Weisong Shan

Increasing numbers of synaptic puncta during late-phase LTP: N-cadherin is synthesized, recruited to synaptic sites, and required for potentiation.

It is an open question whether new synapses form during hippocampal LTP. Here, we show that late-phase LTP (L-LTP) is associated with a significant increase in numbers of synaptic puncta identified by synaptophysin and N-cadherin, an adhesion protein involved in synapse formation during development. During potentiation, protein levels of N-cadherin are significantly elevated and N-cadherin dimerization is enhanced. The increases in synaptic number and N-cadherin levels are dependent on cAMP-dependent protein kinase (PKA) and protein synthesis, both of which are also required for L-LTP. Blocking N-cadherin adhesion prevents the induction of L-LTP, but not the early-phase of LTP (E-LTP). Our data suggest that N-cadherin is synthesized during the induction of L-LTP and recruited to newly forming synapses. N-cadherin may play a critical role in L-LTP by holding nascent pre-and postsynaptic membranes in apposition, enabling incipient synapses to acquire function and contribute to potentiation.

Molecular Modification of N-Cadherin in Response to Synaptic Activity

The relationship between adhesive interactions across the synaptic cleft and synaptic function has remained elusive. At certain CNS synapses, pre- to postsynaptic adhesion is mediated at least in part by neural (N-) cadherin. Here, we demonstrate that upon depolarization of hippocampal neurons in culture by K+ treatment, or application of NMDA or alpha-latrotoxin, synaptic N-cadherin dimerizes and becomes markedly protease resistant. These properties are indices of strong, stable, enhanced cadherin-mediated intercellular adhesion. N-cadherin retained protease resistance for at least 2 hr after recovery, while other surface molecules, including other cadherins, were completely degraded. The acquisition of protease resistance and dimerization of N-cadherin is not dependent on new protein synthesis, nor is it accompanied by internalization of N-cadherin. By immunocytochemistry, we found that high K+ selectively induces surface dispersion of N-cadherin, which, after recovery, returns to synaptic puncta. N-cadherin dispersion under K+ treatment parallels the rapid expansion of the presynaptic membrane consequent to the massive vesicle fusion that occurs with this type of depolarization. In contrast, with NMDA application, N-cadherin does not disperse but does acquire enhanced protease resistance and dimerizes. Our data strongly suggest that synaptic adhesion is dynamically and locally controlled, and modulated by synaptic activity.

Glial membranes at the node of Ranvier prevent neurite outgrowth.

Nodes of Ranvier are regularly placed, nonmyelinated axon segments along myelinated nerves. Here we show that nodal membranes isolated from the central nervous system (CNS) of mammals restricted neurite outgrowth of cultured neurons. Proteomic analysis of these membranes revealed several inhibitors of neurite outgrowth, including the oligodendrocyte myelin glycoprotein (OMgp). In rat spinal cord, OMgp was not localized to compact myelin, as previously thought, but to oligodendroglia-like cells, whose processes converge to form a ring that completely encircles the nodes. In OMgp-null mice, CNS nodes were abnormally wide and collateral sprouting was observed. Nodal ensheathment in the CNS may stabilize the node and prevent axonal sprouting.

Differential expression of individual gamma-protocadherins during mouse brain development

Three tandemly arrayed protocadherin gene clusters (Pcdh-alpha, -beta, -gamma) comprising more than 50 genes are found in human and mouse. Here, we have investigated the expression and distribution of individual gamma-protocadherins (Pcdhs-gamma) in the developing mouse brain. We find that transfection of Pcdh-gamma genes promotes calcium-dependent cell adhesion in HEK 293 cells. Furthermore, Pcdh-gamma can be recruited to synapses of transfected primary hippocampal neurons. Several individual members of the in total 22 Pcdhs-gamma were chosen to examine the expression of the three subfamilies, Pcdh-gammaA, -gammaB, and -gammaC. These Pcdh-gamma transcripts are expressed all over the brain, with minor regional and cell-type specific differences. Interestingly, a distinct, later onset of expression is observed for Pcdh-gammaC5, a gene located at the end of the Pcdh-gamma cluster. Largely overlapping expression patterns of individual Pcdh-gamma proteins are detected with anti-peptide antibodies. Small differences are observed in the staining of dendritic processes and synapse-rich layers. Our results support the idea that Pcdhs-gamma participate in neuronal differentiation and may be implicated in the fine-tuning of neuronal morphology and synaptogenesis. Cell autonomous regulation of transcription might generate the widespread distribution of individual Pcdhs-gamma in the brain, which is strikingly different from the restricted expression patterns observed for classical cadherins. Thus, a defined set of Pcdhs-gamma may engage in neuronal adhesion and signaling on the cellular level.

