Multi-scale entropy assessment of magnetoencephalography signals in schizophrenia.

Schizophrenia is a severe disruption in cognition and emotion, affecting fundamental human functions. In this study, we applied Multi-Scale Entropy analysis to resting-state Magnetoencephalography data from 54 schizophrenia patients and 98 healthy controls. This method quantifies the temporal complexity of the signal across different time scales using the concept of sample entropy. Results show significantly higher sample entropy in schizophrenia patients, primarily in central, parietal, and occipital lobes, peaking at time scales equivalent to frequencies between 15 and 24 Hz. To disentangle the contributions of the amplitude and phase components, we applied the same analysis to a phase-shuffled surrogate signal. The analysis revealed that most differences originate from the amplitude component in the δ, α, and ß power bands. While the phase component had a smaller magnitude, closer examination reveals clear spatial patterns and significant differences across specific brain regions. We assessed the potential of multi-scale entropy as a schizophrenia biomarker by comparing its classification performance to conventional spectral analysis and a cognitive task (the n-back paradigm). The discriminative power of multi-scale entropy and spectral features was similar, with a slight advantage for multi-scale entropy features. The results of the n-back test were slightly below those obtained from multi-scale entropy and spectral features.

The generation of oscillations in networks of electrically coupled cells.

In several biological systems, the electrical coupling of nonoscillating cells generates synchronized membrane potential oscillations. Because the isolated cell is nonoscillating and electrical coupling tends to equalize the membrane potentials of the coupled cells, the mechanism underlying these oscillations is unclear. Here we present a dynamic mechanism by which the electrical coupling of identical nonoscillating cells can generate synchronous membrane potential oscillations. We demonstrate this mechanism by constructing a biologically feasible model of electrically coupled cells, characterized by an excitable membrane and calcium dynamics. We show that strong electrical coupling in this network generates multiple oscillatory states with different spatio-temporal patterns and discuss their possible role in the cooperative computations performed by the system.

Engineering of human cholinesterases explains and predicts diverse consequences of administration of various drugs and poisons.

The acetylcholine hydrolyzing enzyme, acetylcholinesterase, primarily functions in nerve conduction, yet it appears in several guises, due to tissue-specific expression, alternative mRNA splicing and variable aggregation modes. The closely related enzyme, butyrylcholinesterase, most likely serves as a scavenger of toxins to protect acetylcholine binding proteins. One or both of the cholinesterases probably also plays a non-catalytic role(s) as a surface element on cells to direct intercellular interactions. The two enzymes are subject to inhibition by a wide variety of synthetic (e.g., organophosphorus and carbamate insecticides) and natural (e.g., glycoalkaloids) anticholinesterases that can compromise these functions. Butyrylcholinesterase may function, as well, to degrade several drugs of interest, notably aspirin, cocaine and cocaine-like local anesthetics. The widespread occurrence of butyrylcholinesterase mutants with modified activity further complicates this picture, in ways that are only now being dissected through the use of site-directed mutagenesis and heterologous expression of recombinant cholinesterases.

Population diversity and distinct haplotype frequencies associated with ACHE and BCHE genes of Israeli Jews from trans-Caucasian Georgia and from Europe.

Variant alleles of the butyrylcholinesterase gene, BCHE, have often been used to trace the genetic histories of populations. The D70G substitution in BCHE causes prolonged postanesthesia apnea ("atypical" phenotype); H322N substitution in the closely related acetylcholinesterase gene, ACHE, is the basis of the mutually incompatible Yt blood groups. In both genes, additional point mutations were reported to be linked to these phenotypically evident ones. To examine whether the intragenic linkage reported for the ACHE and BCHE mutations in Americans is universal, we studied frequencies of these mutations in trans-Caucasian Georgian Jews, a population that has remained relatively isolated for 1500 years. To this end we employed PCR amplification followed by DNA sequencing and enzymatic restriction and compared the frequencies we found to corresponding reported phenotype data. Georgian Jews' N322 ACHE was a rather low 7.0% and was totally linked to a P446 mutation, in agreement with a recent report. In BCHE, however, G70 was a relatively high 5.8%, and the V497 and T539 mutations were not found, either in Georgian or in Ashkenazi Jews, in contrast to reported findings in Americans. Our findings reveal distinct displays of ACHE and BCHE haplotypes in Georgian Jews and suggest different founder effects, genetic drifts, and/or selection pressures in the evolution of each of these genes.

Overexpressed monomeric human acetylcholinesterase induces subtle ultrastructural modifications in developing neuromuscular junctions of Xenopus laevis embryos.

