Butyrylcholinesterase-Mediated enhancement of the enzymatic activity of trypsin

1. Acetylcholinesterase (AChE, EC 3.1.1.7) and butyrylcholinesterase (BuChE, EC 3.1.1.8) are enzymes that catalyze the hydrolysis of esters of choline.2. Both AChE and BuChE have been shown to copurify with peptidases.3. BuChE has also been shown to copurify with other proteins such as transferrin, with which it forms a stable complex. In addition, BuChE is found in association with -amyloid protein in Alzheimer brain tissues.4. Since BuChE copurifies with peptidases, we hypothesized that BuChE interacts with these enzymes and that this association had an influence on their catalytic activities. One of the peptidases that copurifies with cholinesterases has specificity similar to trypsin, hence, this enzyme was used as a model to test this hypothesis.5. Purified BuChE causes a concentration-dependent enhancement of the catalytic activity of trypsin while trypsin does not influence the catalytic activity of BuChE.6. We suggest that, in addition to its esterase activity, BuChE may assume a regulatory role by interacting with other proteins.     

Acetylcholinesterase H and T dimers are associated through the same contact. Mutations at this interface interfere with the C-terminal T peptide, inducing degradation rather than secretion.

Acetylcholinesterase (AChE) exists as AChE(H) and AChE(T) subunits, which differ by their C-terminal H or T peptides, generating glycophosphatidylinositol-anchored dimers and various oligomers, respectively. We introduced mutations in the four-helix bundle interface of glycophosphatidylinositol-anchored dimers, and analyzed their effect on the production and oligomerization of AChE(H), of AChE(T), and of truncated subunits, AChE(C) (without H or T peptide). Dimerization was reduced for all types of subunits, showing that they interact through the same contact zone; the formation of amphiphilic tetramers (Torpedo AChE(T)) and 13.5 S oligomers (rat AChE(T)) was also suppressed. Oligomerization appeared totally blocked by introduction of an N-linked glycan on the surface of helix alpha(7,8). Other point mutations did not affect the synthesis or the catalytic properties of AChE but reduced or blocked the secretion of AChE(T) subunits. Secretion of AChE(T) was partially restored by co-expression with Q(N), a secretable protein containing a proline-rich attachment domain (PRAD); Q(N) organized PRAD-linked tetramers, except for the N-glycosylated mutants. Thus, the simultaneous presence of an abnormal four-helix bundle zone and an exposed T peptide targeted the enzyme toward degradation, indicating a cross-talk between the catalytic and tetramerization domains.     

THE SUBUNIT STRUCTURE OF MAMMALIAN ACETYLCHOLINESTERASE: CATALYTIC SUBUNITS, DISSOCIATING EFFECT OF PROTEOLYSIS AND DISULPHIDE REDUCTION ON THE POLYMERIC FORMS

Abstract— An analysis of the [³H]DFP-labelled catalytic subunits of mammalian (bovine SCG) acetylcholinesterase (AChE, EC 3.1.1.7.) indicates a monomer molecular weight of 75,000. This is equivalent to the mass previously determined for the smallest active form and demonstrates that the globular, or G forms, are respectively monomeric (G₁ form, 4S), dimeric (G₂ form, 6.5S) and tetrameric (G₄ form, 10S). In the tetrameric G₄ form the catalytic chains are associated in dimers, by disulphide bonds.
The effect of reduction and proteolysis has shown that the dimeric form (G₂ form, 6.5S) is readily reduced into G₁, while the tetramer G₄ is very stable, being only dissociated by a combination of reduction and proteolysis by high concentration of trypsin. The asymmetric forms A₁₂ (16S), A₈ (13S) and A₄ (9S) are not sensitive to reduction, but are readily dissociated by low concentrations of trypsin, into each other, progressively liberating isolated tetramers. We obtained essentially identical results with AChE preparations from rat brain or superior cervical ganglion. These observations support a general model for the quaternary structure of acetylcholinesterase molecular forms.     

