Reduced SNAP-25 increases PSD-95 mobility and impairs spine morphogenesis.

Impairment of synaptic function can lead to neuropsychiatric disorders collectively referred to as synaptopathies. The SNARE protein SNAP-25 is implicated in several brain pathologies and, indeed, brain areas of psychiatric patients often display reduced SNAP-25 expression. It has been recently found that acute downregulation of SNAP-25 in brain slices impairs long-term potentiation; however, the processes through which this occurs are still poorly defined. We show that in vivo acute downregulation of SNAP-25 in CA1 hippocampal region affects spine number. Consistently, hippocampal neurons from SNAP-25 heterozygous mice show reduced densities of dendritic spines and defective PSD-95 dynamics. Finally, we show that, in brain, SNAP-25 is part of a molecular complex including PSD-95 and p140Cap, with p140Cap being capable to bind to both SNAP-25 and PSD-95. These data demonstrate an unexpected role of SNAP-25 in controlling PSD-95 clustering and open the possibility that genetic reductions of the protein levels - as occurring in schizophrenia - may contribute to the pathology through an effect on postsynaptic function and plasticity.

Recruitment of synaptic molecules during synaptogenesis.

The glutamatergic synapse is the main type of excitatory synapse in the mammalian brain. The formation of each glutamatergic synapse is associated with the recruitment of numerous (probably hundreds) different molecules and their assimilation into functional assemblies. Intense research has revealed the identity of many of these molecules, provided information as to interactions they are involved in, and offered clues as to their roles in synaptic function. Recent work has also begun to shed light on fundamental mechanisms underlying molecule recruitment to developing glutamatergic synapses. Current data indicate that the formation of presynaptic active zones-sites of neurotransmitter release-may be realized by the insertion of precursor vesicles containing multiple active zone components, possibly in pre-assembled form. The assembly of the postsynaptic reception apparatus, on the other hand, seems to occur via the sequential recruitment of molecules to the postsynaptic membrane and their assimilation in situ. Several molecules and mechanisms have been identified that display a capacity for inducing pre- or postsynaptic differentiation. These exciting findings are starting to provide a rudimentary framework for understanding key processes underlying the formation of glutamatergic synaptic connections.

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.

The dynamics of SAP90/PSD-95 recruitment to new synaptic junctions.

SAP90/PSD-95 is thought to be a central organizer of the glutamatergic synapse postsynaptic reception apparatus. To assess its potential role during glutamatergic synapse formation, we used GFP-tagged SAP90/PSD-95, time lapse confocal microscopy, and cultured hippocampal neurons to determine its dynamic recruitment into new synaptic junctions. We report that new SAP90/PSD-95 clusters first appeared at new axodendritic contact sites within 20-60 min of contact establishment. SAP90/PSD-95 clustering was rapid, with kinetics that fit a single exponential with a mean time constant of approximately 23 min. Most new SAP90/PSD-95 clusters were found juxtaposed to functional presynaptic boutons as determined by labeling with FM 4-64. No evidence was found for the existence of discrete transport particles similar to those previously reported to mediate presynaptic active zone cytoskeleton assembly. Instead, we found that SAP90/PSD-95 is recruited to nascent synapses from a diffuse dendritic cytoplasmic pool. Our findings show that SAP90/PSD-95 is recruited to nascent synaptic junctions early during the assembly process and indicate that its assimilation is fundamentally different from that of presynaptic active zone components.

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.

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.

Induction of growth cone formation by transient and localized increases of intracellular proteolytic activity.

The formation of a growth cone at the tip of a transected axon is a crucial step in the subsequent regeneration of the amputated axon. During this process, the transected axon is transformed from a static segment into a motile growth cone. Despite the importance of this process for regeneration of the severed axon, little is known about the mechanisms underlying this transformation. Recent studies have suggested that Ca2+-activated proteinases underlay the morphological remodeling of neurons after injury. However, this hypothesis was never tested directly. Here we tested the ability of transient and localized increases in intracellular proteolytic activity to induce growth cone formation and neuritogenesis. Minute amounts of the proteinase trypsin were microinjected into intact axonal segments or somata of cultured Aplysia neurons, transiently elevating the intracellular protease concentration to 13-130 nM in the vicinity of the injection site. Such microinjections were followed by the formation of ectopic growth cones and irreversible neuritogenesis. Growth cones were not formed after external application of trypsin, microinjection of the carrier solution, or inactivated trypsin. Growth cone formation was not preceded by increases in free intracellular Ca2+ or changes in passive membrane properties, and was blocked by inhibitors of actin and tubulin polymerization. Trypsin-induced neuritogenesis was associated with ultrastructural alterations similar to those observed by us after axotomy. We conclude that local and transient elevations of cytoplasmic proteolytic activity can induce growth cone formation and neuritogenesis, and suggest that localized proteolytic activity plays a role in growth cone formation after axotomy.