Formation of a functional neuromuscular junction (NMJ) involves the biosynthesis and transport of numerous muscle-specific proteins, among them the acetylcholine-hydrolyzing enzyme acetylcholinesterase (AChE). To study the mechanisms underlying this process, we have expressed DNA encoding human AChE downstream of the cytomegalovirus promoter in oocytes and developing embryos of Xenopus laevis. Recombinant human AChE (rHAChE) produced in Xenopus was biochemically and immunochemically indistinguishable from native human AChE but clearly distinguished from the endogenous frog enzyme. In microinjected embryos, high levels of catalytically active rHAChE induced a transient state of over-expression that persisted for at least 4 days postfertilization. rHAChE appeared exclusively as nonassembled monomers in embryos at times when endogenous Xenopus AChE displayed complex oligomeric assembly. Nonetheless, cell-associated rHAChE accumulated in myotomes of 2- and 3-day-old embryos within the same subcellular compartments as native Xenopus AChE. NMJs from 3-day-old DNA-injected embryos displayed fourfold or greater overexpression of AChE, a 30% increase in postsynaptic membrane length, and increased folding of the postsynaptic membrane. These findings indicate that an evolutionarily conserved property directs the intracellular trafficking and synaptic targeting of AChE in muscle and support a role for AChE in vertebrate synaptogenesis.

Site-directed mutagenesis of active site residues reveals plasticity of human butyrylcholinesterase in substrate and inhibitor interactions.

In search of the molecular mechanisms underlying the broad substrate and inhibitor specificities of butyrylcholinesterase (BuChE), we employed site-directed mutagenesis to modify the catalytic triad residue Ser198, the acyl pocket Leu286 and adjacent Phe329 residues, and Met437 and Tyr440 located near the choline binding site. Mutant proteins were produced in microinjected Xenopus oocytes, and Km values towards butyrylthiocholine and IC50 values for the organophosphates diisopropylfluorophosphonate (DFP), diethoxyphosphinylthiocholine iodide (echothiophate), and tetraisopropylpyrophosphoramide (iso-OMPA) were determined. Substitution of Ser198 by cysteine and Met437 by aspartate nearly abolished activity, and other mutations of Ser198 completely abolished it. Tyr440 and Leu286 mutants remained active, but with higher Km and IC50 values. Rates of inhibition by DFP were roughly parallel to IC50 values for several Leu286 mutants. Both Km and IC50 values increased for Leu286 mutants in the order Asp < Gln < Lys. In contrast, cysteine, leucine, and glutamine mutants of Phe329 displayed unmodified Km values toward butyrylthiocholine, but up to 10-fold decreased IC50 values for DFP, iso-OMPA, and echothiophate. These findings add Tyr440 and Phe329 to the list of residues interacting with substrate and ligands, demonstrate plasticity in the active site region of BuChE, and foreshadow the design of recombinant BuChEs with tailored scavenging properties.

Mutations and impaired expression in the ACHE and BCHE genes: neurological implications.

The acetylcholine hydrolysing cholinesterases control the termination of cholinergic signalling in multiple tissues and are targets for a variety of drugs, natural and man-made poisons and common insecticides. Molecular cloning and gene mapping studies revealed the primary structure of human acetyl- and butyrylcholinesterase and localized the corresponding ACHE and BCHE genes to the chromosomal positions 3q26-ter and 7q22, respectively. Several different point mutations in the coding region of BCHE were found to be particularly abundant in the Israeli population. Analytical expression studies in microinjected Xenopus oocytes have demonstrated that the biochemical properties of cholinesterases may be modified by rationalized site-directed mutagenesis and in chimeric ACHE/BCHE constructs. These properties are differently altered in the various allelic BCHE variants, conferring resistance to several anti-cholinesterases, which may explain the evolutionary emergence of these multiple alleles. At the clinical level, abnormal expression of both ACHE and BCHE and the in vivo amplification of the ACHE and BCHE genes has been variously associated with abnormal megakaryocytopoiesis, leukemias and brain and ovarian tumors. Moreover, antisense oligonucleotides blocking the expression of these genes were shown to interfere with hemocytopoiesis in culture, implicating these genes in cholinergic influence on cell growth and proliferation.

Structure-function relationship studies in human cholinesterases reveal genomic origins for individual variations in cholinergic drug responses.