The origin of the molecular diversity and functional anchoring of cholinesterases

Vertebrates possess two cholinesterases, acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) which both hydrolyze acetylcholine, but differ in their specificity towards other substrates, and in their sensitivity to inhibitors. In mammals, the AChE gene produces three types of coding regions through the choice of 3' splice acceptor sites, generating proteins which 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 induced by stress in the mouse brain. AChE subunits of type H ('hydrophobic') produce GPI-anchored dimers, but also secreted molecules; they are mostly expressed in blood cells. Subunits of type T ('tailed') exist for both AChE and BChE. They represent the enzyme forms expressed in brain and muscle. These subunits generate a variety of quaternary structures, including homomeric oligomers (monomers, dimers, tetramers), as well as hetero-oligomeric assemblies with anchoring proteins, ColQ and PRiMA. Mutations in the four-helix bundle (FHB) zone of the catalytic domain indicate that subunits of type H and T use the same interaction for dimerization. On the other hand, the C-terminal T peptide is necessary for tetramerization. Four T peptides, organized as amphiphilic alpha helices, can assemble around proline-rich motifs of ColQ or PRiMA. The association of AChE(T) or BChE subunits with ColQ produces collagen-tailed molecules, which are inserted in the extracellular matrix, e.g. in the basal lamina of neuromuscular junctions. Their association with PRiMA produces membrane-bound tetramers which constitute the predominant form of cholinesterases in the mammalian brain; in muscles, the level of PRiMA-anchored tetramers is regulated by exercise, but their functional significance remains unknown. In brain and muscles, the hydrolysis of acetylcholine by cholinesterases, in different contexts, and their possible noncatalytic functions clearly depend on their localization by ColQ or PRiMA.     

Amphiphilic and Nonamphiphilic Forms of Bovine and Human Dopamine β-Hydroxylase

We show that human and bovine dopamine beta-hydroxylases (DBH) exist under three main molecular forms: a soluble nonamphiphilic form and two amphiphilic forms. Sedimentation in sucrose gradients and electrophoresis under nondenaturing conditions, by comparison with acetylcholinesterase (AChE), suggest that the three forms are tetramers of the DBH catalytic subunit and bind either no detergent, one detergent micelle, or two detergent micelles. By analogy with the Gna4 and Ga4 AChE forms, we propose to call the nonamphiphilic tetramer Dna4 and the amphiphilic tetramers Da4I and Da4II. In addition to the major tetrameric forms, DBH dimers occur as very minor species, both amphiphilic and nonamphiphilic. Reduction under nondenaturing conditions leads to a partial dissociation of tetramers into dimers, retaining their amphiphilic character. This suggests that the hydrophobic domain is not linked to the subunits through disulfide bonds. The two amphiphilic tetramers are insensitive to phosphatidylinositol phospholipase C, but may be converted into soluble DBH by proteolysis in a stepwise manner; Da4II----Da4I----Dna4. Incubation of soluble DBH with various phospholipids did not produce any amphiphilic form. Several bands corresponding to the catalytic subunits of bovine DBH were observed in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but this multiplicity was not simply correlated with the amphiphilic character of the enzyme. In the case of human DBH, we observed two bands of 78 and 84 kDa. As previously reported by others, the presence of the heavy subunit characterizes the amphiphilic forms of the enzyme. We discuss the nature of the hydrophobic domain, which could be an uncleaved signal peptide, and the organization of the different amphiphilic and nonamphiphilic DBH forms. We present two models in which dimers may possess either one hydrophobic domain or two domains belonging to each subunit; in both cases, a single detergent micelle would be bound per dimer.     

Cholinesterases: anchored enzymes in membranes and basal laminae

Two proteins, ColQ and PRiMA, organize tetramers of acetylcholinesterase (AChE) and of butyrylcholinesterase (BChE) through peptide interactions. A short proline rich sequence in the N-terminal domain of ColQ or PRiMA associates four C-terminal extension of AChE or BChE. ColQ targets the enzymes in the basal lamina, PRiMA targets the enzymes at the plasma membrane. These complexes represent the mature proteins. The unassembled C-terminal extention of AChE is the key determinant recognized during the "quality control" of protein synthesis. Unassembled catalytic subunits are then degraded by the proteasome pathway. At the neuromuscular junction, ColQ/AChE represents the concentrated enzyme. The clusterisation of AChE depends upon ColQ through three sites of interactions: two different heparin binding domains in the collagen domain interact with heparan sulfate proteoglycan particularly the perlecan and the C-terminal non collagenic domain interacts with MuSK, the tyrosine kinase receptor organiser of the neuromuscular junction. The absence of ColQ and AChE has revealed that the excess of Ach stimulates more nicotinic receptors but probably not until their desensitization. Several morphological modifications may help the clearance of Ach. Conversely the synapse transmission fails during high frequency nerve stimulation.     

