Faculty Bibliography

Recent studies have shown that prolonged stimulation of afferents of the rat fascia dentata in vivo leads to the development of chronic epileptiform activity of the dentate granule cell region, and degeneration of certain cell types in the adjacent hilus. To investigate the development of dentate hyperexcitability and the selective vulnerability of hilar cells, the hippocampal slice preparation offers an in vitro model in which cellular mechanisms can be examined. We have recorded intracellularly from granule cells and hilar cells in tissue slices from rat before, during, and following sustained stimulation of the major afferent input to the dentate gyrus, the perforant path. Results from intracellular studies in slices were consistent with in vivo studies. Hilar cells were far more sensitive to short-term or prolonged perforant path stimulation than granule cells. At a time when the granule cell population response was not affected by prolonged stimulation, simultaneous recordings from hilar cells and some granule layer interneurons showed that these cells were already depolarized, had very low input resistance, and showed other electrophysiological changes indicative of deterioration. In contrast, granule cells generally hyperpolarized during stimulation and their input resistance increased; no signs of injury were evident in granule cells. Some stimulus-induced changes in the physiological characteristics of granule cells, such as decreased spike frequency adaptation and reduced inhibitory postsynaptic potentials, may contribute to the development of dentate hyperexcitability

Following prolonged stimulation of the perforant path input to the dentate gyrus, long-lasting changes occur in the synaptic responses and cell properties of cells in the fascia dentata. The present study describes the effects of sustained stimulation on the major population of cells innervated by the dentate granule cells: are CA3 pyramidal cells of hippocampus. In 46% of slices from rat, sustained stimulation of perforant path was followed by spontaneous, synchronized, rhythmic bursting activity in area CA3 pyramidal cells that was evident for several hours. These bursts could be recorded extracellularly in the pyramidal cell layer, throughout the hilar region, and even in the granule cell layer. With intracellular recording, all of the cells of the fascia dentata were found to be affected by the pyramidal cell bursts. Hyperpolarizing, inhibitory postsynaptic potential (IPSP)-like events occurred in all granule cells tested during the CA3 pyramidal cell burst. In contrast, spiny hilar 'mossy' cells discharged synchronously with the pyramidal cells, as did some of the 'fast spiking' interneurons. However, most interneurons only depolarized a few millivolts during the pyramidal cell burst. These results show that sustained stimulation of the perforant path is followed by a period of hyperexcitability in area CA3 of the hippocampus, and that hyperexcitability in area CA3 influences the activity of the cells in the fascia dentata

We used immunoblot and immunocytochemical methodologies to characterize the appearance and intracellular localization of the high molecular weight neurofilament subunit (NF-H) within the Triton-insoluble cytoskeleton during the first 5 days of differentiation of mouse NB2a/d1 neuroblastoma cells. Hypophosphorylated and partially phosphorylated forms of NF-H were detected in cells before and throughout differentiation. By contrast, some extensively phosphorylated forms of NF-H were first detected on the third day of differentiation and at least one additional 200 kDa isoform was visualized in cytoskeletons only after five days of differentiation. Extensively phosphorylated forms of NF-H were restricted to axonal neurites; by contrast, hypophosphorylated and partially phosphorylated forms of NF-H were present throughout undifferentiated and differentiated cells

Prolonged afferent stimulation of the rat dentate gyrus in vivo leads to degeneration only of those cells that lack immunoreactivity for the calcium binding proteins parvalbumin and calbindin. In order to test the hypothesis that calcium binding proteins protect against the effects of prolonged stimulation, intracellular recordings were made in hippocampal slices from cells that lack immunoreactivity for calcium binding proteins. Calcium binding protein-negative cells showed electrophysiological signs of deterioration during prolonged stimulation; cells containing calcium binding protein did not. When neurons without calcium binding proteins were impaled with microelectrodes containing the calcium chelator BAPTA, and BAPTA was allowed to diffuse into the cells, these cells showed no deterioration. These results indicate that, in a complex tissue of the central nervous system, an activity-induced increase in intracellular calcium can trigger processes leading to cell deterioration, and that increasing the calcium binding capacity of a cell decreases its vulnerability to damage

