An antiserum specific for cholinergic synaptic vesicles from electric organ.

Rabbit antisera to highly purified synaptic vesicles from the electric organ of Narcine brasiliensis, an electric ray, reveal a unique population of synaptic vesicle antigens in addition to a population shared with other electric organ membranes. Synaptic vesicle antigens were detected by binding successively rabbit antivesicle serum and radioactive goat anti-rabbit serum. To remove antibodies directed against antigens common to synaptic vesicles and other electric organ fractions, the antivesicle serum was extensively preadsorbed against an electric organ membrane fraction that was essentially free of synaptic vesicles. The adsorbed serum retained 40% of its ability to bind to synaptic vesicles, suggesting that about half of the antigenic determinants are unique. Vesicle antigens were quantified with a radioimmunoassay (RIA) that utilized precipitation of antibody-antigen complexes with Staphylococcus aureus cells. By this assay, the vesicles, detected by their acetylcholine (ACh) content and the antigens detected by the RIA, have the same buoyant density after isopycnic centrifugation of crude membrane fractions on sucrose and glycerol density gradients. The ratio of ACh to antigenicity was constant across the vesicle peaks and was close to that observed for vesicles purified to homogeneity. Even though the vesicles make up only approximately 0.5% of the material in the original homogenate, the ratio of acetylcholine to vesicle antigenicity could still be measured and also was indistinguishable from that of pure vesicles. We conclude that synaptic vesicles contain unique antigenic determinants not present to any measurable extent in other fractions of the electric organ. Consequently, it is possible to raise a synaptic vesicle-specific antiserum that allows vesicles to be detected and quantified. These findings are consistent with earlier immunohistochemical observations of specific antibody binding to motor nerve terminals.

A nerve terminal anchorage protein from electric organ.

The nerve terminal and the postsynaptic receptor-containing membranes of the electric organ are both linked to the basal lamina that runs between them. We have identified an extracellular matrix protein whose physical properties suggest it anchors the nerve terminal to the basal lamina. The protein was identified because it shares an epitope with a proteoglycan component of electric organ synaptic vesicles. It too behaves like a proteoglycan. It is solubilized with difficulty from extracellular matrix fractions, elutes from DEAE Sephacel at pH 4.9 only at high ionic strength, and binds to a laminin affinity column from which it can be eluted with heparin. Under denaturing conditions it sediments rapidly and has a large excluded volume although it can be included in Sephacryl S-1000 columns. This large, highly charged extracellular matrix molecule can be readily reconstituted into liposomes consistent with the presence of a hydrophobic tail. By immunoelectron microscopy the antigen is found both in synaptic vesicles and on the plasma membrane of the nerve terminal. Since this is the first protein described that links the nerve terminal membrane to the extracellular matrix, we propose calling it terminal anchorage protein one (TAP-1).

Nerve terminal anchorage protein 1 (TAP-1) is a chondroitin sulfate proteoglycan: biochemical and electron microscopic characterization.

