Synapsin I: A regulated synaptic vesicle organizing protein

Synapsin is a protein initially discovered and characterized as a target for cyclic AMP and Ca/calmodulin-regulated protein kinases that is concentrated in nerve endings and is localized on the surface of small synaptic vesicles. Synapsin shares antigenic sites and some local regions of homology with erythrocyte protein 4.1, although these proteins in general are quite different in sequence. Protein 4.1 and synapsin share several local regions of homology with erythrocyte spectrin alpha subunit. Protein 4.1 and synapsin may be related to each other through a common relationship with spectrin. Synapsin binds to synaptic vesicles and membrane sites with a Kd of 0.01-0.02 microM and associates with a Kd of 0.5-4 microM to spectrin, microtubules and neurofilaments in in vitro assays. Synapsin interconnects synaptic vesicles to membranes, and this activity is inhibited by phosphorylation with Ca/calmodulin-dependent protein kinase. Synapsin may have a role in neurons as a structural protein capable of interconnecting small synaptic vesicles with a number of proteins, including spectrin, microtubules, neurofilaments, and membrane sites. A physiological function of synapsin could be as a vesicle-organizing protein that mediates calcium-regulated association of vesicles with cytoskeletal proteins during axonal transport and attaches vesicles to active zones in nerve endings.     

The effect of synapsin I phosphorylation upon binding of synaptic vesicles to spectrin.

We have previously demonstrated that brain spectrin is attached to small spherical synaptic vesicles via synapsin I. These studies utilized a novel microfiltration assay in which 125I-labelled synaptic vesicles were incubated with brain spectrin which was covalently attached to cellulosic membranes. In these studies purified dephosphosynapsin I was demonstrated to competitively inhibit the binding of the synaptic vesicles to the immobilized brain spectrin with a KI = 45 nM. In the current study we demonstrate that phosphorylation of synapsin I site 1 (0.74 mol Pi/mol synapsin I) with cAMP-dependent protein kinase and sites 2 and 3 (2.0 mol Pi/mol synapsin I) with Ca(2+)-calmodulin kinase II had little effect upon its interaction with brain spectrin. cAMP-dependent protein kinase phosphorylated synapsin I and Ca(2+)-calmodulin kinase II phosphorylated synapsin I both inhibited the binding of 125I-labelled synaptic vesicles to immobilized brain spectrin with a KI of 23 nM and 24 nM respectively. We conclude that phosphorylation of synapsin I does not down-regulate the interaction of synaptic vesicles with brain spectrin.     

The domain of brain beta-spectrin responsible for synaptic vesicle association is essential for synaptic transmission

We have examined the interaction between synapsin I, the major phosphoprotein on the membrane of small synaptic vesicles, and brain spectrin. Using recombinant peptides we have localized the synapsin I attachment site upon the beta-spectrin isoform betaSpIISigmaI to a region of 25 amino acids, residues 211 through 235. This segment is adjacent to the actin binding domain and is within the region of the betaSpIISigmaI that we previously predicted as a candidate synapsin I binding domain based upon sequence homology. We used differential centrifugation techniques to quantitatively assess the interaction of spectrin with synaptic vesicles. Using this assay, high affinity saturable binding of recombinant betaSpIISigmaI proteins was observed with synaptic vesicles. Binding was only observed when the 25 amino acid synapsin I binding site was included on the recombinant peptides. Further, we demonstrate that antibodies directed against 15 amino acids of the synapsin I binding domain specifically blocked synaptic transmission in cultured hippocampal neurons. Thus, the synapsin I attachment site on betaSpIISigmaI spectrin comprises a approximately 25 amino acid segment of the molecule and interaction of these two proteins is an essential step for the process of neurotransmission.     

