Hepatocellular BChE as a therapeutic target to ameliorate hypercholesterolemia through PRMT5 selective degradation to restore LDL receptor transcription.

AIMS: Individuals with nonalcoholic hepatosteatosis (NAFLD) have a worse atherogenic lipoprotein profile and are susceptible to cardiovascular diseases. The MEK-ERK signaling cascades are central regulators of the levels of LDL receptor (LDLR), a major determinant of circulating cholesterol. It is elusive how hepatic steatosis contributes to dyslipidemia, especially hypercholesterolemia. MAIN METHODS: The effects of BChE on signaling pathways were determined by immunoblotting in a BChE knockout hepatocyte cell line. DiI-LDL probe was used to explore the effect of BChE expression on LDL internalization. Co-immunoprecipitation and LC-MS were used to explore the interacting proteins with BChE. Finally, a hepatocyte-restricted BChE silencing mouse model was established by AAV8-Tbg-shRNA, and the hypercholesterolemia was induced by 65% kcal% high-fat, high-sucrose diet feeding. MAIN FINDINGS: Here we demonstrate that butyrylcholinesterase (BChE) governs the LDL receptor levels and LDL uptake capacity through the MEK-ERK signaling cascades to promote Ldlr transcription. BChE interacts and co-localizes with PRMT5, a protein methylation modifier controlling the ERK signaling. PRMT5 regulates LDLR-dependent LDL uptake and is a substrate of chaperone-mediated autophagy (CMA). BChE deficiency induces the PRTM5 degradation dependent on CMA activity, possibly through facilitating the HSC70 (Heat shock cognate 71 kDa) recognition of PRMT5. Remarkably, in vivo hepatocyte-restricted BChE silencing reduces plasma cholesterol levels substantially. In contrast, the BChE knockout mice are predisposed to hypercholesterolemia. SIGNIFICANCE: Taken together, these findings outline a regulatory role for the BChE-PRMT5-ERK-LDLR axis in hepatocyte cholesterol metabolism, and suggest that targeting liver BChE is an effective therapeutic strategy to treat hypercholesterolemia.

Selective Pseudo-irreversible Butyrylcholinesterase Inhibitors Transferring Antioxidant Moieties to the Enzyme Show Pronounced Neuroprotective Efficacy In Vitro and In Vivo in an Alzheimer's Disease Mouse Model.

A series of multitarget-directed ligands (MTDLs) was designed by functionalizing a pseudo-irreversible butyrylcholinesterase (BChE) inhibitor. The obtained hybrids were investigated in vitro regarding their hBChE and hAChE inhibition, their enzyme kinetics, and their antioxidant physicochemical properties (DPPH, ORAC, metal chelating). In addition, in vitro assays were applied to investigate antioxidant effects using murine hippocampal HT22 cells and immunomodulatory effects on the murine microglial N9 cell line. The MTDLs retained their antioxidative properties compared to the parent antioxidant-moieties in vitro and the inhibition of hBChE was maintained in the submicromolar range. Representative compounds were tested in a pharmacological Alzheimer's disease (AD) mouse model and demonstrated very high efficacy at doses as low as 0.1 mg/kg. The most promising compound was also tested in BChE-/- mice and showed reduced efficacy. In vivo neuroprotection by BChE inhibition can be effectively enhanced by incorporation of structurally diverse antioxidant moieties.

Hereditary pseudocholinesterase deficiency discovery after electroconvulsive therapy.

Inherited pseudocholinesterase deficiency refers to an uncommon defect in the butyrylcholinesterase enzyme which can result in prolonged muscle paralysis due to delayed breakdown of choline ester paralytic anaesthetic agents. We describe a 25-year-old woman receiving electroconvulsive therapy (ECT) for treatment of depression in whom motor function did not recover adequately after administration of succinylcholine. Investigated post-ECT, she was found to have severe pseudocholinesterase deficiency. Implications of pseudocholinesterase deficiency for ECT treatment and anaesthetic strategies are discussed.

Pseudocholinesterase Deficiency Considerations: A Case Study.

