Astrocytic Ca2+ Waves Guide CNS Growth Cones to Remote Regions of Neuronal Activity

Activity plays a critical role in network formation during developmental, experience-dependent, and injury related remodeling. Here we report a mechanism by which axon trajectory can be altered in response to remote neuronal activity. Using photoconductive stimulation to trigger high frequency action potentials in rat hippocampal neurons in vitro, we find that activity functions as an attractive cue for growth cones in the local environment. The underlying guidance mechanism involves astrocyte Ca2+ waves, as the connexin-43 antagonist carbenoxolone abolishes the attraction when activity is initiated at a distance greater than 120 µm. The asymmetric growth cone filopodia extension that precedes turning can be blocked with CNQX (10 µM), but not with the ATP and adenosine receptor antagonists suramin (100 µM) and alloxazine (4 µM), suggesting non-NMDA glutamate receptors on the growth cone mediate the interaction with astrocytes. These results define a potential long-range signalling pathway for activity-dependent axon guidance in which growth cones turn towards directional, temporally coordinated astrocyte Ca2+ waves that are triggered by neuronal activity. To assess the viability of the guidance effect in an injury paradigm, we performed the assay in the presence of conditioned media from lipopolysaccharide (LPS) activated purified microglial cultures, as well as directly activating the glia present in our co-cultures. Growth cone attraction was not inhibited under these conditions, suggesting this mechanism could be used to guide regeneration following axonal injury

A radioimmunoassay to monitor synaptic activity in hippocampal neurons in vitro

Exocytosis of synaptic vesicles (SV) results in the surface exposure of lumenal epitopes of SV proteins. We have recently described the use of antibodies directed against the lumenal N-terminus of synaptotagmin I (Sytlum-Abs) to morphologically monitor exo-endocytic recycling of SVs. We report here that a radioimmunoassay based on these antibodies can be used to quantify levels of synaptic activity in primary neuronal cultures. High density cultures of hippocampal neurons grown in the absence of glia were used for these studies. A significant cell surface pool of synaptotagmin I immunoreactivity was detectable by Sytlum-Abs at steady state. The increase in the amount of Sytlum-Abs which became cell bound during a 3 min incubation at 37 degrees C over the Ab bound to this cell surface pool, was substantially higher in depolarizing media containing extracellular Ca2+ than in Ca(2+)-free media. Incubation of the cultures with Sytlum-Abs for longer time periods indicated a sustained increase in the rate of SV exocytosis in depolarizing media which lasted for at least 1 h. This increase was completely abolished by pretreating the neurons with tetanus toxin and this block correlated with a disappearance of synaptobrevin immunoreactivity. This radioimmunoassay therefore offers a new way to monitor SV exocytosis of neuronal populations in vitro irrespective of the type of neurotransmitter secreted and of postsynaptic effects

Synaptic vesicle dynamics in living cultured hippocampal neurons visualized with CY3-conjugated antibodies directed against the lumenal domain of synaptotagmin

Antibodies directed against the lumenal domain of synaptotagmin I conjugated to CY3 (CY3-Syt1-Abs) and video microscopy were used to study the dynamics of synaptic vesicles in cultured hippocampal neurons. When applied to cultures after synapse formation, CY3-Syt1-Abs produced a strong labeling of presynaptic vesicle clusters which was markedly increased by membrane depolarization. The increase of the rate of CY3-Syt1-Ab uptake in a high K+ medium was maximal during the first few minutes but persisted for as long as 60 min. In axons developing in isolation, CY3-Syt1-Abs, in combination with electron microscopy immunocytochemistry, revealed the presence of synaptic vesicle clusters which move in bulk in anterograde and retrograde direction. Clusters are present both in the axon shaft and in filopodia but not in the filopodia of the growth cone. Both presynaptic vesicle clusters and clusters present in isolated axons were disrupted by okadaic acid as previously shown for synaptic vesicle clusters at the frog neuromuscular junction. These findings indicate that synaptic vesicle aggregation may occur independently of cell-cell interaction, but that, in the absence of a synaptic contact, vesicle clusters are not stably anchored to a given region of the cell surface. Labeling of synaptic vesicles in immature isolated neurons was found to be depolarization and Ca2+ dependent, demonstrating that Ca(2+)-regulated exocytosis is an intrinsic characteristic of synaptic vesicles irrespective of their localization at a synapse

Morphologic and biochemical analysis of the intracellular trafficking of the Alzheimer beta/A4 amyloid precursor protein

Abnormal metabolic processing of the beta/A4 amyloid precursor protein (APP) has been implicated in the pathogenesis of Alzheimer disease. Several aspects of normal APP processing have been elucidated, but the precise cellular trafficking of APP remains unclear. To investigate APP trafficking pathways further, we have examined the subcellular distribution of APP in rat brain tissue and a variety of cultured cell types, and correlated this distribution with the biochemical processing of APP. In immunofluorescence microscopy of rat brain sections, APP immunoreactivity was concentrated in the Golgi complex and in proximal axon segments. In addition, a lower level of punctate fluorescence was visible throughout the neuropil. By immunoelectron microscopy of rat brain tissue fragments, APP was found associated with Golgi elements and with medium-sized, invaginated vesicles in both axons and dendrites. Prominent localization of APP to the Golgi complex was also found in primary cultures of rat hippocampal neurons and in non-neuronal cell lines. When cultured cells were treated with brefeldin A (BFA), APP immunoreactivity changed from a Golgi-like to an endoplasmic reticulum-like distribution. No APP was detected in the BFA-induced reticulum identified by the transferrin receptor, indicating that concentration of APP in the Golgi does not reflect recycling between the trans-Golgi network and early endosomal system. In immunoblots of BFA-treated cells, there was an accumulation of full-length APP and inhibition of APP secretory processing. Treatment with phorbol ester resulted in a marked elevation of APP secretion, but no obvious redistribution of APP immunoreactivity was apparent at the light microscope level. The lysosomotropic drug chloroquine induced accumulation of APP in cell lysates, as seen by immunoblotting. Immunofluorescence microscopy of chloroquine-treated cells demonstrated a colocalization of APP with the lysosomal marker Igp 120, whereas no colocalization was seen in untreated cells. Taken together, these results support a scheme in which APP is concentrated in the Golgi complex as it travels through the central vacuolar system en route to the plasma membrane for secretion of its amino-terminal domain and/or to lysosomes for degradation

Mechanisms of synaptogenesis in hippocampal neurons in primary culture

To improve our understanding of the mechanisms which regulate the formation and the functional maturation of synaptic contacts between neurons, we used hippocampal neurons maintained in primary cultures as experimental system. In this model, which offers several advantages for the study of neuronal development and synaptogenesis, we investigated some of the cellular mechanisms underlying the formation of presynaptic and postsynaptic compartments