Endochondral Ossification Is Accelerated in Cholinesterase-Deficient Mice and in Avian Mesenchymal Micromass Cultures.

Most components of the cholinergic system are detected in skeletogenic cell types in vitro, yet the function of this system in skeletogenesis remains unclear. Here, we analyzed endochondral ossification in mutant murine fetuses, in which genes of the rate-limiting cholinergic enzymes acetyl- (AChE), or butyrylcholinesterase (BChE), or both were deleted (called here A-B+, A+B-, A-B-, respectively). In all mutant embryos bone growth and cartilage remodeling into mineralizing bone were accelerated, as revealed by Alcian blue (A-blu) and Alizarin red (A-red) staining. In A+B- and A-B- onset of mineralization was observed before E13.5, about 2 days earlier than in wild type and A-B+ mice. In all mutants between E18.5 to birth A-blu staining disappeared from epiphyses prematurely. Instead, A-blu+ cells were dislocated into diaphyses, most pronounced so in A-B- mutants, indicating additive effects of both missing ChEs in A-B- mutant mice. The remodeling effects were supported by in situ hybridization (ISH) experiments performed on cryosections from A-B- mice, in which Ihh, Runx2, MMP-13, ALP, Col-II and Col-X were considerably decreased, or had disappeared between E18.5 and P0. With a second approach, we applied an improved in vitro micromass model from chicken limb buds that allowed histological distinction between areas of cartilage, apoptosis and mineralization. When treated with the AChE inhibitor BW284c51, or with nicotine, there was decrease in cartilage and accelerated mineralization, suggesting that these effects were mediated through nicotinic receptors (α7-nAChR). We conclude that due to absence of either one or both cholinesterases in KO mice, or inhibition of AChE in chicken micromass cultures, there is increase in cholinergic signalling, which leads to increased chondroblast production and premature mineralization, at the expense of incomplete chondrogenic differentiation. This emphasizes the importance of cholinergic signalling in cartilage and bone formation.

Learning performances and vulnerability to amyloid toxicity in the butyrylcholinesterase knockout mouse.

Butyrylcholinesterase (BChE) is an important enzyme for detoxication and metabolism of ester compounds. It also hydrolyzes the neurotransmitter acetylcholine (ACh) in pathological conditions and may play a role in Alzheimer's disease (AD). We here compared the learning ability and vulnerability to Aß toxicity in male and female BChE knockout (KO) mice and their 129Sv wild-type (Wt) controls. Animals tested for place learning in the water-maze showed increased acquisition slopes and presence in the training quadrant during the probe test. An increased passive avoidance response was also observed for males. BChE KO mice therefore showed enhanced learning ability in spatial and non-spatial memory tests. Intracerebroventricular (ICV) injection of increasing doses of amyloid-ß[25-35] (Aß25-35) peptide oligomers resulted, in Wt mice, in learning and memory deficits, oxidative stress and decrease in ACh hippocampal content. In BChE KO mice, the Aß25-35-induced deficit in place learning was attenuated in males and blocked in females. No change in lipid peroxidation or ACh levels was observed after Aß25-35 treatment in male or female BChE KO mice. These data showed that the genetic invalidation of BChE in mice augmented learning capacities and lowered the vulnerability to Aß toxicity.

Use of neuromuscular monitoring to detect prolonged effect of succinylcholine or mivacurium: three case reports.

Mutations in the butyrylcholinesterase gene can lead to a prolonged effect of the neuromuscular blocking agents, succinylcholine and mivacurium. If the anaesthesiologist is not aware of this condition, it may result in insufficient respiration after tracheal extubation. However, this can be avoided with the use of objective neuromuscular monitoring if used adequately. Three case reports of prolonged effect of succinylcholine or mivacurium were presented to illustrate the importance of neuromuscular monitoring during anaesthesia. In the first case, continuous intraoperative neuromuscular monitoring allowed a prolonged neuromuscular blockade to be discovered prior to tracheal extubation of the patient. The patient was extubated after successful reversal of the neuromuscular blockade. On the contrary, neuromuscular monitoring was not used during anaesthesia in the second patient; hence, the prolonged effect of the neuromuscular blocking agent was not discovered until after extubation. In the third patient, the lack of response to nerve stimulation was interpreted as a technical failure and the prolonged effect of succinylcholine was discovered when general anaesthesia was terminated. Both patients had insufficient respiration. They were therefore re-sedated, transferred to the intensive care unit and the tracheas were extubated after full recovery from neuromuscular blockade. We recommend the use of monitoring every time these agents are used, even with short-acting drugs like succinylcholine and mivacurium.

