar to the animal AChEs. We compared the enzymatic properties of the dimeric maize and trimeric siratro AChEs. Similar to electric eel AChE, both plant AChEs hydrolyzed acetylthiocholine (or acetylcholine) and propionylthiocholine (or propionylcholine), but not butyrylthiocholine (or butyrylcholine), and their specificity constant was highest against acetylcholine. There was no significant difference between the enzymatic properties of trimeric and dimeric AChEs, although two plant AChEs had low substrate turnover numbers compared with electric eel AChE. The two plant AChE activities were not inhibited by excess substrate concentrations. Thus, similar to some plant AChEs, siratro and maize AChEs showed enzymatic properties of both animal AChE and animal BChE. On the other hand, both siratro and maize AChEs exhibited low sensitivity to the AChE-specific inhibitor neostigmine bromide, dissimilar to other plant AChEs. These differences in enzymatic properties of plant AChEs may reflect the phylogenetic evolution of AChEs.

Purification and characterization of an acetylcholinesterase from the infective juveniles of Heterorhabditis bacteriophora

Acetylcholinesterases (AChEs) have been estimated in the infective juveniles (IJs) of eight different strains of heterorhabditid nematodes. The enzyme content ranged from 45.6 to 421.3 units/10(5) IJs with specific activity 34.0 to 82.6 units/mg protein. The isoenzyme patterns revealed the existence of two-slow-moving isoforms. Heterorhabditis bacteriophora AChE1A has been purified from the IJs of the heterorhabditid nematode strain of the highest enzymatic activity to homogeneity by ammonium sulfate precipitation, gel filtration on Sephacryl S-200 and DEAE-Sepharose. The specific activity of the purified enzyme was 1378.1 units/mg protein with purification fold 17.5 over crude extract. The enzyme has a pH optimum at 7.5. The optimum temperature for enzyme activity and stability was 35 degrees C. The activation energy was calculated to be 9.0 kcal/mol. The enzyme hydrolyzes acetylthiocholine (AcSCh), propionylthiocholine (PrSCh), S-butyrylthiocholine (BuSCh) and benzoylthiocholine (BzSCh) iodides with relative rate 100, 74.6, 41.7 and 22.2%, respectively. It displayed an apparent Michaelis-Menten behavior in the concentration range from 0.1 to 2 mM for the three former substrates with Km values 0.27, 0.42 and 0.59 mM, respectively. H. bacteriophora ChE1A is an AChE since it hydrolyzed AcSChI at higher rate than the other substrates and displayed excess substrate inhibition with AcSChI at concentrations over 2 mM. It was inhibited by eserine and BW284C51, but not by iso-OMPA. Its biochemical properties were compared with those reported for different species of insects as target hosts for heterorhabditid nematodes and animal parasitic nematodes.

Hydrolysis of oxo- and thio-esters by human butyrylcholinesterase

Catalytic parameters of human butyrylcholinesterase (BuChE) for hydrolysis of homologous pairs of oxo-esters and thio-esters were compared. Substrates were positively charged (benzoylcholine versus benzoylthiocholine) and neutral (phenylacetate versus phenylthioacetate). In addition to wild-type BuChE, enzymes containing mutations were used. Single mutants at positions: G117, a key residue in the oxyanion hole, and D70, the main component of the peripheral anionic site were tested. Double mutants containing G117H and mutations on residues of the oxyanion hole (G115, A199), or the pi-cation binding site (W82), or residue E197 that is involved in stabilization of tetrahedral intermediates were also studied. A mathematical analysis was used to compare data for BuChE-catalyzed hydrolysis of various pairs of oxo-esters and thio-esters and to determine the rate-limiting step of catalysis for each substrate. The interest and limitation of this method is discussed. Molecular docking was used to analyze how the mutations could have altered the binding of the oxo-ester or the thio-ester. Results indicate that substitution of the ethereal oxygen for sulfur in substrates may alter the adjustment of substrate in the active site and stabilization of the transition-state for acylation. This affects the k2/k3 ratio and, in turn, controls the rate-limiting step of the hydrolytic reaction. Stabilization of the transition state is modulated both by the alcohol and acyl moieties of substrate. Interaction of these groups with the ethereal hetero-atom can have a neutral, an additive or an antagonistic effect on transition state stabilization, depending on their molecular structure, size and enantiomeric configuration.

In vitro characterization of cholinesterases in the earthworm Eisenia andrei

Assessment of pollution impact in soil ecosystems has become a priority and interest has grown concerning the use of invertebrates as sentinel organisms. Inhibition of cholinesterase (ChE) activity has a great potential as a biomarker of pesticide exposure, and we evaluated the ChE kinetic parameters in the earthworm Eisenia andrei in the presence of acetylthiocholine (ASCh), proprionylthiocholine (PSCh) and butyrylthiocholine (BSCh). The highest ChE activity was found in the presence of ASCh and PSCh (42.45 and 49.82 nmol min(-1) mg protein(-1), respectively). BSCh was hydrolyzed at a rate of 4.04 nmol min(-1) mg protein(-1), but the time course did not reach a plateau under our experimental conditions. Km values were 0.142+/-0.006 and 0.183+/-0.053 mM for ASCh and PSCh, respectively. ASCh and PSCh hydrolysis were significantly inhibited by eserine (IC50 values were 1.44 x 10(-8) and 1.20 x 10(-8) M, respectively) and by carbaryl (IC50 values of 5.75 x 10(-9) and 4.79 x 10(-9) M). The presence of different ChEs in tissues from E. andrei was assessed by using selective inhibitors for AChE (BW284c51) and BChE (iso-OMPA). BW284c51 strongly reduced ASCh and PSCh hydrolysis and slightly affected that of BSCh, while iso-OMPA was without effect in all cases.

