Faculty Bibliography

A recent study has described synchronous burst discharges of dentate hilar neurons and area CA3 pyramidal cells in the presence of the convulsants 4-aminopyridine and picrotoxin in guinea-pig hippocampal slices [Muller W. and Misgeld U. (1991) J. Neurophysiol. 65, 141-147]. To examine the synchronous activity of dentate cells and area CA3 pyramidal cells further, epileptiform burst discharges were examined in morphologically and/or electrophysiologically identified non-granule cells in the hilus and granule cell layer of the rat dentate gyrus and compared to simultaneously-recorded pyramidal cells of area CA3a, b, and c. Specifically, the types of dentate cells and the types of discharge were examined, as well as the timing of burst discharge of dentate cells relative to different cells of area CA3. In the presence of the GABAA receptor antagonist bicuculline (30 microM), all dentate cell types discharged in rhythmic, spontaneous bursts that were synchronized with area CA3 pyramidal cell epileptiform bursts. The sampled cells included hilar 'mossy' cells, hilar fast-spiking cells (putative interneurons) as well as interneurons located in the granule cell layer, such as the pyramidal 'basket' cells. Simultaneous recording from dentate non-granule cells and area CA3 pyramidal cells during exposure to bicuculline demonstrated that stimulus-evoked and spontaneous epileptiform bursts occurred almost exactly at the same time; there were only a few milliseconds between the onsets of pyramidal cell bursts and dentate cell bursts, with the pyramidal cell preceding the dentate cell in almost every case. There were no systematic differences among dentate cell types in the extent they lagged behind pyramidal cells, and there were no detectable differences among area CA3 pyramidal cells. In slices that were cut between area CA3 and the dentate gyrus, epileptiform bursts occurred in area CA3 but not in the dentate. These findings suggest that, in the absence of GABAA receptor-mediated inhibition, excitatory pathways from area CA3 to the dentate gyrus are strong and widespread. These pathways, and possibly other mechanisms, can lead to tightly synchronized action potential discharge of pyramidal cells and dentate non-granule cells. The results also suggest that disinhibition alone is insufficient to cause synchronous bursts in the dentate gyrus, in contrast to area CA3

Stimulation of the fimbria in rat hippocampal slices evoked an extracellular negativity in the granule cell layer and a small depolarization in granule cells at their resting potentials. The intracellular potentials appeared to be GABAA receptor-mediated IPSPs because they reversed at -69.1 +/- 1.0 mV (mean +/- S.E.M., n = 14) and were blocked by the GABAA receptor antagonist bicuculline (10-50 microM, n = 14). However, during the first few minutes of perfusion with bicuculline, IPSPs transiently and paradoxically increased in amplitude. As IPSPs increased, the reversal potential and latency to onset remained the same. These effects were reversible, and during the wash period IPSPs first increased and then stabilized at a smaller amplitude, similar to IPSPs evoked in control conditions. As the GABAA receptor-mediated IPSP decreased, it was followed by a second hyperpolarization. This late hyperpolarization appeared to be a GABAB receptor-mediated IPSP, because it reversed near the equilibrium potential for potassium (mean -81.8 +/- 2.3 mV, n = 12, [K+]o = 5 mM) and was blocked by the GABAB receptor antagonist 2-hydroxy saclofen (250-500 microM, n = 5). The results suggest that GABAA and GABAB receptor-mediated IPSPs evoked in granule cells by fimbria stimulation are normally inhibited by activation of GABAA receptors. The inhibition by GABAA receptors is strong enough that, in control conditions, the GABAA IPSPs are barely detectable and the GABAB IPSPs are undetectable.(ABSTRACT TRUNCATED AT 250 WORDS)