Unbiased expression mapping identifies a link between the complement and cholinergic systems in the rat central nervous system.

The complement system is activated in a wide spectrum of CNS diseases and is suggested to play a role in degenerative phenomena such as elimination of synaptic terminals. Still, little is known of mechanisms regulating complement activation in the CNS. Loss of synaptic terminals in the spinal cord after an experimental nerve injury is increased in the inbred DA strain compared with the PVG strain and is associated with expression of the upstream complement components C1q and C3, in the absence of membrane attack complex activation and neutrophil infiltration. To further dissect pathways regulating complement expression, we performed genome-wide expression profiling and linkage analysis in a large F2(DA × PVG) intercross, which identified quantitative trait loci regulating expression of C1qa, C1qb, C3, and C9. Unlike C1qa, C1qb, and C9, which all displayed distinct coregulation with different cis-regulated C-type lectins, C3 was regulated in a coexpression network immediately downstream of butyrylcholinesterase. Butyrylcholinesterase hydrolyses acetylcholine, which exerts immunoregulatory effects partly through TNF-α pathways. Accordingly, increased C3, but not C1q, expression was demonstrated in rat and mouse glia following TNF-α stimulation, which was abrogated in a dose-dependent manner by acetylcholine. These findings demonstrate new pathways regulating CNS complement expression using unbiased mapping in an experimental in vivo system. A direct link between cholinergic activity and complement activation is supported by in vitro experiments. The identification of distinct pathways subjected to regulation by naturally occurring genetic variability is of relevance for the understanding of disease mechanisms in neurologic conditions characterized by neuronal injury and complement activation.

[Interest of the cholinesterase assay during organophosphate poisonings]. / Intérêt du dosage des cholinestérases dans le cadre des intoxications aux organophosphorés.

Cholinesterases are the main targets of organophosphorus compounds. The two enzymes present in the blood (butyrylcholinesterase, BChE; acetylcholinesterase, AChE) are biomarkers of their systemic toxicity. Activity of the plasma BChE is very often determined as it allows a rapid diagnostic of poisoning and is a marker of the persistence of the toxicant in the blood. The activity of the red blood cell AChE gives a better picture of the synaptic inhibition in the nervous system but the assay is less commonly available in routine laboratories. Better biomarker of the exposure, it allows a diagnosis of the severity of the poisoning and helps to assess the efficacy of oxime therapy. Besides the practical aspects of blood collection and sample processing, and the interpretation of the assays, this review stresses the complementarity of both enzyme assays and recalls their crucial interest for the confirmation of poisoning with an organophosphorus in a situation of war or terrorist attack and for the monitoring of occupational exposures.

Differential effects of developmental hypo- and hyperthyroidism on acetylcholinesterase and butyrylcholinesterase activity in the spinal cord of developing postnatal rat pups.

The plasticity and vulnerability of the rat spinal cord (SC) during postnatal development has been less investigated compared to other CNS structures. In this study, we determined the effects of thyroid hormonal (TH) deficiency and excess on postnatal growth and neurochemical development of the rat SC. The growth as well as the specific and total activity of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) enzymes of the SC were determined in hypo- and hyperthyroid rat pups at postnatal (P) days P1, P5, P10 and P21 (weaning), and were compared to age-matched untreated normal controls. AChE is a cholinergic synaptic enzyme while BuChE is a metabolic enzyme mainly found in glial cells and neurovascular cells. The SC is rich in somatic motor, autonomic cholinergic neurons and associated interneurons. Daily subcutaneous injection of pups with thyroxine (T4) and administration of antithyroid goitrogen propylthiouracil (PTU) in the litter's drinking water were used to induce hyper- and hypothyroidism, respectively. Enzyme assays were carried out spectrophotometrically at the above-mentioned ages, using SC homogenates with acetylthiocholine-chloride as the substrate, together with specific cholinesterase inhibitors, which specifically target AChE and BuChE. SC weights were significantly lower at P10 and P21 in hypothyroid pups but unchanged in the hyperthyroid ones. Hypothyroidism significantly reduced both specific and total AChE activity in SC of P10 and P21 rat pups, while having no effects on the BuChE activity, although total BuChE activity was decreased due to reduced total tissue weight. In contrast both specific and total AChE activities were markedly and significantly increased (>100%) in the P10 and P21 hyperthyroid pups. However, BuChE specific activity was unaffected by this treatment. The results indicate that hypothyroid condition significantly reduces, while hyperthyroidism increases, the postnatal development of cholinergic synapses, thereby influencing the functional development of this major sensory and motor structure. However, the neurochemical development of glia and other non-neuronal cells, where BuChE is mainly localized, is comparatively unaffected in these abnormal developmental conditions.