The domain of brain β-spectrin responsible for synaptic vesicle association is essential for synaptic transmission

We have examined the interaction between synapsin I, the major phosphoprotein on the membrane of small synaptic vesicles, and brain spectrin. Using recombinant peptides we have localized the synapsin I attachment site upon the β-spectrin isoform βSpIIΣI to a region of 25 amino acids, residues 211 through 235. This segment is adjacent to the actin binding domain and is within the region of the βSpIIΣI that we previously predicted as a candidate synapsin I binding domain based upon sequence homology. We used differential centrifugation techniques to quantitatively assess the interaction of spectrin with synaptic vesicles. Using this assay, high affinity saturable binding of recombinant βSpIIΣI proteins was observed with synaptic vesicles. Binding was only observed when the 25 amino acid synapsin I binding site was included on the recombinant peptides. Further, we demonstrate that antibodies directed against 15 amino acids of the synapsin I binding domain specifically blocked synaptic transmission in cultured hippocampal neurons. Thus, the synapsin I attachment site on βSpIIΣI spectrin comprises a 25 amino acid segment of the molecule and interaction of these two proteins is an essential step for the process of neurotransmission.     

Spectrin (betaSpIIsigma1) is an essential component of synaptic transmission

The cellular mechanism that underlies the regulated release of synaptic vesicles during neurotransmission is not fully known. Our previous data has shown that brain spectrin (alphaSpIIsigma1/betaSpIIsigma1)2 is localized in axons and nerve terminals and we have shown that the beta subunit (betaSpIIsigma1) contains a synapsin-binding domain capable of interacting with synapsin and small synaptic vesicles in vitro and in vivo. These findings suggested a role for brain beta-spectrin in synaptic neurotransmission. To examine this possibility further, peptide-specific antibodies directed against epitopes within the synapsin-binding domain of brain beta-spectrin, or against flanking regions, were injected into the presynaptic neuron of synaptically paired rat hippocampal neurons in culture. Here, we show that the antibodies directed against the synapsin-binding domain specifically blocked synaptic neurotransmission.     

Axonal transport of synapsin I-like proteins in rabbit retinal ganglion cells

Synapsin I is a neuronal phosphoprotein that is associated with the cytoplasmic surface of small, clear synaptic vesicles in neuronal synaptic terminals; it may play an important role in synaptic transmission. In vitro, it can interact with fodrin, a relative of the erythrocyte protein spectrin. We have investigated the delivery of synapsin I from its site of synthesis in neuronal cell bodies to synaptic terminals by means of the process of axonal transport. We labeled the newly synthesized proteins of rabbit retinal ganglion cells by injecting 35S-methionine into the vitreous humour, and subsequently observed the appearance of radioactive synapsin I (identified by its 2-dimensional electrophoretic mobility) in tissues containing the axons and synaptic terminals of these neurons. A portion of the newly synthesized synapsin I was axonally transported at the velocity of the most rapidly transported (group I) proteins, which comprise membrane-associated proteins and may include elements of synaptic vesicles. However, the subsequent time course of labeling of synapsin I in the axons suggests that greater than 90% of the axonally transported synapsin I may comprise 2 additional populations--one transported rapidly, the other slowly--that are released from the cell bodies only after a delay of more than 1 d. The delayed, slowly transported population moves at the velocity (approximately 6 mm/d) of groups III and IV (which include fodrin and other proteins of the membrane cytoskeleton). We consider whether such distinct populations may correspond to functionally specialized variants of synapsin I-like proteins that may be transported in association with different organelles. The electrophoretic mobility of labeled synapsin I-like proteins in the axons changed subtly with time. Additional subtle differences between labeled synapsin I-like proteins in the axons and the terminal-containing tissues suggest that certain posttranslational modifications occur specifically in the terminals.     

Spectrin (βSpIIΣ1) is an essential component of synaptic transmission

The cellular mechanism that underlies the regulated release of synaptic vesicles during neurotransmission is not fully known. Our previous data has shown that brain spectrin (αSpIIΣ1/βSpIIΣ1)₂ is localized in axons and nerve terminals and we have shown that the β subunit (βSpIIΣ1) contains a synapsin-binding domain capable of interacting with synapsin and small synaptic vesicles in vitro and in vivo. These findings suggested a role for brain β-spectrin in synaptic neurotransmission. To examine this possibility further, peptide-specific antibodies directed against epitopes within the synapsin-binding domain of brain β-spectrin, or against flanking regions, were injected into the presynaptic neuron of synaptically paired rat hippocampal neurons in culture. Here, we show that the antibodies directed against the synapsin-binding domain specifically blocked synaptic neurotransmission.     

