Synaptic proteins and the assembly of synaptic junctions.

Synapses are highly specialized contact sites between neurons and their target cells where information in the form of chemical substances travels from a pre- to a postsynaptic cell. In the central nervous system of mammals, most nerve cells are innervated by functionally distinct types of synapses, each requiring a specific set of molecular constituents for proper function. Various molecular players that may be involved in the assembly of synaptic junctions have been identified recently.

PDZ domains in synapse assembly and signalling.

Synaptic junctions are highly specialized structures designed to promote the rapid and efficient transmission of signals from the presynaptic terminal to the postsynaptic membrane within the central nervous system. Proteins containing PDZ domains play a fundamental organizational role at both the pre- and postsynaptic plasma membranes. This review focuses on recent advances in our understanding of the mechanisms underlying the assembly of synapses in the central nervous system.

Different forms of microtubule-associated protein 2 are encoded by separate mRNA transcripts.

Brain microtubule-associated protein 2 (MAP2) consists of a pair of high molecular mass (280 kD) polypeptides, MAP2a and MAP2b, and a recently identified 70-kD protein, MAP2c, which is antigenically related to these high molecular mass MAP2's. Using cDNA clones we have analyzed the expression of these three proteins at the nucleic acid level. cDNA probes selective for the high molecular mass MAP2's a and b identified only a 9-kb mRNA, whereas a probe for sequence common to all three MAP2 isoforms, a, b, and c, recognized the 9-kb transcript and additionally a 6-kb mRNA. Southern blot analysis with cDNA probes indicated that there is only one MAP2 gene from which these two distinct mRNAs are derived. The 70-kD MAP2c protein is much more abundant in neurons of developing brain than those of adult tissues. Similarly the expression of the 6-kb MAP2c-related mRNA, is much greater in neonatal than adult rat brain, indicating that the developmental expression of MAP2 is determined by transcriptional regulation from a single MAP2 gene.

Bassoon, a novel zinc-finger CAG/glutamine-repeat protein selectively localized at the active zone of presynaptic nerve terminals.

The molecular architecture of the cytomatrix of presynaptic nerve terminals is poorly understood. Here we show that Bassoon, a novel protein of >400,000 Mr, is a new component of the presynaptic cytoskeleton. The murine bassoon gene maps to chromosome 9F. A comparison with the corresponding rat cDNA identified 10 exons within its protein-coding region. The Bassoon protein is predicted to contain two double-zinc fingers, several coiled-coil domains, and a stretch of polyglutamines (24 and 11 residues in rat and mouse, respectively). In some human proteins, e.g., Huntingtin, abnormal amplification of such poly-glutamine regions causes late-onset neurodegeneration. Bassoon is highly enriched in synaptic protein preparations. In cultured hippocampal neurons, Bassoon colocalizes with the synaptic vesicle protein synaptophysin and Piccolo, a presynaptic cytomatrix component. At the ultrastructural level, Bassoon is detected in axon terminals of hippocampal neurons where it is highly concentrated in the vicinity of the active zone. Immunogold labeling of synaptosomes revealed that Bassoon is associated with material interspersed between clear synaptic vesicles, and biochemical studies suggest a tight association with cytoskeletal structures. These data indicate that Bassoon is a strong candidate to be involved in cytomatrix organization at the site of neurotransmitter release.

Unwebbing the presynaptic web.

The release of neurotransmitter from nerve terminals occurs at a specialized region of the presynaptic plasma membrane called the active zone. A dense matrix of proteins associated with the active zone, called the presynaptic web, is thought to play a fundamental role in defining these neurotransmitter release sites. In this issue of Neuron, Phillips et al. have identified conditions for the biochemical purification of the presynaptic web and show that the web is comprised of proteins involved in the docking, fusion, and recycling of synaptic vesicles.

In situ localization of microtubule-associated protein mRNA in the developing and adult rat brain.

We have used cDNA probes specific for three of the major brain microtubule-associated proteins (MAPs), MAP1, MAP2, and MAP5, to study the timing of appearance, relative abundance, and intracellular compartmentalization of MAP gene transcripts in developing rat brain. The MAP1 probe hybridizes throughout the brain, in both grey and white matter. MAP2 mRNA is detected only in grey matter and appears in cerebral neurons only after they have ceased dividing and have migrated to the cortical plate. The MAP5 cDNA hybridizes throughout the embryonic brain, but by P12, MAP5 mRNA distribution is restricted to relatively immature areas. MAP2 mRNA, found in dendrites in the developing brain, persists in some adult dendrites. MAP5 mRNA, like beta-tubulin mRNA, is found only in the cell bodies of developing neurons, indicating that the protein must be transported from the soma into processes. MAP1 mRNA is found only in the proximal regions of cortical pyramidal cell dendrites in both developing and adult brain. The diverse distributions of MAP gene transcripts emphasize the importance of these proteins in generating heterogeneity of microtubule function and indicate that MAP compartmentalization within neurons is regulated in part by differential mRNA transport.