Why has butyrylcholinesterase been retained? Structural and functional diversification in a duplicated gene.

While acetylcholinesterase (EC 3.1.1.7) has a clearly defined role in neurotransmission, the functions of its sister enzyme butyrylcholinesterase (EC 3.1.1.8) are more obscure. Numerous mutations, many inactivating, are observed in the human butyrylcholinesterase gene, and the butyrylcholinesterase knockout mouse has an essentially normal phenotype, suggesting that the enzyme may be redundant. Yet the gene has survived for many millions of years since the duplication of an ancestral acetylcholinesterase early in vertebrate evolution. In this paper, we ask the questions: why has butyrylcholinesterase been retained, and why are inactivating mutations apparently tolerated? Butyrylcholinesterase has diverged both structurally and in terms of tissue and cellular expression patterns from acetylcholinesterase. Butyrylcholinesterase-like activity and enzymes have arisen a number of times in the animal kingdom, suggesting the usefulness of such enzymes. Analysis of the published literature suggests that butyrylcholinesterase has specific roles in detoxification as well as in neurotransmission, both in the brain, where it appears to control certain areas and functions, and in the neuromuscular junction, where its function appears to complement that of acetylcholinesterase. An analysis of the mutations in human butyrylcholinesterase and their relation to the enzyme's structure is shown. In conclusion, it appears that the structure of butyrylcholinesterase's catalytic apparatus is a compromise between the apparently conflicting selective demands of a more generalised detoxifier and the necessity for maintaining high catalytic efficiency. It is also possible that the tolerance of mutation in human butyrylcholinesterase is a consequence of the detoxification function. Butyrylcholinesterase appears to be a good example of a gene that has survived by subfunctionalisation.

Scutellarin protects against Aß-induced learning and memory deficits in rats: involvement of nicotinic acetylcholine receptors and cholinesterase.

AIM: To examine the protective effects of scutellarin (Scu) on rats with learning and memory deficit induced by ß-amyloid peptide (Aß). METHODS: Fifty male Wistar rats were randomly divided into 5 groups: control, sham operation, Aß, Aß+Scu, and Aß+piracetam groups. Aß(25-35) was injected into the lateral ventricle (10 µg each side). Scu (10 mg/2 mL) or piracetam (10 mg/2 mL was intragastrically administered per day for 20 consecutive days following Aß treatment. Learning and memory was assessed with Morris water maze test. The protein and mRNA levels of nicotinic acetylcholine receptor (nAChR) α4, α7, and ß2 subunits in the brain were examined using Western blotting and real-time PCR, respectively. The activities of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) in the brain and plasma were measured using Ellman's colorimetric method. RESULTS: In Aß group, the escape latency period and first platform cross was significantly increased, and the total number of platform crossings was significantly decreased, as compared with the control and the sham operation groups. Both Scu and piracetam treatment significantly reduced the escape latency period and time to cross platform, and increased the number of platform crosses, but there were no significant differences between Aß+Scu and Aß+piracetam groups. In Aß group, the protein levels of nAChR α4 and α7 subunits in the cerebral cortex were significantly decreased by 42%-47% and 58%-61%, respectively, as compared to the control and the sham operation groups. Scu treatment caused upregulation of α4 and α7 subunit proteins by around 24% and 30%, respectively, as compared to Aß group, but there were no significant differences between Aß+Scu and Aß+piracetam groups. The protein level of nAChR ß2 subunit had no significant difference among different groups. The mRNA levels of nAChR α4, α7, and ß2 subunits were not significantly changed. In Aß group, the activities of AChE and BuChE in the brain were significantly increased, but were significantly decreased in the plasma, as compared to the control and the sham operation groups. Scu or piracetam treatment restored the activities in brain and plasma nearly to the levels in the control group. CONCLUSION: The results suggest that Scu may rescue some of the deleterious effects of Aß, possibly by stimulating nAChR protein translation and regulating cholinesterase activity.