Brain spectrin: Of mice and men

This article reviews our current knowledge of the structure of α spectrins and β spectrins in the brain, as well as their location and expression within neural tissue. We discuss the known protein interactions of brain spectrin isoforms, and then describe results that suggest an important role for spectrin (αSpIIΣ1/βSpIIΣ1) in the Ca²⁺-regulated release of neurotransmitters. Evidence that supports a role for spectrin in the docking of synaptic vesicles to the presynaptic plasma membrane and as a Ca²⁺ sensor protein that uanclamps the fusion machinery is desaibed, along with the Casting the Line model, which summarizes the information. We finish with a discussion of the value of spectrin and ankyrin-deficient mouse models in deciphering spectrin function in neural tissue.     

Spectrin subtypes in mammalian brain: an immunoelectron microscopic study

Spectrin is a major cytoskeletal component of the brain. At least 2 distinct spectrin subtypes are found in mammalian brain: brain spectrin(240/235) and brain spectrin(240/235E). In the present study spectrin subtypes were localized in the adult mouse brain by immunoelectron microscopy using antibodies that recognize each subtype. Brain spectrin(240/235E) was concentrated in neuronal cell bodies, dendrites, and postsynaptic terminals. It was also prominently associated with the plasma membrane, microtubules, filaments, mitochondria, endoplasmic reticulum, and nuclear envelope, and it appeared to interconnect structural elements within the cell. Brain spectrin(240/235E) also was localized to the plasma membrane, nuclear envelope, and cytoplasmic organelles of glial cell bodies. Brain spectrin(240/235) was detected in axons and presynaptic elements, where it was associated with the plasma membrane, microtubules, filaments, synaptic vesicles, and mitochondria. These results show that spectrin is distributed throughout the cytoplasm of neural cells, the location of spectrin is dependent on subtype, and the cytoplasmic surface of plasma membrane and organelles contains an extensive and intricate spectrin meshwork.     

A novel function of synapsin II in neurotransmitter release

Although synapsin has been localized to presynaptic structures, its function remains poorly understood. In the present study, we investigated the presynaptic function of synapsin II using a synaptic vesicle recycling process using synapsin-II-overexpressing NG108-15 cells. Western blot analysis with antibodies for synaptic-vesicle-associated protein indicated that the number of synaptic vesicles was approximately doubled in synapsin II transfectants as reported previously. In differentiated synapsin-II-overexpressing and control cells, the application of high potassium induced strong intracellular calcium elevation along neurites and varicosities after differentiation and a weak calcium rise in the cell bodies. The uptake and release of the fluorescent dye FM1-43 revealed that synaptic vesicle recycling in synapsin-II-transfected cells occurred with the same kinetics in the cell body and neuritic varicosities. Furthermore, the area labeled with FM1-43 fluorescence in the synapsin-II-transfected cells was approximately twice as much as in control cells after stimulation, and ATP released after synaptic vesicle fusion with the plasma membrane in synapsin-II-expressing cells was significantly elevated relative to controls. The number of synaptic vesicles paralleled the amount of transmitter released from the cells leading to the conclusion that the number of releasable synaptic vesicles were increased by synapsin II transfection into NG108-15 cells, suggesting that synapsin II may have a role in the regulation of synaptic vesicle number in presynapse-like structures in NG108-15 cells.     

Glucose/oxygen deprivation induces the alteration of synapsin I and phosphosynapsin

Synapsin I is believed to be involved in regulating neurotransmitter release and in synapse formation. Its interactions with the actin filaments and synaptic vesicles are regulated by phosphorylation. Because exocytosis and synapsin I phosphorylation are a Ca(2+)-dependent process, it is possible that an ischemic insult modifies the presynaptic proteins. However, the neuronal damage and the changes in synapsin I as well as its phosphorylation level as a result of glucose/oxygen deprivation (GOD) and reperfusion in organotypic hippocampal slice cultures have not been established. In this study, the level of synapsin I and phosphosynapsin was measured in organotypic hippocampal slice cultures in order to determine the role of synapsin I in the presynaptic nerve terminals during GOD/reperfusion. Propidium iodide fluorescence was observed in the CA1 area after GOD for 30 min, which could be detected in the whole pyramidal cell layer during reperfusion for 24 h. The immunofluorescence of the neuron specific nuclear protein, NeuN, showed a negative correlation with the PI fluorescence. During GOD/reperfusion, the immunofluorescence of synapsin I increased in the stratum radiatum and the stratum oriens of the CA1 area and the stratum lucidum and the stratum oriens of the CA3 area. The phosphosynapsin level evidently increased in the stratum lucidum of the CA3 area after GOD for 30 min, which was reduced to the control level after reperfusion. These results suggested that the neuronal damage and degenerations were observed as a result of GOD/reperfusion and the increase in synapsin I and its phosphorylation might play a role in modulating the release of neurotransmitters via exocytosis and in the formation of new synapses after brain ischemia.     