The plasma membranes of the nerve terminal and the postsynaptic cell of electric organ are separated by a basal lamina. We have purified, biochemically characterized, and visualized in the electron microscope a macromolecule which appears to anchor the nerve terminal to this basal lamina. This molecule, terminal anchorage protein 1 (TAP-1) is associated with the nerve terminal membrane of electric organ, has the properties of an integral membrane protein, and is tightly bound to the extracellular matrix (Carlson, S.S., P. Caroni, and R.B. Kelly. 1986. J. Cell Biol. 103:509-520). TAP-1 can be solubilized from an electric organ extracellular matrix preparation with guanidine-HCl/3-[(3-cholamidopropyl)-dimethylammnio]-1-propane sulfonate and purified by a combination of permeation chromatography on Sephacryl S-1000, sedimentation velocity, and ion exchange chromatography on DEAE Sephacel. The total purification from electric organ is 91-fold and results in at least 86% purity. Digestion of the molecule with chondroitin ABC or AC lyase produces a large but similar shift in the molecular weight of the molecule on SDS-PAGE. The presence of chondroitin-4- or 6-sulfate is confirmed by identification of the isolated glycosaminoglycans with cellulose acetate electrophoresis. Gel filtration of the isolated chains indicates an average molecular weight of 42,000. Digestion of TAP-1 with other glycosaminoglycan lyases such as heparitinase indicates that only chondroitin sulfate is present. These results demonstrate that TAP-1 is a proteoglycan. Visualization of TAP-1 in the electron microscope reveals a "bottlebrush" structure expected for a proteoglycan. The molecule has an average total length of 345 +/- 17 nm with 20 +/- 2 side projections of 113 +/- 5 nm in length. These side projections are presumably the glycosaminoglycan side chains. From this structure, we predict that the TAP-1 glycosaminoglycan side chains should have a molecular weight of approximately 50,000, which is in close agreement with the biochemical studies. Both biochemical and morphologic data indicate that TAP-1 has a relative molecular weight of approximately 1.2 X 10(6). The large size of TAP-1 suggests that this molecule could span the synaptic cleft and make a significant contribution to the structure of the nerve terminal basal lamina of electric organ.

Antibodies to synaptic vesicles purified from Narcine electric organ bind a subclass of mammalian nerve terminals.

Antibodies were raised in rabbits to synaptic vesicles purified to homogeneity from the electric organ of Narcine brasiliensis, a marine electric ray. These antibodies were shown by indirect immunofluorescence techniques to bind a wide variety of nerve terminals in the mammalian nervous system, both peripheral and central. The shared antigenic determinants are found in cholinergic terminals, including the neuromuscular junction, sympathetic ganglionic and parasympathetic postganglionic terminals, and in those synaptic areas of the hippocampus and cerebellum that stain with acetylcholinesterase. They are also found in some noncholinergic regions, including adrenergic sympathetic postganglionic terminals, the peptidergic terminals in the posterior pituitary, and adrenal chromaffin cells. They are, however, not found in many noncholinergic synapse-rich regions. Such regions include the molecular layer of the cerebellum and those laminae of the dentate gyrus that receive hippocampal associational and commissural input. We conclude that one or more of the relatively small number of antigenic determinants in pure electric fish synaptic vesicles have been conserved during evolution, and are found in some but not all nerve terminals of the mammalian nervous system. The pattern of antibody binding in the central nervous system suggests unexpected biochemical similarities between nerve terminals heretofore regarded as unrelated.

The presynaptic calcium channel is part of a transmembrane complex linking a synaptic laminin (alpha4beta2gamma1) with non-erythroid spectrin.

Nerve regeneration studies at the neuromuscular junction (NMJ) suggest that synaptic basal lamina components tell the returning axon where to locate neurotransmitter release machinery, including synaptic vesicle clusters and active zones. Good candidates for these components are the synaptic laminins (LNs) containing alpha4, alpha5, or beta2 chains. Results from a beta2 laminin knockout mouse have suggested a linkage of this extracellular laminin to cytosolic synaptic vesicle clusters. Here we report such a transmembrane link at the electric organ synapse, which is homologous to the NMJ. We immunopurified electric organ synaptosomes and found on their surface two laminins of 740 and 900 kDa. The 740 kDa laminin has a composition of alpha4beta2gamma1 (laminin-9). Immunostaining reveals that as in the NMJ, alpha4 and beta2 chains are concentrated at the electric organ synapse. Using detergent-solubilized synaptosomes, we immunoprecipitated a complex containing alpha4beta2gamma1 laminin, the voltage-gated calcium channel, and the cytoskeletal protein spectrin. Other presynaptic proteins such as 900 kDa laminin are not found in this complex. We hypothesize that alpha4beta2gamma1 laminin in the synaptic basal lamina attaches to calcium channel, which in turn is attached to cytosolic spectrin. Spectrin could then organize synaptic vesicle clusters by binding vesicle-associated proteins.