Rapid method for culturing embryonic neuron-glial cell cocultures

A streamlined, simple technique for primary cell culture from E17 rat tissue is presented. In an attempt to standardize culturing methods for all neuronal cell types in the embryo, we evaluated a commercial medium without serum and used similar times for trypsinization and tested different surfaces for plating. In 1 day, using one method and a single medium, it is possible to produce robust E17 cultures of dorsal root ganglia (DRG), cerebellum, and enteric plexi. Allowing the endogenous glial cells to repopulate the cultures saves time compared with existing techniques, in which glial cells are added to cultures first treated with antimitotic agents. It also ensures that all the cells present in vivo will be present in the culture. Myelination commences after approximately 2 weeks in culture for dissociated DRG and 3–4 weeks in cerebellar cultures. In enteric cultures, glial wrapping of the enteric neurons is seen after 3 weeks (2 weeks in ascorbic acid), suggesting that basal lamina production is important even for glial ensheathment in the enteric nervous system. No overgrowth of fibroblasts or other nonneuronal cells was noted in any cultures, and myelination of the peripheral nervous system and central nervous system cultures was very robust.

The Minimal Essential Unit for Cadherin-mediated Intercellular Adhesion Comprises Extracellular Domains 1 and 2*

N-cadherin comprises five homologous extracellular domains, a transmembrane, and a cytoplasmic domain. The extracellular domains of N-cadherin play important roles in homophilic cell adhesion, but the contribution of each domain to this phenomenon has not been fully evaluated. In particular, the following questions remain unanswered: what is the minimal domain combination that can generate cell adhesion, how is domain organization related to adhesive strength, and does the cytoplasmic domain serve to facilitate extracellular domain interaction? To address these issues, we made serial constructs of the extracellular domains of N-cadherin and produced various cell lines to examine adhesion properties. We show that the first domain of N-cadherin alone on the cell surface fails to generate adhesive activity and that the first two domains of N-cadherin form the “minimal essential unit” to mediate cell adhesion. Cell lines expressing longer extracellular domains or N-cadherin wild type cells formed larger cellular aggregates than those expressing shorter aggregates. However, adhesion strength, as measured by a shearing test, did not reveal any differences among these aggregative cell lines, suggesting that the first two domains of N-cadherin cells generate the same strength of adhesive activity as longer extracellular domain cells. Furthermore, truncations of the first two domains of N-cadherin are also sufficient to form cisdimerization at an adhesive junction. Our findings suggest that the extracellular domains of N-cadherin have distinct roles in cell adhesion, i.e. the first two domains are responsible for homophilic adhesion activity, and the other domains promote adhesion efficiency most likely by positioning essential domains relatively far out from the cell surface.

Neural (N-) cadherin, A synaptic adhesion molecule, is induced in hippocampal mossy fiber axonal sprouts by seizure

