Positive modulation of AMPA receptors increases neurotrophin expression by hippocampal and cortical neurons

This study investigated whether positive modulators of AMPA-type glutamate receptors influence neurotrophin expression by forebrain neurons. Treatments with the ampakine CX614 markedly and reversibly increased brain-derived neurotrophic factor (BDNF) mRNA and protein levels in cultured rat entorhinal/hippocampal slices. Acute effects of CX614 were dose dependent over the range in which the drug increased synchronous neuronal discharges; threshold concentrations for acute responses had large effects on mRNA content when applied for 3 d. Comparable results were obtained with a second, structurally distinct ampakine CX546. Ampakine-induced upregulation was broadly suppressed by AMPA, but not NMDA, receptor antagonists and by reducing transmitter release. Antagonism of L-type voltage-sensitive calcium channels blocked induction in entorhinal cortex but not hippocampus. Prolonged infusions of suprathreshold ampakine concentrations produced peak BDNF mRNA levels at 12 hr and a return to baseline levels by 48 hr. In contrast, BDNF protein remained elevated throughout a 48 hr incubation with the drug. Nerve growth factor mRNA levels also were increased by ampakines but with a much more rapid return to control levels during chronic administration. Finally, intraperitoneal injections of CX546 increased hippocampal BDNF mRNA levels in aged rats and middle-aged mice. The present results provide evidence of regional differences in mechanisms via which activity regulates neurotrophin expression. Moreover, these data establish that changes in synaptic potency produce sufficient network level physiological effects for inducing neurotrophin genes, indicate that the response becomes refractory during prolonged ampakine exposure, and raise the possibility of using positive AMPA modulators to regulate neurotrophin levels in aged brain.

Stable expression of recombinant AMPA receptor subunits: binding affinities and effects of allosteric modulators

Homomeric AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid)-type glutamate receptors (GluRs) were stably expressed in kidney cells from cDNAs encoding GluR1 flop, GluR2 flip, GluR2 flop, and GluR3 flop subunits. The recombinant receptors were of the expected size and showed functional properties in whole-cell recording as previously reported. [3H]AMPA binding to all subunits was increased to a similar extent by the chaotropic ion thiocyanate (SCN-). Significant differences were found in the Scatchard plots, however, which were linear and of high affinity for GluR1 and -3 receptors (K(D) values of 33 and 52 nM, respectively) but showed curvature for GluR2 receptors, indicating the presence of two components with distinct affinities. As with brain AMPA receptors, solubilization of GluR2 receptors reduced the number of lower-affinity sites and correspondingly increased the number of higher-affinity sites. The sulfhydryl reagent p-chloromercuriphenylsulfonic acid, which increases binding to brain receptors, produced only minor changes except in the case of GluR2 flip. These results indicate that GluR2, among the subunits examined here, most closely resembles the native AMPA receptors in brain membranes. [3H]AMPA binding was inhibited in a noncompetitive manner by two drugs that change the desensitization kinetics of the AMPA receptor. In agreement with physiological observations, the apparent affinity of cyclothiazide for GluR2 flip (EC50 = 7 microM) was higher than that for receptors made of flop subunits (49-130 microM). In contrast, BDP-37, a member of the benzamide family of drugs, exhibited a lower potency for GluR2 flip (58 microM) than for any of the flop isoforms (18-40 microM). These results predict that the action of centrally active AMPA-receptor modulators varies across brain regions depending on their flip/flop composition.

Translational suppression of calpain blocks long-term potentiation

Transfection with antisense oligonucleotides was used to reduce calpain 1 activity to approximately 50% of normal values in cultured hippocampal slices. This had no detectable effects on baseline synaptic responses but greatly reduced the incidence and magnitude of long-term potentiation induced with a theta-burst stimulation paradigm. These results suggest that activation of calpain by repetitive bursts of afferent activity, as shown to occur in prior studies, is an essential step in the production of stable increases in synaptic strength.