Cholinesterase from the common prawn (Palaemon serratus) eyes: catalytic properties and sensitivity to organophosphate and carbamate compounds

The main purpose of this study was to describe the kinetic properties of the cholinesterase (ChE) enzyme present in the eyes of the prawn Palaemon serratus, an abundant, ecological and commercially relevant species of European coastal environments. The obtained results suggest that the studied enzyme is a ChE and not a non-specific esterase, due to its apparent affinity for choline esters and the high sensitivity to eserine sulphate. This ChE displays a distinct preference for the substrate acetylthiocholine, showing a triphasic behaviour, with activation at low concentrations and inhibition by excess of substrate. Moreover, irreversible ChE inhibition by several organophosphate and carbamate compounds was characterized. All the irreversible inhibitions were homogeneous following a second-order rate reaction. The bimolecular rate constant (k(i)) values of ChE inhibition by the tested pesticides were also estimated and compared with available data from other invertebrate and vertebrate species. In conclusion, the results of the present study showed that prawn eyes possess only one ChE with typical properties of acetylcholinesterase, which is highly sensitive to the tested anti-cholinesterase compounds.

Origin of acetylcholinesterase in the neuromuscular junction formed in the in vitro innervated human muscle

Synaptic basal lamina is interposed between the pre- and postsynaptic membrane of the neuromuscular junction (NMJ). This position permits deposition of basal lamina-bound NMJ components of both neuronal and muscle fibre origin. One such molecule is acetylcholinesterase (AChE). The origin of NMJ AChE has been investigated previously as the answer would elucidate the relative contributions of muscle fibers and motor neurons to NMJ formation. However, in the experimental models used in prior investigations either the neuronal or muscular components of the NMJs were removed, or the NMJs were poorly differentiated. Therefore, the question of AChE origin in the intact and functional NMJ remains open. Here, we have approached this question using an in vitro model in which motor neurons, growing from embryonic rat spinal cord explants, form well differentiated NMJs with cultured human myotubes. By immunocytochemical staining with species-specific anti-AChE antibodies, we are able to differentiate between human (muscular) and rat (neuronal) AChE at the NMJ. We observed strong signal at the NMJ after staining with human AChE antibodies, which suggests a significant muscular AChE contribution. However, a weaker, but still clearly recognizable signal is observed after staining with rat AChE antibodies, suggesting a smaller fraction of AChE was derived from motor neurons. This is the first report demonstrating that both motor neuron and myotube contribute synaptic AChE under conditions where they interact with each other in the formation of an intact and functional NMJ.

Evaluation of mechanisms of azinphos-methyl resistance in the codling moth Cydia pomonella (L.)

Resistance of the codling moth Cydia pomonella (L.) to azinphos-methyl is not based on enhanced detoxifying enzymes like oxidation mediated by mixed function oxidases or by glutathione S-transferases. Synergism by S,S,S-tributylphosphoro-trithioate was evident, but the overall activity of general esterases using p-nitrophenyl acetate as the substrate was similar in resistant and susceptible insects. In comparison to acetylcholinesterase (AChE) from susceptible adult codling moth, the enzyme of insects resistant to azinphos-methyl has low affinities (higher K(m) values) to the substrates acetylthiocholine (ATCh) and propionylthiocholine. This difference indicates a possible amino acid alteration at the catalytic or anionic binding sites of the resistant enzyme. Inhibition studies revealed no apparent differences in sensitivity of AChE enzymes from resistant and susceptible moths to organophosphorus compounds (OPs), carbamate insecticides and quaternary ammonium ligands. MEPQ (7-Methylethoxyphosphinyloxy)-1-methylquinolinium) is the most powerful OP inhibitor acting at a nM range, while chlopyrifos oxon, azinphos-methyl oxon and paraoxon are less inhibitory by 22.9, 82.3 and 475 fold, respectively. The codling moth AChE is a typical enzyme that displays substrate inhibition by ATCh, negligible hydrolysis of butyrylthiocholine, very high sensitivity to the bisquaternary ammonium compound BW284c51 and it is not inhibited by the powerful butyrylcholinesterase inhibitor iso-OMPA. Of the three carbamates examined, only carbaryl was inhibitory at the mM range while pirimicarb and aldicarb were inactive. Of the quaternary ammonium ligands (except for the powerful BW284c51), edrophonium and decamethonium displayed appreciable inhibition rates, while d-tubocuraine was practically inactive.

Characterization of cholinesterase activity from different tissues of Nile tilapia (Oreochromis niloticus)

Cholinesterases (ChE) from brain, muscle and liver in Nile tilapia (Oreochromis niloticus) were characterized using three substrates: acetylthiocholine iodide, propionylthiocholine iodide, and butyrylthiocholine iodide. Eserine was used as a total ChE inhibitor; BW284c51 and iso-OMPA were used as selective inhibitors for acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE), respectively. The results indicate that AChE is the enzyme present in brain, whereas in both liver and muscle, the presence of atypical ChEs are suggested. These findings indicate that characterization of ChE is necessary prior to use in monitoring programs.

Partial Purification and Characterization of Soluble Isoform of Butyrylcholinesterase from Rat Intestine

Butyrylcholinesterase (BChE; E.C. 3.1.1.8.) was 260-fold purified from soluble fraction of rat intestine. The enzyme was composed of tetrameric globular form by nonreducing electrophoresis. Optimum pH value was determined as 7.2 after zero buffer extrapolation. Optimum temperature was examined as 37 degrees C after zero time extrapolation. The enzyme showed marked substrate activation with positively charged, acyl-choline substrates. As a measure of catalytic efficiency, kcat/Km values were determined as 16,210, 25,650, and 46,150 for acetylthiocholine (ATCh), propionylthiocholine (PTCh), and butyrylthiocholine (BTCh), respectively. When the catalytic efficiencies are compared, soluble isoform of rat intestinal BChE became increasingly efficient as the size of the acyl portion of the substrate increases; BTCh > PTCh > ATCh. Differently, the enzyme showed substrate inhibition with benzoylcholine (BzCh) and a kcat/Km value of 21,190 was found. Triton X-100 inhibited more efficiently the rat intestinal BChE soluble isoform than it did the human serum BChE.