Pseudocholinesterase deficiency, sometimes called butyrylcholinesterase deficiency, is a rare disorder in which the neuromuscular blocking drugs succinylcholine and mivacurium cannot be metabolized properly in the blood plasma. This disorder can either be acquired as a result of certain comorbidities or it can be inherited genetically. Anesthesia providers must understand the pathophysiology of pseudocholinesterase deficiency and be prepared to safely and effectively manage patients who show signs and symptoms consistent with the disorder after the use of the indicated neuromuscular blocking drugs. This article summarizes the pharmacologic and physiologic data relevant to understanding the basic pathophysiology associated with pseudocholinesterase deficiency and illustrates a case study of a young woman suspected of having the disorder after a prolonged delay in emergence from general anesthesia.

A Case Report of Primary Neonatal Hypocholinesterase Caused by Homozygous Frameshift Mutation of the utyrylcholinesterase (BCHE) Gene and Review of Literature.

BACKGROUND: Primary neonatal hypocholinesterase is rare; its genetic pattern and mutation still need to be further studied. METHODS: The patient and his parents are studied using next-generation sequencing technology. RESULTS: A boy one day after birth is admitted to the Neonatal Intensive Care Unit at our hospital after experiencing intermittent vomiting for 12 hours. The patient's serum cholinesterase level (113 - 283 U/L) is lower than normal value (4,000 - 12,600 U/L). Many factors of low serum cholinesterase are excluded. We highly suspect that it may be related to congenital factors. Molecular genetic test results show that the patient carried the BCHE gene (NM_000055.2) and has homozygous frameshift mutations at exon 2 c.401dupA (p.Asn134fs) of chromosome 3q26. It is a pathogenicity mutation. This locus mutation belongs to a novel pathogenic mutation. As a result of this mutation, the 134th amino acid Asn began to frameshift and the translation is terminated early. It can cause the Encoding of protein to truncate and lose its normal function. His parents' serum cholinesterase levels (father: 5,135 U/L; mother: 4,367 U/L) are in the normal value range, but his parents carried a heterozygous BCHE gene. CONCLUSIONS: This study suggests that gene sequence detection should be carried out early in hypocholinesterase of nknown cause in neonates. This study can not only improve understanding of the etiology and pathological mechanism of hypocholinesterase, but also it can enlarge the hypocholinesterase gene mutation spectrum.

Butyrylcholinesterase deficiency and its clinical importance in anaesthesia: a systematic review.

Butyrylcholinesterase deficiency prolongs the effects of the drugs it degrades; succinylcholine and mivacurium. Existing literature on butyrylcholinesterase deficiency is dominated by genetic and biochemical studies. We searched MEDLINE, Embase, Web of Science and Biosis to systematically review the causes and clinical consequences of butyrylcholinesterase deficiency. We considered outcomes clinically relevant if neuromuscular blockade, induced by succinylcholine or mivacurium, was assessed using clinical criteria or neuromuscular monitoring. We included 66 studies: 25 randomised controlled trials; 13 clinically controlled trials; 26 prospective observational studies; 1 retrospective study; and 1 qualitative study. Data heterogeneity precluded quantitative synthesis. Studies described genetic, physiological, acquired or pharmacologically induced causes of butyrylcholinesterase deficiency. The prolongation of neuromuscular blockade by butyrylcholinesterase deficiency was most pronounced with homozygosity of a genetic variant, but other more common factors included increasing age, pregnancy, severe liver disease, burn injuries and drug interactions.

Pseudocholinesterase Deficiency: What the Proceduralist Needs to Know.

Pseudocholinesterase deficiency is a rare genetic as well as an acquired disorder that affects the body's ability to metabolize choline esters such as succinylcholine and mivacurium. It can be inherited as an autosomal recessive trait, occurring in approximately 1 in 3,200 to 1 in 5,000 people. In most cases of pseudocholinesterase deficiency, no signs or symptoms of the condition exist. It is first suspected after a prolonged recovery from paralysis following general anesthesia in which succinylcholine or mivacurium are administered. We emphasize the importance of obtaining a detailed history prior to any endoscopic intervention or surgery requiring monitored anesthesia care or general anesthesia. In addition, a family history of anesthesia complications may help identify patients at risk. This article examines a case of a patient who underwent a successful endoscopic pneumatic dilation under general anesthesia for the treatment of achalasia, but was subsequently admitted to the intensive care unit, requiring mechanical ventilator support, for 18 hours. The patient made a complete recovery and was discharged home with no further complications. This case stimulated a review of this entity and we provide recommendations relevant to all proceduralist and anesthesia staff, as well as all personnel involved in procedures.