Translational suppression of calpain I reduces NMDA-induced spectrin proteolysis and pathophysiology in cultured hippocampal slices

Transfection of cultured hippocampal slices for five days with antisense oligonucleotides directed against mRNA encoding calpain I resulted in an approximately 60% decrease in the amount of caseinolytic activity stimulated by 10 microM calcium. Increases in a single proteolytic fragment of spectrin produced by 10-20 min of NMDA receptor stimulation were substantially (approximately 50%) reduced in antisense treated slices; this effect was not obtained in slices exposed to NMDA for 45 min. Attenuation of NMDA receptor-induced spectrin proteolysis by the antisense oligonucleotides was confirmed in immunoassays using antibodies that recognize multiple spectrin breakdown products and in immunocytochemical experiments with an antibody that detects an individual calpain I-mediated fragment. Translational suppression of calpain I did not detectably affect evoked synaptic responses but markedly improved their recovery from a 15 min infusion of NMDA. These results indicate that spectrin breakdown products provide a useful index of in situ calpain I activity and support the hypothesis that the protease plays a significant role in excitotoxicity.

Proteolysis of spectrin by calpain accompanies theta-burst stimulation in cultured hippocampal slices

Tests were carried out to determine if repetitive bursts of afferent stimulation activate calpain, a calcium-dependent protease hypothesized to be involved in the production of long-term potentiation. Antibodies against a stable breakdown product that results from proteolysis of spectrin by calpain were used to identify sites of enzyme activation in cultured hippocampal slices. Slices in which theta-burst stimulation was applied to the Schaffer collateral fibers had pronounced accumulations of breakdown product that were restricted to field CA1, the zone innervated by the stimulated axons. Labelling occurred in the form of scattered puncta and was also present in dendritic processes. The extent of these effects was correlated (r = 0.73) with the amount of theta-burst stimulation delivered. Control slices or those receiving low frequency stimulation had variable, but uniformly lower, amounts of breakdown product and were clearly distinguishable from those given theta bursts. Statistical analyses using a six point rating scheme confirmed this point (P < 0.001). These results satisfy an essential prediction of the hypothesis that calpain plays an important role in the induction of long-term potentiation.

Stimulation of NMDA receptors activates calpain in cultured hippocampal slices

The hypothesis that intense stimulation of NMDA receptors activates calpain was tested in long-term cultures of hippocampus. Slices prepared from 10-day-old rats were maintained for periods of up to 6 weeks and then assayed for a stable breakdown product that results from the proteolysis of spectrin by calpain. The breakdown product increased dramatically during the first 24 h after tissue preparation and then decreased to a low level that remained unchanged for weeks. NMDA caused a 2- to 3-fold increase in breakdown product that rose linearly with time (5-30 min) and was blocked by the receptor antagonist MK-801. The effect of NMDA was the same throughout the culture period and was dependent upon the concentration of extracellular calcium with no effect at 2 mM and maximal effect at 4 mM calcium. These results indicate that rapid activation of calpain occurs in undamaged hippocampal neurons following stimulation of NMDA receptors.

Corticosterone exacerbates kainate-induced alterations in hippocampal tau immunoreactivity and spectrin proteolysis in vivo