[Cholinesterases: structure, role, and inhibition]. / Kolinesteraze: struktura, uloga, inhibicija.

Enzymes acetylcholinesterase (AChE; E.C. 3.1.1.7) and butyrylcholinesterase (BChE; E.C. 3.1.1.8) have intensively been investigated in biomedicine and toxicology due to important role in organisms. Even if structurally homologous, they differ in catalytic activity, specificity, for substrates, and selectivity in binding to many ligands. This paper compiles the results of research on cholinesterases and their interactions with ligands and inhibitors, and identifies amino acids of active sites involved in these interactions.

Prolonged toxic effects after cocaine challenge in butyrylcholinesterase/plasma carboxylesterase double knockout mice: a model for butyrylcholinesterase-deficient humans.

Death and toxicity after cocaine use do not correlate with cocaine blood levels. One explanation for this observation is that cocaine abusers may posses one or more of the 58 possible known mutations in the butyrylcholinesterase gene (BCHE). Butyrylcholinesterase (BChE) serves as the primary cocaine hydrolase producing a nontoxic product ecgonine methyl ester. A reduction in endogenous levels of BChE may result in increased metabolism by hepatic carboxylesterase to produce norcocaine, a toxic product. Humans have carboxylesterase in tissues but not in plasma, whereas wild-type mice have significant amounts of carboxylesterase in tissues and plasma. Knockout mice with no plasma carboxylesterase were created to eliminate the contribution of plasma carboxylesterase in cocaine hydrolysis, thereby simulating human enzyme levels. This study tested the hypothesis that reductions in BChE such as those in humans with BChE mutations contribute to increased toxicity after cocaine use. Carboxylesterase and BChE double knockout mice, models for humans with BChE deficiency, were challenged with a nonlethal dose of 100 mg/kg (-)-cocaine. Carboxylesterase/BChE double knockout mice demonstrated toxic signs significantly longer than did wild-type and carboxylesterase knockout mice. The carboxylesterase/BChE-deficient mice took approximately 2.5 times as long to recover from cocaine toxicities, including the following: hypothermia, hyperactivity, stereotypical behavior, ocular effects, and dorsiflexion of the tail. The carboxylesterase/BChE double knockout mouse model demonstrates the importance of endogenous BChE for protection against cocaine toxicity and provides an in vivo system for studying drug sensitivity of humans who carry a BChE mutation.

Cysteine thioesters as myelin proteolipid protein analogues to examine the role of butyrylcholinesterase in myelin decompaction.

Multiple sclerosis (MS) is a neuroinflammatory and neurodegenerative disorder involving demyelination, axonal transection, and neuronal loss in the brain. Recent studies have indicated that active MS lesions express elevated levels of butyrylcholinesterase (BuChE). BuChE can hydrolyze a wide variety of esters, including fatty acid esters of protein. Proteolipid protein (PLP), an important transmembrane protein component of myelin, has six cysteine residues acylated, via thioester linkages, with fatty acids, usually palmitic, that contribute to the stability of myelin. Experimental chemical deacylation of PLP has been shown to lead to decompaction of myelin. Because of elevated levels of BuChE in active MS lesions and its propensity to catalyze the hydrolysis of acylated protein, we hypothesized that this enzyme may contribute to deacylation of PLP in MS, leading to decompaction of myelin and contributing to demyelination. To test this hypothesis, a series of increasing chain length (C2-C16) acyl thioester derivatives of N-acetyl-l-cysteine methyl ester were synthesized and examined for hydrolysis by human cholinesterases. All N-acetyl-l-cysteine fatty acyl thioester derivatives were hydrolyzed by BuChE but not by the related enzyme acetylcholinesterase. In addition, it was observed that the affinity of BuChE for the compound increased the longer the fatty acid chain, with the highest affinity for cysteine bound to palmitic acid. This suggests that the elevated levels of BuChE observed in active MS lesions could be related to the decompaction of myelin characteristic of the disorder.

Cholinesterases, a target of pharmacology and toxicology.