Cholinesterases during development of the avian nervous system

1. Long before onset of synaptogenesis in the chicken neural tube, the closely related enzymes butyrylcholinesterase (BChE) and acetylcholinesterase (AChE) are expressed in a mutually exclusive manner. Accordingly, neuroblasts on the ventricular side of the neural tube transiently express BChE before they abruptly accumulate AChE while approaching the outer brain surface. 2. By exploiting AChE as a sensitive and early histochemical differentiation marker, we have demonstrated complex polycentric waves of differentiation spreading upon the cranial part of the chicken neural tube but a smooth rostrocaudal wave along the spinal cord. Shortly after expression of AChE, these cells extend long projecting neurites. In particular, segmented spinal motor axons originate from AChE-positive motoneurones; they navigate through a BChE-active zone within the rostral half of the sclerotomes before contacting BChE/AChE-positive myotome cells. At synaptogenetic stages, cholinesterases additionally are detectable in neurofibrillar laminae foreshadowing the establishment of cholinergic synapses. 3. In order to elucidate the functional significance of cholinesterases at early stages, we have investigated specific cholinesterase molecules and their mechanisms of action in vivo and in vitro. A developmental shift from the low molecular weight forms to the tetramers of both enzymes has been determined. In vitro, the addition of a selective BChE inhibitor leads to a reduction of AChE gene expression. Thus, in vivo and in vitro data suggest roles of cholinesterases in the regulation of cell proliferation and neurite growth. 4. Future research has to show whether neurogenetic functioning of cholinesterases can help to understand their reported alterations in neural tube defects, mental retardations, dementias and in some tumours.     

Different Glycosylation in Acetylcholinesterases from Mammalian Brain and Erythrocytes

Acetylcholinesterases (EC 3.1.1.7, AChE) have varying amounts of carbohydrates attached to the core protein. Sequence analysis of the known primary structures gives evidence for several asparagine-linked carbohydrates. From the differences in molecular mass determined on sodium dodecyl sulfate-polyacrylamide gel before and after deglycosylation with N-glycosidase F (EC 3.2.2.18), it is seen that dimeric AChE from red cell membranes is more heavily glycosylated than the tetrameric brain enzyme. Furthermore, dimeric and tetrameric forms of bovine AChE are more heavily glycosylated than the corresponding human enzymes. Monoclonal antibodies 2E6, 1H11, and 2G8 raised against detergent-soluble AChE from electric organs of Torpedo nacline timilei as well as Elec-39 raised against AChE from Electrophorus electricus cross-reacted with AChE from bovine and human brain but not with AChE from erythrocytes. Treatment of the enzyme with N-glycosidase F abolished binding of monoclonal antibodies, suggesting that the epitope, or part of it, consists of N-linked carbohydrates. Analysis of N-acetylglucosamine sugars revealed the presence of N-acetylglucosamine in all forms of cholinesterases investigated, giving evidence for N-linked glycosylation. On the other hand, N-acetylgalactosamine was not found in AChE from human and bovine brain or in butyrylcholinesterase (EC 3.1.1.8) from human serum, indicating that these forms of cholinesterase did not contain O-linked carbohydrates. Despite the notion that within one species, the different forms of AChE arise from one gene by different splicing, our present results show that dimeric erythrocyte and tetrameric brain AChE must undergo different postsynthetic modifications leading to differences in their glycosylation patterns.     