Aberrant elevations in intracellular calcium levels, promoted by the excitatory amino acid glutamate, may be a final common mediator of the neuronal damage that occurs in hypoxic-ischemic and seizure disorders. Glutamate and altered neuronal calcium homeostasis have also been proposed to play roles in more chronic neurodegenerative disorders, including Alzheimer's disease. Any extrinsic factors that may augment calcium levels during such disorders may significantly exacerbate the resulting damage. Glucocorticoids (GCs), the adrenal steroid hormones released during stress, may represent one such extrinsic factor. GCs can exacerbate hippocampal damage induced by excitotoxic seizures and hypoxia-ischemia, and we have observed recently that GCs elevate intracellular calcium levels in hippocampal neurons. We now report that the excitotoxin kainic acid (KA) can elicit antigenic changes in the microtubule-associated protein tau similar to those seen in the neurofibrillary tangles of Alzheimer's disease. KA induced a transient increase in the immunoreactivity of hippocampal CA3 neurons towards antibodies that recognize aberrant forms of tau (5E2 and Alz-50). The tau immunoreactivity appeared within 3 h of KA injection, preceded extensive neuronal damage, and subsequently disappeared as neurons degenerated. KA also caused spectrin breakdown, indicating the involvement of calcium-dependent proteases. Physiological concentrations of corticosterone (the species-typical GC of rats) enhanced the neuronal damage induced by KA and, critically, enhanced the intensity of tau immunoreactivity and spectrin breakdown. Moreover, the GC enhancement of spectrin proteolysis was prevented by energy supplementation, supporting the hypothesis that GC disruption of calcium homeostasis in the hippocampus is energetic in nature. Taken together, these findings demonstrate that neurofibrillary tangle-like alterations in tau, and spectrin breakdown, can be induced by excitatory amino acids and exacerbated by GCs in vivo.

Seizure activity-induced changes in polyamine metabolism and neuronal pathology during the postnatal period in rat brain

Systemic injection of kainic acid (KA) does not cause neuronal pathology in limbic structures in rat brain prior to postnatal day (PND) 21. The present study tested if the development of the pathogenic response is associated with the maturation of a link between seizure activity and polyamine metabolism. Pathology was assessed with histological techniques and with the binding of [3H]Ro5-4864, a ligand for the peripheral type benzodiazepine binding sites (PTBBS), a marker of glial cell proliferation. In agreement with previous results, peripherally administered kainate at doses sufficient to induce intense behavioral seizures produced a loss of Nissl staining in hippocampus after PND 21 but not at earlier ages. The pattern of neuronal damage observed after PND 21 resembled that found in adult animals: extensive losses of Nissl staining in area CA3 of hippocampus and in piriform cortex, more modest effects in CA1 and sparing of the granule cells of the dentate gyrus. Similarly, no increase in [3H]Ro5-4864 binding as a result of KA administration was observed in hippocampus and piriform cortex until PND 21. Ornithine decarboxylase (ODC) activity and putrescine levels were high in the neonatal brain and decreased to reach adult values by PND 21. KA-induced seizure activity did not significantly alter both variables until PND 21. After PND 21, ODC activity and putrescine levels markedly increased 16 h after KA-induced seizure activity in hippocampus and piriform cortex. The magnitude of the effects increased between PND 21 and PND 30, at which point the changes in both parameters were comparable to those found in adults. Polyamines stimulate the activity of the calcium-dependent proteases calpain in brain fractions and may increase calpain-mediated proteolysis in situ. In accord with this, kainate-induced breakdown of spectrin, a preferred substrate of calpain, measured 16 h after KA injection followed a developmental curve parallel to that for kainate-induced increases in putrescine levels. These results indicate that the onset of vulnerability to seizure activity triggered by kainic acid is correlated with the development of an ODC/polyamine response to the seizures and further support a critical role for the ODC/polyamine pathway in neuronal pathology following a variety of insults.

Changes in polyamine levels and spectrin degradation following kainate-induced seizure activity: effect of difluoromethylornithine