BACKGROUND: Cholinesterases are a group of serine hydrolases that split the neurotransmitter acetylcholine (ACh) and terminate its action. Of the two types, butyrylcholinesterase and acetylcholinesterase (AChE), AChE plays the key role in ending cholinergic neurotransmission. Cholinesterase inhibitors are substances, either natural or man-made that interfere with the break-down of ACh and prolong its action. Hence their relevance to toxicology and pharmacology. METHODS AND RESULTS: The present review summarizes current knowledge of the cholinesterases and their inhibition. Particular attention is paid to the toxicology and pharmacology of cholinesterase-related inhibitors such as nerve agents (e.g. sarin, soman, tabun, VX), pesticides (e.g. paraoxon, parathion, malathion, malaoxon, carbofuran), selected plants and fungal secondary metabolites (e.g. aflatoxins), drugs for Alzheimer's disease (e.g. huperzine, metrifonate, tacrine, donepezil) and Myasthenia gravis (e.g. pyridostigmine) treatment and other compounds (propidium, ethidium, decamethonium). CONCLUSIONS: The crucial role of the cholinesterases in neural transmission makes them a primary target of a large number of cholinesterase-inhibiting drugs and toxins. In pharmacology, this has relevance to the treatment of neurodegenerative disorders.

Mechanism of hydrolysis of dicholine esters with long polymethylene chain by human butyrylcholinesterase.

Human butyrylcholinesterase hydrolyzes long chain dicholine esters more rapidly than short chain dicholine esters. The active site of butyrylcholinesterase is deeply buried within the enzyme molecule and there is limited space for binding of large compounds. Our goal was to understand how butyrylcholinesterase accommodates long chain dicholine esters to make them better substrates than short chain dicholine esters. For this purpose we studied the rate of hydrolysis of adipyldicholine (n=4) and sebacyldicholine (n=8) with mass spectrometry, a method that allowed monitoring the dicholine substrates, the monocholine intermediates, the dicarboxylic acid and choline products. It was shown that hydrolysis of adipyldicholine involves two consecutive steps, dicholine ester hydrolysis followed by relatively slow monocholine ester hydrolysis. However, sebacyldicholine was hydrolyzed at both choline ester sites, though hydrolysis of dicholine was faster than hydrolysis of monocholine. Sebacyldicholine was completely converted to sebacic acid and choline within 90 min, whereas only 15% of the adipyldicholine was converted to adipic acid in this time. Molecular modeling indicated that these dicholine esters can bind to butyrylcholinesterase in two energetically equivalent alternative conformations that may theoretically lead to hydrolysis. The long chain dicholine ester makes closer contact than the short chain ester between one of its carbonyl carbons and the catalytic Ser198, thus explaining why long-chain dicholine esters are hydrolyzed more rapidly by butyrylcholinesterase.

The butyrylcholinesterase knockout mouse is obese on a high-fat diet.

Butyrylcholinesterase (BChE) inactivates the appetite stimulating hormone octanoyl-ghrelin. The hypothesis was tested that BChE-/- mice would have abnormally high body weight and high levels of octanoyl-ghrelin. It was found that BChE-/- mice fed a standard 5% fat diet had normal body weight. However, BChE-/- mice fed a diet containing 11% fat became obese. Their obesity was not explained by increased levels of octanoyl-ghrelin, or by increased caloric intake, or by decreased exercise. Instead, a role for BChE in fat utilization was suggested.

Human recombinant butyrylcholinesterase purified from the milk of transgenic goats interacts with beta-amyloid fibrils and suppresses their formation in vitro.

BACKGROUND: In Alzheimer's disease (AD), brain butyrylcholinesterase (BChE) co-localizes with beta-amyloid (Abeta) fibrils. AIMS: In vitro testing of the significance of this phenomenon to AD progress. METHODS: A thioflavine T (ThT) fluorogenic assay, photo-induced cross-linking and quantifiable electron microscopy served to compare the effect on Abeta fibril formation induced by highly purified recombinant human BChE (rBChE) produced in the milk of transgenic goats with that of serum-derived human BChE. RESULTS: Both proteins at 1:50 and 1:25 ratios to Abeta dose-dependently prolonged the ThT lag time and reduced the apparent rate of Abeta fibril formation compared to Abeta alone. Photo-induced cross-linking tests showed that rBChE prolonged the persistence of amyloid dimers, trimers and tetramers in solution, whereas Abeta alone facilitated precipitation of such multimers from solution. Transmission electron microscopy showed that rBChE at 1:100 to Abeta prevented the formation of larger, over 150-nm-long, Abeta fibrils and reduced fibril branching compared to Abeta alone as quantified by macro programming of Image Pro Plus software. CONCLUSION: Our findings demonstrate that rBChE interacts with Abeta fibrils and can attenuate their formation, extension and branching, suggesting further tests of rBChE, with unlimited supply and no associated health risks, as a therapeutic agent for delaying the formation of amyloid toxic oligomers in AD patients.

