The effect of intrastriatal injection of fluorocitrate on amino acid pattern, cell enzyme markers, and ultrastructural appearance was investigated. A dose of 1 nmol of fluorocitrate resulted in temporarily decreased levels of glutamine, glutamate, and aspartate, whereas the level of alanine was increased. The glutamine level was severely reduced after 4 h but was reversed after 24 h. The activity of different cellular enzyme markers did not change markedly after this dose. Ultrastructural changes in glial cells were observed, concomitant with the biochemical changes. A dose of greater than or equal to 2 nmol of fluorocitrate resulted in more marked and irreversible changes in amino acid levels. By 24-72 h after the injection of this dose, several marker enzyme activities decreased markedly. The ultrastructural changes affected the neurons as well as the glial cells and were not reversible. The use of microinjection of 1 nmol of fluorocitrate into the neostriatum of the rat to provide a model for studying transmitter amino acid metabolism in brain devoid of glial cell activity is discussed.
Granule cells of the cerebellum constitute the largest homogeneous neuronal population of mammalian brain. Due to their postnatal generation and the feasibility of well characterized primary in vitro cultures, cerebellar granule cells are a model of election for the study of cellular and molecular correlates of mechanisms of survival/apoptosis and neurodegeneration/neuroprotection. The present review mainly deals with recent data on mechanisms and factors promoting survival or apoptotic elimination of cerebellar granule neurons, with a particular focus on the molecular correlates at the level of gene expression and induction of cellular signal pathways. The in vivo development is first analysed with particular reference to the role played by several neurotrophic factors and by the NMDA subtype of glutamate receptor. Then, mechanisms of survival/apoptosis are examined in the model of primary in vitro cultures, where the role of neurotrophins acting on cerebellar granule cells is followed by the large deal of data coming from the paradigm of potassium/serum withdrawal. The role of some key genes of the Bcl family, of some kinase systems and of transcriptional factors is primarily highlighted. Furthermore, the involvement of mitochondria, free radicals and proteases of the caspase family is considered. Finally, the use of cerebellar granule neurons in primary culture to experimentally address the issue of neurodegeneration and pharmacological neuroprotection is considered, with some comments on models at the borderline between necrosis and apoptosis, such as the excitotoxic neuronal damage. The overlapping of cellular signal pathways activated in granule neurons by apparently unrelated stimuli, such as neurotrophins and neurotransmitters/neuromodulators is stressed to put into light the special 'trophic' role played by activity in neurons. Finally, the advantage of designing and performing conceptually equivalent experiments on cerebellar granule neurons during development in vivo and in vitro, is stressed. On the basis of the reviewed material, it is concluded that cerebellar granule neurons have acquired a special position in modern neuroscience as one of the most reliable models for the study of neural development, function and pathology.
Valproic acid (VPA, 2-propylpentanoic acid) has been widely used as an antiepileptic drug and for the therapy of bipolar disorders for several years. Its mechanism of action was initially found to be primarily related to neurotransmission and modulation of intracellular pathways. More recently, it emerged as an anti-neoplastic agent as well, by acting on cell growth, differentiation and apoptosis. Here, it mainly exerts its effect by regulating gene expression at the molecular level, through epigenetic mechanisms. In particular, it has been demonstrated the effect of VPA in chromatin remodeling, as VPA directly inhibits histone deacetylases (HDACs) activity. Interestingly, it has been observed that these biochemical and molecular pathways are involved not only in beneficial effect of VPA against epilepsy and malignancies, but they are also responsible for more general neuroprotective mechanisms. In particular, it has been demonstrated that VPA is neuroprotective in several models of neurodegenerative diseases. Moreover, due to the involvement of the VPA-affected mechanisms in complex behaviors, VPA is increasingly used as a psychotherapeutic agent. This review summarizes the more recent data on VPA neuroprotective mechanisms at the biochemical, molecular and epigenetic levels, focusing on both in vitro and in vivo models of neurodegenerative diseases. In particular, attention is paid to mechanisms by which VPA affects neuronal survival/apoptosis and proliferation/differentiation balance, as well as synaptic plasticity, by acting both directly on neurons and indirectly through glial cells. Perspective applications of the VPA neuroprotective potential in human neurodegenerative diseases are discussed, when relevant.
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