Your search keyword '"Shelley Camp"' showing total 25 results

1. Contributions of selective knockout studies to understanding cholinesterase disposition and function

Author

Oksana Lockridge, Shelley Camp, Véronique Bernard, Palmer Taylor, Antonella De Jaco, Ellen G. Duysen, Limin Zhang, Emmanuelle Girard, Alexandre Dobbertin, Eric Krejci, Department of pharmacology, University of California [San Diego] (UC San Diego), University of California-University of California, Yunnan Agricultural University, Langues, textes, traitement informatique, cognition (LaTTice), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Centre de neurophysique, physiologie, pathologie (UMR 8119), Université Paris Descartes - Paris 5 (UPD5)-Centre National de la Recherche Scientifique (CNRS), Neurosciences Paris Seine (NPS), Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Biologie Paris Seine (IBPS), Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Centre d'étude de la SensoriMotricité (CESEM - UMR 8194), Université Paris Descartes - Paris 5 (UPD5)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), and Department of Pharmacology, Skaggs School of Pharmacy & Pharmaceutical Sciences

Subjects

RNA Splicing, Transgene, Muscle Proteins, Nerve Tissue Proteins, Biology, Toxicology, Gene Expression Regulation, Enzymologic, Article, Gene Knockout Techniques, Mice, alternative splicing, 03 medical and health sciences, Exon, chemistry.chemical_compound, 0302 clinical medicine, COLQ, Animals, RNA, Messenger, Sequence Deletion, 030304 developmental biology, Mice, Knockout, 0303 health sciences, Muscles, Alternative splicing, Intron, Brain, Membrane Proteins, Exons, acetylcholinesterase, differentiation, General Medicine, Molecular biology, Acetylcholinesterase, Introns, Protein Subunits, Spinal Cord, chemistry, Organ Specificity, Knockout mouse, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Collagen, knockout mouse, 030217 neurology & neurosurgery

Abstract

International audience; The complete knockout of the acetylcholinesterase gene (AChE) in the mouse yielded a surprising phenotype that could not have been predicted from deletion of the cholinesterase genes in Drosophila, that of a living, but functionally compromised animal. The phenotype of this animal showed a sufficient compromise in motor function that precluded precise characterization of central and peripheral nervous functional deficits. Since AChE in mammals is encoded by a single gene with alternative splicing, additional understanding of gene expression might be garnered from selected deletions of the alternatively spliced exons. To this end, transgenic strains were generated that deleted exon 5, exon 6, and the combination of exons 5 and 6. Deletion of exon 6 reduces brain AChE by 93% and muscle AChE by 72%. Deletion of exon 5 eliminates AChE from red cells and the platelet surface. These strains, as well as knockout strains that selectively eliminate the AChE anchoring protein subunits PRiMA or ColQ (which bind to sequences specified by exon 6) enabled us to examine the role of the alternatively spliced exons responsible for the tissue disposition and function of the enzyme. In addition, a knockout mouse was made with a deletion in an upstream intron that had been identified in differentiating cultures of muscle cells to control AChE expression. We found that deletion of the intronic regulatory region in the mouse essentially eliminated AChE in muscle and surprisingly from the surface of platelets. The studies generated by these knockout mouse strains have yielded valuable insights into the function and localization of AChE in mammalian systems that cannot be approached in cell culture or in vitro.

Published

2010

2. Acetylcholinesterase (AChE) gene modification in transgenic animals: Functional consequences of selected exon and regulatory region deletion

Author

Goran Bucht, Limin Zhang, Michael Marquez, Shelley Camp, Brian de la Torre, Jeffery M. Long, and Palmer Taylor

Subjects

Transgene, Alternative splicing, Intron, Mice, Transgenic, Exons, General Medicine, Regulatory Sequences, Nucleic Acid, Biology, Toxicology, Acetylcholinesterase, Molecular biology, Mice, chemistry.chemical_compound, Exon, Phenotype, chemistry, Regulatory sequence, COLQ, Animals, Coding region, Sequence Deletion

Abstract

AChE is an alternatively spliced gene. Exons 2, 3 and 4 are invariantly spliced, and this sequence is responsible for catalytic function. The 3' alternatively spliced exons, 5 and 6, are responsible for AChE disposition in tissue [J. Massoulie, The origin of the molecular diversity and functional anchoring of cholinesterases. Neurosignals 11 (3) (2002) 130-143; Y. Li, S. Camp, P. Taylor, Tissue-specific expression and alternative mRNA processing of the mammalian acetylcholinesterase gene. J. Biol. Chem. 268 (8) (1993) 5790-5797]. The splice to exon 5 produces the GPI anchored form of AChE found in the hematopoietic system, whereas the splice to exon 6 produces a sequence that binds to the structural subunits PRiMA and ColQ, producing AChE expression in brain and muscle. A third alternative RNA species is present that is not spliced at the 3' end; the intron 3' of exon 4 is used as coding sequence and produces the read-through, unanchored form of AChE. In order to further understand the role of alternative splicing in the expression of the AChE gene, we have used homologous recombination in stem cells to produce gene specific deletions in mice. Alternatively and together exon 5 and exon 6 were deleted. A cassette containing the neomycin gene flanked by loxP sites was used to replace the exon(s) of interest. Tissue analysis of mice with exon 5 deleted and the neomycin cassette retained showed very low levels of AChE expression, far less than would have been anticipated. Only the read-through species of the enzyme was produced; clearly the inclusion of the selection cassette disrupted splicing of exon 4 to exon 6. The selection cassette was then deleted in exon 5, exon 6 and exons 5 + 6 deleted mice by breeding to Ella-cre transgenic mice. AChE expression in serum, brain and muscle has been analyzed. Another AChE gene targeted mouse strain involving a region in the first intron, found to be critical for AChE expression in muscle cells [S. Camp, L. Zhang, M. Marquez, B. delaTorre, P. Taylor, Knockout mice with deletions of alternatively spliced exons of Acetylcholinesterase, in: N.C. Inestrosa, E.O. Campus (Eds.), VII International Meeting on Cholinesterases, Pucon-Chile Cholinesterases in the Second Millennium: Biomolecular and Pathological Aspects. P. Universidad Catholica de Chile-FONDAP Biomedicina, 2004, pp. 43-48; R.Y.Y. Chan, C. Boudreau-Larivière, L.A. Angus, F. Mankal, B.J. Jasmin, An intronic enhancer containing an N-box motif is required for synapse- and tissue-specific expression of the acetylcholinesterase gene in skeletal muscle fibers. Proc. Natl. Acad. Sci. USA 96 (1999) 4627-4632], is also presented. The intronic region was floxed and then deleted by mating with Ella-cre transgenic mice. The deletion of this region produced a dramatic phenotype; a mouse with near normal AChE expression in brain and other CNS tissues, but no AChE expression in muscle. Phenotype and AChE tissue activities are compared with the total AChE knockout mouse [W. Xie, J.A. Chatonnet, P.J. Wilder, A. Rizzino, R.D. McComb, P. Taylor, S.H. Hinrichs, O. Lockridge, Postnatal developmental delay and supersensitivity to organophosphate in gene-targeted mice lacking acetylcholinesterase. J. Pharmacol. Exp. Ther. 293 (3) (2000) 896-902].