Localized and transient elevations of intracellular Ca2+ induce the dedifferentiation of axonal segments into growth cones.

The formation of a growth cone at the tip of a severed axon is a key step in its successful regeneration. This process involves major structural and functional alterations in the formerly differentiated axonal segment. Here we examined the hypothesis that the large, localized, and transient elevation in the free intracellular calcium concentration ([Ca2+]i) that follows axotomy provides a signal sufficient to trigger the dedifferentiation of the axonal segment into a growth cone. Ratiometric fluorescence microscopy and electron microscopy were used to study the relations among spatiotemporal changes in [Ca2+]i, growth cone formation, and ultrastructural alterations in axotomized and intact Aplysia californica neurons in culture. We report that, in neurons primed to grow, a growth cone forms within 10 min of axotomy near the tip of the transected axon. The nascent growth cone extends initially from a region in which peak intracellular Ca2+ concentrations of 300-500 microM are recorded after axotomy. Similar [Ca2+]i transients, produced in intact axons by focal applications of ionomycin, induce the formation of ectopic growth cones and subsequent neuritogenesis. Electron microscopy analysis reveals that the ultrastructural alterations associated with axotomy and ionomycin-induced growth cone formation are practically identical. In both cases, growth cones extend from regions in which sharp transitions are observed between axoplasm with major ultrastructural alterations and axoplasm in which the ultrastructure is unaltered. These findings suggest that transient elevations of [Ca2+]i to 300-500 microM, such as those caused by mechanical injury, may be sufficient to induce the transformation of differentiated axonal segments into growth cones.

Use of Aplysia neurons for the study of cellular alterations and the resealing of transected axons in vitro.

The present report describes the experimental advantages offered by the combined use of Aplysia neurons and contemporary techniques to analyze the cellular events associated with nerve injury in the form of axotomy. The experiments were performed by transecting, under visual control, the main axon of identified Aplysia neurons in primary culture while monitoring several related parameters. We found that in cultured Aplysia neurons axotomy leads to the elevation of the [Ca2+]i in both the proximal and distal axonal segments from a resting level of 100 nM up to the millimolar range for a duration of 3-5 min. This increase in [Ca2+]i led to identical alterations in the cytoarchitecture of the proximal and distal segments. The formation of a membrane seal over the transected ends by their constriction and the subsequent fusion of the membrane is a [Ca2+]i-dependent process and is triggered by the elevation of [Ca2+]i to the microM level. Seal formation was followed by down-regulation of the [Ca2+]i to control levels. Following the formation of the membrane seal an increase in membrane retrieval was observed. We hypothesize that the retrieved membrane serves as an immediately available membrane reservoir for growth cone extension.

Evidence for a role of dendritic filopodia in synaptogenesis and spine formation.

Axo-dendritic synaptogenesis was examined in live hippocampal cell cultures using the fluorescent dyes DiO to label dendrites and FM 4-64 to label functional presynaptic boutons. As the first functional synaptic boutons appeared in these cultures, numerous filopodia (up to 10 micron long) were observed to extend transiently (mean lifetime 9.5 min) from dendritic shafts. With progressively increasing numbers of boutons, there were coincident decreases in numbers of transient filopodia and increases in numbers of stable dendritic spines. Dendritic filopodia were observed to initiate physical contacts with nearby axons. This sometimes resulted in filopodial stabilization and formation of functional presynaptic boutons. These findings suggest that dendritic filopodia may actively initiate synaptogenic contacts with nearby (5-10 micron) axons and thereafter evolve into dendritic spines.

Potentiation of evoked vesicle turnover at individually resolved synaptic boutons.

We have studied synaptic plasticity in hippocampal cell cultures using a new imaging approach that allows unambiguous discrimination of presynaptic function at the level of single synaptic boutons. Employing a protocol designed to test for use-dependent plasticity resembling N-methyl-D-aspartate receptor-dependent long-term potentiation (NMDA-type LTP), we find that brief tetanic stimuli induce a potentiation of evoked synaptic vesicle turnover that lasts for at least 1 hr. Induction of this clearly presynaptic potentiation is blocked by putative postsynaptic glutamate receptor antagonists, suggesting that a retrograde induction signal might be involved. Potentiation appears to occur approximately equally at boutons of low and high initial release probabilities, and evidently does not involve an increase in the size of the total recycling synaptic vesicle pool.

Axotomy induces a transient and localized elevation of the free intracellular calcium concentration to the millimolar range.