Acetylcholinesterase from the invertebrate Ciona intestinalis is capable of assembling into asymmetric forms when co-expressed with vertebrate collagenic tail peptide

To learn more about the evolution of the cholinesterases (ChEs), acetylcholinesterase (AChE) and butyrylcholinesterase in the vertebrates, we investigated the AChE activity of a deuterostome invertebrate, the urochordate Ciona intestinalis, by expressing in vitro a synthetic recombinant cDNA for the enzyme in COS-7 cells. Evidence from kinetics, pharmacology, molecular biology, and molecular modeling confirms that the enzyme is AChE. Sequence analysis and molecular modeling also indicate that the cDNA codes for the AChE(T) subunit, which should be able to produce all three globular forms of AChE: monomers (G(1)), dimers (G(2)), and tetramers (G(4)), and assemble into asymmetric forms in association with the collagenic subunit collagen Q. Using velocity sedimentation on sucrose gradients, we found that all three of the globular forms are either expressed in cells or secreted into the medium. In cell extracts, amphiphilic monomers (G(1)(a)) and non-amphiphilic tetramers (G(4)(na)) are found. Amphiphilic dimers (G(2)(a)) and non-amphiphilic tetramers (G(4)(na)) are secreted into the medium. Co-expression of the catalytic subunit with Rattus norvegicus collagen Q produces the asymmetric A(12) form of the enzyme. Collagenase digestion of the A(12) AChE produces a lytic G(4) form. Notably, only globular forms are present in vivo. This is the first demonstration that an invertebrate AChE is capable of assembling into asymmetric forms. We also performed a phylogenetic analysis of the sequence. We discuss the relevance of our results with respect to the evolution of the ChEs in general, in deuterostome invertebrates, and in chordates including vertebrates.     

Assembly of monomeric acetylcholinesterase into tetrameric and asymmetric forms

A pulse-chase experiment was performed in embryonic rat myotube cultures to examine possible precursor-product relationships among the various molecular forms of acetylcholinesterase (AChE). AChE was labeled with paraoxon, a compound which diethylphosphorylates AChE at its active site. Diethylphosphorylated (labeled) AChE is inactive but can be reactivated by treatment with 1-methyl-2-hydroxyiminomethyl-pyridinium. Thus labeled enzyme could be followed as AChE that regained activity following treatment with 1-methyl-2-hydroxyiminomethylpyridium. To selectively label monomeric AChE (the hypothesized precursor form), cultures were treated with methanesulfonylfluoride which irreversibly inactivated more than 97% of total cellular AChE. Methylsulfonylfluoride was then washed from the cultures, and they were labeled with paraoxon during a 40-55-min recovery period. AChE appearing in the cultures during this recovery period is newly synthesized and consists almost entirely (92%) of the monomeric form. Immediately and 120-130 min after labeling, cultures were subjected to a sequential extraction procedure to separate globular from asymmetric forms. Individual forms were then separated by velocity sedimentation on sucrose gradients. In our first series of experiments, we observed a 55% decrease in labeled monomers during the chase, a 36% increase in labeled tetramers, and a 36% increase in labeled asymmetric forms. In a second series of experiments focused on individual asymmetric forms, we observed a 55% decrease in labeled monomers, a 58% increase in labeled tetramers, an overall increase of 81% in labeled asymmetric forms, and a 380% increase in labeled A12 AChE. These data provide the first uniequivocal proof that complex forms of AChE are assembled from active monomeric precursors.     

Oligomerization of Chicken Acetylcholinesterase Does Not Require Intersubunit Disulfide Bonds

Abstract: Acetylcholinesterase (AChE) is secreted from muscle and nerve cells and associates as multimers through intermolecular covalent and noncovalent bonds. The amino acid sequence of the C-terminus is thought to play an important role in these interactions. We generated mutants in the C-terminus of the catalytic T-subunit of chicken AChE to determine the importance of this region to oligomerization and to the amphipathic character of the protein. Wild-type recombinant chicken AChE secreted from human embryonic kidney 293 cells was assembled into dimers and tetramers exclusively. Mutants lacking the C-terminal Cys⁷⁶⁴, the only cysteine involved in interchain disulfide bonds, showed lower but significant levels of the secreted dimeric and tetrameric forms. A truncated mutant, lacking the C-terminal 39 amino acids, exhibited a severe decrease in content of the multimeric forms, yet small amounts of the dimer were detectable. The amphipathic character was dependent on the state of oligomerization. When analyzed by sucrose gradients, the sedimentation of tetramers was not affected by detergent, but monomers and dimers sedimented more slowly in the presence of detergent. Most of the recombinant wild-type enzyme, shown to be dimeric and tetrameric by sedimentation analysis, was monomeric when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions, indicating that much of the secreted oligomeric AChE was not disulfide bonded. These data suggest that disulfide bonding of Cys⁷⁶⁴ is not required for the catalytic subunit of chicken AChE to form oligomers and that regions outside of the C-terminus contribute to the hydrophobic interactions that are important for stabilizing the oligomeric forms.     

