Discovery of small molecules that normalize the transcriptome and enhance cysteine cathepsin activity in progranulin-deficient microglia.

Patients with frontotemporal dementia (FTD) resulting from granulin (GRN) haploinsufficiency have reduced levels of progranulin and exhibit dysregulation in inflammatory and lysosomal networks. Microglia produce high levels of progranulin, and reduction of progranulin in microglia alone is sufficient to recapitulate inflammation, lysosomal dysfunction, and hyperproliferation in a cell-autonomous manner. Therefore, targeting microglial dysfunction caused by progranulin insufficiency represents a potential therapeutic strategy to manage neurodegeneration in FTD. Limitations of current progranulin-enhancing strategies necessitate the discovery of new targets. To identify compounds that can reverse microglial defects in Grn-deficient mouse microglia, we performed a compound screen coupled with high throughput sequencing to assess key transcriptional changes in inflammatory and lysosomal pathways. Positive hits from this initial screen were then further narrowed down based on their ability to rescue cathepsin activity, a critical biochemical readout of lysosomal capacity. The screen identified nor-binaltorphimine dihydrochloride (nor-BNI) and dibutyryl-cAMP, sodium salt (DB-cAMP) as two phenotypic modulators of progranulin deficiency. In addition, nor-BNI and DB-cAMP also rescued cell cycle abnormalities in progranulin-deficient cells. These data highlight the potential of a transcription-based platform for drug screening, and advance two novel lead compounds for FTD.

Effects on Neurons and Hippocampal Slices by Single and Multiple Primary Blast Pressure Waves From Detonating Spherical Cyclotrimethylenetrinitramine (RDX) Explosive Charges.

Threshold shock-impulse levels required to induce cellular injury and cumulative effects upon single and/or multiple exposures are not well characterized. Currently, there are few in vitro experimental models with blast pressure waves generated by using real explosives in the laboratory for investigating the effects of primary blast-induced traumatic brain injury. An in vitro indoor experimental platform is developed using real military explosive charges to accurately represent battlefield blast exposure and to probe the effects of primary explosive blast on dissociated neurons and tissue slices. Preliminary results indicate that physical insults altered membrane permeability, impacted cellular viability, created axonal beadings, and led to synaptic protein loss in hippocampal slice cultures. Injuries from blast under the conditions that were examined did not appear to cause immediate or sustained damage to the cells. Three consecutive primary blasts failed to disrupt the overall cellular integrity in the hippocampal slice cultures and produced a unique type of pathology comprised with distinct reduction in synaptic proteins before cellular deterioration set in. These observed changes might add to the challenges in regard to enhancing our understanding of the complex biochemical and molecular mechanisms caused by primary blast-induced injury.

Glutamate-induced and NMDA receptor-mediated neurodegeneration entails P2Y1 receptor activation.

Despite the characteristic etiologies and phenotypes, different brain disorders rely on common pathogenic events. Glutamate-induced neurotoxicity is a pathogenic event shared by different brain disorders. Another event occurring in different brain pathological conditions is the increase of the extracellular ATP levels, which is now recognized as a danger and harmful signal in the brain, as heralded by the ability of P2 receptors (P2Rs) to affect a wide range of brain disorders. Yet, how ATP and P2R contribute to neurodegeneration remains poorly defined. For that purpose, we now examined the contribution of extracellular ATP and P2Rs to glutamate-induced neurodegeneration. We found both in vitro and in vivo that ATP/ADP through the activation of P2Y1R contributes to glutamate-induced neuronal death in the rat hippocampus. We found in cultured rat hippocampal neurons that the exposure to glutamate (100 µM) for 30 min triggers a sustained increase of extracellular ATP levels, which contributes to NMDA receptor (NMDAR)-mediated hippocampal neuronal death through the activation of P2Y1R. We also determined that P2Y1R is involved in excitotoxicity in vivo as the blockade of P2Y1R significantly attenuated rat hippocampal neuronal death upon the systemic administration of kainic acid or upon the intrahippocampal injection of quinolinic acid. This contribution of P2Y1R fades with increasing intensity of excitotoxic conditions, which indicates that P2Y1R is not contributing directly to neurodegeneration, rather behaving as a catalyst decreasing the threshold from which glutamate becomes neurotoxic. Moreover, we unraveled that such excitotoxicity process began with an early synaptotoxicity that was also prevented/attenuated by the antagonism of P2Y1R, both in vitro and in vivo. This should rely on the observed glutamate-induced calpain-mediated axonal cytoskeleton damage, most likely favored by a P2Y1R-driven increase of NMDAR-mediated Ca2+ entry selectively in axons. This may constitute a degenerative mechanism shared by different brain diseases, particularly relevant at initial pathogenic stages.