Prolonged neuromuscular block associated with cholinesterase deficiency.

RATIONALE: Hereditary genetic mutations may cause congenital cholinesterase deficiency. When succinylcholine and mivacurium are applied on cholinesterase-deficient patients during general anesthesia, prolonged postoperative asphyxia occurs, which is an uncommon but very serious complication. PATIENT CONCERNS: A previously healthy 30-year-old female presented prolonged spontaneous breathing recovery after general anesthesia. DIAGNOSES: After the patient's postoperative spontaneous breathing recovery delayed, the plasma cholinesterase was found to be 27 U/L, which was far below the normal level (4000 U/L to 13500 U/L). This patient had no disease that can cause plasma cholinesterase deficiency and was therefore diagnosed as congenital cholinesterase deficiency. INTERVENTIONS AND OUTCOMES: The patient was sent to the intensive care unit (ICU) intubated for mechanical ventilator support, and on the next day the tracheal tube was removed without any complications when her spontaneous respiration resumed. LESSONS: Cholinesterase is an enzyme secreted by the liver involved in many physiological processes in human body. Plasma cholinesterase commonly contains acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). When succinylcholine and mivacurium are applied on patients with cholinesterase-deficiency during general anesthesia, prolonged postoperative asphyxia occurs, which is an uncommon but very serious complication. Lately, new evidences have suggested that hereditary genetic mutations may be responsible for congenital cholinesterase deficiency.

A novel mutation in the BCHE gene and phenotype identified in a child with low butyrylcholinesterase activity: a case report.

BACKGROUND: Butyrylcholinesterase (BChE), an ester hydrolase produced mainly by the liver, hydrolyzes certain short-acting neuromuscular blocking agents, like succinylcholine and mivacurium that are widely used during anesthesia. Patients with BChE deficiency are possibly in danger of postanesthetic apnea. Hereditary BChE deficiency results from the mutations of BCHE gene located on chromosome 3, 3q26.1-q26.2, between nucleotides 165,490,692-165,555,260. CASE PRESENTATION: This study describes a novel mutation in a child with BChE deficiency. In general, this child appeared healthy and well-developed with a normal appearance. However, the results of Wechsler Intelligence Scale showed that the full-scale intelligence quotient (FIQ) was 53, classified into the group with the minor defect. The BChE activity was 32.0 U/L, considerably lower than the normal lower limit (reference range: 5000-12,000 U/L). Sanger sequencing showed that there were 2 mutations in the exon 2 of BCHE gene of this child. One is a heterozygous mutation rs764588882 (NM_000055.3: c.401_402insA, p.Asn134Lysfs*23). The other one is a heterozygous mutation (NM_000055.3: c.73A > T, p.Lys25Ter) that has never been reported before. The two mutations lead to a premature stop of transcription. CONCLUSIONS: Double heterozygous recessive mutations are the cause of BChE deficiency of this boy in this study, including a novel mutation c.73A > T. Intellectual disability is a new phenotype that is probably associated with this mutation.

Butyrylcholinesterase-knockout reduces fibrillar ß-amyloid and conserves 18FDG retention in 5XFAD mouse model of Alzheimer's disease.

