We provide protocols for preparing low-density dissociated-cell cultures of hippocampal neurons from embryonic rats or mice. The neurons are cultured on polylysine-treated coverslips, which are suspended above an astrocyte feeder layer and maintained in serum-free medium. When cultured according to this protocol, hippocampal neurons become appropriately polarized, develop extensive axonal and dendritic arbors and form numerous, functional synaptic connections with one another. Hippocampal cultures have been used widely for visualizing the subcellular localization of endogenous or expressed proteins, for imaging protein trafficking and for defining the molecular mechanisms underlying the development of neuronal polarity, dendritic growth and synapse formation. Preparation of glial feeder cultures must begin 2 weeks in advance, and it takes 5 d to prepare coverslips as a substrate for neuronal growth. Dissecting the hippocampus and plating hippocampal neurons takes 2-3 h.
Dendritic spines have been proposed as primary sites of synaptic plasticity in the brain. Consistent with this hypothesis, spines contain high concentrations of actin, suggesting that they might be motile. To investigate this possibility, we made video recordings from hippocampal neurons expressing actin tagged with green fluorescent protein (GFP-actin). This reagent incorporates into actin-containing structures and allows the visualization of actin dynamics in living neurons. In mature neurons, recordings of GFP fluorescence revealed large actin-dependent changes in dendritic spine shape, similar to those inferred from previous studies using fixed tissues. Visible changes occurred within seconds, suggesting that anatomical plasticity at synapses can be extremely rapid. As well as providing a molecular basis for structural plasticity, the presence of motile actin in dendritic spines implicates the postsynaptic element as a primary site of this phenomenon.
Dendritic spines at excitatory synapses undergo rapid, actin-dependent shape changes which may contribute to plasticity in brain circuits. Here we show that actin dynamics in spines are potently inhibited by activation of either AMPA or NMDA subtype glutamate receptors. Activation of either receptor type inhibited actin-based protrusive activity from the spine head. This blockade of motility caused spines to round up so that spine morphology became both more stable and more regular. Inhibition of spine motility by AMPA receptors was dependent on postsynaptic membrane depolarization and influx of Ca 2+ through voltage-activated channels. In combination with previous studies, our results suggest a two-step process in which spines initially formed in response to NMDA receptor activation are subsequently stabilized by AMPA receptors.
We have investigated the trafficking of two endogenous axonal membrane proteins, VAMP2 and NgCAM, in order to elucidate the cellular events that underlie their polarization. We found that VAMP2 is delivered to the surface of both axons and dendrites, but preferentially endocytosed from the dendritic membrane. A mutation in the cytoplasmic domain of VAMP2 that inhibits endocytosis abolished its axonal polarization. In contrast, the targeting of NgCAM depends on sequences in its ectodomain, which mediate its sorting into carriers that preferentially deliver their cargo proteins to the axonal membrane. These observations show that neurons use two distinct mechanisms to polarize proteins to the axonal domain: selective retention in the case of VAMP2, selective delivery in the case of NgCAM.
During the development of neuronal polarity, the Kinesin-1 motor translocates preferentially to the axon. We show that Kinesin-1 selectivity does not depend on differences between axons and dendrites in microtubule stability or tubulin acetylation, but is likely specified by other tubulin posttranslational modifications.
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