Leslie A. Krushel

Cellular signaling by neural cell adhesion molecules of the immunoglobulin superfamily

Neural cell adhesion molecules (CAMs) of the immunoglobulin superfamily nucleate and maintain groups of cells at key sites during early development and in the adult. In addition to their adhesive properties, binding of CAMs can affect intracellular signaling. Their ability to influence developmental events, including cell migration, proliferation, and differentiation can therefore result both from their adhesive as well as their signaling properties. This review focuses on the two CAMs for which the most information is known, the neural CAM, N‐CAM, and L1. N‐CAM was the first CAM to be characterized and, therefore, has been studied extensively. The binding of N‐CAM to cells leads to a number of signaling events, some of which result in changes in gene expression. Interest in L1 derives from the fact that mutations in its gene lead to human genetic diseases including mental retardation. Much is known about modifications of the L1 cytoplasmic domain and its interaction with cytoskeletal molecules. The study of CAM signaling mechanisms has been assay‐dependent rather than molecule‐dependent, with particular emphasis on assays of neurite outgrowth and gene expression, an emphasis that is maintained throughout the review. The signals generated following CAM binding that lead to alterations in cell morphology and gene expression have been linked directly in only a few cases. We also review information on other CAMs, giving special consideration to those that are anchored in the membrane by a phospholipid anchor. These proteins, including a form of N‐CAM, are presumed to be localized in lipid rafts, membrane substructures that include distinctive subsets of cytoplasmic signaling molecules such as members of the src‐family of nonreceptor protein tyrosine kinases. In the end, these studies may reveal that what CAMs do after they bind cells together may have as profound consequences for the cells as the adhesive interactions themselves. This area will therefore remain a rich ground for future studies. Dev Dyn;218:260–279.

Developmental expression of two rat sialyltransferases that modify the neural cell adhesion molecule, N-CAM.

Polysialylation of the neural cell adhesion molecule (N-CAM) reduces the efficacy of N-CAM-mediated homophilic binding and is regulated both during development and in regions undergoing neurogenesis or remodeling in the adult. Hamster PST-1 (PST) and rat STX are two related sialytransferases that catalyze the polysialylation of N-CAM. We have isolated a cDNA clone for the rat homologue of PST and compared its amino acid and nucleotide sequence to that of rat STX. This analysis revealed regions of high sequence similarity corresponding to the enzymatic domains of the two molecules. Other regions of lower similarity were used to generate specific probes for in situ hybridization. The distribution of PST and STX mRNAs, polysialic acid, and N-CAM were analyzed at three developmental stages. PST and STX mRNAs were expressed abundantly throughout the nervous system at embryonic day 15 and postnatal day 4 and were coexpressed in most tissues examined. In the adult brain, STX expression was reduced relative to PST and expression of both mRNAs was restricted to subsets of cells in areas undergoing constant synaptic rearrangement including hippocampus and olfactory system. The results suggest that both PST and STX participate in the polysialylation of N-CAM in vivo and that their expression levels are dynamically controlled during development and regeneration.

Pattern formation in the mammalian forebrain: patch neurons from the rat striatum selectively reassociate in vitro.

Mechanisms involved in the developmental organization of the rat striatum were investigated in vitro. The neurons of the patch and matrix compartments were preferentially labeled in vivo with a [3H]thymidine injection on embryonic day (E) 13 or 18, respectively. Two or 7 days later the striatum was removed, dissociated into a single cell suspension and plated on a collagen-coated substrate. After 5 days in culture the neurons had migrated into aggregates. Within an individual aggregate, neurons labeled on E13 tended to clump together, whereas neurons labeled on E18 were randomly dispersed. Comparing between aggregates, [3H]thymidine-labeled E13 cells were located in aggregates containing numerous other labeled E13 cells, whereas [3H]thymidine-labeled E18 cells were dispersed randomly between aggregates. These results suggest that early born striatal neurons (primarily patch cells) selectively associate with each other, and that this process may be crucial to the developmental compartmentalization of the rat striatum.