Assay using succinyldithiocholine as substrate: the method of choice for the measurement of cholinesterase catalytic activity in serum to diagnose succinyldicholine sensitivity

No comparative information is available concerning the ability of various cholinesterase (ChE) methods to identify succinyldicholine-sensitive patients, purely on the basis of the enzyme activity recorded in serum. Here, we evaluated six different methods for the measurement of ChE activity; 131 subjects were subdivided according to ChE phenotype and, therefore, to succinyldicholine sensitivity. ChE phenotype was determined by measuring dibucaine and fluoride numbers. DNA analysis was also performed to confirm correlation between the phenotype classification used in the study and the ChE genotype. The tested methods were significantly different in their ability to discriminate between the subjects with and without succinyldicholine-sensitive phenotypes. The succinyldithiocholine/5,5'-dithio-bis(2-nitrobenzoate) (DTNB) method showed the highest accuracy (area under the receiver operating characteristic (ROC) curve 0.97) followed by the propionylthiocholine/DTNB method (area under the ROC curve 0.94). On the other hand, the two methods using butyrylthiocholine as substrate and that employing benzoylcholine showed limited clinical utility in discriminating subjects at risk of prolonged apnea (area under the ROC curve < or = 0.9). Using the succinyldithiocholine method, a value < or = 23 U/l was approximately five times as likely to occur in a sensitive individual as in a normal one.

DNA sequence of butyrylcholinesterase from the rat: expression of the protein and characterization of the properties of rat butyrylcholinesterase

The rat is the model animal for toxicity studies. Butyrylcholinesterase (BChE), being sensitive to inhibition by some organophosphorus and carbamate pesticides, is a biomarker of toxic exposure. The goal of this work was to characterize the purified rat BChE enzyme. The cDNA sequence showed eight amino acid differences between the active site gorge of rat and human BChE, six clustered around the acyl binding pocket and two below the active site serine. A prominent difference in rat was the substitution of arginine for leucine at position 286 in the acyl pocket. Wild-type rat BChE, the mutant R286L, wild-type human BChE, and the mutant L286R were expressed in CHO cells and purified. Arg286 was found responsible for the resistance of rat BChE to inhibition by Triton X-100. Replacement of Arg286 with leucine caused the affinity for Triton X-100 to increase 20-fold, making it as sensitive as human BChE to inhibition by Triton X-100. Wild-type rat BChE had an 8- to 9-fold higher K(m) for the positively charged substrates butyrylthiocholine, acetylthiocholine, propionylthiocholine, benzoylcholine, and cocaine compared with wild-type human BChE. Wild-type rat BChE catalyzed turnover 2- to 7-fold more rapidly than human BChE, showing the highest turnover with propionylthiocholine (201,000 min(-1)). Human BChE does not reactivate spontaneously after inhibition by echothiophate, but rat BChE reactivates with a half-life of 4.3hr. Human serum contains 5mg/L of BChE and 0.01mg/L of AChE. Male rat serum contains 0.2mg/L of BChE and approximately 0.2mg/L of AChE.

Effects of salinity on aldicarb toxicity in juvenile rainbow trout (Oncorhynchus mykiss) and striped bass (Morone saxatilis x chrysops)

Fluctuations in several environmental variables, such as salinity, can influence the interactions between organisms and pollutants in aquatic organisms, and, therefore, affect the toxicity of xenobiotics. In this study, after 2 species of fish, rainbow trout (Oncorhynchus mykiss) and hybrid striped bass (Morone saxatilis x chrysops) were acclimated to 4 salinity regimens of 1.5, 7, 14, and 21 ppt for 1 week and then exposed to 0.5 mg/l aldicarb. Mortality, brain, and muscle cholinesterase levels were measured after 96 h. Rates of (14)C-aldicarb sulfoxide formation were determined in kidney (trout only), liver, and gill microsomes from each species acclimated to the 4 salinity regimens. Salinity significantly enhanced aldicarb toxicity, cholinesterase inhibition, and (14)C-aldicarb sulfoxide formation in rainbow trout but not in striped bass. In vitro incubations with (14)C-aldicarb and the cytochrome P450 (CYP) inhibitor, N-benzylimidazole, did not significantly alter aldicarb sulfoxide formation in tissue microsomes from either species of fish, indicating CYP did not contribute to aldicarb sulfoxidation. Salinity increased flavin-containing monooxygenase (FMO) mRNA expression and catalytic activities in microsomes of liver, gill, and kidney of rainbow trout, which was consistent with the salinity-induced enhancement of aldicarb toxicity. Salinity did not alter FMO mRNA expression and catalytic activities in striped bass, which was also consistent with the lack of an effect of salinity on aldicarb toxicity in this species. These results suggest that salinity-mediated enhancement of aldicarb toxicity is species-dependent, and at least partially due to the salinity-related upregulation of FMOs, which, in turn, increases the bioactivation of aldicarb to aldicarb sulfoxide, which is a more potent inhibitor of cholinesterase than aldicarb.