The induction of ornithine decarboxylase (ODC) in adult CNS and the resulting changes in polyamine levels are often observed under conditions associated with activation of NMDA receptors, calpain stimulation and spectrin degradation. The present study was directed at evaluating the links between these two sets of events. We measured the effects of an acute treatment of adult rats with difluoromethylornithine (DFMO), an irreversible inhibitor of ODC, on biochemical alterations following kainate-induced seizure activity. Beside ODC activity and polyamine levels, we assayed the in situ spectrin degradation and the in vitro binding of 3H-Ro5-4864, a ligand for the peripheral benzodiazepine binding sites which is a good marker of glial proliferation, at various time intervals following systemic kainic acid (KA) injection. Kainate-induced seizure activity was followed by a transient increase in ODC activity, a long-lasting increase in putrescine levels and spectrin degradation, and a delayed increase in 3H-Ro5-4864 binding, mainly in hippocampus and piriform cortex. Treatment of the animals with DFMO markedly reduced the increase in putrescine levels up to 7 days after KA injection. It also reduced the increase in spectrin breakdown observed at 16 h but not at 4 and 7 days after KA injection. Finally, it did not modify the increase in 3H-Ro5-4864 binding measured 4 and 7 days after KA injection. The levels of putrescine were positively correlated with the extent of spectrin proteolysis in KA-treated animals whether or not they were treated with DFMO, at 16 h but not at 7 days after KA injection. The results indicate that the extent of spectrin breakdown observed shortly after KA-induced seizure activity is causally related to the changes in ODC activity and putrescine levels. Although the data are consistent with the idea that putrescine could be a marker for acute pathology, they do not support a role for polyamines in delayed neurotoxicity.

Effect of treatment with difluoromethylornithine on polyamine and spectrin breakdown levels in neonatal rat brain

Impairment of polyamine synthesis by treatment with difluoromehtylornithine (DFMO), an irreversible inhibitor of ornithine decarboxylase, has been shown to alter normal brain development. In the present study we determined the effect of DFMO treatment during a discrete developmental period on polyamine levels and on the in situ activity of calpain, as reflected by the level of degradation of spectrin, in various brain regions of rat pups. DFMO treatment from postnatal days 5 to 10 produced a marked decrease in putrescine levels in every brain structure and a significant decrease in spectrin breakdown levels in hippocampus and cortex but not in cerebellum. The results indicate that the ODC/polyamine pathway partly regulates the in situ activity of calpain and that polyamines may play a role in both growth and degeneration phenomena.

Complex interactions between polyamines and calpain-mediated proteolysis in rat brain

Polyamine synthesis is induced by various extracellular signals, and it is widely held that this biochemical response participates in cell growth and differentiation. Certain of the triggers for synthesis in brain tissues also increase the breakdown of high-molecular-weight structural proteins, apparently by activating calcium-dependent proteases (calpains). The present experiments tested the possibility that calpain activity is modulated by polyamines. Spermine, spermidine, and putrescine all increased calcium-dependent proteolysis of [14C]casein by soluble fractions of rat brain. The order of potency was spermine greater than spermidine greater than putrescine, with apparent affinities of 30, 300, and 6,000 microM, respectively. Each of the three polyamines at physiological concentrations also potentiated the calcium-dependent breakdown of two endogenous high-molecular-weight structural proteins known to be substrates of calpain, in both supernatant and membrane fractions. The thiol protease inhibitor leupeptin, a known calpain inhibitor, also inhibited calcium-dependent proteolysis in the presence and absence of polyamines. The polyamines did not increase the activity of purified calpain I or calpain II determined with either [14C]casein or purified spectrin as the substrate, nor did they interfere with the inhibitory effects of calpastatin, an endogenous inhibitor of calpain. However, polyamines potentiated the stimulation of endogenous but not purified calpain activity produced by an endogenous calpain activator. These results suggest a role for polyamines in protein degradation as well as protein synthesis.

Failure to detect changes in AMPA receptor binding after long-term potentiation

Recent experimental evidence suggests that changes in (RS)-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/quisqualate receptor mediated currents account for the increase in synaptic responses known as long-term potentiation (LTP). These changes could occur in several parameters including receptor density, binding affinity or in the kinetics and conductance properties of the receptor channel. In this study we tested if LTP modifies the affinity or overall number of binding sites. Hippocampal slices were stimulated electrically in at least 12 locations in the stratum radiatum of CA1 in order to induce potentiation in a maximal number of Schaffer-collateral axons. Sections were then prepared from the middle of the slices, incubated with [3H]AMPA or [3H]CNQX (6-cyano-7-nitroquinoxaline-2,3-dione) and processed for autoradiography. To correct for variability among sections, binding in CA1 was expressed relative to that in the molecular layer of the dentate gyrus, which did not receive potentiation. No differences were observed in the absolute or relative amount of binding except for a small decrease of about 5% in [3H]AMPA binding that was not statistically significant. Although the percentage of synapses which were potentiated by our stimulation procedure cannot be determined with certainty, it is unlikely that an increase in the number or affinity of AMPA receptors could explain the 50% LTP effect typically observed in slices.