Assembly of new individual excitatory synapses: time course and temporal order of synaptic molecule recruitment.

Time-lapse microscopy, retrospective immunohistochemistry, and cultured hippocampal neurons were used to determine the time frame of individual glutamatergic synapse assembly and the temporal order in which specific molecules accumulate at new synaptic junctions. New presynaptic boutons capable of activity-evoked vesicle recycling were observed to form within 30 min of initial axodendritic contact. Clusters of the presynaptic active zone protein Bassoon were present in all new boutons. Conversely, clusters of the postsynaptic molecule SAP90/PSD-95 and glutamate receptors were found on average only approximately 45 min after such boutons were first detected. AMPA- and NMDA-type glutamate receptors displayed similar clustering kinetics. These findings suggest that glutamatergic synapse assembly can occur within 1-2 hr after initial contact and that presynaptic differentiation may precede postsynaptic differentiation.

Assembling the presynaptic active zone: a characterization of an active one precursor vesicle.

The active zone is a specialized region of the presynaptic plasma membrane where synaptic vesicles dock and fuse. In this study, we have investigated the cellular mechanism underlying the transport and recruitment of the active zone protein Piccolo into nascent synapses. Our results show that Piccolo is transported to nascent synapses on an approximately 80 nm dense core granulated vesicle together with other constituents of the active zone, including Bassoon, Syntaxin, SNAP-25, and N-cadherin, as well as chromogranin B. Components of synaptic vesicles, such as VAMP 2/synaptobrevin II, synaptophysin, synaptotagmin, or proteins of the perisynaptic plasma membrane such as GABA transporter 1 (GAT1), were not present. These studies demonstrate that the presynaptic active zone is formed in part by the fusion of an active zone precursor vesicle with the presynaptic plasma membrane.

Synaptic clustering of the cell adhesion molecule fasciclin II by discs-large and its role in the regulation of presynaptic structure.

The cell adhesion molecule Fasciclin II (FASII) is involved in synapse development and plasticity. Here we provide genetic and biochemical evidence that proper localization of FASII at type I glutamatergic synapses of the Drosophila neuromuscular junction is mediated by binding between the intracellular tSXV bearing C-terminal tail of FASII and the PDZ1-2 domains of Discs-Large (DLG). Moreover, mutations in fasII and/or dlg have similar effects on presynaptic ultrastructure, suggesting their functional involvement in a common developmental pathway. DLG can directly mediate a biochemical complex and a macroscopic cluster of FASII and Shaker K+ channels in heterologous cells. These results indicate a central role for DLG in the structural organization and downstream signaling mechanisms of cell adhesion molecules and ion channels at synapses.

SAP102, a novel postsynaptic protein that interacts with NMDA receptor complexes in vivo.

Synapse-associated proteins (SAPs) are constituents of the pre- and postsynaptic submembraneous cytomatrix. Here, we present SAP102, a novel 102kDa SAP detected in dendritic shafts and spines of asymmetric type 1 synapses. SAP102 is enriched in preparations of synaptic junctions, where it biochemically behaves as a component of the cortical cytoskeleton. Antibodies directed against NMDA receptors coimmunoprecipitate SAP102 from rat brain synaptosomes. Recombinant proteins containing the carboxy-terminal tail of NMDA receptor subunit NR2B interact with SAP102 from rat brain homogenates. All three PDZ domains in SAP102 bind the cytoplasmic tail of NR2B in vitro. These data represent direct evidence that in vivo SAP102 is involved in linking NMDA receptors to the submembraneous cytomatrix associated with postsynaptic densities at excitatory synapses.

Piccolo, a presynaptic zinc finger protein structurally related to bassoon.

Piccolo is a novel component of the presynaptic cytoskeletal matrix (PCM) assembled at the active zone of neurotransmitter release. Analysis of its primary structure reveals that Piccolo is a multidomain zinc finger protein structurally related to Bassoon, another PCM protein. Both proteins were found to be shared components of glutamatergic and GABAergic CNS synapses but not of the cholinergic neuromuscular junction. The Piccolo zinc fingers were found to interact with the dual prenylated rab3A and VAMP2/Synaptobrevin II receptor PRA1. We show that PRA1 is a synaptic vesicle-associated protein that is colocalized with Piccolo in nerve terminals of hippocampal primary neurons. These data suggest that Piccolo plays a role in the trafficking of synaptic vesicles (SVs) at the active zone.