Published

2005

3. Expression and Activity of Mutants of Fasciculin, a Peptidic Acetylcholinesterase Inhibitor from Mamba Venom

Author

Claudine N. Prowse, Elizabeth J. Ackermann, Pierre E. Bougis, Shelley Camp, Zoran Radić, Joan R. Kanter, Palmer Taylor, and Pascale Marchot

Subjects

Models, Molecular, Signal peptide, medicine.drug_class, Molecular Sequence Data, Mutant, Radioimmunoassay, Peptide, Biology, Biochemistry, Mice, chemistry.chemical_compound, Cricetinae, medicine, Animals, Humans, Amino Acid Sequence, Molecular Biology, Chromatography, High Pressure Liquid, Elapid Venoms, chemistry.chemical_classification, Base Sequence, Chinese hamster ovary cell, HEK 293 cells, Fast protein liquid chromatography, Cell Biology, Chromatography, Ion Exchange, Acetylcholinesterase, Molecular biology, chemistry, Acetylcholinesterase inhibitor, Mutagenesis, Site-Directed, Cholinesterase Inhibitors, Sequence Alignment

Abstract

Fasciculin, a selective peptidic inhibitor of acetylcholinesterase, is a member of the three-fingered peptide toxin superfamily isolated from snake venoms. The availability of a crystal structure of a fasciculin 2 (Fas2)-acetylcholinesterase complex affords an opportunity to examine in detail the interaction of this toxin with its target site. To this end, we constructed a synthetic fasciculin gene with an appropriate leader peptide for expression and secretion from mammalian cells. Recombinant wild-type Fas2, expressed and amplified in Chinese hamster ovary cells, was purified to homogeneity and found to be identical in composition and biological activities to the venom-derived toxin. Sixteen mutations at positions where the crystal structure of the complex indicates a significant interfacial contact point or determinant of conformation were generated. Two mutants of loop I, T8A/T9A and R11Q, ten mutants of the longest loop II, R24T, K25L, R27W, R28D, H29D, DeltaPro30, P31R, K32G, M33A, and V34A/L35A, and two mutants of loop III, D45K and K51S, were expressed transiently in human embryonic kidney cells. Inhibitory potencies of the Fas2 mutants toward mouse AChE were established, based on titration of the mutants with a polyclonal anti-Fas2 serum. The Arg27, Pro30, and Pro31 mutants each lost two or more orders of magnitude in Fas2 activity, suggesting that this subset of three residues, at the tip of loop II, dominates the loop conformation and interaction of Fas2 with the enzyme. The Arg24, Lys32, and Met33 mutants lost about one order of magnitude, suggesting that these residues make moderate contributions to the strength of the complex, whereas the Lys25, Arg28, Val34-Leu35, Asp45, and Lys51 mutants appeared as active as Fas2. The Thr8-Thr9, Arg11, and His29 mutants showed greater ratios of inhibitory activity to immunochemical titer than Fas2. This may reflect immunodominant determinants in these regions or intramolecular rearrangements in conformation that enhance the interaction. Of the many Fas2 residues that lie at the interface with acetylcholinesterase, only a few appear to provide substantial energetic contributions to the high affinity of the complex.

Published

1997

4. Three distinct domains in the cholinesterase molecule confer selectivity for acetyl- and butyrylcholinesterase inhibitors

Author

Zoran Radić, Natilie A. Pickering, Shelley Camp, Palmer Taylor, and Daniel C. Vellom

Subjects

biology, Stereochemistry, Recombinant Fusion Proteins, Active site, Torpedo, Ligand (biochemistry), Biochemistry, Acetylcholinesterase, Substrate Specificity, Kinetics, chemistry.chemical_compound, chemistry, Butyrylcholinesterase, Mutagenesis, Site-Directed, biology.protein, Animals, Cholinesterases, Cholinesterase Inhibitors, Binding site, Choline binding, Cells, Cultured, Binding selectivity, Cholinesterase

Abstract

By examining inhibitor interactions with single and multiple site-specific mutants of mouse acetylcholinesterase, we have identified three distinct domains in the cholinesterase structure that are responsible for conferring selectivity for acetyl- and butyrylcholinesterase inhibitors. The first domain is the most obvious; it defines the constraints on the acyl pocket dimensions where the side chains of F295 and F297 primarily outline this region in acetylcholinesterase. Replacement of these phenylalanine side chains with the aliphatic residues found in butyrylcholinesterase allows for the catalysis of larger substrates and accommodates butyrylcholinesterase-selective alkyl phosphates such as isoOMPA. Also, elements of substrate activation characteristic of butyrylcholinesterase are evident in the F297I mutant. Substitution of tyrosines for F295 and F297 further alters the catalytic constants. The second domain is found near the lip of the active center gorge defined by two tyrosines, Y72 and Y124, and by W286; this region appears to be critical for the selectivity of bisquaternary inhibitors, such as BW284C51. The third domain defines the site of choline binding. Herein, in addition to conserved E202 and W86, a critical tyrosine, Y337, found only in the acetylcholinesterases is responsible for sterically occluding the binding site for substituted tricyclic inhibitors such as ethopropazine. Analysis of a series of substituted acridines and phenothiazines defines the groups on the ligand and amino acid side chains in this site governing binding selectivity. Each of the three domains is defined by a cluster of aromatic residues. The two domains stabilizing the quaternary ammonium moieties each contain a negative charge, which contributes to the stabilization energy of the respective complexes.

Published

1993

5. Tissue-specific expression and alternative mRNA processing of the mammalian acetylcholinesterase gene

Author

Ying Li, Palmer Taylor, and Shelley Camp

Subjects

Gene Expression, Biology, Biochemistry, Mice, Exon, Exon trapping, Species Specificity, Gene expression, Tumor Cells, Cultured, Animals, Humans, Coding region, Tissue Distribution, RNA, Messenger, Molecular Biology, Gene, Cells, Cultured, Splice site mutation, Alternative splicing, DNA, Exons, Cell Biology, Molecular biology, Alternative Splicing, RNA splicing, Acetylcholinesterase

Abstract

This study examines the tissue specificity and the gene products arising from alternative mRNA processing of the mammalian acetylcholinesterase gene. By splicing either alternative exons 5 or 6 in the mouse and human genes directly to the invariant exons (exons 2, 3, and 4), we show that the acetylcholinesterase species expressed by transfected recombinant DNA have the properties expected for the respective enzyme forms found in tissue. Antisense mRNA derived from these cDNAs has been employed to examine differential splicing in various tissues. In most cells, the hydrophilic form of AChE encoded by the exon 4 to exon 6 splice to form the mRNA is the predominant species. However, splicing of exon 4 to exon 5, yielding a mRNA encoding the glycophospholipid-linked form of acetylcholinesterase, is seen primarily in erythroid and to a lesser extent in AtT-20 cells. Only small amounts of this mRNA species appear in some other cells in culture. A novel third mRNA species, which arises from an extension of exon 4 without splicing to a downstream exon, is seen in mouse erythroid but not in human erythroid cells. A cDNA encoding this species when expressed in COS cells gives rise to a unique hydrophilic, secreted form of acetylcholinesterase. Transfection of a human genomic clone into mouse erythroleukemia cells does not result in the appearance of a mRNA species with an extension of exon 4 as seen with the endogenous mouse gene. Hence, differential splicing between the mouse and human genes appears intrinsic to the coding sequence and is not dependent solely on specific factors in the mouse erythroleukemia cell.