Inhibition of proteolysis protects hippocampal neurons from ischemia

Intense proteolysis of cytoskeletal proteins occurs in brain within minutes of transient ischemia, possibly because of the activation of calcium-sensitive proteases (calpains). This proteolytic event precedes overt signs of neuronal degeneration, is most pronounced in regions of selective neuronal vulnerability, and could have significant consequences for the integrity of cellular function. The present studies demonstrate that (i) the early phase of enhanced proteolysis is a direct response to hypoxia rather than other actions of ischemia, (ii) it is possible to pharmacologically inhibit the in vivo proteolytic response to ischemia, (iii) inhibition of proteolysis is associated with a marked reduction in the extent of neuronal death, and (iv) protected neurons exhibit normal-appearing electrophysiological responses and retain their capacity for expressing long-term potentiation, a form of physiological plasticity thought to be involved in memory function. These observations indicate that calcium-activated proteolysis is an important component of the post-ischemic neurodegenerative response and that targeting this response may be a viable therapeutic strategy for preserving both the structure and function of vulnerable neurons.

A brief period of hypoxia causes proteolysis of cytoskeletal proteins in hippocampal slices

Breakdown products (BDPs) resulting from the partial proteolysis of spectrin were examined in hippocampal slices after periods of hypoxia lasting for 5 or 10 min. The concentration of a approximately 155 kDa BDP increased nearly twofold after 5 min of hypoxia; further increases were not seen with 10 min episodes or 10 min of hypoxia followed by reoxygenation. The hypoxia-induced proteolysis was blocked by prior infusion of a newly introduced inhibitor of calpain (calpain inhibitor I, 200 microM). Together with previously published data showing improved recovery of hippocampal slices from hypoxia in the presence of calpain inhibitors, these data suggest that activation of calpain may contribute significantly to the pathophysiology of ischemia.

Modulation of DL-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid/quisqualate receptors by phospholipase A2: a necessary step in long-term potentiation?

The effects of kainate (KA)-induced epileptic seizures on the binding properties of hippocampal glutamate receptors, on the modulation of DL-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/quisqualate receptor by phospholipase A2 (PLA2), and on the formation of long-term potentiation (LTP) were studied in hippocampal membranes and hippocampal slices. Systemic administration of KA (10 mg/kg; 15 hr survival) produced specific changes in the binding properties of the AMPA/quisqualate receptors and its regulation. Whereas the binding of various ligands to the N-methyl-D-aspartate receptors was not modified by KA treatment, there was a significant decrease in the maximal number of binding sites for [3H]AMPA. In addition, the increase in [3H]AMPA binding elicited by PLA2 treatment of hippocampal, but not cerebellar, membranes was markedly decreased after KA injection. LTP was also substantially reduced in area CA1 of hippocampal slices from KA-treated animals. The loss of LTP was not due to changes in postsynaptic responses elicited by the bursts that trigger the potentiation effect, thus suggesting that KA treatment disrupts processes that follow N-methyl-D-aspartate receptor activation. Systemic administration of KA was associated with calpain activation as the amount of spectrin breakdown products was increased severalfold in hippocampus but not in cerebellum. Pretreatment of telencephalic membranes with calpain greatly reduced the PLA2-induced increase in [3H]AMPA binding. The results provide evidence in favor of an essential role of PLA2 in the development of LTP and suggest that the order of activation of different calcium-dependent processes is critical for producing the final changes underlying LTP.