Determination of whole blood cholinesterase in different animal species using specific substrates

Whole blood cholinesterase was measured using acetyl-, butyryl- and propionylthiocholine as substrates in 10 healthy adult dogs, cats, horses, pigs, goats, sheep and cows, in order to determine and characterise the cholinesterase activity in whole blood of the main domestic animals. An in vitro exposure test with two anticholinesterase compounds, the organophosphate insecticide coumaphos and the carbamate insecticide imidocarb, was also performed. In whole blood of ruminants and pigs, acetylthiocholine yielded the highest cholinesterase activity and other substrates were poorly hydrolysed; in dogs and cats, although acetylthiocholine showed the highest cholinesterase activity, butyryl- and propionylthiocholine also produced high cholinesterase values; in horses, propionylthiocholine was the substrate that yielded the highest cholinesterase activity, closely followed by butyrylthiocholine. All within- and between-run coefficients of variation observed in whole blood samples were less than 5 and 7 per cent, respectively, except when butyrylthiocholine was used as substrate in ruminant blood samples. Butyryl- and propionylthiocholine were the substrates that yielded higher inhibitions after coumaphos exposure, whereas the use of acetylthiocholine showed the highest cholinesterase inhibition after imidocarb exposure. The use of at least two substrates (acetyl and butyrylthiocholine) is recommended for whole blood cholinesterase analyses in domestic animals since it will allow monitoring of both acetyl- and butyrylcholinesterase activities, respectively, and a more accurate detection of exposure to anticholinesterase compounds. However, acetylthiocholine could be used as a unique substrate for whole blood cholinesterase determination in porcine and ruminant samples since butyrylcholinesterase activity is very low in these species. Additionally, propionylthiocholine could be used as an alternative substrate to butyrylthiocholine in horse whole blood samples.

Organophosphate inhibition of human heart muscle cholinesterase isoenzymes

The rate of acetylcholine hydrolysis of mammalian heart muscle influences cardiac responses to vagal innervation. We characterized cholinesterases of human left ventricular heart muscle with respect to both substrate specificity and irreversible inhibition kinetics with the organophosphorus inhibitor N,N'-di-isopropylphosphorodiamidic fluoride (mipafox). Specimens were obtained postmortem from three men and four women (61 +/- 5 years) with no history of cardiovascular disease. Myocardial choline ester hydrolyzing activity was determined with acetylthiocholine (ASCh; 1.25 mM), acetyl-beta-methylthiocholine (AbetaMSCh; 2.0 mM), and butyrylthiocholine (BSCh; 30 mM). After irreversible and covalent inhibition (60 min; 25 degrees C) with a wide range of mipafox concentrations (50 nM-5 mM), residual choline ester hydrolyzing activities were fitted to a sum of up to five exponentials using weighted least-squares non-linear curve fitting. In each ease, quality of curve fitting reached its optimum on the basis of a four component model. Final classification of heart muscle cholinesterases was achieved according to substrate hydrolysis patterns (nmol/min per g wet weight) and to second-order organophosphate inhibition rate constants k2 (1/mol per min); one choline ester hydrolyzing enzyme was identified as acetylcholinesterase (AChE; k2/mipafox = 6.1 (+/- 0.8) x 10(2)), and one as butyrylcholinesterase (BChE; k2/mipafox = 5.3 (+/- 1.1) x 10(3)). An enzyme exhibiting both ChE-like substrate specificity and relative resistance to mipafox inhibition (k2/mipafox = 5.2 (+/- 1.0) x 10(-1)) was classified as atypical cholinesterase.

An explanation for the different inhibitory characteristics of human serum butyrylcholinesterase phenotypes deriving from inhibition of atypical heterozygotes

The time course of inhibition of butyrylcholinesterase (EC 3.1.1.8) by the dimethylcarbamate Ro 02-0683 in sera taken from patients heterozygous for the usual (U), atypical (A), K or J variants was followed using propionylthiocholine as substrate. Data obtained were used to determine rate constants of inhibition together with the contribution made by each variant to total enzyme activity. The findings substantiate earlier reports that J and K mutations lead to quantitative changes in the concentration of usual enzyme in contrast to the qualitative changes of the atypical variant. The contribution of the atypical enzyme to the total activity in serum from UA, AK and AJ heterozygotes was respectively 17-20, 24-31 and 34-53%. The altered ratios of atypical to usual, K or J enzyme in UA, AK and AJ together with the constants on the usual enzyme alone, explain the differences in observed inhibitor numbers which enable these heterozygotes to be identified.

Activation of microsomal glutathione S-transferase and inhibition of cytochrome P450 1A1 activity as a model system for detecting protein alkylation by thiourea-containing compounds in rat liver microsomes

The recent development of several promising new thiourea-containing drugs has renewed interest in the thiourea functionality as a potential toxicophore. Most adverse reactions of thiourea-containing compounds are attributed to the thionocarbonyl moiety. Oxidation of these thionocarbonyl compounds by flavin-containing monooxygenases (FMO) and cytochrome P450 isoenzymes (P450) to reactive sulfenic, sulfinic, or sulfonic acids leads to alkylation of essential macromolecules. To more rationally design thiourea-containing drugs, structure-toxicity relationships (STRs) must be derived. Since for the development of STRs a large number of thiourea-containing compounds must be investigated, it is important to develop rapid in vitro assays for alkylating potential. In this study, the utility of activation of microsomal glutathione S-transferase (mGST) and inactivation of P450 1A1 as markers of the alkylating potential of metabolites of thiourea-containing compounds was investigated. It was found that metabolites of thiourea-containing compounds inactivate P450 1A1 in a time-dependent manner, as evidenced by a decrease in 7-ethoxyresorufin O-dealkylation (EROD) activity. An extent of inactivation of P450 1A1 by 100 microM N-phenylthiourea (PTU) of 64% was found after 10 min. This inactivation was dependent on the presence of NADPH and the presence of the thionosulfur, since the carbonyl analogue of PTU was not found to inactivate P450 1A1, and was partially prevented by heat treatment of the microsomes which is known to selectively inactivate FMO enzymes. Inactivation of P450 1A1 could be reversed by treatment with dithiothreitol, indicating the formation of disulfide bonds. However, thiourea-containing compounds also inhibited the EROD activity of P450 1A1 in a competitive manner. This property complicates the usefulness of the EROD activity of P450 1A1 as a marker for the alkylating potential of thiourea-containing compounds. It was found that metabolites of thiourea-containing compounds could transiently activate the mGST. A maximal level of activation by 100 microM PTU of 162+/-16% was found after 10 min. Activation of mGST by 100 microM PTU was dependent on the presence of NADPH and the presence of the thionosulfur, since the carbonyl analogue of PTU was not found to activate mGST. Activation was completely prevented by heat treatment of the microsomes, indicating involvement of FMO in the bioactivation process. Finally, a series of structurally diverse thiourea-containing compounds were tested for their ability to activate mGST. It appeared that their potency in alkylating mGST was inversely related to their Vmax/Km value for the FMO enzyme. From this study, it is concluded that, whereas activation of mGST in rat liver microsomes may be a useful system with which to investigate the relationship between structure and alkylating potential of thiourea-containing compounds in vitro, inactivation of P450 1A1 is not.