Published

1993

6. Processing of cholinesterase-like α/β-hydrolase fold proteins: alterations associated with congenital disorders

Author

Antonella, De Jaco, Davide, Comoletti, Noga, Dubi, Shelley, Camp, and Palmer, Taylor

Subjects

Models, Molecular, Protein Folding, Structure-Activity Relationship, Structural Homology, Protein, Mutation, Animals, Cholinesterases, Humans, Models, Biological, Protein Processing, Post-Translational, Article, Congenital Abnormalities

Abstract

The α/β hydrolase fold family is perhaps the largest group of proteins presenting significant structural homology with divergent functions, ranging from catalytic hydrolysis to heterophilic cell adhesive interactions to chaperones in hormone production. All the proteins of the family share a common three-dimensional core structure containing the α/β-hydrolase fold domain that is crucial for proper protein function. Several mutations associated with congenital diseases or disorders have been reported in conserved residues within the α/β-hydrolase fold domain of cholinesterase-like proteins, neuroligins, butyrylcholinesterase and thyroglobulin. These mutations are known to disrupt the architecture of the common structural domain either globally or locally. Characterization of the natural mutations affecting the α/β-hydrolase fold domain in these proteins has shown that they mainly impair processing and trafficking along the secretory pathway causing retention of the mutant protein in the endoplasmic reticulum. Studying the processing of α/β-hydrolase fold mutant proteins should uncover new functions for this domain, that in some cases require structural integrity for both export of the protein from the ER and for facilitating subunit dimerization. A comparative study of homologous mutations in proteins that are closely related family members, along with the definition of new three-dimensional crystal structures, will identify critical residues for the assembly of the α/β-hydrolase fold.

Published

2010

7. Distinct localization of collagen Q and PRiMA forms of acetylcholinesterase at the neuromuscular junction

Author

Anna Hrabovska, Emmanuelle Girard, Véronique Bernard, Shelley Camp, Palmer Taylor, Benoit Plaud, Eric Krejci, Neurosciences Paris Seine (NPS), Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Biologie Paris Seine (IBPS), Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Centre d'étude de la SensoriMotricité (CESEM - UMR 8194), Université Paris Descartes - Paris 5 (UPD5)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Langues, textes, traitement informatique, cognition (LaTTice), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Department of Pharmacology, Skaggs School of Pharmacy & Pharmaceutical Sciences, University of California [San Diego] (UC San Diego), University of California-University of California, Department of pharmacology, Hôpital Saint-Louis, Université Paris Diderot - Paris 7 (UPD7)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP), Bernard, Veronique, Neuroscience Paris Seine (NPS), Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de Biologie Paris Seine (IBPS), Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Université Paris Diderot - Paris 7 (UPD7)-Université Paris Descartes - Paris 5 (UPD5)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Paris (ENS-PSL), University of California (UC)-University of California (UC), and Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Université Paris Diderot - Paris 7 (UPD7)

Subjects

Neuromuscular Junction, Nerve Tissue Proteins, Biology, Neuromuscular junction, Article, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Mice, 0302 clinical medicine, Postsynaptic potential, COLQ, medicine, Animals, [SDV.NEU] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Molecular Biology, 030304 developmental biology, Mice, Knockout, 0303 health sciences, Membrane Proteins, Cell Biology, Bungarotoxins, Acetylcholinesterase, Immunohistochemistry, humanities, Acetylcholine, Cell biology, Isoenzymes, medicine.anatomical_structure, Nicotinic agonist, Biochemistry, chemistry, Synapses, Cholinergic, Basal lamina, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Collagen, 030217 neurology & neurosurgery, medicine.drug

Abstract

International audience; Acetylcholinesterase (AChE) terminates the action of acetylcholine at cholinergic synapses thereby preventing rebinding of acetylcholine to nicotinic postsynaptic receptors at the neuromuscular junction. Here we show that AChE is not localized close to these receptors on the postsynaptic surface, but is instead clustered along the presynaptic membrane and deep in the postsynaptic folds. Because AChE is anchored by ColQ in the basal lamina and is linked to the plasma membrane by a transmembrane subunit (PRiMA), we used a genetic approach to evaluate the respective contribution of each anchoring oligomer. By visualization and quantification of AChE in mouse strains devoid of ColQ, PRiMA or AChE, specifically in the muscle, we found that along the nerve terminus the vast majority of AChE is anchored by ColQ that is only produced by the muscle, whereas very minor amounts of AChE are anchored by PRiMA that is produced by motoneurons. In its synaptic location, AChE is therefore positioned to scavenge ACh that effluxes from the nerve by non-quantal release. AChE-PRiMA, produced by the muscle, is diffusely distributed along the muscle in extrajunctional regions.

Published

2010

8. Neuroligin Trafficking Deficiencies Arising from Mutations in the α/β-Hydrolase Fold Protein Family*

Author

Shelley Camp, Davide Comoletti, Roger Y. Tsien, Noga Dubi, Antonella De Jaco, Michael Z. Lin, Margaret T. Butko, Palmer Taylor, Mark H. Ellisman, and Meghan T. Miller

Subjects

Protein Folding, Protein family, Hydrolases, Cell Adhesion Molecules, Neuronal, Protein domain, Mutant, Amino Acid Motifs, Mutation, Missense, Neuroligin, Nerve Tissue Proteins, Biochemistry, Hippocampus, Cell Line, Protein structure, Congenital Hypothyroidism, Missense mutation, Animals, Humans, Autistic Disorder, Molecular Biology, Genetics, biology, Membrane Proteins, Cell Biology, Dendrites, Transport protein, Protein Structure, Tertiary, Rats, Protein Transport, Amino Acid Substitution, Chaperone (protein), Protein Structure and Folding, biology.protein, Protein Processing, Post-Translational

Abstract

Despite great functional diversity, characterization of the alpha/beta-hydrolase fold proteins that encompass a superfamily of hydrolases, heterophilic adhesion proteins, and chaperone domains reveals a common structural motif. By incorporating the R451C mutation found in neuroligin (NLGN) and associated with autism and the thyroglobulin G2320R (G221R in NLGN) mutation responsible for congenital hypothyroidism into NLGN3, we show that mutations in the alpha/beta-hydrolase fold domain influence folding and biosynthetic processing of neuroligin3 as determined by in vitro susceptibility to proteases, glycosylation processing, turnover, and processing rates. We also show altered interactions of the mutant proteins with chaperones in the endoplasmic reticulum and arrest of transport along the secretory pathway with diversion to the proteasome. Time-controlled expression of a fluorescently tagged neuroligin in hippocampal neurons shows that these mutations compromise neuronal trafficking of the protein, with the R451C mutation reducing and the G221R mutation virtually abolishing the export of NLGN3 from the soma to the dendritic spines. Although the R451C mutation causes a local folding defect, the G221R mutation appears responsible for more global misfolding of the protein, reflecting their sequence positions in the structure of the protein. Our results suggest that disease-related mutations in the alpha/beta-hydrolase fold domain share common trafficking deficiencies yet lead to discrete congenital disorders of differing severity in the endocrine and nervous systems.