Acetylcholinesterase in Cocultures of Rat Myotubes and Spinal Cord Neurons: Effects of Collagenase and cis-Hydroxyproline on Molecular Forms, Intra- and Extracellular Distribution, and Formation of Patches at Neuromuscular Contacts

Cultures of rat myotubes from 18-day-old embryos produce both globular (G) and asymmetric (A) forms of acetylcholinesterase (AChE; EC 3.1.1.7), mostly G1, G4, and A12 and a small proportion of A8. We show that all forms are partly intracellular and partly exposed to the extracellular medium; the A forms and their intra- and extracellular distribution are not modified when myotubes are grown in the presence of spinal cord neurons. In these cocultures, however, AChE patches may be detected immunohistochemically at sites of neuromuscular contacts. These patches represent a very minor proportion of AChE activity. We found that collagenase removes AChE patches but not the acetylcholine receptor clusters with which they coincide. This digestion specifically decreases the level of the A12 form. cis-Hydroxyproline, an inhibitor of collagen synthesis, reduces the level of G1 and blocks the synthesis of A forms.     

Genetic analysis of collagen Q: roles in acetylcholinesterase and butyrylcholinesterase assembly and in synaptic structure and function

Acetylcholinesterase (AChE) occurs in both asymmetric forms, covalently associated with a collagenous subunit called Q (ColQ), and globular forms that may be either soluble or membrane associated. At the skeletal neuromuscular junction, asymmetric AChE is anchored to the basal lamina of the synaptic cleft, where it hydrolyzes acetylcholine to terminate synaptic transmission. AChE has also been hypothesized to play developmental roles in the nervous system, and ColQ is also expressed in some AChE-poor tissues. To seek roles of ColQ and AChE at synapses and elsewhere, we generated ColQ-deficient mutant mice. ColQ-/- mice completely lacked asymmetric AChE in skeletal and cardiac muscles and brain; they also lacked asymmetric forms of the AChE homologue, butyrylcholinesterase. Thus, products of the ColQ gene are required for assembly of all detectable asymmetric AChE and butyrylcholinesterase. Surprisingly, globular AChE tetramers were also absent from neonatal ColQ-/- muscles, suggesting a role for the ColQ gene in assembly or stabilization of AChE forms that do not themselves contain a collagenous subunit. Histochemical, immunohistochemical, toxicological, and electrophysiological assays all indicated absence of AChE at ColQ-/- neuromuscular junctions. Nonetheless, neuromuscular function was initially robust, demonstrating that AChE and ColQ do not play obligatory roles in early phases of synaptogenesis. Moreover, because acute inhibition of synaptic AChE is fatal to normal animals, there must be compensatory mechanisms in the mutant that allow the synapse to function in the chronic absence of AChE. One structural mechanism appears to be a partial ensheathment of nerve terminals by Schwann cells. Compensation was incomplete, however, as animals lacking ColQ and synaptic AChE failed to thrive and most died before they reached maturity.     