1. Due to their involvement in the termination of neurotransmission at cholinergic synapses and neuromuscular junctions, cholinesterases are the target proteins for numerous drugs of neuro-psychopharmacology importance. 2. In order to perform structure-function relationship studies on human cholinesterases with respect to such drugs, a set of expression vectors was engineered, all of which include cloned cDNA inserts encoding various forms of human acetyl- and butyrylcholinesterase. These vectors were designed to be transcribed in vitro into their corresponding mRNA products which, when microinjected into Xenopus oocytes, are efficiently translated to yield their catalytically active enzymes, each with its distinct substrate specificity and sensitivity to selective inhibitors. 3. A fully automated microtiter plate assay for evaluating the inhibition of said enzymes by tested cholinergic drugs and/or poisons has been developed, in conjunction with computerized data analysis, which offers prediction of such inhibition data on the authentic human enzymes and their natural or mutagenized variants. 4. Thus, it was found that asp70-->gly substitution renders butyrylcholinesterase succinylcholine insensitive and resistant to oxime reactivation while ser 425-->Pro with gly70 gives rise to the "atypical" butyrylcholinesterase phenotype, abolishing dibucaine binding. 5. Furthermore, differences in cholinesterase affinities to physostigmine, ecothiophate and bambuterol were shown in these natural variants. 6. Definition of key residues important for drug interactions may initiate rational design of more specific cholinesterase inhibitors, with fewer side effects. This, in turn, offers therapeutic potential in the treatment of clinical syndromes such as Alzheimer's and Parkinson's disease, glaucoma and myasthenia gravis.

Chimeric human cholinesterase. Identification of interaction sites responsible for recognition of acetyl- or butyrylcholinesterase-specific ligands.

Acetyl- and butyrylcholinesterases (AChE, BuChE) from various species differ in their substrate specificities and sensitivities to a wide range of inhibitors, yet display conserved sequence, structure and catalytic properties. To determine features that confer these selective properties, residues 58 through 133 of recombinant human BuChE were replaced with the corresponding sequence from human AChE. The replaced region (> 60% identity) spans the Asp70 residue, important for ligand interactions, and the choline binding site, and introduces differences of charge and hydrophobicity in the outer rim and on the surface of the active site gorge. Expressed in microinjected Xenopus laevis oocytes, the resultant chimera retained the catalytic activity, substrate specificity and the Km value toward butyrylthiocholine characteristic of BuChE. Further, it did not acquire substrate inhibition, which is unique to AChE, although it lost the property of substrate activation, characteristic of BuChE. Moreover, the chimera resembled BuChE in its sensitivity to succinylcholine and physostigmine, but acquired the AChE-like sensitivity to echothiophate and iso-OMPA, and displayed an intermediate pattern of inhibition, more similar to that of AChE than of BuChE, toward bambuterol, dibucaine and BW284C51. These findings demonstrate that the exchanged residues are involved in inhibitor recognition, but not in substrate distinction and in direct catalysis. Furthermore, substrate interaction with the exchanged domain may mediate structural changes leading to substrate activation in BuChE and inhibition in AChE. The two AChE-specific aromatic tyrosine residues positioned near Asp70 within this region are hence implicated in the peripheral anionic site of cholinesterases, which is involved in the recognition of various ligands.

Molecular dissection of cholinesterase domains responsible for carbamate toxicity.

Carbamate compounds marked for their cholinesterase (ChE) inhibition are widely used as therapeutics and as insecticides. Groups of closely related carbamate molecules provide an important tool in the understanding of the domains responsible for binding these ligands to ChEs. Comparative inhibition profiles were derived for five N-methyl carbamates, mostly carbofuran derivatives, differing in length and branching of their hydrocarbonic chain towards human erythrocyte acetylcholinesterase (H.AChE), human serum butyrylcholinesterase (H.BChE) in its normal form or in a mutant form containing the point mutation Asp70-->Gly, and Drosophila nervous system ChE. Carbofuran was more toxic to all three ChEs than any of the other derivatives, with IC50 values which differed by more than 1000-fold. Drosophila ChE appeared to be most sensitive to all of the examined carbamates, and H.AChE was consistently more sensitive than H.BChE. Moreover, inhibition efficiency for H.BChE decreased more effectively than it did for H.AChE with increased length and complexity of the side chain, indicating less flexible carbamate binding site in BChE as compared with AChE. The Asp70-->Gly mutation had no apparent effect on H.BChE inhibition by N-methyl carbamates, suggesting that the Asp70 domain localized near the rim of the active site groove is not important in carbamate binding. Comparison of the carbamate IC50 values with published LD50 values demonstrated correlation between the in vivo toxicity and inhibition of BChE by carbamates, suggesting a biological in addition to scavenging importance for BChE in mammals. Pinpointing different domains characteristic of carbamate binding in each member of the ChE family can thus shed light on the variable toxicity of these inhibitors to insects and mammals, predict the toxicity of yet untested inhibitor molecules and help in designing novel and improved ChE inhibitors.