A putative kinetic model for substrate metabolisation by Drosophila acetylcholinesterase

Insect acetylcholinesterase, an enzyme whose catalytic site is located at the bottom of a gorge, can metabolise its substrate in a wide range of concentrations (from 1 microM to 200 mM) since it is activated at low substrate concentrations. It also presents inhibition at high substrate concentrations. Among the various rival kinetic models tested to analyse the kinetic behaviour of the enzyme, the simplest able to explain all the experimental data suggests that there are two sites for substrate molecules on the protein. Binding on the catalytic site located at the bottom of the gorge seems to be irreversible, suggesting that each molecule of substrate which enters the active site gorge is metabolised. Reversible binding at the peripheral site of the free enzyme has high affinity (2 microM), suggesting that this binding increases the probability of the substrate entering the active site gorge. Peripheral site occupation decreases the entrance rate constant of the second substrate molecule to the catalytic site and strongly affects the catalytic activity of the enzyme. On the other hand, catalytic site occupation lowers the affinity of the peripheral site for the substrate (34 mM). These effects between the two sites result both in apparent activation at low substrate concentration and in general inhibition at high substrate concentration.

Cytotoxicity of a series of mono- and di-substituted thiourea in freshly isolated rat hepatocytes: a preliminary structure-toxicity relationship study

The cytotoxicity of a series of 12 mono- and 4 di-substituted thiourea containing compounds in freshly isolated rat hepatocytes was investigated. It was found that thiourea toxicity, as evidenced by an increase in LDH-leakage from the cells, was accompanied by a depletion of intracellular glutathione (GSH). No increase in lipid peroxidation was observed with any of the thiourea. Burimamide and thioperamide, thiourea-containing histamine receptor ligands, were also found to deplete intracellular GSH. A clear structure-toxicity relationship was uncovered among a homologous series of N-phenylalkylthiourea. N-benzylthiourea (BTU) and N-phenylethylthiourea (PETU) were found to be non-toxic at a concentration of 1 mM, while N-phenylpropylthiourea (PPTU) and N-phenylbutylthiourea (PBTU) were found to cause significant LDH-leakage from the cells, accompanied by a depletion of intracellular GSH. This structure-toxicity relationship was further investigated using hepatocytes of differentially induced rats, however, no significantly different results were obtained when using hepatocytes of rats induced with phenobarbital (PB) or beta-naphthoflavone (BNF). Oxidation of the thiourea moiety is thought to be the first step in the bioactivation of thiourea containing compounds. The oxidation of thiocholine sulfenic acids, produced by FMO-mediated oxidation of the thiourea moiety, was used to determine whether the compounds examined are substrates for the FMO enzymes in rat liver. No clear relationship was found between cytotoxicity of the mono-substituted thiourea and lipophilicity of the N-substituent, nor with the FMO-mediated oxidation of the thionosulfur atom of the mono-substituted thiourea. It is concluded from this study, that thiourea toxicity in rat hepatocytes is structure-dependent and manifests itself as LDH-leakage and as a depletion of intracellular non-protein sulfhydryls, notably GSH, most likely followed by alkylation of vital macromolecular structures.

Characterization of acetylcholinesterase purified from the lesser grain borer, Rhyzopertha dominica (Coleoptera: Bostrichidae)

Acetylcholinesterase (AChE, EC 3.1.1.7) purified from the lesser grain borer (Rhyzopertha dominica) was significantly inhibited by higher concentrations of the substrates acetylthiocholine (ATC), acetyl-(beta-methyl) thiocholine (A beta MTC) and propionylthiocholine (PTC). 2. The efficiency of AChE for hydrolyzing different substrates was ATC > A beta MTC > PTC > S-butyrylthiocholine. The enzyme activity was completely inhibited by 10(-5) M eserine or BW284C51, but was only partially inhibited by ethopropazine at the same concentration. These results confirmed that the purified enzyme was an typical insect AChE. 3. Non-denaturing and SDS polyacrylamide gel electrophoresis (PAGE) showed only one major molecular form in the purified AChE with a molecular weight of about 107,000 prior to reduction and about 56,000 after reduction, suggesting the homodimer of AChE linked with disulfide bonds.

Investigation of the effect of tetrahydroaminoacridine on turnover kinetics of camel (Camelus dromedarius) retina acetylcholinesterase

The effect of tetrahydroaminoacridine (THA) on turnover kinetics of camel retina acetylcholinesterase has been investigated. The turnover number (Kcat) and specificity constant (Ksp) were 62.1 min-1 and 9.92 x 10(5) (M. min)-1 in the control system while the values for both parameters were lowered by 25-68% and 48-87% in the THA (0.05-0.4 microM) treated systems respectively. Therefore, THA's effect on turnover number must be considered at the time of therapy to the Alzheimer's disease patients.

