Bovine brain acetylcholinesterase primary sequence involved in intersubunit disulfide linkages

Three distinct classes of membrane-bound acetylcholinesterases (AChEs) have been identified. A12 AChE is composed of 12 catalytic subunits that are linked to noncatalytic collagen-like subunits through intersubunit disulfide bonds. G2 AChE is localized in membranes by a glycoinositol phospholipid covalently linked to the C-terminal amino acid. Brain G4 AChE involves two catalytic subunits linked by a direct intersubunit disulfide bond while the other two are disulfide-linked to a membrane-binding 20-kDa noncatalytic subunit. Molecular cloning studies have so far failed to find evidence of more than one AChE gene in any organism although alternative splicing of torpedo AChE mRNA results in different C-terminal sequences for the A12 and G2 AChE forms. Support for a single bovine AChE gene is provided in this report by amino acid sequencing of the N-terminal domains from the G2 erythrocyte, G4 fetal serum, and G4 brain AChE. Comparison of the 38-amino acid sequences reveals virtually complete identity among the three AChE forms. Additional extensive identity between the fetal serum and brain AChEs was demonstrated by sequencing several brain AChE peptides isolated by high performance liquid chromatography after trypsin digestion of nitrocellulose blots of brain AChE catalytic subunits. Cysteines involved in intersubunit disulfide linkages in brain AChE were reduced selectively with dithiothreitol in the absence of denaturants and radioalkylated with iodoacetamide. The observed sequence of the major radiolabeled tryptic peptide was C*SDL, where C* was the radioalkylated cysteine residue. This sequence is precisely the same as that observed at the C terminus of fetal bovine serum AChE and shows close homology to the C-terminal sequence of torpedo A12 AChE. We conclude that the mammalian brain G4 AChEs utilize the same exon splicing pattern as the A12 AChEs and that factors other than the primary sequence of the AChE catalytic subunits dictate assembly with either the collagen-like or the 20-kDa noncatalytic subunits.     

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.     

A four-to-one association between peptide motifs: four C-terminal domains from cholinesterase assemble with one proline-rich attachment domain (PRAD) in the secretory pathway.

The major type of acetylcholinesterase in vertebrates (AChET) is characterized by the presence of a short C-terminal domain of 40 residues, the 'tryptophan amphiphilic tetramerization' (WAT) domain. The presence of this domain is not necessary for catalytic activity but is responsible for hydrophobic interactions and for the capacity of AChET subunits to form quaternary associations with anchoring proteins, thereby conditioning their functional localization. In the collagen tail of asymmetric forms, we characterized a small conserved region that is sufficient for binding an AChET tetramer, the proline-rich attachment domain (PRAD). We show that the WAT domain alone is sufficient for association with the PRAD, and that it can attach foreign proteins (alkaline phosphatase, GFP) to a PRAD-containing construct with a glycophosphatidylinositol anchor (GPI), and thus anchor them to the cell surface. Furthermore, we show that isolated WAT domains, or proteins containing a WAT domain, can replace individual AChET subunits in PRAD-linked tetramers. This suggests that the four WAT domains interact with the PRAD in a similar manner. These quaternary interactions can form without intercatenary disulfide bonds. The common catalytic domains of AChE are not necessary for tetrameric assembly, although they may contribute to the stability of the tetramer.     

The membrane form of acetylcholinesterase from rat brain contains a 20 kDa hydrophobic anchor

Rat brain acetylcholinesterase (AChE, EC 3.1.1.7) consists of about 80% amphiphilic detergent-soluble (DS-) AChE and 20% hydrophilic salt-soluble (SS-) AChE. DS-AChE contains about 65% tetrameric, 20% dimeric and 10% monomeric, SS-AChE about 40% tetrameric and 60% monomeric forms. N-terminal sequencing of DS- and SS-AChE gave identical N-termini corresponding to the published cDNA sequence of the mature enzyme. The band pattern on SDS-gels is similar to that of AChE from human and bovine brain. SDS-PAGE of hydrophobically labeled DS-AChE revealed the presence of a disulfide bonded hydrophobic membrane anchor of about 20 kDa. Monoclonal antibodies (mAbs) recognizing the anchor-containing subunits of mammalian brain DS-AChE, crossreacted with rat brain DS-AChE but not with SS-AChE. DS- and SS-AChE also reacted with antibodies raised against a peptide comprising the last 10 amino acids of the sequence of bovine brain AChE. Our results led us to conclude that both DS- and SS-AChE from rat brain contain T-type catalytic subunits, and DS-AChE in addition a P-type hydrophobic anchor similar to other mammalian brain DS-AChE.     