1. Axonal transection triggers a cascade of pathological processes that frequently lead to the degeneration of the injured neuron. It is generally believed that the degenerative process is triggered by an overwhelming influx of calcium through the cut end of the axon. 2. Theoretical considerations and indirect observations suggest that axotomy is followed by an increase in the free intracellular calcium concentration ([Ca2+]i) to the millimolar level. In contrast, only relatively modest and transient elevation in [Ca2+]i to the micromolar level was revealed by recent fura-2 studies. 3. In the current study we used the low-affinity Ca2+ indicator mag-fura-2 to reexamine the spatiotemporal distribution pattern of Ca2+ after axotomy and to map the free intracellular Mg2+ concentration gradients. 4. We report that axotomy elevates [Ca2+]i well beyond the "physiological" range of calcium concentrations, to levels > 1 mM near the tip of the cut axon and to hundreds of micromolars along the axon further away from the cut end. Nevertheless, [Ca2+]i recovers to the control levels within 2-3 min after the resealing of the cut end. 5. A comparison of the behavior of fura-2 and mag-fura-2 in the cytosol of the axotomized neurons reveals that the determination of [Ca2+]i by fura-2 largely underestimates the actual intracellular Ca2+ concentrations. 6. Experiments in which one branch of a bifurcated axon was transected revealed that the elevation in [Ca2+]i is confined to the transected axonal branch and does not spread beyond the bifurcation point. 7. After axotomy, the intracellular Mg2+ concentration equilibrates rapidly with the external concentration and then recovers at a rate somewhat slower than that of [Ca2+]i. 8. To the best of our knowledge, this study is the first direct demonstration that axotomy elevates [Ca2+]i to the millimolar range and that neurons are able to recover from these extreme calcium concentrations.

Use of 2,3-naphthalenedicarboxaldehyde derivatization for single-cell analysis of glutathione by capillary electrophoresis and histochemical localization by fluorescence microscopy.

We report that 2,3-naphthalenedicarboxaldehyde reacts rapidly with glutathione and its precursor, gamma-glutamylcysteine, to form highly fluorescent derivatives under physiological conditions. In contrast to previous accounts of 2,3-naphthalenedicarboxaldehyde labeling of primary amines, no additional CN- ion or any other additional nucleophile is required. The fluorescence spectral properties of the chromophores (lambda exc max = 472 nm, lambda em max = 528 nm) make these derivatives amenable to excitation and detection by optical instrumentation that is optimized for fluorescein wavelengths. This selective labeling chemistry enabled quantitative determination and histochemical localization of glutathione in neurobiological samples. Intracellular glutathione was labeled by incubating cultured cells or cell suspensions in a 2,3-naphthalenedicarboxaldehyde-supplemented, DMSO-containing physiological buffer (pH = 7.4) for 2-10 min. Applications include imaging of cultured NG 108-15 cells (mouse neuroblastoma x rat glioma) and primary glial and neuronal cell cocultures (rat hippocampus) using epiluminescent and confocal fluorescence microscopy. Quantitative determination of glutathione in single NG 108-15 cells was accomplished using laser-induced fluorescence detection and capillary electrophoresis.

Spatiotemporal distribution of Ca2+ following axotomy and throughout the recovery process of cultured Aplysia neurons.

This study investigates the alterations in the spatiotemporal distribution pattern of the free intracellular Ca2+ concentration ([Ca2+]i) during axotomy and throughout the recovery process of cultured Aplysia neurons, and correlates these alterations with changes in the neurons input resistance and trans-membrane potential. For the experiments, the axons were transected while imaging the changes in [Ca2+]i with fura-2, and monitoring the neurons' resting potential and input resistance (Ri) with an intracellular microelectrode inserted into the cell body. The alterations in the spatiotemporal distribution pattern of [Ca2+]i were essentially the same in the proximal and the distal segments, and occurred in two distinct steps: concomitantly with the rupturing of the axolemma, as evidenced by membrane depolarization and a decrease in the input resistance, [Ca2+]i increased from resting levels of 0.05-0.1 microM to 1-1.5 microM along the entire axon. This is followed by a slower process in which a [Ca2+]i front propagates at a rate of 11-16 microns/s from the point of transection towards the intact ends, elevating [Ca2+]i to 3-18 microM. Following the resealing of the cut end 0.5-2 min post-axotomy, [Ca2+]i recovers in a typical pattern of a retreating front, travelling from the intact ends towards the cut regions. The [Ca2+]i recovers to the control level 7-10 min post-axotomy. In Ca(2+)-free artificial sea water (2.5 mM EGTA) axotomy does not lead to increased [Ca2+]i and a membrane seal is not formed over the cut end. Upon reperfusion with normal artificial sea water, [Ca2+]i is elevated at the tip of the cut axon and a membrane seal is formed. This experiment, together with the observations that injections of Ca2+, Mg2+ and Na+ into intact axons do not induce the release of Ca2+ from intracellular stores, indicates that Ca2+ influx through voltage gated Ca2+ channels and through the cut end are the primary sources of [Ca2+]i following axotomy. However, examination of the spatiotemporal distribution pattern of [Ca2+]i following axotomy and during the recovery process indicates that diffusion is not the dominating process in shaping the [Ca2+]i gradients. Other Ca2+ regulatory mechanisms seem to be very effective in limiting these gradients, thus enabling the neuron to survive the injury.