Dissection of the human acetylcholinesterase active center determinants of substrate specificity. Identification of residues constituting the anionic site, the hydrophobic site, and the acyl pocket

Substrate specificity determinants of human acetylcholinesterase (HuAChE) were identified by combination of molecular modeling and kinetic studies with enzymes mutated in residues Trp-86, Trp-286, Phe-295, Phe-297, Tyr-337, and Phe-338. The substitution of Trp-86 by alanine resulted in a 660-fold decrease in affinity for acetythiocholine but had no effect on affinity for the isosteric uncharged substrate (3,3-dimethylbutylthioacetate). The results demonstrate that residue Trp-86 is the anionic site which binds, through cation-pi interactions, the quaternary ammonium of choline, and that of active center inhibitors such as edrophonium. The results also suggest that in the non-covalent complex, charged and uncharged substrates with a common acyl moiety (acetyl) bind to different molecular environments. The hydrophobic site for the alcoholic portion of the covalent adduct (tetrahedral intermediate) includes residues Trp-86, Tyr-337, and Phe-338, which operate through nonpolar and/or stacking interactions, depending on the substrate. Substrates containing choline but differing in the acyl moiety (acetyl, propyl, and butyryl) revealed that residues Phe-295 and Phe-297 determine substrate specificity of the acyl pocket for the covalent adducts. Phe-295 also determines substrate specificity in the non-covalent enzyme substrate complex and thus, the HuAChE F295A mutant exhibits over 130-fold increase in the apparent bimolecular rate constant for butyrylthiocholine compared with wild type enzyme. Reactivity toward specific butyrylcholinesterase inhibitors is similarly dependent on the nature of residues at positions 295 and 297. Amino acid Trp-286 at the rim of the active site "gorge" and Trp-86, in the active center, are essential elements in the mechanism of inhibition by propidium, a peripheral anionic site ligand. Molecular modeling and kinetic data suggest that a cross-talk between Trp-286 and Trp-86 can result in reorientation of Trp-86 which may then interfere with stabilization of substrate enzyme complexes. It is proposed that the conformational flexibility of aromatic residues generates a plasticity in the active center that contributes to the high efficiency of AChE and its ability to respond to external stimuli.

Differentiation of esterases reacting with organophosphorus compounds

The hydrolysis of paraoxon (POX), phenylacetate (PA) and beta-naphthylacetate (BNA) was studied in human serum. Based upon correlations between enzyme activities, upon reversible inhibition by EDTA and upon progressive inhibition by iso-OMPA, tabun, eserine and bis-4 nitrophenylphosphate, the following conclusions were drawn about the number and specificity of enzymes involved in the hydrolysis. Two paraxonases hydrolyse paraoxon: one sensitive and the other insensitive to EDTA. The EDTA-sensitive paraoxonase also hydrolysed BNA. The EDTA-insensitive hydrolysis of BNA and PA was attributed to a serine esterase. The EDTA-sensitive hydrolysis of PA is probably due to more than one enzyme, which might be an arylesterase and a carboxylesterase.

Estimation of flavin-containing monooxygenase activities in crude tissue preparations by thiourea-dependent oxidation of thiocholine

The activity of flavin-containing monooxygenases in microsomes and whole homogenates is readily estimated by following the thiourea-dependent oxidation of thiocholine. NADPH- and oxygen-dependent flavin-containing monooxygenases catalyze the oxidation of thiourea to formamidine sulfenic acid, which oxidizes thiocholine to thiocholine disulfide. The latter reaction is quite rapid and never rate limiting even at concentrations of thiocholine below 30 microM. The loss of thiocholine in deproteinized aliquots of the reaction medium is measured colorimetrically with the thiol reagent, DTNB [5,5'-dithiobis(2-nitrobenzoate)]. In the absence of thiourea, thiocholine is not oxidized and its disulfide is not reduced at a detectable rate even in reactions containing 4-5 mg of liver or kidney homogenate protein per milliliter. In all tissues where both can be measured, rates of thiocholine oxidation and N,N-dimethylaniline N-oxygenation were virtually identical, which suggests that both activities are catalyzed by the same monooxygenase.

Immunological assay of erythrocyte acetylcholinesterase

An immunoassay for the quantitation of erythrocyte surface acetylcholinesterase is described; using a red cell suspension, bound mouse monoclonal acetylcholinesterase antibody is detected by an alkaline phosphatase conjugated rabbit anti mouse IgG. Extraction is not required. In addition, the activity of erythrocyte surface acetylcholinesterase using dithiobisnitrobenzoate to detect released thiocholine has been measured. The coefficient of variation for each method is 7%. Reference ranges have been established for healthy adults and cord blood.

Pseudomonas aeruginosa cholinesterase and phosphorylcholine phosphatase: two enzymes contributing to corneal infection

Choline, acetylcholine and betaine used as the sole carbon, nitrogen or carbon and nitrogen source increase cholinesterase activity in addition to phosphorylcholine phosphatase and phospholipase C activities in Pseudomonas aeruginosa. The cholinesterase activity catalyses the hydrolysis of acetylthiocholine (Km approx. 0.13 mM) and propionylthiocholine (Km approx. 0.26 mM), but not butyrylthiocholine, which is a pure competitive inhibitor (Ki 0.05 mM). Increasing choline concentrations in the assay mixture decreased the affinity of cholinesterase for acetylthiocholine, but in all cases prevented inhibition raised by high substrate concentrations. Considering the properties of these enzymes, and the fact that in the corneal epithelium there exists a high acetylcholine concentration and that Pseudomonas aeruginosa produces corneal infection, it is proposed that these enzymes acting coordinately might contribute to the breakdown of the corneal epithelial membrane.