Synaptic protein expression by regenerating adult photoreceptors.

Regeneration of functionally normal synapses is required for functional recovery after degenerative central nervous system insults and requires proper expression and targeting of presynaptic proteins by regenerating neurons. The reconstitution of presynaptic terminals by regenerating adult neurons is poorly understood, however. We examined the intrinsic ability of regenerating adult retinal photoreceptors to reconstitute properly differentiated presynaptic terminals in the absence of target contact. The expression and localization of vesicle-associated membrane protein (VAMP), synaptic vesicle protein 2 (SV2), synaptophysin, synapsin I, and synaptosomal-associated protein of 25 kDa (SNAP-25) was assessed immunocytochemically. Photoreceptor terminals in the intact retina contain VAMP, SV2, synaptophysin, and SNAP-25, but not synapsin I. Isolated, regenerating adult photoreceptors intrinsically expressed the proper complement of synaptic vesicle proteins in the absence of target contact: VAMP, SV2, and synaptophysin were present at all stages of regenerative growth; synapsin I was never expressed. At early stages of regenerative growth, VAMP, SV2, and synaptophysin were diffusely localized in the cell, with prominent VAMP labeling distributed along the plasma membrane. SV2 and synaptophysin rapidly localized to regenerated terminals, but VAMP accumulated much more slowly, indicating that these proteins are trafficked independently. In contrast, labeling for SNAP-25, which is associated with the presynaptic plasma membrane, was undetectable in regenerating photoreceptors, suggesting that SNAP-25 expression is target-regulated. Thus, regenerating photoreceptors can intrinsically regulate the expression of the proper set of synaptic vesicle proteins. Proper expression of other presynaptic proteins, such as SNAP-25, and proper subcellular localization of synaptic proteins such as VAMP, however, may require extrinsic cues such as target contact.     

Brain spectrin(240/235A): a novel astrocyte specific spectrin isoform

We have previously demonstrated the existence of two distinct isoforms of spectrin in mammalian brain (23). Brain spectrin(240/235) is found primarily in neuronal axons and presynaptic terminals, and brain spectrin(240/235E) is located in neuronal cell bodies, dendrites and postsynaptic terminals, and oligodendrocytes. These isoforms are thought to play important roles in controlling the early events of synaptic transmission, axonal transport of organelles and vesicles, and lateral mobility of integral membrane proteins. In this study, we have utilized a panel of monoclonal antibodies to identify a novel astrocyte specific isoform(240/235A) with subunits of 240 kDa and 235 kDa in a 1:1 ratio. Double label indirect immunofluorescence has indicated that brain spectrin (240/235A) is distinct from brain spectrin (240/235E). This novel isoform located in the soma and processes of astrocytes may play a role in actin-membrane attachment, cellular architecture, strengthening of the membrane fabric, and translocation of cytoplasmic organelles and vesicles.     

Synapsin selectively controls the mobility of resting pool vesicles at hippocampal terminals