Pattern Formation in the Mammalian Forebrain: Striatal Patch and Matrix Neurons Intermix Prior to Compartment Formation

The striatum of the mammalian forebrain is divided into two compartments: the patches and the matrix. Neurons of the patch compartment in the rat striatum become postmitotic earlier in neurogenesis than neurons of the matrix compartment. The selective adhesion of patch neurons to one another has been suggested previously to be an important developmental mechanism of striatal compartmentation. We asked if the selective adhesion of patch neurons is expressed before or after the migration of the majority of the matrix neurons into the striatum. Patch neurons were labelled in vivo by a fluorescent retrograde tracer injected into the substantia nigra on embryonic day 19, which almost exclusively labelled patch neurons. Matrix neurons were labelled with a maternal injection of bromodeoxyuridine at embryonic day 18. When animals were killed at embryonic day 20, the majority of the retrogradely labelled patch neurons were intermixed with the bromodeoxyuridine‐labelled matrix neurons, although there appeared to be clustering of some of the patch neurons. However, by postnatal day 2 there was a complete segregation of the clusters of the retrogradely labelled patch neurons from the bromodeoxyuridine‐labelled matrix neurons in the striatum. This process was modelled in vitro. The patch and matrix compartments were labelled in vivo at embryonic day 13 and 18 respectively, with different birthdate markers ([3H]thymidine or bromodeoxyuridine). At embryonic day 20 the striatal tissue was removed, dissociated and reaggregated in suspension cultures. After 1 day in vitro, labelled patch and matrix neurons were randomly intermixed within the reaggregates. Examination of the cultures at 2.5 and 4 days in vitro revealed clumping of the labelled patch neurons towards the centres of the reaggregates. Over this same period, the labelled matrix neurons did not clump and were dispersed towards the periphery of the reaggregates. The results suggest that patch neuron adhesiveness may appear relatively soon after these neurons become postmitotic, but that this adhesiveness is unable to overcome the initial force produced by the massive migration of matrix neurons into the striatum. We hypothesize that a migratory phase of embryonic striatal development exists, when fated patch and matrix neurons intermix. After this migratory phase, patch neuron adhesiveness can produce the mature segregation of the striatal compartments.

NF-κB activation by N-CAM and cytokines in astrocytes is regulated by multiple protein kinases and redox modulation

Interaction of the neural cell adhesion molecule (N‐CAM) with astrocytes activates a transcription factor, NF‐κB, that mediates inflammatory responses after neural injury. Here we describe intracellular signaling events that link N‐CAM binding to NF‐κB–mediated transcription. Addition of the third immunoglobulin domain of N‐CAM (Ig III), which mimics the activity of intact N‐CAM, or of cytokines (interleukin‐1β or tumor necrosis factor‐α), increased transcription from an NF‐κB–responsive luciferase reporter gene construct that had been transiently transfected into neonatal rat forebrain astrocytes. NF‐κB activity induced by Ig III or cytokines was decreased by inhibition of nonreceptor protein tyrosine kinases (PTKs), phospholipase C, protein kinase C (PKC), calcium/calmodulin‐dependent protein kinase II (CaMKII), or oxidative stress. Inhibition of PKC blocked nuclear translocation of NF‐κB protein while binding of NF‐κB to DNA was decreased by modulation of redox homeostasis. In contrast, inhibition of CaMKII and nonreceptor PTKs altered neither nuclear translocation nor DNA binding, suggesting that these kinases affect NF‐κB transactivation. A number of agents that inhibit NF‐κB activation in other cell types did not affect activation in astrocytes. These findings suggest that activation of NF‐κB by N‐CAM and cytokines in astrocytes involves multiple signals that differentially affect NF‐κB nuclear translocation, DNA binding, and transactivation. GLIA 33:45–56, 2001.

A short segment within the cytoplasmic domain of the neural cell adhesion molecule (N-CAM) is essential for N-CAM-induced NF-κB activity in astrocytes

The neural cell adhesion molecule (N-CAM) is expressed on the surface of astrocytes, where its homophilic binding leads to the activation of the transcription factor NF-κB. Transfection of astrocytes with a construct encompassing the transmembrane region and the cytoplasmic domain of N-CAM (designated Tm-Cyto, amino acids 685–839 in the full-length molecule) inhibited this activation up to 40%, and inhibited N-CAM-induced translocation of NF-κB to the nucleus. N-CAM also activated NF-κB in astrocytes from N-CAM knockout mice, presumably through binding to a heterophile. This activation, however, was not blocked by Tm-Cyto expression, indicating that the inhibitory effect of the Tm-Cyto construct is specific for cell surface N-CAM. Deletions and point mutations of the cytoplasmic portion of the Tm-Cyto construct indicated that the region between amino acids 780 and 800 were essential for inhibitory activity. This region contains four threonines (788, 793, 794, and 797). Mutation to alanine of T788, T794, or T797, but not T793, abolished inhibitory activity, as did mutation of T788 or T797 to aspartic acid. A Tm-Cyto construct with T794 mutated to aspartic acid retained inhibitory activity but did not itself induce a constitutive NF-κB response. This result suggests that phosphorylation of T794 may be necessary but is not the triggering event. Overall, these findings define a short segment of the N-CAM cytoplasmic domain that is critical for N-CAM-induced activation of NF-κB and may be important in other N-CAM-mediated signaling.