Interspecific variations of cerebral endothelial cholinesterases in rodents and carnivores

The cholinesterase equipment of cerebral microvessels was studied in some rodents and carnivores using the Koelle-Friedenwald histochemical method with 3 artificial substrates and specific inhibitors for butyrylcholinesterase or acetylcholinesterase. Our observations reveal a great heterogeneity in cholinesterase types and their distribution in each of the different species studied. Only in the rat, butyrylcholinesterase appears to be a marker for the microvessels provided with a blood-brain barrier.

Characterization of a pseudocholinesterase purified from surgeonfish tissues confirms the atypical nature of this enzyme

The sialated, presumed-globular form of an atypical pseudocholinesterase (pseudo-ChE) previously described from surgeonfish tissues (Leibel: Comparative Biochemistry and Physiology 1988) has been purified to apparent homogeneity using a combination of salt fractionation along with ion-exchange and concanavalin A-Sepharose affinity chromatographic techniques. An overall 1,400-fold purification has been achieved with a 24% final yield of a cholinesterase (ChE) whose final specific activity is 50 mumol/min-mg. The purified enzyme was subjected to detailed biochemical and physical analysis. The purified pseudo-ChE is a sialated, globular, tetrameric enzyme with an apparent sedimentation coefficient of 11.5 S (+/- 0.5 S) and a molecular weight of 250 kilodaltons. The monomers are apparently not secured by disulfide bridges. The enzyme preferentially hydrolyzes acetyl(thio)choline but also hydrolyzes propionyl(thio)choline at reduced but comparable rates along with a wide variety of other noncholine esters. As such, it demonstrates the relative nonspecificity associated with classical pseudo-ChEs. However, the enzyme exhibits limited, but real, substrate inhibition with all choline esters as does true acetylcholinesterase (AChE). The enzyme is insensitive to the AChE inhibitor BW 284C51, sensitive to one (RO2-0683) of two (RO2-1250) pseudo-ChE inhibitors, and particularly sensitive to paraoxon inhibition (10(3)-10(4)-fold more so than AChE). It exhibits the short thermal half-life characteristic of pseudo-ChEs but not the expected ionic activation/inhibition profile. It is clear from this and other studies of atypical extrasynaptic cholinesterase activities occurring in other vertebrates that the orthodox categorization of cholinesterase as either "true" ("specific"; E.C. 3.1.1.7) or "pseudo" ("nonspecific"; E.C. 3.1.1.8) is inadequate to accommodate the increasing instances of ChE activities that exhibit atypical, intermediate properties.

The hydrolysis of succinyldithiocholine and related thiocholine esters by human plasma and purified cholinesterase

The kinetic properties of cholinesterase (ChE) present in plasma were compared with those of purified human ChE using the substrates succinyldithiocholine (SDTCh), acetylthiocholine (AcTCh) and butyrylthiocholine (BuTCh). SDTCh was hydrolysed at two sites; a site with a low Km (Km1 11.4 +/- 3.3 microM) with a Vmax of 0.06 mumol/min/ml and a site with a high Km (Km2 132.4 +/- 14.8 microM) and a Vmax of 0.107 mumol/min/ml. The Km2 site was absent in the sample of purified ChE. The related thiocholine esters, AcTCh and BuTCh were hydrolysed at two sites by both plasma and purified ChE. This indicated that the Km2 site which hydrolysed SDTCh was not ChE. The identity of this component in plasma remains unknown but it was shown not to be albumin. The anticholinesterase agents soman and pyridostigmine were used to demonstrate the direct relationship between inhibition of plasma ChE and hydrolysis of SDTCh at the low concentrations present clinically (20 microM). Whereas high concentrations of SDTCh (200 micron) could be partly hydrolysed by an enzyme present in plasma which is insensitive to ChE inhibitors. In a limited study on the plasma from two "atypical" individuals (Dibucaine number less than 20) all three substrates were hydrolysed at a single site with a higher Km than the Km2 site present in normal plasma. The clinical implications of these results are discussed.

Distribution of 'non-specific' cholinesterase-containing neurons in the dorsal thalamus of the rat

This report describes the distribution of histochemically identified 'non-specific' cholinesterase (ChE)-containing neurons in the dorsal thalamus of the rat. Juvenile or young adult Long-Evans or Sprague-Dawley rats were sacrificed by formalin perfusion. Some animals received systemic injections of 1.5-2.0 mg/kg DFP 4-24 h prior to sacrifice. Separate series of 50 micron frozen sections were processed for cholinesterase histochemistry using acetylthiocholine, butyrylthiocholine, or propionylthiocholine as substrates. Adjacent sections processed with each of the 3 substrates allowed comparison of the distributions of neurons containing the histochemical reaction products. Neurons containing moderate to high concentrations of ChE reaction product were found in 3 distinct regions of the dorsal thalamus. First, neurons staining intensely for ChE were found in a cluster that corresponds to the thalamic reuniens nucleus. Second, a cluster of neurons staining intensely for ChE was found in a region that included the lateral part of the central lateral nucleus and extended laterally into the ventral-lateral part of the lateral dorsal nucleus. Third, moderate ChE staining was observed in the neurons of the anterior dorsal nucleus. Of these regions, only the anterior dorsal nucleus shows moderate to high levels of acetylcholinesterase. The function of ChE in normal brain function is unknown. It is particularly interesting, however, that the thalamic nuclei containing ChE-positive neurons send thalamocortical projections to the medial limbic cortex, including cingulate, retrosplenial and subicular cortices.