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.     

The synaptic acetylcholinesterase tetramer assembles around a polyproline II helix

Functional localization of acetylcholinesterase (AChE) in vertebrate muscle and brain depends on interaction of the tryptophan amphiphilic tetramerization (WAT) sequence, at the C-terminus of its major splice variant (T), with a proline-rich attachment domain (PRAD), of the anchoring proteins, collagenous (ColQ) and proline-rich membrane anchor. The crystal structure of the WAT/PRAD complex reveals a novel supercoil structure in which four parallel WAT chains form a left-handed superhelix around an antiparallel left-handed PRAD helix resembling polyproline II. The WAT coiled coils possess a WWW motif making repetitive hydrophobic stacking and hydrogen-bond interactions with the PRAD. The WAT chains are related by an approximately 4-fold screw axis around the PRAD. Each WAT makes similar but unique interactions, consistent with an asymmetric pattern of disulfide linkages between the AChE tetramer subunits and ColQ. The P59Q mutation in ColQ, which causes congenital endplate AChE deficiency, and is located within the PRAD, disrupts crucial WAT-WAT and WAT-PRAD interactions. A model is proposed for the synaptic AChE(T) tetramer.     

Acetylcholinesterases of the nematode Steinernema carpocapsae. Characterization of two types of amphiphilic forms differing in their mode of membrane association.

We analyzed the molecular forms of acetylcholinesterase (AChE) in the nematode Steinernema carpocapsae. Two major AChEs are involved in acetylcholine hydrolysis. The first class of AChE is highly sensitive to eserine (IC50 = 0.05 microM). The corresponding molecular forms are: an amphiphilic 14S form converted into a hydrophilic 14.5S form by mild proteolysis and two hydrophilic 12S and 7S forms. Reduction of the amphiphilic 14S form with 10 mM dithiothreitol produces hydrophilic 7S and 4S forms, indicating that it is an oligomer of hydrophilic catalytic subunits linked by disulfide bond(s) to a hydrophobic structural element that confers the amphiphilicity to the complex. Sedimentation coefficients suggest that 4S, 7S, 12S forms correspond to hydrophilic monomer, dimer, tetramer and that the 14S form is also a tetramer linked to one structural element. The second class of AChE is less sensitive to eserine (IC50 = 0.1 mM). Corresponding molecular forms are hydrophilic and amphiphilic 4S forms (monomers) and a major amphiphilic 7S form converted into a hydrophilic dimer by Bacillus thuringiensis phosphatidylinositol-specific phospholipase C. This amphiphilic 7S form thus possesses a glycolipid anchor. It appears that Steinernema (a very primitive invertebrate) presents AChEs with two types of membrane association that closely resemble those described for amphiphilic G2 and G4 forms of AChE in more evolved animals.     

Tetrameric (G4) Acetylcholinesterase: Structure, Localization, and Physiological Regulation

Abstract: Acetylcholinesterase (AChE), a highly conserved enzyme in the animal kingdom, is distributed throughout a wide range of vertebrate tissues where it is expressed as multiple molecular forms comprising different arrangements of catalytic and structural subunits. The major AChE form in the CNS is an amphiphilic globular tetramer (G₄ AChE) consisting of four identical catalytic subunits attached to cellular membranes by a hydrophobic noncatalytic subunit (P-subunit). This study focuses primarily on current data involving the structure of the G₄ AChE P-subunit, the expression and regulation of G₄ AChE during development and adulthood, and its role(s) in certain neurological disorders including Alzheimer's disease.     

The C-terminal t peptide of acetylcholinesterase forms an alpha helix that supports homomeric and heteromeric interactions.