Although normally quiescent, astrocytes in the adult brain respond to various types of brain injury by rapidly dividing, swelling, extending cellular processes, and expressing increased amounts of glial fibrillary acidic protein (GFAP). These phenomena are collectively referred to as 'astrogliosis.' Similarly, astroglia in primary culture stop dividing when they attain confluency, yet, as seen in situ, they retain their proliferative capacity for extended periods and resume rapid division when subcultured. To examine the impact of glial division on secretion of neurite-promoting factors, conditioned medium (CM) was removed from subconfluent, newly confluent, and long-term confluent ('aged') neonatal rat astrocyte cultures, and from aged confluent cultures that had been repassaged, 'lesioned' (scraping with a rubber policeman), or triturated 3 days before harvest. Secretion of neurite-promoting factor(s) by glial cells into these CM was then assayed by treating neuroblastoma cultures with these various CM and quantitating neurite elaboration. Extensive neurite sprouting was elicited by CM from cultures just reaching confluency and from repassaged, lesioned, or triturated cultures. CM from aged confluent cultures did not induce sprouting. These results indicate that secretion of neurite-promoting factor(s) is regulated by glial division, and suggest that gliosis in situ may contribute to neurite sprouting by similar mechanisms. Immunoblot analysis demonstrated the presence in CM of varying amounts of laminin and amyloid precursor protein (APP), including isoforms containing the Kunitz-type protease inhibitor domain. CM from subconfluent cultures contained trace amounts of these proteins, but CM from cultures just reaching confluency contained significant amounts. Although CM from aged cultures contained barely detectable levels of either protein, trituration or repassage of aged cultures dramatically increased secretion of these proteins. APP- and laminin-enriched CM fractions promoted neuritogenesis to a similar level as respective unfractionated CM; anti-APP and anti-laminin antisera blocked this effect. Purified human brain APP promoted neuritogenesis when added to non-conditioned medium and aged CM. Increased secretion of APP and laminin therefore mediates at least a portion of CM-induced neuronal sprouting; these proteins may perform analogous functions during astrogliosis in situ

The mechanisms of cytotoxic activity of Griffonia simplicifolia 1-B4 (GS1B4) and wheat germ agglutinin (WGA) lectins against various murine tumour cell lines were studied. Tumour cells that lack lectin-binding carbohydrates were resistant to lysis by these lectins. However, YAC-1 cells that expressed GS1B4 lectin-binding sites showed low sensitivity to lysis. To further analyse the relative importance of cell surface carbohydrates in lectin cytotoxicity, BL6-8 melanoma cells, which do not express the alpha 1,3 galactosyltransferase (alpha 1,3GT) gene and cell surface alpha-galactosyl epitopes reacting with GS1B4 lectin, were transfected with cDNA encoding alpha 1,3GT. After transfection, BL6-8 cells expressed high levels of GS1B4-binding alpha-galactosyl epitopes, but remained resistant to lysis by GS1B4 lectin, suggesting that the presence of lectin-binding epitopes, while essential, is not sufficient for tumour cell lysis and probably some intracellular mechanisms are involved in the regulation of lectin-mediated cytotoxicity. We found that the GS1B4 and WGA lectins induced apoptosis with DNA fragmentation of sensitive, but not resistant, tumour cell lines. DNA fragmentation, as well as tumour cell lysis, was blocked in the presence of the specific inhibitory sugar. To determine whether binding of the lectin to cell surface carbohydrates is sufficient to trigger tumour cell lysis, lectin-sensitive CL8-1 melanoma cells were incubated with GS1B4 lectin immobilized on agarose beads. Although these tumour cells bind to the immobilized lectin, it failed to trigger tumour cell death, suggesting that only soluble lectin is capable of tumour cell lysis and lectin internalization is probably required for their lysis.(ABSTRACT TRUNCATED AT 250 WORDS)

A series of neuroanatomic analyses have been undertaken to identify potential neuropathological changes seen in monkeys exposed to early social deprivation, which leads to psychopathology, inappropriate responses to stress and appetitive disorders. The animals used in this study were either socially reared or maternal- and peer-deprived. Within this framework, the distribution and density of noradrenergic (and adrenergic) varicosities was assessed in the hypothalamic paraventricular nucleus of rhesus monkeys using dopamine-beta-hydroxylase immunohistochemistry combined with laser scanning microscopy. Quantitative analysis of dopamine-beta-hydroxylase-immunoreactive varicosity density within magnocellular and parvicellular regions revealed no significant differences between rearing conditions, suggesting that this chemically identified afferent input to the paraventricular nucleus was not affected by the early environmental insult of social deprivation. The apparent lack of vulnerability of the paraventricular nucleus to differential rearing conditions contrasts with the neuropathological changes observed in several discrete brain regions.