Aß42-mediated proteasome inhibition and associated tau pathology in hippocampus are governed by a lysosomal response involving cathepsin B: Evidence for protective crosstalk between protein clearance pathways.

Impaired protein clearance likely increases the risk of protein accumulation disorders including Alzheimer's disease (AD). Protein degradation through the proteasome pathway decreases with age and in AD brains, and the Aß42 peptide has been shown to impair proteasome function in cultured cells and in a cell-free model. Here, Aß42 was studied in brain tissue to measure changes in protein clearance pathways and related secondary pathology. Oligomerized Aß42 (0.5-1.5 µM) reduced proteasome activity by 62% in hippocampal slice cultures over a 4-6-day period, corresponding with increased tau phosphorylation and reduced synaptophysin levels. Interestingly, the decrease in proteasome activity was associated with a delayed inverse effect, >2-fold increase, regarding lysosomal cathepsin B (CatB) activity. The CatB enhancement did not correspond with the Aß42-mediated phospho-tau alterations since the latter occurred prior to the CatB response. Hippocampal slices treated with the proteasome inhibitor lactacystin also exhibited an inverse effect on CatB activity with respect to diminished proteasome function. Lactacystin caused earlier CatB enhancement than Aß42, and no correspondence was evident between up-regulated CatB levels and the delayed synaptic pathology indicated by the loss of pre- and postsynaptic markers. Contrasting the inverse effects on the proteasomal and lysosomal pathways by Aß42 and lactacystin, such were not found when CatB activity was up-regulated two-fold with Z-Phe-Ala-diazomethylketone (PADK). Instead of an inverse decline, proteasome function was increased marginally in PADK-treated hippocampal slices. Unexpectedly, the proteasomal augmentation was significantly pronounced in Aß42-compromised slices, while absent in lactacystin-treated tissue, resulting in >2-fold improvement for nearly complete recovery of proteasome function by the CatB-enhancing compound. The PADK treatment also reduced Aß42-mediated tau phosphorylation and synaptic marker declines, corresponding with the positive modulation of both proteasome activity and the lysosomal CatB enzyme. These findings indicate that proteasomal stress contributes to AD-type pathogenesis and that governing such pathology occurs through crosstalk between the two protein clearance pathways.

Potential Alzheimer's Disease Therapeutics Among Weak Cysteine Protease Inhibitors Exhibit Mechanistic Differences Regarding Extent of Cathepsin B Up-Regulation and Ability to Block Calpain.

Cysteine protease inhibitors have long been part of drug discovery programs for Alzheimer's disease (AD), traumatic brain injury (TBI), and other disorders. Select inhibitors reduce accumulating proteins and AD pathology in mouse models. One such compound, Z-Phe-Aladiazomethylketone (PADK), exhibits a very weak IC50 (9-11 µM) towards cathepsin B (CatB), but curiously PADK causes marked up-regulation of the Aß-degrading CatB and improves spatial memory. Potential therapeutic and weak inhibitor E64d (14 µM IC50) also up-regulates CatB. PADK and E64d were compared regarding the blockage of calcium-induced cytoskeletal deterioration in brain samples, monitoring the 150-kDa spectrin breakdown product (SBDP) known to be produced by calpain. PADK had little to no effect on SBDP production at 10-100 µM. In contrast, E64d caused a dose-dependent decline in SBDP levels with an IC50 of 3-6 µM, closely matching its reported potency for inhibiting µ-calpain. Calpain also cleaves the cytoskeletal organizing protein gephyrin, producing 49-kDa (GnBDP49) and 18-kDa (GnBDP18) breakdown products. PADK had no apparent effect on calcium-induced gephyrin fragments whereas E64d blocked their production. E64d also protected the parent gephyrin in correspondence with reduced BDP levels. The findings of this study indicate that PADK's positive and selective effects on CatB are consistent with human studies showing exercise elevates CatB and such elevation correlates with improved memory. On the other hand, E64d exhibits both marginal CatB enhancement and potent calpain inhibition. This dual effect may be beneficial for treating AD. Alternatively, the potent action on calpain-related pathology may explain E64d's protection in AD and TBI models.

Abnormal response of distal Schwann cells to denervation in a mouse model of motor neuron disease.