Acetylcholinesterase subunits of type T (AChET) possess an alternatively spliced C-terminal peptide (t peptide) which endows them with amphiphilic properties, the capacity to form various homo-oligomers and to associate, as a tetramer, with anchoring proteins containing a proline rich attachment domain (PRAD). The t peptide contains seven conserved aromatic residues. By spectroscopic analyses of the synthetic peptides covering part or all of the t peptide of Torpedo AChET, we show that the region containing the aromatic residues adopts an alpha helical structure, which is favored in the presence of lipids and detergent micelles: these residues therefore form a hydrophobic cluster in a sector of the helix. We also analyzed the formation of disulfide bonds between two different AChET subunits, and between AChET subunits and a PRAD-containing protein [the N-terminal fragment of the ColQ protein (QN)] possessing two cysteines upstream or downstream of the PRAD. This shows that, in the complex formed by four T subunits with QN (T4-QN), the t peptides are not folded on themselves as hairpins but instead are all oriented in the same direction, antiparallel to that of the PRAD. The formation of disulfide bonds between various pairs of cysteines, introduced by mutagenesis at various positions in the t peptides, indicates that this complex possesses a surprising flexibility.     

Stabilization of cauliflower mosaic virus P3 tetramer by covalent linkage

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein (P3) that is indispensable for viral infectivity. Although P3 has been shown to be a prerequisite for CaMV aphid transmission, its role in viral replication remains unknown. We previously showed that P3 forms a tetramer in planta and that P3 tetramer co-sediments with viral coat protein on sucrose gradient centrifugation, suggesting that a tetramer may be the functional form of P3. We presumed that disulfide bonds were involved in tetramer formation because 1) the tetramer was detected by Western blotting after electrophoresis under non-reducing conditions, and 2) the cysteine-X-cysteine motif is well conserved in CaMV P3 and P3 homologues among Caulimoviruses. Therefore we mutated either or both of the cysteine residues of CaMV P3. The mutant viruses were infectious and accumulated to a similar extent as the wild-type. An analysis of mutant proteins confirmed that the wild-type P3 molecules in the tetramer are covalently bound with one another through disulfide bonds. It was also suggested that mutant proteins are less stable than wild-type protein in planta. Furthermore, sedimentation study suggested that the disulfide bonds are involved in stable association of P3 with CaMV virions or virion-like particles, or both. The mutant viruses could be transmitted by aphids. These results suggested that the covalent bonds in P3 tetramer are dispensable for biological activity of P3 under experimental situations and may have some biological significance in natural infection in the field.     

Acetylcholinesterase from bovine caudate nucleus is attached to membranes by a novel subunit distinct from those of acetylcholinesterases in other tissues

Acetylcholinesterase extracted with Triton X-100 from bovine brain caudate nuclei was purified by affinity chromatography to apparent homogeneity. The purified enzyme was labeled with [3H]diisopropyl fluorophosphate at the active sites and with the photoactivated reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine, a compound which has been shown to be selective for the hydrophobic membrane-binding domains of several other proteins. The subunit structure was analyzed by polyacrylamide gel electrophoresis in sodium dodecyl sulfate before and after disulfide reduction. After reduction, a single 3H-labeled band at 70 kDa was stained by silver, but most of the 125I label corresponded to a 20-kDa species. Prior to reduction, five 3H-labeled and silver-stained bands were apparent at 70, 140, 160, 260, and greater than 360 kDa. These species were presumed to represent monomer and disulfide-linked oligomers of 70-kDa catalytic subunits. 125I label was selectively associated with the 160-, 260-, greater than 360-, and a 90-kDa species. Quantitative gel slicing of 3H- and 125I-labeled nonreduced enzyme supported a structural model in which the tetrameric enzyme is a dimer of nonidentical catalytic subunit dimers, one of which involves a direct intersubunit disulfide linkage between two 70-kDa catalytic subunit monomers and the second of which contains two disulfide linkages through an intervening 125I-labeled 20-kDa noncatalytic subunit. This 20-kDa subunit is proposed to contain the membrane attachment site. The brain enzyme did not contain components characteristic of the glycolipid anchors of erythrocyte acetylcholinesterases. However, part of the 125I label was associated with fatty acids, indicating that at least a portion of the brain enzyme membrane anchor is composed of nonamino acid components.     