Excavations into the active-site gorge of cholinesterases.

Acetyl- and butyrylcholinesterase (ACHE, BCHE) from evolutionarily distant species display a high degree of primary sequence homology and have biochemically similar catalytic properties, yet they differ in substrate specificity and affinity for various inhibitors. The biochemical information derived from analyses of ACHE and BCHE from human, Torpedo, mouse, and Drosophila, as well as that from the recombinant forms of their natural variants and site-directed mutants, can currently be re-examined in view of the recent X-ray crystallography data revealing the three-dimensional structure of Torpedo ACHE. The picture that emerges deepens the insight into the biochemical basis for choline ester catalysis and the complex mechanism of interaction between cholinesterases and their numerous ligands.

Intramolecular relationships in cholinesterases revealed by oocyte expression of site-directed and natural variants of human BCHE.

Structure-function relationships of cholinesterases (CHEs) were studied by expressing site-directed and naturally occurring mutants of human butyrylcholinesterase (BCHE) in microinjected Xenopus oocytes. Site-directed mutagenesis of the conserved electronegative Glu441,Ile442,Glu443 domain to Gly441,Ile442,Gln443 drastically reduced the rate of butyrylthiocholine (BTCh) hydrolysis and caused pronounced resistance to dibucaine binding. These findings implicate the charged Glu441,Ile442,Glu443 domain as necessary for a functional CHE catalytic triad as well as for binding quinoline derivatives. Asp70 to Gly substitution characteristic of 'atypical' BCHE, failed to alter its Km towards BTCh or dibucaine binding but reduced hydrolytic activity to 25% of control. Normal hydrolytic activity was restored to Gly70 BCHE by additional His114 or Tyr561 mutations, both of which co-appear with Gly70 in natural BCHE variants, which implies a likely selection advantage for these double BCHE mutants over the single Gly70 BCHE variant. Gly70 BCHE variants also displayed lower binding as compared with Asp70 BCHE to cholinergic drugs, certain choline esters and solanidine. These effects were ameliorated in part by additional mutations or in binding solanidine complexed with sugar residues. These observations indicate that structural interactions exist between N' and C' terminal domains in CHEs which contribute to substrate and inhibitor binding and suggest a crucial involvement of both electrostatic and hydrophobic domains in the build-up of the CHE active center.

Aspartate-70 to glycine substitution confers resistance to naturally occurring and synthetic anionic-site ligands on in-ovo produced human butyrylcholinesterase.

The "atypical" allelic variant of human butyrylcholinesterase (BuChE) can be characterized by its failure to bind the local anesthetic dibucaine, the muscle relaxant succinylcholine, and the naturally occurring steroidal alkaloid solanidine, all assumed to bind to the charged anionic site component within the normal BuChE enzyme. A single nucleotide substitution conferring a change of aspartate-70 into glycine was recently reported in the CHE gene encoding BuChE from several individuals having the "atypical" BuChE phenotype, whereas in two other DNA samples, this mutation appeared together with a second alteration conferring a change of serine-425 into proline. To separately assess the contribution of each of these mutations toward anionic site interactions in BuChE, three transcription constructs were engineered with each of these substitutions alone or both of them together. Xenopus oocyte microinjection of normal or mutated synthetic BuChEmRNA transcripts was employed in conjunction with biochemical analyzes of the resultant recombinant BuChE variants. The presence of the Gly-70 mutation alone was found to render the enzyme resistant to 100 microM solanidine and 5 mM succinylcholine; concentrations sufficient to inhibit the "normal," Asp-70 containing BuChE by over 50%. Furthermore, when completely inhibited by the organophosphorous poison diisopropylfluorophosphate (DFP), Gly-70 BuChE failed to be reactivated by 10 mM of the cholinesterase-specific oxime pyridine 2-aldoxime methiodide (2-PAM); a concentration restoring about 50% of activity in the "normal" Asp-70 recombinant enzyme. The Pro-425 mutation alone had no apparent influence on BuChE interactions with any of these ligands. However, it conferred synergistic effects on some of the anionic site changes induced by the Gly-70 mutation.(ABSTRACT TRUNCATED AT 250 WORDS)