Alzheimer's disease (AD) is the most common neurodegenerative disorder causing dementia. One hallmark of the AD brain is the deposition of ß-amyloid (Aß) plaques. AD is also a state of cholinergic dysfunction and butyrylcholinesterase (BChE) associates with Aß pathology. A transgenic mouse (5XFAD) is an aggressive amyloidosis model, producing Aß plaques with which BChE also associates. A derived strain (5XFAD/BChE-KO), with the BChE gene knocked out, has significantly lower fibrillar Aß than 5XFAD mice at the same age. Therefore, BChE may have a role in Aß pathogenesis. Furthermore, in AD, diminished glucose metabolism in the brain can be detected in vivo with positron emission tomography (PET) imaging following 2-deoxy-2-(18F)fluoro-D-glucose (18FDG) administration. To determine whether hypometabolism is related to BChE-induced changes in fibrillar Aß burden, whole brain and regional uptake of 18FDG in 5XFAD and 5XFAD/BChE-KO mice was compared to corresponding wild-type (WT5XFAD and WTBChE-KO) strains at 5months. Diminished fibrillar Aß burden was confirmed in 5XFAD/BChE-KO mice relative to 5XFAD. 5XFAD and 5XFAD/BChE-KO mice demonstrated reduction in whole brain 18FDG retention compared to respective wild-types. Regional analysis of relevant AD structures revealed reduction in 18FDG retention in 5XFAD mice in all brain regions analyzed (save cerebellum) compared to WT5XFAD. Alternatively, 5XFAD/BChE-KO mice demonstrated a more selective pattern of reduced retention in the cerebral cortex and thalamus compared to WTBChE-KO, while retention in hippocampal formation, amygdala and basal ganglia remained unchanged. This suggests that in knocking out BChE and reducing fibrillar Aß, a possible protective effect on brain function may be conferred in a number of structures in 5XFAD/BChE-KO mice.

Butyrylcholinesterase regulates central ghrelin signaling and has an impact on food intake and glucose homeostasis.

BACKGROUND: Ghrelin is the only orexigenic hormone known to stimulate food intake and promote obesity and insulin resistance. We recently showed that plasma ghrelin is controlled by butyrylcholinesterase (BChE), which has a strong impact on feeding and weight gain. BChE knockout (KO) mice are prone to obesity on high-fat diet, but hepatic BChE gene transfer rescues normal food intake and obesity resistance. However, these mice lack brain BChE and still develop hyperinsulinemia and insulin resistance, suggesting essential interactions between BChE and ghrelin within the brain. METHODS: To test the hypothesis we used four experimental groups: (1) untreated wild-type mice, (2) BChE KO mice with LUC delivered by adeno-associated virus (AAV) in combined intravenous (i.v.) and intracerebral (i.c.) injections, (3) KO mice given AAV for mouse BChE (i.v. only) and (4) KO mice given the same vector both i.v. and i.c. All mice ate a 45% calorie high-fat diet from the age of 1 month. Body weight, body composition, daily caloric intake and serum parameters were monitored throughout, and glucose tolerance and insulin tolerance tests were performed at intervals. RESULTS: Circulating ghrelin levels dropped substantially in the KO mice after i.v. AAV-BChE delivery, which led to normal food intake and healthy body weight. BChE KO mice that received AAV-BChE through i.v. and i.c. combined treatments not only resisted weight gain on high-fat diet but also retained normal glucose and insulin tolerance. CONCLUSIONS: These data indicate a central role for BChE in regulating both insulin and glucose homeostasis. BChE gene transfer could be a useful therapy for complications linked to diet-induced obesity and insulin resistance.

Resequencing array for gene variant detection in malignant hyperthermia and butyrylcholinestherase deficiency.

Malignant hyperthermia (MH) and butyrylcholinestherase (BCHE) deficiency are two relevant pharmacogenetic disorders in anesthetic practice linked with sequence variants, the former in the RyR1 and CACNA1S genes, the latter in the BCHE gene. Genotyping for known pathogenic variants in these genes is useful to help identify susceptible individuals, and others may exist but remain unknown, because full-length sequence of these genes is, in general, not investigated. To facilitate this task, we developed a resequencing DNA array, the perioperative patient safety (POPS) array, to be able to screen the entire coding sequences of the RyR1, CACNA1S and BCHE genes. MH-susceptible individuals (n = 121) identified with the in vitro contracture test, the standard diagnostic tool for MH susceptibility, were genotyped with the arrays. Compared with capillary sequencing, call rates with the arrays could achieve 100% at maximal sensitivity, although to reduce false positive rates, sensitivity was adjusted to 0.85, 0.87 and 0.66 for RyR1, CACNA1S and BCHE respectively, with overall base call specificity exceeding 99%. Detection of 29 predetermined RyR1 variants in 44 individuals was successful in 97% of the cases, among them all 16 variants of established diagnostic value. In a trial application of the arrays, 21 MH-susceptible subjects with no known RyR1 or CACNA1S variants were screened, resulting in the discovery of new variants, all confirmed by capillary sequencing. In conclusion, arrays offer an efficient high-throughput alternative for diagnostic genotyping of candidate genes affecting MH susceptibility, BCHE deficiency and other neuromuscular disorders, simultaneously enabling a comprehensive search for rare variants in these genes.