Production of human prolyl 4-hydroxylase in Escherichia coli

Prolyl 4-hydroxylase (P4H) catalyzes the post-translational hydroxylation of proline residues in collagen strands. The enzyme is an alpha2beta2 tetramer in which the alpha subunits contain the catalytic active sites and the beta subunits (protein disulfide isomerase) maintain the alpha subunits in a soluble and active conformation. Heterologous production of the native alpha2beta2 tetramer is challenging and had not been reported previously in a prokaryotic system. Here, we describe the production of active human P4H tetramer in Escherichia coli from a single bicistronic vector. P4H production requires the relatively oxidizing cytosol of Origami B(DE3) cells. Induction of the wild-type alpha(I) cDNA in these cells leads to the production of a truncated alpha subunit (residues 235-534), which assembles with the beta subunit. This truncated P4H is an active enzyme, but has a high Km value for long substrates. Replacing the Met235 codon with one for leucine removes an alternative start codon and enables production of full-length alpha subunit and assembly of the native alpha2beta2 tetramer in E. coli cells to yield 2 mg of purified P4H per liter of culture (0.2 mg/g of cell paste). We also report a direct, automated assay of proline hydroxylation using high-performance liquid chromatography. We anticipate that these advances will facilitate structure-function analyses of P4H.     

The 35- and 36-kDa beta subunits of GTP-binding regulatory proteins are products of separate genes

The wide range of functions attributed to GTP-binding regulatory proteins (G proteins) is reflected in the structural diversity which exists among the alpha, beta, and gamma subunits of G proteins. Recently two cDNA clones encoding beta subunits, beta 1 and beta 2, were isolated from bovine and human cDNA libraries. We report here that the beta 2 gene encodes the 35-kilodalton (kDa) component of the beta 35/beta 36 subunit of G proteins and that the beta 1 gene encodes the 36-kilodalton component. The in vitro translation product of the beta 2 cDNA co-migrates with the 35-kDa beta subunit (beta 35), while the in vitro product of the beta 1 cDNA co-migrates with the 36-kDa beta subunit (beta 36) on denaturing polyacrylamide gels. In addition, antisera generated against synthetic beta 2 peptides bind specifically to the beta 35 component of isolated G proteins and to a 35-kDa protein in myeloid cell membranes. Our results suggest that the two beta subunits could serve distinct functions, as they are derived from separate genes which have been highly conserved in evolution.     

Structure of the 116-kDa polypeptide of the clathrin-coated vesicle/synaptic vesicle proton pump.

A 116-kDa polypeptide has recently been found to be a common component of vacuolar proton pumps isolated from a variety of sources. The 116-kDa subunit of the proton pump was purified from clathrin-coated vesicles of bovine brain, and internal sequences were obtained from proteolytic peptides. Oligonucleotide probes designed from these peptide sequences were utilized in polymerase chain reactions to isolate partial bovine cDNA clones for the protein. Sequences from these were then utilized to isolate rat brain cDNA clones containing the full-length coding region. RNA blots indicate the presence of an abundant 3.9-kilobase message for the 116-kDa subunit in brain, and primer extension analysis demonstrates that the cloned sequence is full-length. The rat cDNA sequences predict synthesis of a protein of 96,267 Da. Analysis of the deduced amino acid sequence of the 116-kDa subunit suggests that it consists of two fundamental domains: a hydrophilic amino-terminal half that is composed of greater than 30% charged residues, and a hydrophobic carboxyl-terminal half that contains at least six transmembrane regions. The structural properties of the 116-kDa proton pump polypeptide agree well with its proposed function in coupling ATP hydrolysis by the cytoplasmic subunits to proton translocation by the intramembranous components of the pump.     