Proteoglycans are present in the transverse tubule system of skeletal muscle.

The transverse tubule system (T-tubule, T-system) of skeletal muscle is a membranous network that penetrates the interior of myofibers. The T-system is continuous with the sarcolemma and therefore provides a path for membrane excitation to reach internal myofibrils. In this study we demonstrate that T-tubules in elasmobranch fish, frog, and rat skeletal muscle contain a matrix of chondroitin sulfate proteoglycans. We used anti-T1, a mouse monoclonal antibody that recognizes a rare chondroitin sulfate epitope, for immunolocalization and biochemical studies. First, we find that T1 immunoreactivity colocalizes with a T-tubule marker, the dihydropyridine receptor alpha 2 subunit, in both frog and fish muscle. Secondly, the distribution of T1 immunoreactivity exactly matches the different distribution of T-tubules in rat and frog muscle. In rat muscle, two bands of T1 immunoreactivity are detected per sarcomere, a distribution that corresponds to the T-tubules located at the two A-I junctions of each sarcomere. In frog muscle, we detect one band of T1 immunoreactivity per sarcomere that corresponds to the one T-tubule per sarcomere located at the Z line. Lastly, we have isolated and biochemically characterized T1 antigenicity from fish skeletal muscle. Like extracellular matrix proteoglycans of cartilage, T1 antigenicity requires denaturing conditions to be solubilized. In fish muscle, two chondroitin sulfate proteoglycans bear T1: a heavily glycosylated proteoglycan with a molecular mass of about 1000 kDa, and a smaller proteoglycan that has a mobility on SDS-PAGE like a protein of molecular mass 280 kDa. We propose that proteoglycans function as structural components in the T-system. The proteoglycans may form a matrix, like the one formed by the cartilage proteoglycans they resemble, that can withstand the cytosolic osmotic pressures present in muscle cells and therefore may prevent the T-tubule from collapsing. We present a quantitative argument in support of this hypothesis.

A chondroitin sulfate/keratan sulfate proteoglycan, PG-1000, forms complexes which are concentrated in the reticular laminae of electric organ basement membranes.

Previously, we identified PG-1000 as part of a disulfide-linked complex of two large proteoglycans (PG-1000 and the beta component) and three smaller proteins purified from the extracellular matrix of elasmobranch electric organ (Iwata and Carlson, 1991, J. Biol. Chem. 266: 323-333). PG-1000 is a chondroitin sulfate/keratan sulfate proteoglycan with a molecular mass of about 1.2 x 16(6) daltons. When visualized in the electron microscope, PG-1000 has the typical "bottle-brush" appearance expected for a proteoglycan with an average total length of about 345 nm and about 20 chains of approximately 110 nm (Carlson and Wight, 1987, J. Cell Biol. 105: 3075-3086). Using immunocytochemical methods, we now demonstrate that PG-1000 is a component of the interstitial extracellular matrix of the electric organ. PG-1000 immunoreactivity is found throughout the interstitial matrix, but it is highly concentrated in that region of the matrix immediately adjacent to the basal lamina, the reticular lamina. The reticular and basal laminae together form the basement membrane. PG-1000 immunoreactivity is especially apparent on basal laminae that surround nerve fibers and nerve terminals. When the disulfide-linked PG-1000 complexes are purified and examined in the electron microscope following rotary shadowing, they appear as bottle-brush structures which are often attached at a central region and radiate like spokes of a wheel. These aggregates contain two to six proteoglycan monomers. We hypothesize that the PG-1000 complexes are disulfide-stabilized parts of an extended network of linked proteoglycans in the reticular lamina.

Localization and axonal transport of immunoreactive cholinergic organelles in rat motor neurons--an immunofluorescent study.