Presynaptic terminals are specialized sites for information transmission where vesicles fuse with the plasma membrane and are locally recycled. Recent work has extended this classical view, with the observation that a subset of functional vesicles is dynamically shared between adjacent terminals by lateral axonal transport. Conceptually, such transport would be expected to disrupt vesicle retention around the active zone, yet terminals are characterized by a high-density vesicle cluster, suggesting that counteracting stabilizing mechanisms must operate against this tendency. The synapsins are a family of proteins that associate with synaptic vesicles and determine vesicle numbers at the terminal, but their specific function remains controversial. Here, using multiple quantitative fluorescence-based approaches and electron microscopy, we show that synapsin is instrumental for resisting vesicle dispersion and serves as a regulatory element for controlling lateral vesicle sharing between synapses. Deleting synapsin disrupts the organization of presynaptic vesicle clusters, making their boundaries hard to define. Concurrently, the fraction of vesicles amenable to transport is increased, and more vesicles are translocated to the axon. Importantly, in neurons from synapsin knock-out mice the resting and recycling pools are equally mobile. Synapsin, when present, specifically restricts the mobility of resting pool vesicles without affecting the division of vesicles between these pools. Specific expression of synapsin IIa, the sole isoform affecting synaptic depression, rescues the knock-out phenotype. Together, our results show that synapsin is pivotal for maintaining synaptic vesicle cluster integrity and that it contributes to the regulated sharing of vesicles between terminals.     

A rapid purification of synapsin I: a neuron specific spectrin binding protein

We have developed a one chromatographic step isolation protocol for the neuron specific protein synapsin I. This procedure results in a yield of 80 micrograms/g brain, which is ten fold better than the highest yield yet reported for this protein. The authenticity of the synapsin I isolated by this procedure is demonstrated by comigration with authentic synapsin I on SDS-polyacrylamide gels, crossreactivity with antibody specific against synapsin I, and nearly identical two dimensional chrymotryptic iodopeptide maps of authentic synapsin I and the protein purified by this protocol. Synapsin I isolated by this procedure retains its functional properties, demonstrated by the ability of synapsin I to stimulate the formation of a brain spectrin(240/235)/synapsin I/F-actin ternary complex as determined by a low shear falling ball viscometry assay. This novel protocol therefore has the advantage of being a rapid, high yield procedure that retains the functional properties of synapsin I.     

Accelerated Structural Maturation Induced by Synapsin I at Developing Neuromuscular Synapses of Xenopus laevis

The role of synapsin I, a synaptic vesicle-associated phosphoprotein, in the maturation of nerve–muscle synapses was investigated in nerve–muscle co-cultures prepared from Xenopus embryos loaded with the protein by the early blastomere injection method. The stage of maturation of the synapses was analysed by electron microscopy as well as by whole-cell patch-clamp recording. The acceleration in the functional maturation of neuromuscular synapses induced by synapsin I was accompanied by a profound rearrangement in the ultrastructure of the nerve terminal. Nerve terminals formed by synapsin I-loaded neurons were characterized by a higher number of small synaptic vesicles organized in clusters and predominantly localized close to the nerve terminal plasma membrane, a smaller number of large dense-core vesicles and no significant change in the number of coated vesicles. Precocious development of active zone-like structures as well as deposition of basal lamina into the synaptic cleft were also observed at these synapses. These results support a role for synapsin I in the architectural changes which occur during synaptogenesis and lead to the maturation of quantal neurotransmitter release mechanisms.     

The morphological localization and biochemical characterization of a synapsin I-like antigen in the nervous system of Aplysia californica.

Synapsins are a well-characterized class of phosphoproteins found at synapses in the mammalian nervous system. One member of this family, synapsin I, has been extensively studied and shown to associate in a phosphorylation-dependent manner with both small synaptic vesicles and cytoskeletal elements. Though the characteristics of synapsin I suggest an important function in synaptic transmission, its definitive role is still in question. In an effort to find a model system in which to test directly the function of synapsin I, we have looked in the nervous system of the marine mollusc Aplysia californica for synapsin I-like antigens (SILA). Light microscope immunocytochemical studies using polyclonal and monoclonal antibodies to bovine brain synapsin I demonstrate Aplysia SILA in neuronal somata, in the neuropil, and at some identified synapses. Though SILA were exclusively associated with neuronal structures in Aplysia, the pattern of staining suggested that they are not present at all synaptic terminals. This interpretation was corroborated by ultrastructural studies in which SILA were present at some synaptic terminals but absent, or in low abundance, in adjacent terminals. In axons, SILA were associated with vesicles of 120-150 nm diameter, as well as with filamentous structures. Biochemical studies identified small amounts of SILA of 40 and 50 kD molecular weight that are recognized by several antibodies to mammalian synapsin I, and are acid extractable, collagenase-sensitive phosphoproteins; these are criteria used to define synapsin I homologues in other species. Our studies indicate that SILA are present in neurons in Aplysia californica but suggested that they represent only a small percentage of the total protein within the nervous system.     