The deduced protein sequence of the human carboxypeptidase N high molecular weight subunit reveals the presence of leucine-rich tandem repeats

Human plasma carboxypeptidase N is a 280-kDa tetramer with two high molecular mass (83-kDa) glycosylated subunits which protect the two 50-kDa catalytic subunits and keep them in the circulation. An initial clone for the 83-kDa subunit was obtained by screening two lambda gt11 human liver cDNA expression libraries with antiserum specific for carboxypeptidase N or the 83-kDa subunit. The libraries were rescreened with the labeled cloned cDNA, and the largest clone obtained (2536-base pair insert) was completely sequenced. The deduced protein sequence matched the sequence of several tryptic peptides from the 83-kDa subunit but did not contain the NH2-terminal sequence. The remaining portion of the protein coding sequence was synthesized by the polymerase chain reaction, cloned, and sequenced. The composite cDNA sequence is 2870 base pairs long with an open reading frame of 1608 base pair coding for a protein of 536 amino acids (Mr = 58,762). The protein sequence contains seven potential N-linked glycosylation sites and a threonine/serine-rich region which is a potential site for attachment of O-linked carbohydrate. The most striking feature is a region (residues 68-355) containing 12 leucine-rich tandem repeats of 24 residues with the following consensus sequence: P-X-X-alpha-F-X-X-L-X-X-L-X-X-L-X-L-X-X-N-X-L-X-X-L (X = any amino acid and alpha = aliphatic amino acids, I, L, or V). This repeating pattern is found in the leucine-rich alpha 2-glycoprotein and in other proteins where it might mediate interactions with macromolecules. This region also contains five sequences with heptad repeating leucine residues comprising a leucine zipper motif. The leucine-rich domain likely constitutes an important structural or functional element in the interactions of the 83- and 50-kDa subunits to form the active tetramer of carboxypeptidase N.     

Characterization of a tetrameric G4 form of acetylcholinesterase from bovine brain: a comparison with the dimeric G2 form of the electric organ

Globular forms (G forms) of acetylcholinesterase (AChE) are formed by monomers, dimers and tetramers of the catalytic subunits (G₁, G₂ and G₄). In this work the hydrophobic G₂ and G₄ AChE forms were purified to homogeneity from Discopyge electric organ and bovine caudate nucleus and studied from different points of view, including: velocity sedimentation, affinity to lectins and SDS-polyacrylamide gel electrophoresis under reducing and non-reducing conditions. The polypeptide composition of Discopyge electric organ G₂ is similar to Torpedo, however the pattern of the brain G₄ AChE is much complex. Under non-reducing conditions the catalytic subunit possesses a molecular weight of 65 kDa, however this value increases to 68 kDa after reduction, suggesting that intrachain-disulfide bonds are important in the folding of the catalytic subunits of the AChE. Also it was found that after mild proteolysis; the (¹²⁵I)-TID-20 kDa fragment decreased its molecular weight to approximately 10 kDa with little loss of AChE activity. Finally, we suggest a model for the organization of the different domains of the hydrophobic anchor fragment of the G₄ form.     

Determinants of the t peptide involved in folding, degradation, and secretion of acetylcholinesterase

The C-terminal 40-residue t peptide of acetylcholinesterase (AChE) forms an amphiphilic alpha helix with a cluster of seven aromatic residues. It allows oligomerization and induces a partial degradation of AChE subunits through the endoplasmic reticulum-associated degradation pathway. We show that the t peptide induces the misfolding of a fraction of AChE subunits, even when mutations disorganized the cluster of aromatic residues or when these residues were replaced by leucines, indicating that this effect is due to hydrophobic residues. Mutations in the aromatic-rich region affected the cellular fate of AChE in a similar manner, with or without mutations that prevented dimerization. Degradation was decreased and secretion was increased when aromatic residues were replaced by leucines, and the opposite occurred when the amphiphilic alpha helix was disorganized. The last two residues (Asp-Leu) somewhat resembled an endoplasmic reticulum retention signal and caused a partial retention but only in mutants possessing aromatic residues in their t peptide. Our results suggested that several "signals" in the catalytic domain and in the t peptide act cooperatively for AChE quality control.     

The thioredoxin system of Penicillium chrysogenum and its possible role in penicillin biosynthesis.