Antisera produced in rabbits against pure fractions of cholinergic vesicles from Narcine brasiliensis were used to study cholinergic organelles in rat motor neurons. The indirect immunofluorescence method was used on perfusion-fixed material. The rats were surgically sympathectomized to remove sympathetic adrenergic and cholinergic nerves from the sciatic nerve. In the intact animal immunoreactive material, likely to represent cholinergic vesicles, was observed in motor endplates, identified by labelling with rhodamine-conjugated alpha-bungarotoxin or with subsequent acetylcholinesterase staining. The motor perikarya contained very little immunoreactive material. Non-terminal axons were virtually devoid of immunofluorescence in the intact animal. After crushing the sciatic nerve, immunoreactive material (likely to represent axonal cholinergic organelles) accumulated rapidly on both sides of the crush, indicating a rapid bidirectional transport. The transport was sensitive to local application of mitotic inhibitors. The axons which accumulated immunoreactive organelles were motor axons, as demonstrated by various procedures: Cutting of ventral roots prevented accumulation of immunoreactive material in the nerve. Deafferentation did not notably influence accumulations of immunoreactive material. Ligated axons with immunoreactive material were acetylcholinesterase positive when identification was made on the same section; the intra-axonal distribution of immunoreactive material and acetylcholinesterase was not identical, however, and the Narcine antisera did not cross-react with bovine acetylcholinesterase in a solid phase immunoassay. Most axons in ventral roots, but not in dorsal roots, accumulated strongly fluorescent immunoreactive material, while axons in dorsal roots contained weakly fluorescent material. On the other hand, substance P-like immune reactivity was present in many dorsal root axons, but only very rarely in ventral roots. It is suggested that the antisera against Narcine cholinergic vesicles can be used as a marker for cholinergic organelles in the motor neuron, and may be an important tool for studying the axonal cholinergic vesicles. It cannot, however, be used to identify cholinergic structures in unknown locations because it recognizes common antigenic determinants in transmitter organelles of other nerves, e.g. adrenergic nerves. The axonal cholinergic organelles may carry important molecules, other than acetylcholine to the nerve endings.

SV2proteoglycan: a potential synaptic vesicle transporter and nerve terminal extracellular matrix receptor.

SV2Proteoglycan (SV2pg) is a specific component of small clear synaptic vesicles. It is a keratan sulfate proteoglycan with oligosaccharide side chains N-linked to a core protein of 80 kDa. Two glycosylated forms, H and L, are present in synaptic vesicles. The amino acid sequence suggests that SV2pg contains 12 transmembrane domains and is homologous to bacterial and eukaryotic sugar transporters. Although its structure suggests that SV2pg is a vesicular transporter, what it transports is unknown. SV2pg is probably not a neurotransmitter transporter, since that function resides in an unrelated family of synaptic vesicle proteins. In addition to its vesicular function, SV2pg may have a secondary function as an extracellular matrix (ECM) receptor on the nerve terminal surface. At the electric organ synapse, which is closely related to the neuromuscular junction. SV2pg is bound to laminin, a component of the synaptic ECM. SV2pg is only associated with laminin on the nerve terminal surface, not in the synaptic vesicle. Studies on synaptogenesis during motor nerve regeneration have suggested that nerve terminal ECM receptors play an important role in synaptic recognition.

A highly antigenic proteoglycan-like component of cholinergic synaptic vesicles.

A monoclonal antibody, tor70, recognizes an antigenic determinant on the inside surface of synaptic vesicles, purified from the electric organ of Narcine brasiliensis. The antigenic determinant appears to be unique to vesicles since it co-purifies with vesicle content and is blocked by an antiserum specific for synaptic vesicle antigens. Immunoblotting of vesicle proteins after sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that the antigen has a low heterogeneous electrophoretic mobility and corresponds to a major protein component of pure synaptic vesicles. Synaptic vesicles contain a proteoglycan-like material since proteolytic digestion yields a ruthenium red-binding material that migrates during electrophoresis with a mammalian heparin standard. The only major vesicle component with which the proteoglycan-like material co-elutes during chromatography on Sepharose 6B is the material recognized by tor70. The antigen adsorbs specifically to beads coated with the lectin wheat germ agglutinin. Isolation of the tor70 antigen by velocity sedimentation in sodium dodecyl sulfate-sucrose gradients shows it to contain glucosamine (0.75 nmol/microgram of protein) and uronic acid but no galactosamine. Earlier work has shown that specific antiserum to pure synaptic vesicles could be used to identify nerve terminals, quantitate vesicle components, purify membranes, and monitor exocytosis. We now know that one of the components recognized by the antiserum is a molecule with properties of a proteoglycan, attached to the inside surface of vesicle membranes.