Increased spectrin proteolysis in fibroblasts from aged and Alzheimer donors

Since calcium homeostasis is altered in cultured skin fibroblasts from aged and Alzheimer donors, the present study examined the degradation of spectrin, a substrate of the calcium dependent protease calpain. Spectrin proteolysis was estimated as the percentage of spectrin breakdown products (e.g., 150 + 155 kDa bands) per total spectrin immunoreactivity. In the baseline condition (e.g., unstimulated fibroblasts), spectrin breakdown was 53% greater in cells from aged donors when compared to cells from either young or Alzheimer donors. Compared to unstimulated cells, serum increased spectrin breakdown in cells from aged (22.4%) or Alzheimer (92.1%) donors but was ineffective in cells from young donors. Thus, when compared to young donors (100%), serum stimulation increased spectrin proteolysis by 183.9% (aged) or 231.7% (Alzheimer) after serum stimulation. Treatment of unstimulated cells with carbonyl cyanide 4-trifluoromethoxy-phenylhydrazone (FCCP), an uncoupler of mitochondrial function, increased spectrin degradation by 360.6% (young), 242.4% (aged) or 239.7% (Alzheimer) when compared to unstimulated cells of the same group. The combination of FCCP and serum stimulation enhanced spectrin breakdown in cells from aged (123.6%) and Alzheimer (154.0%) donors when compared to young cells (100%). Thus, changes in the regulation of calcium dependent proteases may contribute to decreased cell spreading and may play a role in the altered cytoskeletal dynamics characteristic of Alzheimer's disease.

Increased spectrin proteolysis in the brindled mouse brain

Proteolytically generated fragments of the microfilament anchoring protein brain spectrin were found to accumulate in brindled mouse brain. Proteolysis was most extensive in brain regions possessing high concentrations of N-methyl-D-aspartate (NMDA) receptors (e.g. cortex, striatum, hippocampus). The brindle mutation affects copper homeostasis and thus a variety of copper-dependent enzymes needed in intermediary metabolism. The altered mitochondria of these mice are suggested to less efficiently buffer NMDA receptor-gated calcium fluxes, thus promoting activation of calcium-activated proteases and subsequent degradation of the spectrin meshwork.

Intrahippocampal colchicine injection results in spectrin proteolysis

Neurons in the hippocampal formation vary markedly in their susceptibility to colchicine toxicity. The present study was directed at evaluating the effects of colchicine on the proteolytic breakdown of the cytoskeletal protein spectrin within the hippocampus in the rat. Quantified by immunoblot analysis of spectrin breakdown products, the extent of proteolysis was found to correlate with the relative vulnerability of different hippocampal subfields to colchicine toxicity. Levels of breakdown products increased dramatically between 1 and 2 days after colchicine injection, peaked between 2 and 4 days, and remained detectably elevated for at least 35 days. Two days after colchicine injection, the spectrin breakdown products were significantly more concentrated in the molecular layer than in the granule cell/hilar region of the dentate gyrus. The colchicine-induced increase in spectrin breakdown products was significantly reduced by pretreatment with the protease inhibitor leupeptin and was significantly elevated by pretreatment with the lysosomal inhibitor chloroquine. Immunohistochemical analyses of the hippocampus at various times after colchicine injection revealed changes in the distribution of spectrin-like immunoreactivity that paralleled the changes observed by Western blot analysis. Thus increased staining was observed in the molecular layer of the dentate gyrus at 2 and 4 days after the injection, while staining in CA3 was only slightly increased. In addition, abnormal staining of reactive astrocytes was prominent at 2 days. The mechanism whereby colchicine results in neuronal death is as yet unknown. However, the results presented here demonstrate that extensive proteolysis of a cytoskeletal protein occurs in response to the drug, suggesting a plausible mechanism for its neurotoxicity. The protease responsible for the effect is likely to be calpain since the process is non-lysosomal, leupeptin-sensitive and produces spectrin breakdown products indistinguishable from those generated by calpain treatment in vitro. These data support the hypothesis that calpain-mediated degradation of cytoskeletal elements is a common and early response to neurodegenerative events and serves as a trigger in the development of various neuropathologies.