Penicillium chrysogenum is an important producer of penicillin antibiotics. A key step in their biosynthesis is the oxidative cyclization of delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine (ACV) to isopenicillin N by the enzyme isopenicillin N synthase (IPNS). bis-ACV, the oxidized disulfide form of ACV is, however, not a substrate for IPNS. We report here the characterization of a broad-range disulfide reductase from P. chrysogenum that efficiently reduces bis-ACV to the thiol monomer. When coupled in vitro with IPNS, it converts bis-ACV to isopenicillin N and may therefore play a role in penicillin biosynthesis. The disulfide reductase consists of two protein components, a 72-kDa NADPH-dependent reductase, containing two identical subunits, and a 12-kDa general disulfide reductant. The latter reduces disulfide bonds in low-molecular-weight compounds and in proteins. The genes coding for the reductase system were cloned and sequenced. Both possess introns. A comparative analysis of their predicted amino acid sequences showed that the 12-kDa protein shares 26 to 60% sequence identity with thioredoxins and that the 36-kDa protein subunit shares 44 to 49% sequence identity with the two known bacterial thioredoxin reductases. In addition, the P. chrysogenum NADPH-dependent reductase is able to accept thioredoxin as a substrate. These results establish that the P. chrysogenum broad-range disulfide reductase is a member of the thioredoxin family of oxidoreductases. This is the first example of the cloning of a eucaryotic thioredoxin reductase gene.     

Latent high molecular weight complex of transforming growth factor beta 1. Purification from human platelets and structural characterization

Human transforming growth factor beta 1 (TGF-beta 1) was purified as a latent high Mr complex from human platelets by a six-step procedure. Analysis by sodium dodecyl sulfate (SDS)-gel electrophoresis under reducing conditions revealed that the complex was composed of at least three components with apparent Mr values of 13,000, 40,000, and 125,000-160,000. The 13-kDa subunit was part of a disulfide-bonded dimer and was identified by amino acid sequencing as TGF-beta 1. The 40-kDa subunit was identified as the amino-terminal part of the TGF-beta 1 precursor lacking the hydrophobic signal sequence. Partial sequencing of the 125-160-kDa protein revealed that it is distinct from known proteins. The 40-kDa and the 125-160-kDa subunits are linked by disulfide bonds, forming a complex with an apparent Mr of 210,000 on SDS gels under nonreducing conditions. Experiments with partial reduction revealed that each complex contains two 40-kDa components linked by disulfide bonds; in addition, the dimer is disulfide-linked to one 125-160-kDa binding protein. TGF-beta 1 binds noncovalently to the 210-kDa complex, and in bound form, TGF-beta 1 is inactive. Incubations of the latent form of TGF-beta 1 at extreme pH values, in 0.02% SDS or in 8 M urea, lead to activation of TGF-beta 1, whereas the complex was resistant to treatment with 5 M NaCl or heat (3 min at 95 degrees C).     

Molecular properties of acetylcholinesterase in mouse spleen

The presence of acetylcholinesterase (AChE) mRNA and activity in the tissues and cells involved in immune responses prompted us to investigate the level and pattern of AChE components in spleen. AChE activity was higher in mouse spleen (0.46 +/- 0.13 micromol of acetylthiocholine split per hour and per mg protein) than in muscle or heart, but lower than in brain. The spleen was essentially free of butyrylcholinesterase (BuChE) activity. About 40% of spleen AChE was extracted with a saline buffer, and a further 40% with 1% Triton X-100. Sedimentation analyses, the splitting of subunits in AChE dimers, phosphatidylinositol-specific phospholipase C (PIPLC) exposure, and phenyl-agarose chromatography showed that hydrophilic (G1H, 43%) and amphiphilic AChE monomers (G1A, 36%), as well as amphiphilic dimers (G2A, 21%), occurred in spleen. All these molecules bound to fasciculin-2-Sepharose, although the extent of binding was higher for G1H (77%) than for G1A (63%) or G2A (48%) forms. Differences in the extent to which wheat germ lectin (WGA) adsorbed with AChE of mouse spleen and of erythrocyte allowed us to discard the blood origin of spleen AChE activity. A 62 kDa protein was labeled in spleen samples using antibodies against human AChE. The protein was attributed to AChE monomers since its size was the same, regardless of whether disulfide bonds were reduced or not. Since cholinergic stimulation modulates proliferation/maturation of lymphoid cells, AChE may be important for regulating the level of acetylcholine (ACh) in the neighborhood of cholinergic receptors (AChR) in spleen and other lymphoid tissues.