Social deprivation during early postnatal life has profound and long-lasting effects on the behavior of primates, including prolonged and exaggerated responses to stress as well as impaired performance on a variety of learning tasks. Although the cellular changes that underlie such alterations in behavior are unknown, environmentally induced psychopathology may involve morphologic or biochemical changes in select neuronal populations. The hippocampal formation of both socially deprived and socially reared prepubescent rhesus monkeys was selected for immunocytochemical investigation because of its association with the behavioral stress response and learning. Immunocytochemical analysis using antibodies specific for the neurofilament protein triplet was performed since these proteins are modified within degenerating neurons in a variety of neurodegenerative disorders. Results from optical density measurements indicate an increase in the intensity of non-phosphorylated neurofilament protein immunoreactivity in the dentate gyrus granule cell layer of socially deprived monkeys in comparison with that of socially reared animals, suggesting that early social deprivation may result in an increase in the amount of non-phosphorylated neurofilament protein in these cells. This phenotypic difference in dentate granule cells between differentially reared monkeys supports the notion that specific subpopulations of neurons in brain regions that subserve complex behaviors may undergo long-term modifications induced by environmental conditions. Furthermore, the data suggest that constitutive chemical components related to structural integrity may be as susceptible to early environmental manipulations as the more traditionally viewed measures of cellular perturbations, such as neurotransmitter dynamics, cell density and the establishment of connectivity. The observed modifications may serve as an anatomical substrate for behavioral abnormalities that persist in later life.

1. Excitation of the spiny subtype of hilar neurons in the fascia dentata was characterized by intracellular recording from hilar cells in hippocampal slices. Stimulation of the outer molecular layer was used to activate the perforant path. Evoked responses were examined, as well as the large spontaneous excitatory potentials that are a distinctive characteristic of spiny hilar cells. 2. Excitatory potentials that occurred spontaneously, as well as those that occurred in response to outer molecular layer stimulation, were similar among the cells that were sampled, regardless of morphological variations such as the presence or absence of thorny excrescences. Spontaneous and evoked excitatory postsynaptic potentials (EPSPs) were complex depolarizations that often had several discrete peaks. Spontaneous EPSPs increased in amplitude slightly with hyperpolarization, and evoked EPSPs clearly increased with hyperpolarization. 3. Applications of selective antagonists of excitatory amino acid receptors were used to determine which excitatory amino acid receptor mediates EPSPs of these cells. 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) was used to block the receptor subtype selective for the agonists alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and kainic acid (the 'AMPA/kainate' receptor). 2-amino-5-phosphonovaleric acid (APV) was used to block receptors specific for the agonist N-methyl-D-aspartate (NMDA; the 'NMDA' receptor). Perfusion with CNQX (5-25 microM) completely blocked all spontaneous and evoked excitation, even when activity was examined at relatively depolarized membrane potentials and a low concentration of extracellular magnesium (0.5 mM) was used. Under these conditions, APV (25-50 microM) had no detectable effect on spontaneous activity but did increase the stimulus strength required to elicit responses to outer molecular layer stimulation. 4. When extracellular magnesium was lowered to 0 mM (nominally), there was strong evidence for a contribution of NMDA receptors to spontaneous and evoked EPSPs. Thus, when cells were perfused with 0 mM extracellular magnesium and 5 microM CNQX, spontaneous depolarizations were present and EPSPs could be triggered by stimulation of the outer molecular layer. Both the spontaneous and evoked EPSPs were blocked by 25 microM APV. 5. Because gamma-aminobutyric acid (GABA)A receptors can cause depolarizations in hippocampal neurons, the GABAA receptor antagonist bicuculline was used to determine whether some of the EPSPs were mediated by GABAergic neurons that are normally activated by spontaneous release of excitatory amino acids. Bicuculline (5-25 microM) had no effect on spontaneous depolarizations, and led to an enhancement of evoked depolarizations. Therefore it does not appear that GABAA receptor-mediated depolarizations contribute to hilar cell depolarizations.(ABSTRACT TRUNCATED AT 400 WORDS)