Regulatory differences in the stress response of hippocampal neurons and glial cells after heat shock.

During periods of stress, cells depend on a transient, highly conserved, and regulated response to maintain homeostasis. This "heat shock response" is mediated transcriptionally by a multigene family of heat shock factors (HSF). The presence of multiple HSF suggests that activation of a given HSF is stress-specific. Using Western blot analysis, we have demonstrated the inability of primary cultured rat hippocampal neurons to induce a heat shock response after hyperthermia. In contrast, secondary cultured rat glial cells demonstrated a robust response. Examination of whole-cell extracts from the two cell types with gel shift mobility analysis and Western blot analysis revealed that although glial cells express HSF1 and HSF2, hippocampal neurons only express HSF2. Incubation of whole-cell extracts with monoclonal antisera raised against HSF1 and HSF2 before gel shift mobility analysis demonstrated HSF1 DNA-binding activity in glial cells and HSF2 DNA-binding activity in neurons. HSF1 has been shown to be the principal mediator of heat-induced heat shock gene expression. These results suggest that the deficient heat shock response of hippocampal neurons at this developmental stage is attributable to a lack of HSF1 expression. Furthermore, these results suggest that considerations of selective neuronal vulnerability to environmental stress should include the principal mediators of the stress response, the HSF.

Delayed antagonism of calpain reduces excitotoxicity in cultured neurons.

BACKGROUND AND PURPOSE: Glutamate receptor antagonists can produce protection against the neurotoxicity of excessive glutamate stimulation. However, antagonism of the postreceptor processes that produce cell damage may provide a longer window of opportunity for protecting neurons after the initiation of excitotoxic injury. Among various processes that have been thought to mediate the toxic effects of glutamate are activation of the Ca(2+)-dependent proteases calpain I and II and the activation of nitric oxide synthase. We tested the potential for neuroprotection by delayed application of calpain antagonists after excitotoxic treatment. METHODS: Primary cultures of cerebellar and hippocampal neurons were exposed to the glutamate receptor agonists kainate and N-methyl-D-aspartate (NMDA) for 20-minute periods, and survival was examined by fluorescent assay after 24 hours. Enzyme antagonists were applied at various time points during this interval. RESULTS: The neurotoxic effects of NMDA in cultured hippocampal neurons and of kainate in cultured cerebellar neurons have been previously shown to be Ca2+ dependent. Here we show that in both of these examples of glutamate receptor-mediated toxicity, activation of a calpainlike proteolytic activity occurred, which was blocked by the calpain inhibitor MDL-28170. This inhibitor also limited the toxicity, even when applied at times up to 1 hour after the onset of the toxic exposure. Another protease inhibitor, E-64, also blocked the proteolysis and toxicity produced by kainate in cerebellar neurons. Blocking nitric oxide synthase activity after 1 hour with the antagonist NG-nitro-L-arginine was also protective of cerebellar and hippocampal neurons, as was the combination of MDL-28170 and NG-nitro-L-arginine. CONCLUSIONS: The activation of calpain is among several enzymatic processes that contribute to the toxicity of glutamate receptor stimulation, and blocking these postreceptor mechanisms can be effective in protecting neurons from excitotoxicity at delayed time points.

Regulation of excitatory transmission at hippocampal synapses by calbindin D28k.

Distinct subpopulations of neurons in the brain contain one or more of the Ca(2+)-binding proteins calbindin D28k, calretinin, and parvalbumin. Although it has been shown that these high-affinity Ca(2+)-binding proteins can increase neuronal Ca2+ buffering capacity, it is not clear which aspects of neuronal physiology they normally regulate. To investigate this problem, we used a recently developed method for expressing calbindin D28k in the somatic and synaptic regions of cultured hippocampal pyramidal neurons. Ninety-six hours after infection with a replication-defective adenovirus containing the calbindin D28k gene, essentially all cultured hippocampal pyramidal neurons robustly expressed calbindin D28k. Our results demonstrate that while calbindin D28k does not alter evoked neurotransmitter release at excitatory pyramidal cell synapses, this protein has a profound effect on synaptic plasticity. In particular, we show that calbindin D28k expression suppresses posttetanic potentiation.

The Ca2+ influx induced by beta-amyloid peptide 25-35 in cultured hippocampal neurons results from network excitation.

Although a neurotoxic role has been postulated for the beta-amyloid protein (beta AP), which accumulates in brain tissues in Alzheimer's disease, a precise mechanism underlying this toxicity has not been identified. The peptide fragment consisting of amino acid residues 25 through 35 (beta AP25-35), in particular, has been reported to be toxic in cultured neurons. We report that beta AP25-35, applied to rat hippocampal neurons in culture, caused reversible and repeatable increases in the intracellular Ca2+ concentration ([Ca2+]i), as measured by fura 2 fluorimetry. Furthermore, beta AP25-35 induced bursts of excitatory potentials and action potential firing in individual neurons studied with whole cell current clamp recordings. The beta AP25-35-induced [Ca2+]i elevations and electrical activity were enhanced by removal of extracellular Mg2+, and they could be blocked by tetrodotoxin, by non-N-methyl-D-aspartate (NMDA) and NMDA glutamate receptor antagonists, and by the L-type Ca2+ channel antagonist nimodipine. Similar responses of bursts of action potentials and [Ca2+]i increases were evoked by beta AP1-40. Responses to beta AP25-35 were not prevented by pretreatment with pertussis toxin. Excitatory responses and [Ca2+]i elevations were not observed in cerebellar neuron cultures in which inhibitory synapses predominate. Although the effects of beta AP25-35 depended on the activation of glutamatergic synapses, there was no enhancement of kainate- or NMDA-induced currents by beta AP25-35 in voltage-clamp studies. We conclude that beta AP25-35 enhances excitatory activity in glutamatergic synaptic networks, causing excitatory potentials and Ca2+ influx. This property may explain the toxicity of beta AP25-35.

Regulation of neuronal Bcl2 protein expression and calcium homeostasis by transforming growth factor type beta confers wide-ranging protection on rat hippocampal neurons.

Excessive activation of glutamate receptors accompanied by Ca2+ overloading is thought to be responsible for the death of neurons in various conditions including stroke and epilepsy. Neurons also die if deprived of important growth factors and trophic influences, conditions sensitive to certain oncogene products such as the Bcl2 protein. We now demonstrate that transforming growth factor type beta (TGF-beta) prevents neuronal Ca2+ overloading of rat hippocampal neurons in response to the glutamatergic agonist N-methyl-D-aspartate or the Ca2+ ionophore 4-Br-A23187 and, in addition, leads to a substantial increase in neuronal Bcl2 protein expression. Parallel cytotoxicity experiments demonstrate that treatment with TGF-beta protects rat hippocampal neurons from death induced by excitotoxicity, trophic factor removal, and oxidative injury. Thus, TGF-beta may protect against a wide range of toxic insults by regulating two factors with great importance for neuronal viability.