Phosphorylation-dependent inhibition by synapsin I of organelle movement in squid axoplasm

Synapsin I, a neuron-specific, synaptic vesicle-associated phosphoprotein, is thought to play an important role in synaptic vesicle function. Recent microinjection studies have shown that synapsin I inhibits neurotransmitter release at the squid giant synapse and that the inhibitory effect is abolished by phosphorylation of the synapsin I molecule (Llinas et al., 1985). We have considered the possibility that synapsin I might modulate release by regulating the ability of synaptic vesicles to move to, or fuse with, the plasma membrane. Since it is not yet possible to examine these mechanisms in the intact nerve terminal, we have used video-enhanced microscopy to study synaptic vesicle mobility in axoplasm extruded from the squid giant axon. We report here that the dephosphorylated form of synapsin I inhibits organelle movement along microtubules within the interior of extruded axoplasm and that phosphorylation of synapsin I on sites 2 and 3 by calcium/calmodulin-dependent protein kinase II removes this inhibitory effect. Phosphorylation of synapsin I on site 1 by the catalytic subunit of cAMP-dependent protein kinase only partially reduces the inhibitory effect. In contrast to the inhibition of movement along microtubules seen within the interior of the axoplasm, movement along isolated microtubules protruding from the edges of the axoplasm is unaffected by dephospho-synapsin I, despite the fact that the synapsin I concentration is higher there. Thus, synapsin I does not appear to inhibit the fast axonal transport mechanism itself. Rather, these results are consistent with the possibility that dephospho-synapsin I acts by a crosslinking mechanism involving some component(s) of the cytoskeleton, such as F-actin, to create a dense network that restricts organelle movement. The relevance of the present observations to regulation of neurotransmitter release is discussed.     

Translocations of fodrin and its binding proteins

Fodrin, a protein related to erythrocyte spectrin, redistributes within the cell in certain situations. We compare such movements of fodrin and several fodrin binding proteins during the processes of axonal transport in neurons, and capping of surface proteins in lymphocytes. In neurons, three different populations of newly synthesized fodrin appear to be transported down the axons at different velocities corresponding to those of groups of transported proteins designated II, IV, and V. Actin, which can interact with fodrin, is transported at the velocity of group IV. Synapsin, a component of synaptic vesicles, is also reported to bind to fodrin. One population of synapsin is transported more rapidly than fodrin, at the velocity of group I: two additional populations of transported synapsin may overlap fodrin in groups II and IV. We consider possible functional associations of these different populations of fodrin and fodrin binding proteins. We note that the transport of group IV proteins resembles in certain respects the process of capping in lymphocytes, suggesting the possibility of a common mechanism. We outline one of several possible mechanisms.     

Axonal transport kinetics and posttranslational modification of synapsin I in mouse retinal ganglion cells.

Synapsin I is a neuron-specific phosphoprotein primarily localized at the presynaptic terminals, where it is thought to play an important role in the mechanisms involved in neurotransmitter release. Its interaction with cytoskeletal proteins and with small synaptic vesicles is regulated in vitro by phosphorylation by a calcium/calmodulin-dependent kinase. Here, we present the first evidence that, in the mouse retinal ganglion cells, synapsin I, moving along the axon with the slow component of axonal transport, is phosphorylated in vivo at both the head and tail regions. In addition, our data suggest that, after synapsin I has reached the nerve endings, the relative proportion of differently phosphorylated molecules of synapsin I changes, and that these changes lead to a decrease of the overall content of phosphorus. The more basic forms, here collectively referred to as beta-forms, become predominant at the terminals after 7 d postlabeling, when the bulk of transported synapsin I has entered the superior colliculus. Along the axon, phosphorylation could be functional in preventing synapsin I from forming, with actin, a dense meshwork that would restrict organelle movement. On the other hand, at the terminals, the dephosphorylation-phosphorylation of synapsin I may regulate the clustering of small synaptic vesicles and modulate neurotransmitter release by controlling the availability of small synaptic vesicles for exocytosis.