SAP90 binds and clusters kainate receptors causing incomplete desensitization.

The mechanism of kainate receptor targeting and clustering is still unresolved. Here, we demonstrate that members of the SAP90/PSD-95 family colocalize and associate with kainate receptors. SAP90 and SAP102 coimmunoprecipitate with both KA2 and GluR6, but only SAP97 coimmunoprecipitates with GluR6. Similar to NMDA receptors, GluR6 clustering is mediated by the interaction of its C-terminal amino acid sequence, ETMA, with the PDZ1 domain of SAP90. In contrast, the KA2 C-terminal region binds to, and is clustered by, the SH3 and GK domains of SAP90. Finally, we show that SAP90 coexpressed with GluR6 or GluR6/KA2 receptors alters receptor function by reducing desensitization. These studies suggest that the organization and electrophysiological properties of synaptic kainate receptors are modified by association with members of the SAP90/PSD-95 family.

Juvenile and mature MAP2 isoforms induce distinct patterns of process outgrowth.

Microtubule-associated protein-2 (MAP2) is the most abundant MAP in neurons, where its distribution is restricted to the somatodendritic compartment. This molecule undergoes developmentally regulated alternative splicing, resulting in at least two isoforms, a juvenile isoform (termed MAP2c) and a mature isoform (MAP2), with greatly different molecular masses. Spodoptera frugiperda (Sf9) cell expression of the juvenile versus the mature MAP2 isoform generates two distinct patterns of process outgrowth. The smaller juvenile isoform induces multiple short thin processes. Mature MAP2 tends to induce single processes that are considerably thicker than those processes induced by juvenile MAP2. We found important differences in the variability of spacing between microtubules and the number of microtubules along the processes induced by MAP2c and mature MAP2. MAP2c showed variability with most microtubules spaced as closely as with tau, but some spaced as far apart as with mature MAP2. Over their length, the mature MAP2 processes demonstrate proximo-distal taper, which corresponds to a narrowing of the spacing between microtubules from 90 nm to 40 nm. Moreover, there is a decreased number of microtubules in mature MAP2-induced processes whereas in tau and MAP2-induced processes, the number of microtubules is constant along the length. Based on these observations, we conclude that MAP2 isoforms can serve as architectural elements by establishing specific morphological features of processes and specific arrangements of their microtubules.

Molecular characterization of microtubule-associated proteins tau and MAP2.

Tau and MAP2 are two of the major microtubule-associated proteins in the vertebrate nervous system. They promote microtubule assembly and stability, and might be involved in the establishment and maintenance of neuronal polarity. In nerve cells immunohistochemistry shows complementary distributions, with tau being concentrated in axons and high molecular mass MAP2 being confined to dendrites. Each protein consists of multiple isoforms that contain three or four homologous tandem repeats near the carboxy-terminus, which constitute microtubule-binding domains. In humans, tau consists of at least six isoforms of related amino acid sequences that are produced from a single gene by alternative mRNA splicing and that are expressed in a stage- and cell type-specific manner. Tau is also a component of the paired helical filaments associated with Alzheimer's disease and other disorders of the CNS. Rat MAP2 consists of at least three isoforms produced from a single gene: high molecular mass MAP2a and MAP2b, and low molecular mass MAP2c. MAP2c is expressed only during early development and has so far been seen only in axons; MAP2a appears to replace MAP2c, whereas MAP2b is expressed throughout life. Messenger RNAs for MAP2 of high molecular mass are expressed both in cell bodies and in dendrites, consistent with the dendritic localization of the corresponding protein isoforms.

Principles of glutamatergic synapse formation: seeing the forest for the trees.

General principles regarding glutamatergic synapse formation in the central nervous system are beginning to emerge. These principles concern the specific roles that dendrites and axons play in the induction of synaptic differentiation, the modes of presynaptic and postsynaptic assembly, the time course of synapse formation and maturation, and the roles of synaptic activity in these processes.

Molecular determinants of presynaptic active zones.

The presynaptic cytoskeletal matrix (cytomatrix) assembled at active zones has been implicated in defining neurotransmitter release sites. Munc13, Rim, Bassoon and Piccolo/Aczonin are recently identified presynaptic cytomatrix proteins. These multidomain proteins are thought to organize the exocytotic and endocytotic machinery precisely at active zones.

Subcellular redistribution of the synapse-associated proteins PSD-95 and SAP97 in animal models of Parkinson's disease and L-DOPA-induced dyskinesia.