Published

2010

9. Targeting of Acetylcholinesterase in Neurons In Vivo: A Dual Processing Function for the Proline-Rich Membrane Anchor Subunit and the Attachment Domain on the Catalytic Subunit

Author

Eric Krejci, Shelley Camp, Korami Dembele, Anna Hrabovska, Alexandre Dobbertin, Palmer Taylor, Véronique Bernard, Institut de Physique et Chimie des Matériaux de Strasbourg (IPCMS), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Réseau nanophotonique et optique, Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA), Biologie des Jonctions Neuromusculaires Normales et Pathologiques (U686), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Neurosciences Paris Seine (NPS), Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Biologie Paris Seine (IBPS), and Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Male, Protein subunit, Molecular Sequence Data, Nerve Tissue Proteins, Biology, Article, Cell Line, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Catalytic Domain, Enzyme Stability, Animals, Humans, Amino Acid Sequence, Binding site, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, Mice, Knockout, Neurons, 0303 health sciences, Binding Sites, Base Sequence, General Neuroscience, Endoplasmic reticulum, Wild type, Membrane Proteins, Acetylcholinesterase, Transmembrane protein, humanities, Cell biology, Membrane protein, chemistry, Biochemistry, Gene Targeting, Female, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], 030217 neurology & neurosurgery, Intracellular

Abstract

Acetylcholinesterase (AChE) accumulates on axonal varicosities and is primarily found as tetramers associated with a proline-rich membrane anchor (PRiMA). PRiMA is a small transmembrane protein that efficiently transforms secreted AChE to an enzyme anchored on the outer cell surface. Surprisingly, in the striatum of the PRiMA knock-out mouse, despite a normal level of AChE mRNA, we find only 2–3% of wild type AChE activity, with the residual AChE localized in the endoplasmic reticulum, demonstrating that PRiMAin vivois necessary for intracellular processing of AChE in neurons. Moreover, deletion of the retention signal of the AChE catalytic subunit in mice, which is the domain of interaction with PRiMA, does not restore AChE activity in the striatum, establishing that PRiMA is necessary to target and/or to stabilize nascent AChE in neurons. These unexpected findings open new avenues to modulating AChE activity and its distribution in CNS disorders.

Published

2009

10. Influence of differential expression of acetylcholinesterase in brain and muscle on respiration

Author

Arthur S. Foutz, Palmer Taylor, Shelley Camp, Jean Champagnat, Eliane Boudinot, Véronique Bernard, Eric Krejci, Neurobiologie génétique et intégrative (NGI), Centre National de la Recherche Scientifique (CNRS), Institut de Neurobiologie Alfred Fessard (INAF), Biologie des Jonctions Neuromusculaires Normales et Pathologiques (U686), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Department of pharmacology, University of California [San Diego] (UC San Diego), University of California-University of California, and Université Paris Descartes - Paris 5 (UPD5) - Institut National de la Santé et de la Recherche Médicale (INSERM) - Centre National de la Recherche Scientifique (CNRS)

Subjects

Male, MESH: Muscles, MESH: Body Temperature, Physiology, MESH: Anoxia, MESH: Pulmonary Ventilation, MESH: Tidal Volume, MESH: Mice, Knockout, Body Temperature, Hypercapnia, Mice, chemistry.chemical_compound, 0302 clinical medicine, Respiratory function, MESH: Animals, Respiratory system, Hypoxia, Butyrylcholinesterase, MESH: Plethysmography, Whole Body, Sequence Deletion, Mice, Knockout, 0303 health sciences, MESH: Butyrylcholinesterase, Muscles, Respiration, General Neuroscience, Brain, Exons, MESH: Sequence Deletion, Acetylcholinesterase, MESH: Gene Expression Regulation, Bronchodilator Agents, medicine.anatomical_structure, Knockout mouse, Female, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], MESH: Terbutaline, Acetylcholine, medicine.drug, Pulmonary and Respiratory Medicine, medicine.medical_specialty, Biology, Article, Neuromuscular junction, 03 medical and health sciences, MESH: Brain, Internal medicine, MESH: Analysis of Variance, Terbutaline, Tidal Volume, medicine, Animals, [SDV.NEU] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], MESH: Mice, Gene knockout, Plethysmography, Whole Body, 030304 developmental biology, MESH: Respiration, Analysis of Variance, MESH: Acetylcholinesterase, MESH: Male, Endocrinology, Gene Expression Regulation, chemistry, MESH: Hypercapnia, MESH: Bronchodilator Agents, Pulmonary Ventilation, MESH: Exons, MESH: Female, 030217 neurology & neurosurgery

Abstract

International audience; A mouse strain with a deleted acetylcholinesterase (AChE) gene (AChE knockout) shows a decreased inspiration time and increased tidal volume and ventilation .To investigate the respective roles of AChE in brain and muscle, we recorded respiration by means of whole-body plethysmography in knockout mice with tissue selective deletions in AChE expression. A mouse strain with the anchoring domains of AChE deleted (del E5+6 knockout mice) has very low activity in the brain and neuromuscular junction, but increased monomeric AChE in serum. A mouse strain with deletion of the muscle specific region of AChE (del i1RR knockout mice) exhibits no expression in muscle, but unaltered expression in the central nervous system. Neither strain exhibits the pronounced phenotypic traits observed in the complete AChE knockout strain. A third strain lacking the anchor molecule PRiMA, has no functional AChE and butyrylcholinesterase (BChE) in brain and an unaltered respiratory function. BChE inhibition by bambuterol decreases tidal volume and body temperature in del E5+6 and i1RR knockout strains, but not in PRiMA deletion or wild-type controls. We find that: (1) deletion of the full AChE gene is required for a pronounced alteration in respiratory phenotype, (2) BChE is involved in respiratory muscles contraction and temperature control in del E5+6 and i1RR knockout mice, and (3) AChE expression requiring a gene product splice to either exons 5 and 6 or regulated by intron1 influences temperature control.

Published

2009

11. Gene structure of mammalian acetylcholinesterase. Alternative exons dictate tissue-specific expression

Author

Shelley Camp, Palmer Taylor, Ying Li, D. Getman, and Tara L. Rachinsky

Subjects

RNA Splicing, Molecular Sequence Data, Restriction Mapping, Biology, Exon shuffling, Polymerase Chain Reaction, Biochemistry, Mice, Exon, Ribonucleases, Exon trapping, Sequence Homology, Nucleic Acid, Tumor Cells, Cultured, Animals, Humans, Amino Acid Sequence, Molecular Biology, Gene, Mammals, Splice site mutation, Base Sequence, Intron, DNA, Exons, Cell Biology, Blotting, Northern, Molecular biology, Introns, Stop codon, Organ Specificity, Acetylcholinesterase, Tandem exon duplication, Sequence Alignment

Abstract

The genes encoding mouse and human acetylcholinesterases have been cloned from genomic and cosmid libraries. Restriction analysis and a comparison of sequence with the cDNAs have defined the exon-intron boundaries. In mammals, three invariant exons encode the signal peptide and the amino-terminal 535 amino acids common to all forms of the enzyme whereas alternative exon usage of the next exon accounts for the structural divergence in the carboxyl termini of the catalytic subunits. mRNA protection studies show that the cDNA encoding the hydrophilic catalytic subunits represents the dominant mRNA species in mammalian brain and muscle whereas divergent mRNA species are evident in cells of hematopoietic origin (bone marrow cells and a erythroleukemia cell line). Analyses of mRNA species in these cells and the genomic sequence have enabled us to define two alternative exons in addition to the one found in the cDNAs; they encode unique carboxyl-terminal sequences. One mRNA consists of a direct extension through the intervening sequence between the common exon and the 3' exon deduced from the cDNA. This sequence encodes a subunit lacking the cysteine critical to oligomer formation. Another mRNA results from a splice that encodes a stretch of hydrophobic amino acids immediately upstream of a stop codon. This exon, when spliced to the upstream invariant exons, should encode glycophospholipid-linked species of the enzyme. Homologous sequence, identity of exon-intron junctions, and identity of position of the stop codon are seen for this region in mouse and human. Polymerase chain reactions carried out across the expected intron region and mRNA protection studies show that this splice occurs in mouse bone marrow and erythroleukemia cells yielding the appropriate cDNA.