Rescue and Stabilization of Acetylcholinesterase in Skeletal Muscle by N-terminal Peptides Derived from the Noncatalytic Subunits

The vast majority of newly synthesized acetylcholinesterase (AChE) molecules do not assemble into catalytically active oligomeric forms and are rapidly degraded intracellularly by the endoplasmic reticulum-associated protein degradation pathway. We have previously shown that AChE in skeletal muscle is regulated in part post-translationally by the availability of the noncatalytic subunit collagen Q, and others have shown that expression of a 17-amino acid N-terminal proline-rich attachment domain of collagen Q is sufficient to promote AChE tetramerization in cells producing AChE. In this study we show that muscle cells, or cell lines expressing AChE catalytic subunits, incubated with synthetic proline-rich attachment domain peptides containing the endoplasmic reticulum retrieval sequence KDEL take up and retrogradely transport them to the endoplasmic reticulum network where they induce assembly of AChE tetramers. The peptides act to enhance AChE folding thereby rescuing them from reticulum degradation. This enhanced folding efficiency occurs in the presence of inhibitors of protein synthesis and in turn increases total cell-associated AChE activity and active tetramer secretion. Pulse-chase studies of isotopically labeled AChE molecules show that the enzyme is rescued from intracellular degradation. These studies provide a mechanistic explanation for the large scale intracellular degradation of AChE previously observed and indicate that simple peptides alone can increase the production and secretion of this critical synaptic enzyme in muscle tissue.     

Acetylcholinesterase in Mouse Neuroblastoma NB2A Cells: Analysis of Production, Secretion, and Molecular Forms

The mouse neuroblastoma cell line NB2A produces cellular and secreted acetylcholinesterase (AChE). After incubation of the cells for 4 days the ratio between AChE secreted into the medium and AChE in the cells was 1:1. The cell-associated enzyme could be subdivided into soluble AChE (25%) and detergent-soluble AChE (75%). Both extracts contained predominantly monomeric AChE (4.6S) and minor amounts of tetrameric AChE (10.6S), whereas the secreted AChE in the culture supernatant contained only the tetrameric form. All forms were partially purified by affinity chromatography. It could be demonstrated that the secretory and the intracellular soluble tetramers were hydrophilic, whereas the detergent-soluble tetramer was an amphiphilic protein. On the other hand the soluble and the detergent-soluble monomeric forms were amphiphilic and their activity depended on the presence of detergent. By digestion with proteinase K amphiphilic monomeric and tetrameric AChE could be converted to a hydrophilic form that no longer required detergent for catalytic activity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of [3H]diisopropylfluorophosphate-labelled AChE gave one band at 64 kilodaltons (kD) under reducing conditions and two additional bands at 120 kD and 140 kD under nonreducing conditions.     

Primary structure of a collagenic tail peptide of Torpedo acetylcholinesterase: co-expression with catalytic subunit induces the production of collagen-tailed forms in transfected cells.

The asymmetric forms of cholinesterases are synthesized only in differentiated muscular and neural cells of vertebrates. These complex oligomers are characterized by the presence of a collagen-like tail, associated with one, two or three tetramers of catalytic subunits. The collagenic tail is responsible for ionic interactions, explaining the insertion of these molecules in extracellular basal lamina, e.g. at neuromuscular endplates. We report the cloning of a collagenic subunit from Torpedo marmorata acetylcholinesterase (AChE). The predicted primary structure contains a putative signal peptide, a proline-rich domain, a collagenic domain, and a C-terminal domain composed of proline-rich and cysteine-rich regions. Several variants are generated by alternative splicing. Apart from the collagenic domain, the AChE tail subunit does not present any homology with previously known proteins. We show that co-expression of catalytic AChE subunits and collagenic subunits results in the production of asymmetric, collagen-tailed AChE forms in transfected COS cells. Thus, the assembly of these complex forms does not depend on a specific cellular processing, but rather on the expression of the collagenic subunits.     

The C-terminal T peptide of acetylcholinesterase enhances degradation of unassembled active subunits through the ERAD pathway

The catalytic domain of acetylcholinesterase AChE(T) subunits is followed by a C-terminal T peptide which mediates their association with the proline-rich attachment domain (PRAD) of anchoring proteins. Addition of the T peptide induced intracellular degradation and concomitantly reduced to variable degrees the secretion of AChE species differing in their oligomerization capacity and of human alkaline phosphatase. The T peptide forms an amphiphilic alpha-helix, containing a series of conserved aromatic residues. Replacement of two, four or five aromatic residues gradually suppressed degradation and increased secretion. Co-expression with a PRAD- containing protein induced the assembly of PRAD-linked tetramers in the endoplasmic reticulum (ER) and allowed partial secretion of a dimerization- defective mutant; by masking the aromatic side chains, hetero-oligomerization rescued this enzyme from degradation. Degradation was due to ERAD, since it was not blocked by brefeldin A but was sensitive to proteasome inhibitors. Kifunensine reduced degradation, suggesting a cooperativity between the glycosylated catalytic domain and the non-glycosylated T peptide. This system appears particularly well suited to analyze the mechanisms which determine the degradation of correctly folded multidomain proteins in the ER.     

