Cross-linking of NCAM receptors on neurons induces programmed cell death.

Programmed cell death has been implicated in the loss of neurons that occurs in many neurodegenerative diseases. This has led to an increased interest in the types of stimuli that can initiate neurons to undergo programmed cell death. Previously, we have shown that cross-linking of membrane receptors with the lectin concanavalin A can trigger programmed cell death in neurons [D.H. Cribbs, V.M. Kreng, A.J. Anderson, C.W. Cotman, Cross-linking of Concanavalin A receptors on cortical neurons induces programmed cell death, Neuroscience 75 (1996) 173-185]. Concanavalin A, however, binds to many surface glycoproteins and therefore, it is important to determine whether certain specific receptors can initiate the program. We found that surface immobilized anti-neural cell adhesion molecules (NCAM) monoclonal antibodies provide a good substrate for adhesion and neurite outgrowth for cortical neurons. However, neurons treated directly with soluble anti-NCAM monoclonal antibodies show significant cell death after 24 h and exhibit the morphological and biochemical features indicative of apoptosis, including membrane blebbing, cell shrinkage, condensation of nuclear chromatin and internucleosomal DNA cleavage.

Cross-linking of concanavalin A receptors on cortical neurons induces programmed cell death.

The loss of neurons by programmed cell death is a normal feature of the nervous system during development and has recently been implicated as a major mechanism of cell death in neurodegenerative diseases. In some cases, programmed cell death is induced by the activation of membrane receptors and is referred to as activation-induced programmed cell death. Activation-induced programmed cell death has been previously described in cells from the immune system, in which the activation of receptors by receptor clustering leads to programmed cell death. To determine whether activation-induced programmed cell death occurs in neurons, Concanavalin A was used to cross-link membrane receptors on cortical neurons. Concanavalin A-induced neuronal death was dose dependent and effective at concentrations previously shown to induce activation-induced programmed cell death in lymphocytes. Programmed cell death was attenuated when Concanavalin A-specific binding to neurons was blocked with methyl alpha-D-mannopyranoside. Succinyl Concanavalin A, which bound to Concanavalin A receptors but was ineffective at cross-linking them, did not induce programmed cell death. Concanavalin A-induced neuronal death exhibited many of the hallmarks associated with programmed cell death, such as membrane blebbing, nuclear condensation and margination, and internucleosomal DNA cleavage. In addition, neurons exposed to Concanavalin A displayed a rapid, robust, and persistent increase in the immediate early gene protein c-Jun. A similar increase in c-Jun precedes programmed cell death induced by beta-amyloid in neurons, and under some conditions an increase in c-Jun has been shown to be required for programmed cell death to occur in neurons. Increased expression of c-jun and other immediate early genes has also been correlated with activation-induced programmed cell death in lymphocytes. These observations suggest that Concanavalin A induces activation-induced programmed cell death in neurons via signals produced from the cross-linking of receptors on neuronal membranes. These results also raise the possibility that beta-amyloid induces programmed cell death in a similar manner, by causing the cross-linking of receptors on neuronal membranes. This mechanism may be relevant to neuronal programmed cell death that occurs during development and neurodegeneration.