Role of cholinesterase activity on pharmacodynamics of mivacurium preceded by pancuronium in elderly and young adults.

Mivacurium- pancuronium combination proved to be more potent than either drug given alone. The goal of this study was to evaluate the safety and efficacy of this combination in elderly group and its correlation to plasma butyryl cholinesterase (Bche) activity. Forty patients, ASA I or II scheduled for elective open cholecystectomy were allocated into two groups of twenty patients each: young group (18- 55 years) and elderly group (60-75 years). Anesthesia was induced with midazolam, fentanyl, and propofol then maintained with isoflurane and opioid supplementation. Neuromuscular blockade (NMB) was monitored by train-of-four (TOF) stimulation of the ulnar nerve. After calibration, NMB was achieved by 16 microg kg(-1) pancuronium followed by 32 microg kg(-1) mivacurium. The following parameters were recorded: The onset time, clinical duration, recovery index and the total dose of mivacurium and pancuronium together with hemodynamic data. Three blood samples for Bche activity were collected: before pancuronium injection, 3 min. and 30 min. afterwards in both groups. The onset time and the recovery index of NMB were comparable in both groups. The duration of action was significantly prolonged in elderly group (49.8 +/- 10.48 min.) compared to young one (37.13 +/- 7.81 min.). The total dose of mivacurium was significantly less in the elderly group (22.56 +/- 2.39 microg kg(-1) hr(-1)) when compared to the young group (25.78 +/- 3.05 microg kg(-1) hr(-1)). For all patients, the preoperative Bche activity was within the normal range. After pancuronium injecttion, it showed a significant reduction in both groups at three and thirty minutes except a non significant value in young at thirty minutes. This reduction showed a significantly higher percent change in the elderly group (30.37 +/- 22.01) than the young group (8.60 +/- 19.19) at thirty minutes. There were significant intra operative variations in the percent changes of hemodynamic data compared to the preoperative values, yet, still within the clinically acceptable range. So, the use of a small dose of pancuronium followed by a small dose of mivacurium with a ratio of 1:2 can produce synergism without affecting either the recovery profile of mivacurium or the clinical hemodynamic stability even in the elderly group.

Comparison of cognitive functions between people with silent and wild-type butyrylcholinesterase.

In the human brain, butyrylcholinesterase (BuChE) is expressed in neurons and glia. For example, many nuclei in the human thalamus, with projections to the cerebral cortex, contain a large number of neurons with intense BuChE activity. Thalamocortical projections subserve a variety of cognitive functions. Due to genetic mutations, there are individuals who do not have detectable BuChE activity (silent BuChE). While the prevalence of silent BuChE is only 1:100,000 in European and American populations, it is 1:24 in the Vysya community in Coimbatore, India. To examine whether there are differences in cognitive functions between individuals with silent BuChE and those expressing normal BuChE (wild-type), twelve healthy individuals with silent BuChE and thirteen healthy individuals with wild-type BuChE, all from the Vysya community in Coimbatore, were tested for cognitive function using the Automated Neuropsychological Assessment Metrics test battery. The silent BuChE group was slightly faster on simple reaction tasks, but slower on a visual perceptual matching task. Furthermore, discriminant function analyses correctly classified 11/12 silent and 8/13 wild-type BuChE subjects (76% correct classification overall) based on BuChE status. Different profiles of cognitive test performance between individuals with silent and wild-type BuChE were observed. These observations suggest a function for BuChE in cognition.

Excessive hippocampal acetylcholine levels in acetylcholinesterase-deficient mice are moderated by butyrylcholinesterase activity.