Aberrant mossy fiber sprouting and synaptic reorganization are plastic responses in human temporal lobe epilepsy, and in pilocarpine‐induced epilepsy in rodents. Although the morphological features of the hippocampal epileptic reaction have been well documented, the molecular mechanisms underlying these structural changes are not understood. The classic cadherins, calcium‐dependent cell adhesion molecules, are known to function in development in neurite outgrowth, synapse formation, and stabilization. In pilocarpine‐induced status epilepticus, the expression of N‐cadherin mRNA was sharply upregulated and reached a maximum level (1‐ to 2.5‐fold) at 1– to 4 weeks postseizure in the granule cell layer and the pyramidal cell layer of CA3. N‐cadherin protein was correspondingly increased and became concentrated in the inner molecular layer of the dentate gyrus, consistent with the position of mossy fiber axonal sprouts. Moreover, N‐cadherin labeling was punctate; colocalized with definitive synaptic markers, and partially localized on polysialated forms of neural cell adhesion molecule (PSA‐NCAM)‐positive dendrites of granule cells in the inner molecular layer. Our findings show that N‐cadherin is likely to be a key factor in responsive synaptogenesis following status epilepticus, where it functions as a mediator of de novo synapse formation.

N-cadherin mediates interaction between precursor cells in the subventricular zone and regulates further differentiation.

Neurogenesis and cell differentiation in the brain continues throughout life. In the subventricular zone and rostral migratory stream, precursor cells contact each other. Cell–cell interactions mediated via adhesion molecules are no doubt involved in establishing and maintaining the neurogenic ability of these cells. Here, we demonstrate that N‐cadherin plays important roles in forming cell clusters and in regulating cell differentiation. N‐cadherin is abundantly expressed in chain migrating cells in the subventricular zone and rostral migratory stream but is down‐regulated after cells exit these regions. We also show that neurosphere formation is inhibited via suppression of N‐cadherin function and that N‐cadherin expression is decreased after induction of neurosphere differentiation. Furthermore, we demonstrate that functional blockade of N‐cadherin can enhance glial cell differentiation in explant cultures of precursors from the subventricular zone.

N-Cadherin Prodomain Processing Regulates Synaptogenesis

Classical cadherins, which are adhesion molecules functioning at the CNS synapse, are synthesized as adhesively inactive precursor proteins in the endoplasmic reticulum (ER). Signal sequence and prodomain cleavage in the ER and Golgi apparatus, respectively, activates their adhesive properties. Here, we provide the first evidence for sorting of nonadhesive precursor N-cadherin (ProN) to the neuronal surface, where it coexists with adhesively competent mature N-cadherin (N-cad), generating a spectrum of adhesive strengths. In cultured hippocampal neurons, a high ProN/N-cad ratio downregulates synapse formation. Neurons expressing genetically engineered uncleavable ProN make markedly fewer synapses. The synapse number can be rescued to normality by depleting surface ProN levels through prodomain cleavage by an exogenous protease. Finally, prodomain processing is developmentally regulated in the rat hippocampus. We conclude that it is the ProN/N-cad ratio and not mature N-cad alone that is critical for regulation of adhesion during synaptogenesis.

Conserved and divergent expression patterns of the proteolipid protein gene family in the amphibian central nervous system

The recent discovery of a proteolipid protein gene family has revealed that its members are in fact widely distributed and are not exclusively associated with myelination. To date, three different gene products, DMα/DM‐20/PLP, DMβ/M6a, and DMγ/M6b, have been isolated from certain primitive fish species, mouse, and human central nervous system (CNS). We cloned Xenopus laevis orthologues of DMβ/M6a and DMγ/M6b and investigated the expression patterns of these gene transcripts as well as that of PLP in developing Xenopus CNS. As is the case in shark and mouse, the mRNA encoding the major myelin integral protein, PLP, is first detected at stage 42/43 in tadpoles and is exclusively found in morphologically recognizable oligodendrocytes throughout the brain, while DMβ mRNA is solely expressed in young presumptive neurons in the gray matter. There exist two distinct DMγ mRNAs and, in contrast to these evolutionarily conserved expression patterns, DMγ mRNAs distribute uniquely within the ventricular zone in young tadpoles (stage 25) through maturity. Furthermore, both DMβ and DMγ are expressed in the developing retina, and their distributions are different from one other. In Xenopus CNS, therefore, the expression patterns of three proteolipid proteins, PLP, DMβ, and DMγ, are distinct from each other, implying very different roles for their protein products within the cell populations in which they are expressed. J. Neurosci. Res. 57:13–22, 1999.