Apoptosis of mouse neocortical neurons induced by serum deprivation or by staurosporine was associated with an early enhancement of delayed rectifier (IK) current and loss of total intracellular K+. This IK augmentation was not seen in neurons undergoing excitotoxic necrosis or in older neurons resistant to staurosporine-induced apoptosis. Attenuating outward K+ current with tetraethylammonium or elevated extracellular K+, but not blockers of Ca2+, Cl-, or other K+ channels, reduced apoptosis, even if associated increases in intracellular Ca2+ concentration were prevented. Furthermore, exposure to the K+ ionophore valinomycin or the K+-channel opener cromakalim induced apoptosis. Enhanced K+ efflux may mediate certain forms of neuronal apoptosis.
Neuronal death induced by activating N-methyl-D-aspartate (NMDA) receptors has been linked to Ca2+ and Na+ influx through associated channels. Whole-cell recording from cultured mouse cortical neurons revealed a NMDA-evoked outward current, INMDA-K, carried by K+ efflux at membrane potentials positive to -86 millivolts. Cortical neurons exposed to NMDA in medium containing reduced Na+ and Ca2+ (as found in ischemic brain tissue) lost substantial intracellular K+ and underwent apoptosis. Both K+ loss and apoptosis were attenuated by increasing extracellular K+, even when voltage-gated Ca2+ channels were blocked. Thus NMDA receptor-mediated K+ efflux may contribute to neuronal apoptosis after brain ischemia.
Dystroglycan is a core component of the dystrophin receptor complex in skeletal muscle which links the extracellular matrix to the muscle cytoskeleton. Dystrophin, dystrophin-related protein (DRP, utrophin) and dystroglycan are present not only in muscles but also in the brain. Dystrophin is expressed in certain neuronal populations while DRP is associated with perivascular astrocytes. To gain insights into the function and molecular interactions of dystroglycan in the brain, we examined the localization of alpha- and beta-dystroglycan at the cellular and subcellular levels in the rat cerebellum. In blood vessels, we find alpha-dystroglycan associated with the laminin alpha 2-chain-rich parenchymal vascular basement membrane and beta-dystroglycan associated with the endfeet of perivascular astrocytes. We also show that alpha-dystroglycan purified from the brain binds alpha 2-chain-containing laminin-2. These observations suggest a dystroglycan-mediated linkage between DRP in perivascular astrocytic endfeet and laminin-2 in the parenchymal basement membrane similar to that described in skeletal muscle. This linkage of the astrocytic endfeet to the vascular basement membrane is likely to be important for blood vessel formation and stabilization and for maintaining the integrity of the blood-brain barrier. In addition to blood vessel labelling, we show that alpha-dystroglycan in the rat cerebellum is associated with the surface of Purkinje cell bodies, dendrites and dendritic spines. Dystrophin has previously been localized to the inner surface of the plasma membrane of Purkinje cells and is enriched at postsynaptic sites. Thus, the present results also support the hypothesis that dystrophin interacts with dystroglycan in cerebellar Purkinje neurons.
Serum TNF-alpha concentration and colonic TNF-alpha mRNA expression level are increased significantly in UC rats in correlation with the severity of disease. It indicates that TNF-alpha is closely involved in the immune abnormalities and inflammatory responses in UC. EA at ST36 has therapeutic effect on UC by downregulating serum TNF-alpha and colonic TNF-alpha mRNA expression. High levels of TNF-alpha and its corresponding mRNA expression seem to be implicated in the pathogenesis of UC.
The denaturation of creatine kinase in urea solutions of different concentrations has been studied by following the changes in the ultraviolet absorbance and intrinsic fluorescence as well as by the exposure of hidden SH groups. In concentrated urea solutions, the denaturation of the enzyme results in negative peaks at 285 nm with shoulders at 280 and 290 nm and positive peaks at 244 and 302 nm in the denatured minus native enzyme difference spectrum. The fluorescence emission maximum of the enzyme red shifts with increasing intensity in urea solutions of increasing concentrations. At least part of these changes can be attributed to direct effects of urea on the exposed Tyr and Trp residues as shown by experiments with model compounds. The inactivation of this enzyme has been followed and compared with the conformational changes observed during urea denaturation. A marked decrease in enzyme activity is already evident at low urea concentrations before significant conformational changes can be detected by the exposure of hidden SH groups or by ultraviolet absorbance and fluorescence changes. At higher urea concentrations, the enzyme is inactivated at rates 3 orders of magnitude faster than the rates of conformational changes. The above results are in accord with those reported previously for guanidine denaturation of this enzyme [Yao, Q., Hou, L., Zhou, H., & Tsou, C.-L. (1982) Sci. Sin. (Engl. Ed.) 25, 1186-1193] and can best be explained by assuming that the active site of this enzyme is situated near the surface of the enzyme molecule and is sensitive to very slight conformational changes.
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