Central cholinergic systems are involved in a plethora of brain functions and are severely and selectively damaged in neurodegenerative diseases such as Alzheimer's disease and dementia with Lewy bodies. Cholinergic dysfunction is treated with inhibitors of acetylcholinesterase (AChE) while the role of butyrylcholinesterase (BChE) for brain cholinergic function is unclear. We have used in vivo microdialysis to investigate the regulation of hippocampal acetylcholine (ACh) levels in mice that are devoid of AChE (AChE-/- mice). Extracellular ACh levels in the hippocampus were 60-fold elevated in AChE-/- mice compared with wild-type (AChE+/+) animals. In AChE-/- mice, calcium-free conditions reduced hippocampal ACh levels by 50%, and infusion of tetrodotoxin by more than 90%, indicating continuous ACh release. Infusion of a selective AChE inhibitor (BW284c51) caused a dose-dependent, up to 16-fold increase of extracellular ACh levels in AChE+/+ mice but did not change ACh levels in AChE-/- mice. In contrast, infusion of a selective inhibitor of BChE (bambuterol) caused up to fivefold elevation of ACh levels in AChE-/- mice, but was without effect in AChE+/+ animals. These results were corroborated with two other specific inhibitors of AChE and BChE, tolserine and bis-norcymserine, respectively. We conclude that lack of AChE causes dramatically increased levels of extracellular ACh in the brain. Importantly, in the absence of AChE, the levels of extracellular ACh in the brain are controlled by the activity of BChE. These results point to a potential usefulness of BChE inhibitors in the treatment of central cholinergic dysfunction in which brain AChE activity is typically reduced.

Sensitivity of butyrylcholinesterase knockout mice to (--)-huperzine A and donepezil suggests humans with butyrylcholinesterase deficiency may not tolerate these Alzheimer's disease drugs and indicates butyrylcholinesterase function in neurotransmission.

Butyrylcholinesterase (EC 3.1.1.8 BChE) is present in all human and mouse tissues, and is more abundant than acetylcholinesterase (EC 3.1.1.7 AChE) in all tissues except brain. People who have no BChE activity due to a genetic variation are healthy. This has led to the hypothesis that BChE has no physiological function. We tested this hypothesis by challenging BChE and AChE knockout mice, as well as wild-type mice, with the AChE specific inhibitors, (--)-huperzine A and donepezil, and with serine hydrolase inhibitors, echothiophate and chlorpyrifos oxon. (--)-Huperzine A and donepezil caused mortality and significant toxicity in the BChE-/- animals. The BChE heterozygote (BCHE+/-) mice with approximately one-half the BChE activity of the BChE wild type (BChE+/+) exhibited intermediate toxic symptoms, and survived a longer period. The BChE+/+ animals displayed comparatively minor toxic symptoms and recovered by 24h post-dosing. Plasma AChE activity was inhibited to the same extent in BChE-/-, +/-, and +/+ mice, whereas BChE activity was not inhibited. This indicated that the protective effect of BChE was not due to scavenging (--)-huperzine A. AChE-/- mice were unaffected by (--)-huperzine A and donepezil, demonstrating the specificity of these inhibitors for AChE. AChE-/- mice treated with chlorpyrifos oxon lost all BChE activity, had severe cholinergic symptoms and died of convulsions. This showed that BChE activity was essential for survival of AChE-/- mice. In conclusion, we propose that the protective effect of BChE is explained by hydrolysis of excess acetylcholine in physiologically relevant regions such as diaphragm, cardiac muscle, and brain. Thus, BChE has a function in neurotransmission. People with BChE deficiency are expected to be intolerant of standard doses of the anti-Alzheimer's drugs, (--)-huperzine A and donepezil.

A medical health report on individuals with silent butyrylcholinesterase in the Vysya community of India.

BACKGROUND: Butyrylcholinesterase (BChE; gi:116353) deficiency has adverse effects on the response to succinylcholine and mivacurium. A physiological function of BChE is to inactivate octanoyl ghrelin. We determined the health effect of complete absence of BChE in humans. METHODS: Clinical tests of cardiac, lung, liver, and kidney function, body weight, sperm counts and motility were performed on 5 men, age 20-32 y, in the Vysya community of Coimbatore, India who had silent BChE. Postmortem tissues from 2 cadavers with wild-type BChE were assayed. RESULTS: Test results were normal, except for lung function, which indicated mild obstruction in silent as well as in wild-type BChE subjects. Creatine kinase-MB levels were high in 2 subjects, but there were no other indications of damage to the heart. Body weight was normal. Family histories revealed no trend in disease susceptibility. The human body contains 10 times more BChE than acetylcholinesterase molecules. CONCLUSION: Individuals completely deficient in BChE have only minor abnormalities in clinical test results. However, they respond abnormally to standard doses of succinylcholine and mivacurium. It is expected, but not proven, that they are unusually susceptible to the toxicity of cocaine and organophosphorus pesticides, and resistant to bambuterol and irinotecan. Their normal body weight suggests alternative routes for deactivation of octanoyl ghrelin.