Published

1991

12. Acetylcholinesterase expression in muscle is specifically controlled by a promoter-selective enhancesome in the first intron

Author

Palmer Taylor, Shelley Camp, Brian de la Torre, Limin Zhang, Michael Marquez, and Antonella De Jaco

Subjects

muscle, Molecular Sequence Data, Neuromuscular Junction, Chick Embryo, Biology, MyoD, Axonal Transport, Gene Expression Regulation, Enzymologic, Article, Cell Line, Mice, medicine, Myocyte, Animals, Enhancer, Muscle, Skeletal, Promoter Regions, Genetic, Transcription factor, knock-out mouse, acetylcholinesterase, differentiation, enhancesome, myogenesis, Mice, Knockout, Motor Neurons, Base Sequence, Myogenesis, General Neuroscience, Skeletal muscle, Molecular biology, Introns, Myotube differentiation, medicine.anatomical_structure, Enhancer Elements, Genetic, Acetylcholinesterase, C2C12

Abstract

Mammalian acetylcholinesterase (AChE) gene expression is exquisitely regulated in target tissues and cells during differentiation. An intron located between the first and second exons governs a ∼100-fold increase in AChE expression during myoblast to myotube differentiation in C2C12 cells. Regulation is confined to 255 bp of evolutionarily conserved sequence containing functional transcription factor consensus motifs that indirectly interact with the endogenous promoter. To examine controlin vivo, this region was deleted by homologous recombination. The knock-out mouse is virtually devoid of AChE activity and its encoding mRNA in skeletal muscle, yet activities in brain and spinal cord innervating skeletal muscle are unaltered. The transcription factors MyoD and myocyte enhancer factor-2 appear to be responsible for muscle regulation. Selective control of AChE expression by this region is also found in hematopoietic lineages. Expression patterns in muscle and CNS neurons establish that virtually all AChE activity at the mammalian neuromuscular junction arises from skeletal muscle rather than from biosynthesis in the motoneuron cell body and axoplasmic transport.

Published

2008

13. Single gene encodes glycophospholipid-anchored and asymmetric acetylcholinesterase forms: Alternative coding exons contain inverted repeat sequences

Author

Shelley Camp, Palmer Taylor, Tomas J. Ekströ, Yves Maulet, Tara L. Rachinsky, and Gretchen Gibney

Subjects

Untranslated region, Inverted Repeat Sequences, Protein subunit, Molecular Sequence Data, Restriction Mapping, Biology, Torpedo, Exon, Restriction map, Animals, Amino Acid Sequence, RNA, Messenger, Peptide sequence, Gene, Phospholipids, Repetitive Sequences, Nucleic Acid, Genetics, Polymorphism, Genetic, Base Sequence, General Neuroscience, DNA, Exons, Blotting, Northern, Genes, Biochemistry, Acetylcholinesterase, Nucleic Acid Conformation, Tandem exon duplication, Glycolipids

Abstract

Polymorphic forms of acetylcholinesterase are tethered extracellularly either as dimers membrane-anchored by a glycophospholipid or as catalytic subunits disulfidelinked to a collagen tail that associates with the basal lamina. Genomic clones of acetylcholinesterase from T. californica revealed that individual enzyme forms are encoded within a single gene that yields multiple mRNAs. Each enzyme form is encoded in three exons: the first two exons, bases -22 to 1502 and 1503 to 1669, encode sequence common to both forms, while alternative third exons encode a hydrophobic C-terminal region, to which a glycophospholipid is added upon processing, and a nonprocessed C-terminus, yielding a catalytic subunit that disulfide-links with a collagen-like structural unit. The 3' untranslated region of each alternative exon contains tandem repeat sequences that are inverted with respect to the other exon. This may either dictate alternative exon usage by formation of cis stem-loops or affect the abundance of translatable mRNA by trans-hybridization between the alternative spliced mRNA species.

Published

1990

14. Remodeling of the neuromuscular junction in mice with deleted exons 5 and 6 of acetylcholinesterase

Author

Palmer Taylor, Véronique Bernard, Eric Krejci, Emmanuelle Girard, Shelley Camp, Jordi Molgó, Laboratoire de neurobiologie cellulaire et moléculaire (NBCM), Centre National de la Recherche Scientifique (CNRS), Institut de Neurobiologie Alfred Fessard (INAF), Biologie des Jonctions Neuromusculaires Normales et Pathologiques (U686), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Department of pharmacology, University of California [San Diego] (UC San Diego), University of California-University of California, and Université Paris Descartes - Paris 5 (UPD5) - Institut National de la Santé et de la Recherche Médicale (INSERM) - Centre National de la Recherche Scientifique (CNRS)

Subjects

[SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Diaphragm, MESH: Respiratory Muscles, Neuromuscular transmission, Neuromuscular Junction, Biology, Receptors, Nicotinic, MESH: Mice, Knockout, Neuromuscular junction, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Exon, Mice, 0302 clinical medicine, COLQ, medicine, Coding region, Animals, MESH: Animals, MESH: Mice, Butyrylcholinesterase, 030304 developmental biology, Acetylcholine receptor, Sequence Deletion, Mice, Knockout, 0303 health sciences, [SDV.NEU.NB] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, General Medicine, Exons, MESH: Acetylcholinesterase, MESH: Sequence Deletion, Acetylcholinesterase, Molecular biology, Respiratory Muscles, medicine.anatomical_structure, chemistry, MESH: Diaphragm, MESH: Receptors, Nicotinic, MESH: Neuromuscular Junction, MESH: Exons, 030217 neurology & neurosurgery

Abstract

At the vertebrate skeletal neuromuscular junction (NMJ), two closely related enzymes can hydrolyze acetylcholine (ACh): acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). Advances in mouse genomics offer new approaches to assess the role of specific cholinesterases involved in neuromuscular transmission (Minic et al., 2003). AChE knockout mice provide a valuable tool for examining the effects of long-term complete and selective abolition of AChE activity (Xie et al., 2000). AChE and BChE genes encode two functional domains--the catalytic domain (exons 2, 3, and 4 of AChE, or exon 2 of BChE) and a C-terminal domain (exon 5 or 6 of AChE, or exon 3 of BChE)--that dictate the targeting of the enzymes (Massoulie, 2002). In mammals, the AChE gene produces three types of coding regions by deleting 5'- splice acceptor sites, which generate proteins; these proteins possess the same catalytic domain associated with distinct C-terminal peptides. AChE subunits of type R (readthrough) produce soluble monomers; they are expressed during development and are thought to be induced in the mouse brain by stress (Kaufer et al., 1998). AChE subunits of type H (hydrophobic) produce GPI-anchored dimers, mainly in blood cells. Subunits of type T (tailed) exist for both AChE and BChE. They represent the predominant AChE variant expressed in cholinergically innervated tissues (muscle and nerve). These subunits generate a variety of quaternary structures, including homomeric oligomers (monomers, dimers, tetramers), as well as hetero-oligomeric assemblies with anchoring proteins ColQ (Krejci et al., 1997) and PRiMA (Perrier et al., 2002). At the NMJ, AChE is clustered by the interaction of the coding sequence of exon 6 with ColQ (Feng et al., 1999). The deletion of exons 5 and 6 in the AChE gene transforms anchored AChE into a soluble enzyme (Camp et al., 2004). The present study was designed to evaluate neuromuscular transmission and nicotinic ACh receptor (nAChR) distribution in muscles from mutant mice with deletions of these two spliced exons (AChE-del-exons-5+6-/-).