Neurexin is expressed on nerves, but not at nerve terminals, in the electric organ.

Neurexins are highly variable transmembrane proteins hypothesized to be nerve terminal-specific cell adhesion molecules. As a test of the hypothesis that neurexin is restricted to the nerve terminal, we examined neurexins in the electric organ of the elasmobranch electric fish. Specific antibodies generated against the intracellular domain of electric fish neurexin were used in immunocytochemical and Western blot analyses of the electromotor neurons that innervate the electric organ. Our results indicate that neurexin is not expressed at electric organ nerve terminals, as expected by the neurexin hypothesis. Instead, neurexin is expressed by electromotor neurons and on myelinated axons. This neurexin has a molecular weight of 140 kDa, consistent with an alpha-neurexin. In addition, we find that perineurial cells of the electromotor nerve also express a neurexin. These cells surround bundles of axons to form a diffusion barrier and are thought to be a special form of fibroblast. The results of the study argue against a universal role for neurexins as nerve terminal-specific proteins but suggest that neurexins are involved in axon-Schwann cell and perineurial cell interactions.

A large chondroitin sulfate basement membrane-associated proteoglycan exists as a disulfide-stabilized complex of several proteins.

Proteoglycan (PG)-1000 (formerly TAP-1) is a large (Mr = 10(6)) highly glycosylated chondroitin sulfate proteoglycan found associated with Schwann cell and electrocyte basement membranes in elasmobranch electric fish. Previously, purified PG-1000 was visualized in the electron microscope as a "bottlebrush" structure about 345 nm long with about 20 side projections of 113 nm. This molecule was characterized with material purified from electric organ under denaturing and reducing conditions. Here we report that PG-1000, when purified under denaturing conditions without exposure to a reducing agent, exists as a complex of several proteins. In addition to PG-1000, this complex consists of a somewhat smaller, heavily glycosylated protein (beta component) and three smaller proteins with Mr values of 39,000, 21,000, and 18,000. The complex remains intact when exposed to denaturing and non-reducing conditions but falls apart in denaturing and reducing conditions. Presumably the complex is stabilized by disulfide bonds. The beta component of the PG-1000 complex is probably a proteoglycan. However, unlike PG-1000, the beta component does not contain chondroitin sulfate chains and lacks the epitope, T1, that is found on PG-1000. Both molecules share a protease-insensitive antigenic site, SV4, which is probably a modified keratan sulfate epitope. Evidence for the identity of this antigen is that it is found as a minor subfraction in commercial preparations of shark cartilage chondroitin and corneal keratan sulfates but not in other glycosaminoglycan preparations. These SV4 antigens are resistant to chondroitin ABC lyase digestion. However, the SV4 antigen in commercial keratan sulfate is cleaved by keratinase to a smaller antigenic fragment.

Maternal expectations and attitudes toward toilet training: a comparison between clinic mothers and private practice mothers.

Mothers at inner city clinics differ from middle-class suburban mothers with private pediatricians in their attitudes and expectations regarding toilet training, such as the ideal age to initiate bladder and bowel training, ideal age for completion of toilet training, response to the child who soils after a program of toilet training has been initiated, and source of information to guide in toilet training. Possible explanations to account for these differences are explored; the implications for training health personnel are discussed.