In several animal models of motor neuron disease, degeneration begins in the periphery. Clarifying the possible role of Schwann cells remains a priority. We recently showed that terminal Schwann cells (TSCs) exhibit abnormalities in postnatal mice that express mutations of the SOD1 enzyme found in inherited human motor neuron disease. TSC abnormalities appeared before disease-related denervation commenced and the extent of TSC abnormality at P30 correlated with the extent of subsequent denervation. Denervated neuromuscular junctions (NMJs) were also observed that lacked any labeling for TSCs. This suggested that SOD1 TSCs may respond differently than wildtype TSCs to denervation which remain at denervated NMJs for several months. In the present study, the response of SOD1 TSCs to experimental denervation was examined. At P30 and P60, SC-specific S100 labeling was quickly lost from SOD1 NMJs and from preterminal regions. Evidence indicates that this loss eventually becomes complete at most SOD1 NMJs before reinnervation occurs. The loss of labeling was not specific for S100 and did not depend on loss of activity. Although some post-denervation labeling loss occurred at wildtype NMJs, this loss was never complete. Soon after denervation, large cells appeared near SOD1 NMJ bands which colabeled for SC markers as well as for activated caspase-3 suggesting that distal SOD1 SCs may experience cell death following denervation. Denervated SOD1 NMJs viewed 7 days after denervation with the electron microscope confirmed the absence of TSCs overlying endplates. These observations demonstrate that SOD1 TSCs and distal SCs respond abnormally to denervation. This behavior can be expected to hinder reinnervation and raises further questions concerning the ability of SOD1 TSCs to support normal functioning of motor terminals.

Purkinje neuron Ca2+ influx reduction rescues ataxia in SCA28 model.

Spinocerebellar ataxia type 28 (SCA28) is a neurodegenerative disease caused by mutations of the mitochondrial protease AFG3L2. The SCA28 mouse model, which is haploinsufficient for Afg3l2, exhibits a progressive decline in motor function and displays dark degeneration of Purkinje cells (PC-DCD) of mitochondrial origin. Here, we determined that mitochondria in cultured Afg3l2-deficient PCs ineffectively buffer evoked Ca²âº peaks, resulting in enhanced cytoplasmic Ca²âº concentrations, which subsequently triggers PC-DCD. This Ca²âº-handling defect is the result of negative synergism between mitochondrial depolarization and altered organelle trafficking to PC dendrites in Afg3l2-mutant cells. In SCA28 mice, partial genetic silencing of the metabotropic glutamate receptor mGluR1 decreased Ca²âº influx in PCs and reversed the ataxic phenotype. Moreover, administration of the ß-lactam antibiotic ceftriaxone, which promotes synaptic glutamate clearance, thereby reducing Ca²âº influx, improved ataxia-associated phenotypes in SCA28 mice when given either prior to or after symptom onset. Together, the results of this study indicate that ineffective mitochondrial Ca²âº handling in PCs underlies SCA28 pathogenesis and suggest that strategies that lower glutamate stimulation of PCs should be further explored as a potential treatment for SCA28 patients.

Slice Culture Method for Studying Migration of Neuronal Progenitor Cells Derived from Human Embryonic Stem Cells (hESC).

In this unit we describe an overlay brain slice culture assay for studying migration of transgenic neurospheres derived from human embryonic stem cells (hESC). Neuronal progenitor cells were generated from hESC by derivation of embryoid bodies and rosettes. Rosettes were transfected using the PiggyBac transposon system with either control plasmids (GFP) or plasmid encoding a gene important for migration of neuronal progenitor cells, Doublecortin (DCX). Transfected cells were subsequently grown in low-adhesion plates to generate transgenic human neurospheres (t-hNS). Organotypic slice cultures were prepared from postnatal rat forebrain and maintained using the interface method, before transfected t-hNS were overlaid below the cortex of each hemisphere. After 1 to 5 days, forebrain slices were fixed and processed for immunofluorescence. The distance at which cells migrated from the center of neurospheres to the host forebrain tissue was measured using Image J software. This protocol provides details for using the slice culture method for studying migration and integration of human neuronal cells into the host brain tissue.

Z-Phe-Ala-diazomethylketone (PADK) disrupts and remodels early oligomer states of the Alzheimer disease Aß42 protein.

The oligomerization of the amyloid-ß protein (Aß) is an important event in Alzheimer disease (AD) pathology. Developing small molecules that disrupt formation of early oligomeric states of Aß and thereby reduce the effective amount of toxic oligomers is a promising therapeutic strategy for AD. Here, mass spectrometry and ion mobility spectrometry were used to investigate the effects of a small molecule, Z-Phe-Ala-diazomethylketone (PADK), on the Aß42 form of the protein. The mass spectrum of a mixture of PADK and Aß42 clearly shows that PADK binds directly to Aß42 monomers and small oligomers. Ion mobility results indicate that PADK not only inhibits the formation of Aß42 dodecamers, but also removes preformed Aß42 dodecamers from the solution. Electron microscopy images show that PADK inhibits Aß42 fibril formation in the solution. These results are consistent with a previous study that found that PADK has protective effects in an AD transgenic mouse model. The study of PADK and Aß42 provides an example of small molecule therapeutic development for AD and other amyloid diseases.