Published

2006

15. Splicing of 5' introns dictates alternative splice selection of acetylcholinesterase pre-mRNA and specific expression during myogenesis

Author

Palmer Taylor, Zhigang Luo, Shelley Camp, and Annick Mutero

Subjects

Molecular Sequence Data, Exonic splicing enhancer, Biology, Transfection, Biochemistry, Splicing factor, Exon, Mice, RNA Precursors, Animals, Humans, Amino Acid Sequence, RNA, Messenger, Muscle, Skeletal, Molecular Biology, Sequence Deletion, Genetics, Splice site mutation, Models, Genetic, Sequence Homology, Amino Acid, Alternative splicing, Intron, Cell Differentiation, Cell Biology, Group II intron, Introns, Isoenzymes, Alternative Splicing, Mutagenesis, RNA splicing, Acetylcholinesterase, Nucleic Acid Conformation, Protein Binding

Abstract

Splicing of alternative exon 6 to invariant exons 2, 3, and 4 in acetylcholinesterase (AChE) pre-mRNA results in expression of the prevailing enzyme species in the nervous system and at the neuromuscular junction of skeletal muscle. The structural determinants controlling splice selection are examined in differentiating C2-C12 muscle cells by selective intron deletion from and site-directed mutagenesis in the Ache gene. Transfection of a plasmid lacking two invariant introns (introns II and III) within the open reading frame of the Ache gene, located 5′ of the alternative splice region, resulted in alternatively spliced mRNAs encoding enzyme forms not found endogenously in myotubes. Retention of either intron II or III is sufficient to control the tissue-specific pre-mRNA splicing pattern prevalent in situ. Further deletions and branch point mutations revealed that upstream splicing, but not the secondary structure of AChE pre-mRNA, is the determining factor in the splice selection. In addition, deletion of the alternative intron between the splice donor site and alternative acceptor sites resulted in aberrant upstream splicing. Thus, selective splicing of AChE pre-mRNA during myogenesis occurs in an ordered recognition sequence in which the alternative intron influences the fidelity of correct upstream splicing, which, in turn, determines the downstream splice selection of alternative exons.

Published

1998

16. Structural bases for the specificity of cholinesterase catalysis and inhibition

Author

Shelley Camp, Natilie A. Hosea, Zoran Radić, Harvey Alan Berman, Palmer Taylor, Pascale Marchot, University of California [San Diego] (UC San Diego), University of California, Centre National de la Recherche Scientifique (CNRS), State University of New York at Buffalo, Partenaires INRAE, University of California (UC), and State University of New York [Buffalo]

Subjects

Stereochemistry, [SDV]Life Sciences [q-bio], Peptide, Toxicology, Substrate Specificity, Fasciculin, Active center, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Stereospecificity, Animals, Cholinesterases, Humans, Enantiomeric inhibitors, Binding site, 030304 developmental biology, Elapid Venoms, chemistry.chemical_classification, 0303 health sciences, Binding Sites, Mutagenesis, Serine hydrolase, General Medicine, Cholinesterase, Acetylcholinesterase, Organophosphates, 3. Good health, chemistry, Cholinesterase Inhibitors, Enantiomer, 030217 neurology & neurosurgery

Abstract

International audience; The availability of a crystal structure and comparative sequences of the cholinesterases has provided templates suitable for analyzing the molecular bases of specificity of reversible inhibitors, carbamoylating agents and organophosphates. Site-specific mutagenesis enables one to modify the structures of both the binding site and peptide ligand as well as create chimeras reflecting one type of esterase substituted in the template of another. Herein we define the bases for substrate specificity of carboxylesters, the stereospecificity of enantiomeric alkylphosphonates and the selectivity of tricyclic aromatic compounds in the active center of cholinesterase. We also describe the binding loci of the peripheral site and changes in catalytic parameters induced by peripheral site ligands, using the peptide fasciculin.

Published

1995

17. Allosteric control of acetylcholinesterase catalysis by fasciculin

Author

Zoran Radić, Shelley Camp, Palmer Taylor, Daniel C. Vellom, and Daniel M. Quinn

Subjects

Stereochemistry, Protein Conformation, Phenylalanine, Kinetics, Allosteric regulation, Transfection, Biochemistry, Catalysis, Protein Structure, Secondary, Cell Line, Acylation, Active center, chemistry.chemical_compound, Mice, Allosteric Regulation, Side chain, Animals, Humans, Point Mutation, Amino Acid Sequence, Binding site, Molecular Biology, Elapid Venoms, Alanine, Chemistry, Tryptophan, Cell Biology, Models, Theoretical, Acetylcholinesterase, Recombinant Proteins, Mutagenesis, Site-Directed, Tyrosine, Cholinesterase Inhibitors, Allosteric Site, Mathematics

Abstract

The interaction of fasciculin 2 was examined with wild-type and several mutant forms of acetylcholinesterase (AChE) where Trp86, which lies at the base of the active center gorge, is replaced by Tyr, Phe, and Ala. The fasciculin family of peptides from snake venom bind to a peripheral site near the rim of the gorge, but at a position which still allows substrates and other inhibitors to enter the gorge. The interaction of a series of charged and uncharged carboxyl esters, alkyl phosphoryl esters, and substituted trifluoroacetophenones were analyzed with the wild-type and mutant AChEs in the presence and absence of fasciculin. We show that Trp86 is important for the alignment of carboxyl ester substrates in the AChE active center. The most marked influence of Trp86 substitution in inhibiting catalysis is seen for carboxyl esters that show rapid turnover. The extent of inhibition achieved with bound fasciculin is also greatest for efficiently catalyzed, charged substrates. When Ala is substituted for Trp86, fasciculin becomes an allosteric activator instead of an inhibitor for certain substrates. Analysis of the kinetics of acylation by organophosphates and conjugation by trifluoroacetophenones, along with deconstruction of the kinetic constants for carboxyl esters, suggests that AChE inhibition by fasciculin arises from reductions of both the commitment to catalysis and diffusional entry of substrate into the gorge. The former is reflected in the ratio of the rate constant for substrate acylation to that for dissociation of the initial complex. The action of fasciculin appears to be mediated allosterically from its binding site at the rim of the gorge to affect the orientation of the side chain of Trp86 which lies at the gorge base.

Published

1995

18. Promoter elements and transcriptional control of the mouse acetylcholinesterase gene

Author

Tara L. Rachinsky, Palmer Taylor, Shelley Camp, C. Bongiorno, and Ying Li

Subjects

Untranslated region, Transcription, Genetic, Molecular Sequence Data, Restriction Mapping, Biology, Receptors, Nicotinic, Transfection, Biochemistry, Primer extension, Gene Expression Regulation, Enzymologic, Exon, Mice, Transcription (biology), Tumor Cells, Cultured, Animals, Humans, RNA, Messenger, Cloning, Molecular, Promoter Regions, Genetic, Molecular Biology, Gene, Cells, Cultured, Reporter gene, Genomic Library, Base Sequence, Muscles, Brain, Promoter, Cell Biology, DNA, Exons, Blotting, Northern, Molecular biology, TATA Box, Introns, Open reading frame, Alternative Splicing, Oligodeoxyribonucleotides, Acetylcholinesterase, Leukemia, Erythroblastic, Acute

Abstract

The 5'-untranslated region of the mouse acetylcholinesterase gene has been characterized structurally by RNase protection, primer extension, and sequencing. Evidence has been obtained for the use of two alternative promoters in brain. Tissue-specific splicing to alternative acceptor sites in the 5'-untranslated exons occurs in brain, muscle, and erythropoietic cells. cis elements 5' of the cap site that is predominantly used in these tissues and cells have been analyzed by deletion analysis of promoter-reporter gene constructs and by site-specific mutagenesis. The cap site is found 107 base pairs (bp) 5' of the translation start site. This region is devoid of CAAT or TATA sequences; further in the 5' direction 50 and 70 bp are tandem Egr-1 sites. The putative promoter has been coupled to the open reading frame of a luciferase reporter gene. Deletion analysis shows that this region largely accounts for tissue-specific transcription seen upon transfection of neuronal and muscle cells. Mutagenesis of the Egr-1 sites results in a marked loss of reporter gene activity, further substantiating the importance of this region in the control of transcription. cis elements in the promoter differ from those found for the genes encoding the various subunits of the nicotinic acetylcholine receptor, and distinct differences in control of transcription are evident when the respective reporter genes are transfected into C2 muscle cells.