A large chondroitin sulfate proteoglycan has the characteristics of a general extracellular matrix component of adult brain.

Extracellular matrix (ECM) is a secreted extracellular network. Few components of adult brain ECM are known. We have identified a new, large chondroitin sulfate proteoglycan (T1 antigen) that acts like a general ECM protein of brain. First, it is present throughout the brain; second, it has the properties of an extracellular protein; and third, it is extracted only under denaturing conditions. Immunocytochemical localization of the T1 antigen by light microscope shows it to be present throughout the rat brain in both white and gray matter. The T1 antigen outlines Purkinje and other large cells. No antigenicity is seen inside these cells. Biochemical evidence suggests that the T1 antigen is extracellular rather than cytosolic or intravesicular. The T1 antigen is disulfide-linked to two other proteins. Disulfide bonds are found only in extracellular or intravesicular proteins, not in intracellular cytosolic proteins. Moreover, the T1 antigen is probably not intravesicular. Unlike intravesicular proteins, only a small amount of T1 antigen is solubilized by nondenaturing detergents. While nondenaturing detergents extract but a small amount of T1 antigen from rat brain, the majority is solubilized by denaturing conditions (6 M guanidine-HCl). This behavior is similar to that of ECM components in other tissues and is unlike that of membrane proteins, even those linked to the cytoskeleton. We hypothesize that the insolubility of the T1 antigen in brain is due to its presence in an extracellular aggregate. The T1 antigen is a proteoglycan with a highly glycosylated protein core of 300 kDa. It does not appear to be related to the large, heavily glycosylated chondroitin sulfate proteoglycans aggrecan and versican, which were discovered in non-neural tissues. Antibodies to a 15 residue peptide present in both aggrecan and versican do not react with the T1 antigen.

A brain extracellular matrix proteoglycan forms aggregates with hyaluronan.

Unlike many tissues, the adult central nervous system extracellular matrix (ECM) has few known components. Previously, we characterized a large chondroitin sulfate proteoglycan, pgT1, from adult rat brain which has the properties of a general brain ECM component and is immunologically distinct from aggrecan and versican (Iwata, M., and Carlson, S.S. (1993) J. Neurosci. 13, 195-207). In this study we demonstrate that pgT1 binds hyaluronan with relatively high affinity. The pgT1 preparation isolated from rat brain aggregates in non-denaturing conditions. This aggregation is abolished by incubation of pgT1 with Streptomyces hyaluronidase. Examination of these aggregates by electron microscope reveals a structure in which an average of 18 subunits arise laterally from opposite sides of an elongated 350-nm filament. These pgT1 aggregates resemble the proteoglycan aggregates in cartilage which are composed of aggrecan and hyaluronan. Using affinity coelectrophoresis, we measure a dissociation constant (Kd) of 0.9 +/- 0.2 nM for the interaction of pgT1 and hyaluronan. These new findings, combined with the general distribution of pgT1 in brain, suggest that pgT1/hyaluronan aggregates are an extended general structure of the brain extracellular matrix network.

Purification of synaptic vesicles from elasmobranch electric organ and the use of biophysical criteria to demonstrate purity.

We have purified cholinergic synaptic vesicles from the electric organs of two related marine elasmobranchs, Torpedo californica and Narcine brasiliensis, to a specific activity higher than had previously been obtained. We have demonstrated the homogeneity of the vesicles by biophysical criteria. The purification scheme consisted of differential centrifugation, flotation equilibrium in sucrose density gradients, and permeation chromatography on glass bead columns of average pore size 3000 A. Our criteria for purity were that bound acetylcholine, bound nucleotide triphosphate, protein, and lipid--phosphorus behave identically when vesicles were analyzed by procedures which depend on vesicle size, density, and charge. Contaminants were not detected when vesicles were fractionated by preparative and analytical sedimentation, by preparative equilibrium sedimentation using glycerol density gradients, or by electrophoresis in Ficoll density gradients. Pure synaptic vesicles, which have been purified 290-fold from the initial homogenate, contain per mg of protein: 8 mumol of acetylcholine, 3 mumol of ATP, and 7 mumol of lipid phosphorus. These procedures may be of general value in the purification of membrane vesicles.