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.

Unknown Pseudocholinesterase Deficiency in a Patient Undergoing TIVA with Planned Motor Evoked Potential Monitoring: A Case Report.

Pseudocholinesterase abnormalities are a genetic cause of aberrant metabolism of the depolarizing muscle relaxant succinylcholine. This article examines a case where succinylcholine was chosen to facilitate intubation due to its ultra short duration and the request of the surgeon to monitor motor evoked potentials. Following succinylcholine administration the neurophysiologist was unable to obtain motor evoked potentials. This case study highlights the intraoperative and postoperative management of an elderly patient with an unknown pseudocholinesterase deficiency.

A Case of Pseudocholinesterase Deficiency Resulting From Malnutrition.

Pseudocholinesterase deficiencies occur because of both genetic and acquired factors. We present the case of a patient with a history of bariatric surgery and severe malnutrition who subsequently developed prolonged neuromuscular blockade after succinylcholine administration. She had markedly decreased pseudocholinesterase levels at the time of the incident, but her motor function returned to normal with supportive care. After aggressive nutritional support over multiple weeks, her pseudocholinesterase levels drastically improved. For those patients in a poor nutritional state who experience an unexpected episode of apnea or prolonged neuromuscular blockade, practitioners must always consider malnutrition-induced pseudocholinesterase deficiency as a possible etiology.

Butyrylcholinesterase Deficiency Promotes Adipose Tissue Growth and Hepatic Lipid Accumulation in Male Mice on High-Fat Diet.

Despite numerous reports of relationships between weight gain and butyrylcholinesterase (BChE), this enzyme's role in the genesis of obesity remains unclear, but recent research points to strong links with ghrelin, the "hunger hormone." The availability of BChE knockout (KO) mice provides an opportunity to clarify the causal relationship between BChE and obesity onset. We now find that young KO mice have abnormally high plasma ghrelin levels that slowly decline during long-term high-fat feeding and ultimately drop below those in wild-type mice. On such a diet, the KO mice gained notably more weight, more white fat, and more hepatic fat than wild-type animals. In addition to a greater burden of hepatic triglycerides, the livers of these KO mice show distinctly higher levels of inflammatory markers. Finally, their energy expenditure proved to be lower than in wild-type mice despite similar activity levels and increased caloric intake. A gene transfer of mouse BChE with adeno-associated virus vector restored nearly all aspects of the normal phenotype. Our results indicate that BChE strongly affects fat metabolism, has an important impact on fat accumulation, and may be a promising tool for combating obesity.

Butyrylcholinesterase deficiency.

Butyrylcholinesterase (EC 3.1.1.8; BChE) is a sister enzyme of acetylcholinesterase. Though BChE lacks obvious physiological functions, it is of toxicological and pharmacological importance in detoxifying or catabolising ester-containing drugs. Furthermore, individuals deficient in BChE appear asymptomatic, apart from a heightened sensitivity to the muscle relaxants suxamethonium and mivacurium, two BChE substrates used as myorelaxant. Although many acquired conditions may affect BChE activity, BChE deficiency is mainly due to mutations in the BCHE gene (OMIM 177400). Currently, more than 70 natural mutations have been documented in human BCHE. They have an adverse effect on BChE activity by affecting the catalytic functioning or the protein expression. However, the atypical variant (rs1799807) is the most frequently involved in prolonged apnea.