Published

1993

19. Amino acid residues controlling acetylcholinesterase and butyrylcholinesterase specificity

Author

Ying Li, Palmer Taylor, Zoran Radić, Shelley Camp, Natilie A. Pickering, and Daniel C. Vellom

Subjects

Stereochemistry, Protein Conformation, Molecular Sequence Data, Torpedo, Biochemistry, Esterase, Butyrylthiocholine, Substrate Specificity, chemistry.chemical_compound, Mice, Structure-Activity Relationship, Animals, Site-directed mutagenesis, Butyrylcholinesterase, Cholinesterase, chemistry.chemical_classification, Binding Sites, biology, Base Sequence, Molecular Structure, Chemistry, Acetylcholinesterase, Recombinant Proteins, Amino acid, Kinetics, Enzyme inhibitor, biology.protein, Mutagenesis, Site-Directed

Abstract

Acetyl- and butyrylcholinesterase have 51-54% sequence identity in mammalian species; they exhibit distinct substrate and inhibitor specificities. The crystal structure of acetylcholinesterase enables one to predict folding of related esterases as well as assign residues responsible for differences in substrate specificity. These predictions were tested by expression of esterase chimeras and site-specific mutants using mouse acetylcholinesterase as a template. Chimeras of acetylcholinesterase in which the amino-terminal 174 and the carboxyl-terminal 88 amino acids have been converted to the butyrylcholinesterase sequences still exhibit acetyl-like substrate specificity. Four nonconserved amino acids which are within the central sequence and appear to surround the acyl pocket, F295, R296, F297, and V300, have been mutated alone and in combination to the corresponding residues found in butyrylcholinesterase, L286, S287, I288, and G291. The V300 and R296 mutants slightly enhance butyrylthiocholine hydrolysis while the F295 and F297 mutants, alone and in combination, confer butyrylcholinesterase character by enhancing activity to butyrylthiocholine, and diminishing activity to acetylthiocholine. The F297 mutation eliminates substrate inhibition. F295 and F297 may form a clamp around the acetoxy methyl group. They have distinctive roles in affecting catalysis of the two acylcholines and precisely control acyl ester specificity. Comparison of the susceptibilities of the chimeras and site-specific mutants to cholinesterase-specific inhibitors isoOMPA, ethopropazine, and BW284c51 suggests that inhibitor selectivity for isoOMPA is attributable to residues limiting the size of the acyl pocket, while residues in the amino-terminal domain presumably near the lip of the gorge affect BW284c51 selectivity.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1993

20. Molecular cloning of mouse acetylcholinesterase: tissue distribution of alternatively spliced mRNA species

Author

Ying Li, Shelley Camp, Tara L. Rachinsky, Tomas J. Ekström, Michael Newton, and Palmer Taylor

Subjects

Untranslated region, RNA Splicing, Molecular Sequence Data, Molecular cloning, Biology, Polymerase Chain Reaction, Mice, Complementary DNA, Animals, Genomic library, Tissue Distribution, Northern blot, RNA, Messenger, Cloning, Molecular, Gene Library, Cloning, Messenger RNA, Genomic Library, Base Sequence, General Neuroscience, Muscles, Brain, Molecular biology, Open reading frame, Blotting, Southern, Genes, Butyrylcholinesterase, Acetylcholinesterase

Abstract

We have isolated cDNA clones encoding acetylcholinesterase from mouse muscle and brain. The polymerase chain reaction was used to amplify cDNA clones from C2 myotubes encoding the entire open reading frame and large segments of the 5' and 3' untranslated regions. The muscle cDNA clones were used to isolate clones from a brain library encoding the same mRNA species. The mouse clones encode a catalytic subunit containing a C-terminal sequence similar to that of the hydrophilic species of Torpedo. The mouse acetylcholinesterase sequence shares approximately 88% and 61% amino acid identity with bovine and Torpedo acetylcholinesterases, respectively, but only 52% identity with mouse butyrylcholinesterase, the sequence of which we have also deduced by molecular cloning. Northern blot and RNAase protection analyses indicate that the cDNA clones were derived from the acetylcholinesterase transcript that predominates in most expressing tissues. In contrast, erythroid cells are enriched in an mRNA species whose sequence diverges from that of the cDNA in the region encoding the C-terminus of the enzyme.

Published

1990

21. Primary structure of Torpedo californica acetylcholinesterase deduced from its cDNA sequence

Author

Yves Maulet, Susan S. Taylor, Theodore Friedmann, Palmer Taylor, Michael Newton, Mark Schumacher, Shelley Camp, and Kathleen MacPhee-Quigley

Subjects

Protein subunit, Biology, Torpedo, Thyroglobulin, law.invention, chemistry.chemical_compound, law, Sequence Homology, Nucleic Acid, Complementary DNA, medicine, Animals, Amino Acid Sequence, Cloning, Molecular, Binding site, Peptide sequence, Binding Sites, Multidisciplinary, Base Sequence, Protein primary structure, DNA, Acetylcholinesterase, Biochemistry, chemistry, Acetylcholine, medicine.drug

Abstract

Acetylcholinesterase, an essential enzyme of the nervous system, rapidly terminates the action of acetylcholine released into the synapse. Acetylcholinesterase is also found (in lower abundance) in extrajunctional areas of muscle and nerve and on erythrocyte membranes. Hydrodynamic analyses of the native enzyme and characterization of its dissociated subunits have revealed multiple enzyme forms which can be divided into two classes: dimensionally asymmetric forms which are usually found within the synapse and contain a collagen-like structural subunit disulphide-linked to the catalytic subunits; and globular forms which appear to be widely distributed on the outer surface of cell membranes. Both forms have been characterized in the ray Torpedo californica and, although their catalytic behaviours seem to be identical, they differ slightly in amino-acid composition, peptide maps and reactivity with certain monoclonal antibodies. Here, we report the complete amino-acid sequence of an acetylcholinesterase inferred from the sequence of a complementary DNA clone. The 575-residue protein shows significant homology with the C-terminal portion of thyroglobulin.