Comparison of a commercially available assay system with two reference methods for the determination of plasma cholinesterase variants

For assaying plasma cholinesterase (EC 3.1.1.8) activity and phenotyping by means of dibucaine inhibition, we have compared a commercially available kit, in which butyrylthiocholine is used as substrate, with two reference methods, one using benzoylcholine and the other propionylthiocholine. With 50 different samples of three of the most common genetic variants, we could clearly differentiate the variants with benzoylcholine and dibucaine, whereas there was some overlap of the E1uE1u and E1uE1a phenotypes with the other two substrates at 30 degrees C. The phenotypes were better differentiated at 25 degrees C, and in our hands the use of butyrylthiocholine was preferable to propionylthiocholine for phenotyping with dibucaine. The affinity of the usual and atypical homozygotes for fluoride with butyrylthiocholine gave an inverted response to the affinity of these variants for the anion with benzoylcholine. We suggest that this may be explained by the role of the chromogen or its products in the assay procedure with the thiocholine substrate.

A modification of thiocholine-ferricyanide method of Karnovsky and Roots for localization of acetylcholinesterase activity without interference by Koelle's copper thiocholine iodide precipitate

In the original Karnovsky and Roots' method for the localization of acetylcholinesterase (AChE), thiocholine reduces the ferricyanide and cupric ions of this medium competitively, giving simultaneously cupric (Koelle's precipitate) as histochemical products. We modified the method in order to promote the true Karnovsky's reaction, and to slow down the secondary Koelle's reaction by increasing the concentration of the ferricyanide ion from 0.5 mM to 5.0 mM and by decreasing the concentration of the cupric ion from 3.0 mM to 2.5 mM. The cupric ion, complexed with 5 mM sodium citrate in the original method, was further stabilized by the use of 0.1 M citrate buffer in order to prevent the interaction of cupric ion with increased ferricyanide. In order to suppress completely the residual Koelle's precipitate, we used acetylthiocholine chloride as a substrate, instead of acetylthiocholine iodide. The chloride salt of cuprous thiocholine is soluble, contrary to the iodide salt. In addition, the pH of the medium was lowered from 6.0 to 5.0 to avoid artefactual nuclear staining, appearing at a pH beyond 5.5. In this modified medium, Karnovsky's cupric ferrocyanide becomes the sole precipitate at the enzymatic site and this provides fine localization of acetylcholinesterase activity.

Is serum cholinesterase activity a predictor of succinyl choline sensitivity? An assessment of four methods

Four methods for measuring serum cholinesterase activity have been applied to sera of normal individuals and of patients shown to be sensitive to short-acting muscle relaxants of the succinyldicholine type. They have been assessed according to their ability to differentiate between sensitive and insensitive individuals on the basis of enzyme activity measurements alone. The method described, based upon that of Dietz et al. [Clin. Chem. 19, 1309 (1973)], in which propionylthiocholine is used as substrate, is best for this purpose, being capable of identifying over 90% of affected individuals with no false positives. Acetylcholine and butyrylthiocholine are slightly inferior substrates in this respect, and benzoylcholine gives little useful information.

[Properties of the nervous tissue cholinesterase and carboxylesterase in the locust, Locusta migratoria]

It was shown that locust cholinesterase splits various thiocholine esters with different rate. Hydrolysis of p-NPA is due to the effect of carboxylesterase. The latter differs from cholinesterase by a low sensitivity to eserine and cation-containing organophosphorus inhibitor methylsulfomethylate-O-ethyl-S-(beta-ethylmercaptoethyl) methylthiophosphonate, as well as by higher sensitivity to triorthocresylphosphate. The results obtained are discussed in relation to possible differences of the active surface of the enzymes studied.

Innervation of scar tissue in the skin of the rat

In this study the reinnervation of scar tissue was investigated histochemically to demonstrate catecholamine fluorescence and nonspecific cholinesterase activity. The scarring was produced by healing and contraction of a defect in the dorsal skin of the rat. The first regenerating nerves showing nonspecific cholinesterase activity were observed in the scar four weeks postoperatively. Throughout the investigation period, that is up to twenty weeks after the operation, only free regenerated nerves were found in the scar; no encapsulated nerve endings were observed. No fluorescent adrenergic nerves were found in the dense collagenous part of the scar tissue. Regenerated fluorescent nerves were, however, observed in the loose regenerated connective tissue under the scar. Most of these nerves followed the course of blood vessels. In the present work a vigorous contraction of the scar tissue was noted and a poor innervation of the scar tissue with free nerves was observed. The role of these regenerated nerve endings in sensory discrimination, and the importance of different transmitters acting in the sensory system are discussed.

Some properties of cholinesterase of the plant nematode Aphelenchoides ritzema-boosi

Activity and properties of cholinesterase from Aphelenchoides ritzema-boosi, a plant feeding nematode, were investigated by testing the reaction of the enzyme with different substrates and inhibitors. Butyrylthiocholine was a better substrate than propionyl- and acetylthiochine. When compared with mammaliian erythrocyte and plasma cholinesterase, the nematode enzyme was found to be extremely insensitive towards a number of well-known organophosphorus and carbamate inhibitors.

Effect of pH, temperature and incubation period on the study of intrinsic innervation of various organs by thiocholine technique in certain vertebrates

The adrenergic fibres can be demonstrated if the optimal time and temperature are maintained. The cholinergic fibres were demonstrated at pH 5.2, incubation period l4h and temperature 37 degrees C. To ascertain the cholinesterase activity in tongue, heart, lung(birds, mammals and reptiles), gizzard and proventriculus (birds) and penis (rat and embryo of squirrel), pH 4.9, 16h incubation and temperature 37 degrees C, were quite suitable. It was possible to demonstrate the intrinsic innervation in tongue, lung, heart (mammals, birds and reptiles), gizzard and proventriculus (birds) and penis (rat and embryo of squirrel), at pH 5.2, 20h incubation and temperature 40 degrees C.