Enzymoblotting: a method for localizing proteinases and their zymogens using para-nitroanilide substrates after agarose gel electrophoresis and transfer to nitrocellulose

A method--enzymoblotting--was developed for localizing various enzymes after electrophoretic separation, transfer to nitrocellulose, and incubation with specific substrates. As an application, the proteinases porcine trypsin (EC 3.4.21.4), bovine chymotrypsin (EC 3.4.21.1), porcine elastase (EC 3.4.22.11), and their zymogen forms from porcine pancreas homogenate were analyzed utilizing specific p-nitroanilide substrates. After agarose gel electrophoresis, transfer of the separated proteinases to a nitrocellulose membrane was performed by capillary diffusion for 30 min. After air-drying of the nitrocellulose membrane, it was incubated in the appropriate substrate solution for 60 min. N-alpha-Benzoyl-DL-arginine-para-nitroanilide HCl was used as a substrate for trypsin, N-benzoyl-L-tyrosine-para-nitroanilide and succinyl-L-phenylalanine-para-nitroanilide for chymotrypsin, and N-succinyl-L-alanyl-L-alanyl-L-alanine-para-nitroanilide for elastase. p-Nitroaniline, the product thus obtained, was diazotized with N-(1-naphthyl)ethylenediamine to a red azo dye, visible at the site of the proteinases on the nitrocellulose membrane. The results could be preserved at -18 degrees C. Zymogen forms of the pancreas proteinases were detected in a similar manner. They were converted to active proteinases in situ on the nitrocellulose membrane after preincubating the nitrocellulose membrane in the activation enzymes enteropeptidase or trypsin.     

Modes of attachment of acetylcholinesterase to the surface membrane

Acetylcholinesterase (AChE) occurs in multiple molecular forms differing in their quaternary structure and mode of anchoring to the surface membrane. Attachment is achieved by post-translational modification of the catalytic subunits. Two such mechanisms are described. One involves attachment to catalytic subunit tetramers, via disulfide bridges, of a collagen-like fibrous tail. This, in turn, interacts, primarily via ionic forces, with a heparin-like proteoglycan in the extracellular matrix. A second such modification involve the covalent attachment of a single phosphatidylinositol molecule at the carboxyl-terminus of each catalytic subunit polypeptide; the diacylglycerol moiety of the phospholipid serves to anchor the modified enzyme hydrophobically to the lipid bilayer of the plasma membrane. The detailed molecular structure of these two classes of acetylcholinesterase are discussed, as well as their biosynthesis and mode of anchoring.     

Subunit Association and Glycosylation of Acetylcholinesterase from Monkey Brain

Abstract: Cercopithecus monkey brain acetylcholinesterase (AChE; EC 3.1.1.7) consists of about 15% hydrophilic, salt-soluble enzyme and 83% amphiphilic, detergent-soluble enzyme. Sucrose density gradient centrifugation showed that hydrophilic, salt-soluble AChE was composed of about 85% tetramer (10.3S) and 15% monomer (3.3S). In amphiphilic, detergent-soluble AChE, 85% tetramer (9.7S), 10% dimer (5.7S), and 5% monomer (3.2S) were seen. The enzyme is N -glycosylated, and no O-linked carbohydrate could be detected. Use of two monoclonal antibodies, one directed against the catalytic subunit and the other against the hydrophobic anchor, gave new insights into the subunit assembly of brain AChE. It is shown that in tetrameric AChE, not all of the subunits are disulfide-bonded and that two populations of tetramers exist, one carrying one and the other carrying two hydrophobic anchors.