Published

1986

22. Multiple messenger RNA species give rise to the structural diversity in acetylcholinesterase

Author

Palmer Taylor, Shelley Camp, Mark Schumacher, and Yves Maulet

Subjects

Untranslated region, Protein Conformation, RNA Splicing, Molecular Sequence Data, Biology, Torpedo, Biochemistry, Exon, Ribonucleases, Transcription (biology), Animals, Amino Acid Sequence, RNA, Messenger, Molecular Biology, Genetics, Messenger RNA, Electric Organ, Base Sequence, RNA, Cell Biology, DNA, Isoenzymes, Open reading frame, genomic DNA, RNA splicing, Acetylcholinesterase

Abstract

Acetylcholinesterase exists predominantly as a secreted enzyme which remains cell-associated at specific extracellular locations. Its extensive structural diversity appears responsible for the unique cellular disposition of the enzyme. To examine the molecular basis of the structural divergence of acetylcholinesterase species, we hybridized total RNA from Torpedo californica electric organ with restriction fragments from a cDNA encoding the catalytic subunits of asymmetric species of acetylcholinesterase. Multiple RNA species up to 14 kilobases in length can be detected on Northern blots using a full-length cDNA for hybridization. Each of these RNA species also hybridizes with smaller restriction fragments within the open reading frame and 3'-untranslated region of the cDNA. This indicates that the entire open reading frame plus the 3'-untranslated region is contained in the large RNA species. RNase protection experiments revealed at least three points of divergence for the message species. One occurs within the COOH-terminal portion of the open reading frame at a position just 5' to the TGA stop codon. This divergence accounts for the two classes of acetylcholinesterase found in abundance in Torpedo. The site of splicing has been further defined by isolating a genomic clone containing the exon serving as the potential splice donor. We find a divergence between the cDNA and genomic DNA at the position estimated by the protection experiments. A less abundant divergence in mRNA can also be detected in the 3'-untranslated region. Another divergence occurs as a deleted sequence within the 5'-noncoding region and may be important for controlling translation efficiency. Since it is hypothesized that a single gene encodes acetylcholinesterase, the divergences in the very 3' region of the open reading frame and the 5'-noncoding region correspond to presumed splice junction boundaries where alternative RNA splicing occurs.

Published

1988

23. Antigenic and structural differences in the catalytic subunits of the molecular forms of acetylcholinesterase

Author

Bhupendra P. Doctor, Palmer Taylor, Shelley Camp, Susan S. Taylor, and Mary K. Gentry

Subjects

Antigenicity, Macromolecular Substances, Epitope, law.invention, chemistry.chemical_compound, Epitopes, Mice, law, medicine, Animals, Denaturation (biochemistry), Trypsin, Chromatography, High Pressure Liquid, chemistry.chemical_classification, Multidisciplinary, Chemistry, Protein primary structure, Acetylcholinesterase, Isoenzymes, Enzyme, Biochemistry, Torpedo, medicine.drug, Research Article

Abstract

A mixture of the 5.6S hydrophobic dimer and the asymmetric, tail-containing (17 + 13)S forms of acetylcholinesterase (acetylcholine acetylhydrolase, EC 3.1.1.7) from Torpedo californica was used to immunize mice, and spleen cells from these mice were used to produce nine hybridoma lines secreting antibodies against acetylcholinesterase. Antibodies from one of the lines showed a 100-fold greater affinity for the 5.6S species when compared with the catalytic subunits of the (17 + 13)S species. This difference in specificity was retained after denaturation of the two acetylcholinesterase species. Another line produced antibody directed only to structural subunits of the (17 + 13)S species, whereas the remaining seven antibodies exhibited nearly equivalent crossreactivity for all of the forms of acetylcholinesterase. Tryptic peptides were generated from the catalytic subunits of the 5.6S and tail-containing acetylcholinesterase species, and high-pressure liquid chromatographic profiles show at least two distinct peptides in the catalytic subunits for each enzyme species. Some of these peptides exhibit retention times different from those of the identified glycopeptides. Thus, it is likely that the catalytic subunits of two molecular forms of acetylcholinesterase differ in primary structure and sites of antigenicity.

Published

1983

24. Calcineurin enhances acetylcholinesterase mRNA stability during C2-C12 muscle cell differentiation

Author

Kenneth R. Chien, Zhigang Luo, Palmer Taylor, Yibin Wang, Shelley Camp, and Guy Werlen

Subjects

Transcription, Genetic, RNA Stability, Biology, chemistry.chemical_compound, Mice, Immunophilins, Cyclosporin a, medicine, Myocyte, Animals, RNA, Messenger, Cells, Cultured, Pharmacology, Myogenesis, Muscle cell differentiation, Calcineurin, Muscles, Skeletal muscle, Cell Differentiation, Molecular biology, Acetylcholinesterase, medicine.anatomical_structure, chemistry, Cyclosporine, Molecular Medicine, Calcium

Abstract

Treatment of C2-C12 mouse myoblasts with the immunosuppressant drug cyclosporin A (CsA) enhances the increase in acetylcholinesterase (AChE) expression observed during skeletal muscle differentiation. The enhanced AChE expression is due primarily to increased mRNA stability because CsA treatment increases the half-life of AChE mRNA, but not the apparent transcriptional rate of the gene. Neither tacrolimus (FK506), an immunosuppressive agent with a distinct structure, nor cyclosporine H, an inactive congener of CsA, alters AChE expression. The enhanced AChE expression is associated with the muscle differentiation process, but cannot be triggered by CsA exposure before differentiation. Myoblasts and myotubes of C2-C12 cells express similar amounts of cyclophilin A and FKBP12, immunophilins known to be intracellular-binding targets for CsA and tacrolimus, respectively. However, cellular levels of calcineurin, a calcium/calmodulin-dependent phosphatase known to be the cellular target of ligand-immunophilin complexes, increase 3-fold during myogenesis. Overexpression of constitutively active calcineurin in differentiating cells reduces AChE mRNA levels and CsA antagonizes such an inhibition. Conversely, overexpression of a dominant negative calcineurin construct increases AChE mRNA levels, which are further enhanced by CsA. Thus, a CsA sensitive, calcineurin mediated pathway appears linked to differentiation-induced stabilization of AChE mRNA during myogenesis.

25. Mutagenesis of essential functional residues in acetylcholinesterase

Author

Shelley Camp, Kathleen MacPhee-Quigley, Palmer Taylor, Marc Dionne, and Gretchen Gibney

Subjects

Proteases, Molecular Sequence Data, Biology, Torpedo, Transfection, Subtilase, Cell Line, Serine, chemistry.chemical_compound, Sequence Homology, Nucleic Acid, Catalytic triad, medicine, Animals, Humans, Histidine, Multidisciplinary, Binding Sites, Base Sequence, Serine Endopeptidases, Subtilisin, Trypsin, Acetylcholinesterase, Kinetics, chemistry, Biochemistry, Mutation, Cholinesterase Inhibitors, Oligonucleotide Probes, medicine.drug, Research Article

Abstract

The cholinesterases are serine hydrolases that show no global similarities in sequence with either the trypsin or the subtilisin family of serine proteases. The cholinesterase superfamily includes several esterases with distinct functions and other proteins devoid of the catalytic serine and known esterase activity. To identify the residues involved in catalysis and conferring specificity on the enzyme, we have expressed wild-type Torpedo acetylcholinesterase (EC 3.1.1.7) and several site-directed mutants in a heterologous system. Mutation of serine-200 to cysteine results in diminished activity, while its mutation to valine abolishes detectable activity. Two conserved histidines can be identified at positions 425 and 440 in the cholinesterase family; glutamine replacement at position 440 eliminates activity whereas the mutation at 425 reduces activity only slightly. The assignment of the catalytic histidine to position 440 defines a rank ordering of catalytic residues in cholinesterases distinct from trypsin and subtilisin and suggests a convergence of a catalytic triad to form a third, distinct family of serine hydrolases. Mutation of glutamate-199 to glutamine yields an enzyme with a higher Km and without the substrate-inhibition behavior characteristic of acetylcholinesterase. Hence, modification of the acidic amino acid adjacent to the serine influences substrate association and the capacity of a second substrate molecule to affect catalysis.