The SV2 protein of synaptic vesicles is a keratan sulfate proteoglycan.

We have determined that synaptic vesicles contain a vesicle-specific keratan sulfate integral membrane proteoglycan. This is a major proteoglycan in electric organ synaptic vesicles. It exists in two forms on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, i.e., the L form, which migrates like a protein with an M(r) of 100,000, and the H form, with a lower mobility that migrates with an M(r) of approximately 250,000. Both forms contain SV2, an epitope located on the cytoplasmic side of the vesicle membrane. In addition to electric organ, we have analyzed the SV2 proteoglycan in vesicle fractions from two other sources, electric fish brain and rat brain. Both the H and L forms of SV2 are present in these vesicles and all are keratan sulfate proteoglycans. Unlike previously studied synaptic vesicle proteins, this proteoglycan contains a marker specific for a single group of neurons. This marker is an antigenically unique keratan sulfate side chain that is specific for the cells innervating the electric organ; it is not found on the synaptic vesicle keratan sulfate proteoglycan in other neurons of the electric fish brain.

Identification in immunolocalization of a new class of proteoglycan (keratan sulfate) to the neuritic plaques of Alzheimer's disease.

Previous studies have demonstrated three distinct classes of proteoglycans (PGs)/glycosaminoglycans (GAGs) localized to the characteristic lesions (i.e., neuritic plaques, cerebrovascular amyloid deposits, and neurofibrillary tangles) of Alzheimer's disease (AD). These include heparan sulfate (i.e., perlecan), dermatan sulfate (i.e., decorin), and chondroitin sulfate PGs/GAGs. In the present study, two different antibodies demonstrated the presence of a new class of PG (i.e., keratan sulfate) in the neuritic plaques of AD. Asynaptic vesicle keratan sulfate PG (known as SV2PG) was detected by the monoclonal antibodies, anti-SV2 and anti-SV4, which recognize the keratan sulfate core protein and GAG chains, of the SV2PG antigen, respectively. Both antibodies immunolocalized SV2PG primarily to synapses and to dystrophic neurites within neuritic plaques of AD and normal aged brain. The SV2PG was not immunolocalized to diffuse plaques, cerebrovascular amyloid deposits, or neurofibrillary tangles in AD or normal aged brain. SV2PG immunoreactivity in AD brain was similar in distribution to synaptophysin and showed apparent reduced immunoreactiviy+in AD cortex in comparison to age-matched controls. In conjunction with previous studies, these results now suggest that within the neuritic plaques of AD, there are at least four different classes of PGs present. Although heparan sulfate PGs are still the only class of PG immunolocalized to amyloid fibrils within the neuritic plaques of AD, the specific immunolocalization of keratan sulfate, dermatan sulfate, and chondroitin sulfate containing PGs to the periphery of plaques, suggests that these particular PGs/GAGs may also play distinct and important roles in neuritic plaque pathogenesis.

Presynaptic neurones may contribute a unique glycoprotein to the extracellular matrix at the synapse.

As the extracellular matrix at the original site of a neuromuscular junction seems to play a major part in the specificity of synaptic regeneration, considerable attention has been paid to unique molecules localized to this region. Here we describe an extracellular matrix glycoprotein of the elasmobranch electric organ that is localized near the nerve endings. By immunological criteria, it is synthesized in the cell bodies, transported down the axons and is related to a glycoprotein in the synaptic vesicles of the neurones that innervate the electric organ. It is apparently specific for these neurones, as it cannot be detected elsewhere in the nervous system of the fish. Therefore, neurones seem to contribute unique extracellular matrix glycoproteins to the synaptic region. Synaptic vesicles could be involved in transporting these glycoproteins to or from the nerve terminal surface.