Abnormalities in subcellular localization and interaction between receptors and their signaling molecules occur within the striatum in Parkinson's disease (PD) and L-DOPA-induced dyskinesia (LID). Synapse-associated proteins (SAPs), for example, PSD-95 and SAP97 organize the molecular architecture of synapses and regulate interactions between receptors and downstream-signaling molecules. Here, we show that expression and subcellular distribution of PSD-95 and SAP97 are altered in the striatum of unilateral 6-OHDA-lesioned rats following repeated vehicle (a model of PD) or L-DOPA administration (a model of L-DOPA-induced dyskinesia). Furthermore, following dopamine-depletion and development of behavioral deficits in Rotorod performance, indicative of parkinsonism, we observed a dramatic decrease in total striatal levels of PSD-95 and SAP97 (to 25.6 +/- 9.9% and 19.0 +/- 5.0% of control, respectively). The remaining proteins were redistributed from the synapse into vesicular compartments. L-DOPA (6.5mg/kg twice a day, 21 days) induced a rotational response, which became markedly enhanced with repeated treatment (day 1: -15.8+/-7.3 rotations cf day 21: 758.2+/-114.0 rotations). Post L-DOPA treatment, PSD-95 and SAP97 levels increased (367.4 +/- 43.2% and 159.9 +/- 9.5% from control values, respectively), with both being redistributed toward synaptic membranes from vesicular compartments. In situ hybridization showed that changes in total levels of PSD-95, but not SAP97, were accompanied by qualitatively similar changes in mRNA. These data highlight the potential role of abnormalities in the subcellular distribution of SAPs in the pathophysiology of a neurological disease.

Identification of a cis-acting dendritic targeting element in MAP2 mRNAs.

In neurons, a limited number of mRNAs have been identified in dendritic processes, whereas other transcripts are restricted to the cell soma. Here we have investigated the molecular mechanisms underlying extrasomatic localization of mRNAs encoding microtubule-associated protein 2 (MAP2) in primary neuronal cultures. Vectors expressing recombinant mRNAs were introduced into hippocampal and sympathetic neurons using DNA transfection and microinjection protocols, respectively. Chimeric mRNAs containing the entire 3' untranslated region of MAP2 transcripts fused to a nondendritic reporter mRNA are detected in dendrites. In contrast, RNAs containing MAP2 coding and 5' untranslated regions or tubulin sequences are restricted to the cell soma. Moreover, 640 nucleotides from the MAP2 3' untranslated region (UTR) are both sufficient and essential for extrasomatic localization of chimeric mRNAs in hippocampal and sympathetic neurons. Thus, a cis-acting dendritic targeting element that is effective in two distinct neuronal cell types is contained in the 3' UTR of MAP2 transcripts. The observation of RNA granules in dendrites implies that extrasomatic transcripts seem to assemble into multimolecular complexes that may function as transport units.

Functional expression of rat synapse-associated proteins SAP97 and SAP102 in Drosophila dlg-1 mutants: effects on tumor suppression and synaptic bouton structure.

The synapse-associated proteins SAP97 and SAP102 are mammalian proteins that are structurally related to the Drosophila tumor suppressor protein DlgA. Previous analyses revealed that DlgA is essential for the integrity of epithelia and neuromuscular synapses. Here we show that synaptic bouton structure is severely affected in mutant larvae carrying the dlg-1(XI-2) allele. We have tested SAP97 and SAP102 for functional homology to DlgA by heterologous expression in Drosophila. Both SAP97 and SAP102 can suppress tumor formation in dlg-1 mutant flies and mimic DlgA at larval neuromuscular junctions. Neuronal expression of SAP97 or SAP102 is required for morphological restoration of synaptic boutons, indicating that presynaptic DlgA function is essential for establishing structurally intact motor nerve terminals at larval neuromuscular junctions.

Piccolo, a novel 420 kDa protein associated with the presynaptic cytomatrix.

In this study, we describe a novel 420 kDa protein, called Piccolo, found at a wide variety of adult rat brain synapses. High protein levels in the cerebellum, the olfactory bulb and the hippocampus were frequently observed to be associated with asymmetric type 1 synapses. Piccolo is selectively enriched in presynaptic terminals, but is not a component of synaptic vesicles (SVs). Immunogold electron microscopy revealed that Piccolo localizes to the amorphous material among SVs at the presynaptic plasma membrane. Biochemical studies showed that it is very tightly bound to this structure. Thus, we speculate that Piccolo is a structural component of the presynaptic cytomatrix which anchors SVs to the presynaptic plasmalemma.