A total of 27 subjects began active treatment in this double-blind study comparing the efficacy and safety of trazodone and fluoxetine in geriatric depressed patients, but only 13 completed 6 weeks on study medication. Both agents were effective according to weekly and endpoint analyses, and there was no evidence of significant effects on blood pressure, pulse, or weight. Separate analysis of patients who had received an adequate trial of medication indicated a trend toward relatively more fluoxetine-treated patients meeting clinical criteria for resolved depression

In area CA1 of hippocampus, a subpopulation of gamma-aminobutyric acid (GABA)-containing interneurons that make synaptic contacts on pyramidal cells also contains the neuropeptide, somatostatin. The effects of GABA and somatostatin on hippocampal pyramidal cells have been investigated separately, but it is not known whether an interaction occurs between these co-localized substances. We demonstrate that somatostatin has a potent inhibitory effect on GABA-mediated synaptic potentials which hyperpolarize pyramidal cells. This effect may be relevant to the well-documented epileptogenicity of the hippocampus, as well as the phenomenon of long-term potentiation, which is a well-studied example of synaptic plasticity

NB2a/dl neuroblastoma cells were exposed to aluminum chloride or aluminum lactate (0.1-1 mM) for 3 and 6 days. Additional cultures were exposed to aluminum salts as the cells were stimulated to elaborate axonal neurites by dibutyryl cyclic AMP. By phase-contrast microscopy, aluminum salts had no effect on the morphology of undifferentiated (NB2a(-] or differentiated (NB2a(+] cells, or on neuritic elaboration and maintenance. Silver straining by the Bielschowsky method, however, demonstrated argyrophilic accumulations in perikarya of many NB2a(-) and NB2a(+) cells treated with aluminum salts. At the ultrastructural level, whorls of intermediate filaments were the most prominent abnormalities in neuronal perikarya. Although phosphorylated high-molecular weight neurofilament subunits (NF-H) are normally detected by immunocytochemical analyses only within axonal neurites of NB2a/dl cells, aluminum salt treatment caused the detection of phosphorylated epitopes of NF-H within perikaryal of NB2a(-) and NB2a(+) cytoskeletons, suggesting that the argyrophilic filamentous accumulations are composed at least partly of phosphorylated NF-H

Cystatin C is an inhibitor of lysosomal cysteine proteases and consists of 120 amino acids. A variant of cystatin C lacking the first NH2-terminal residues and having one amino acid substitution at position 68 forms amyloid deposits mainly in the walls of brain arteries, causing fatal strokes in Icelandic patients with familial cerebral hemorrhage secondary to a form of an autosomal dominant amyloidosis. To understand the molecular basis of the genetic defect, the gene encoding cystatin C was isolated from genomic DNA libraries made from normal tissue and the brain of an Icelandic patient with hereditary cerebral hemorrhage with amyloidosis (HCHWA-I). The data indicate that the cystatin C gene encodes a polypeptide of 146 amino acids, of which the first 26 correspond to a secretory peptide signal sequence. The gene contains two intervening sequences that interrupt the coding region at amino acids 55 and 93. Comparison with genes encoding salivary cystatins and kininogen proteins show sequence homology and conservation of exon-intron structure. Except for a mutation in the second exon (CAG instead of CTG in the normal gene, resulting in the substitution of glutamine for a leucine residue), the gene cloned from the brain of the Icelandic patient is identical to the normal cystatin C gene. Thus, HCHWA-I is the first familial type of amyloidosis related to a point mutation in a gene encoding for an inhibitor. The mutation in the structural gene encoding cystatin C appears to be the primary defect in this inherited disorder causing amyloid fibril formation and accumulation followed by cerebral hemorrhage