Nuclear translocation and calpain-dependent reduction of Bcl-2 after neonatal cerebral hypoxia-ischemia.

Apoptosis-related mechanisms are important in the pathophysiology of hypoxic-ischemic injury in the neonatal brain. Caspases are the major executioners of apoptosis, but there are a number of upstream players that influence the cell death pathways. The Bcl-2 family proteins are important modulators of mitochondrial permeability, working either to promote or prevent apoptosis. In this study we focused on the anti-apoptotic Bcl-2 protein after neonatal cerebral hypoxia-ischemia (HI) in 8-day-old rats. Bcl-2 translocated to nuclei and accumulated there over the first 24h of reperfusion after HI, as judged by immunohistochemistry and immuno-electron microscopy. We also found that the total level of Bcl-2 decreased after HI in vivo and after ionophore challenge in cultured human neuroblastoma (IMR-32) cells in vitro. Furthermore, the Bcl-2 reduction was calpain-dependent, because it could be prevented by the calpain inhibitor CX295 both in vivo and in vitro, suggesting cross-talk between excitotoxic and apoptotic mechanisms.

Human neural precursor cells continue to proliferate and exhibit low cell death after transplantation to the injured rat spinal cord.

During the last decade, the interest in stem and progenitor cells, and their applications in spinal cord injuries have steadily increased. However, little is known about proliferation and cell death mechanisms in these cells after transplantation to the spinal cord. The aim of the present project was to study cell turn-over, i.e. total cell number, with time course of proliferation and cell death, in human neural precursor cells (NPCs) after transplantation to the injured rat spinal cord. Immunodeficient rats were subjected to lateral clip compression injuries, transplanted with neurospheres of human forebrain-derived NPCs two weeks after lesion, and sacrificed after 6 h, 1, 3, 10, or 21 days. Cell death was assessed by quantifying human cells immunoreactive for active caspase-3 and calpain 1-dependent fodrin breakdown products (FBDP). The results showed that after an initial drop, the number of implanted cells increased over time after transplantation. Cell proliferation was substantial, with 34% of human cells being immunoreactive for proliferating cell nuclear antigen at 6 h, but which declined over the next few days. The fractions of caspase-3-, and FBDP-immunoreactive cells were remarkably low, together representing 18% of all human cells at 6 h, and rapidly decreasing the next few days. Our results show that already 10 days after spinal cord transplantation of human NPCs as intact neurospheres, the number of human cells exceeded the initially implanted, which was the result of marked cell proliferation in combination with a low rate of apoptotic and non-apoptotic cell death taking place early after transplantation.

Protein kinase C is a common component of CGRP receptor desensitization induced by distinct agonists.

The calcitonin gene-related peptide (CGRP) is a neuropeptide involved in vasodilation and other physiological functions throughout the body. The receptor for CGRP has been cloned and well studied, but the mechanism of CGRP receptor desensitization has not been fully elucidated. In the present study, we evaluated the kinetics for agonist-mediated desensitization of the adenylate cyclase response in human neuroblastoma SK-N-MC cells. Distinct CGRP receptor agonists were used, including alpha and beta isoforms of CGRP, the linearized derivative cys(Et)2,7 alphaCGRP, adrenomedullin, and adrenomedullin 2. betaCGRP was 4-600 times more potent at desensitizing the cAMP production as compared to the other receptor-activating ligands, and all of the desensitization effects were blocked by a CGRP receptor antagonist. Although the different agonists vary in their ability to induce functional desensitization, a pretreatment/washout sequence with each peptide was able to reduce the activation potency of the other members of the calcitonin/CGRP peptide family. Next we tested whether the desensitizing effects of the distinct peptides involve protein kinase C (PKC) or protein kinase A (PKA). A PKC inhibitor, Ro 31-8220, concentration-dependently reduced the desensitization induced by the 5 CGRP receptor agonists, while having little effect on their desensitization potencies. PKA inhibitors KT-5720 and H-89, on the other hand, showed little effect on the induced level of desensitization. The findings indicate that functional desensitization is produced by distinct peptides acting through the active site of CGRP receptors, and involves the activation of PKC as a common component necessary to achieve maximal desensitization of receptor signaling.

Desensitization and re-sensitization of CGRP receptor function in human neuroblastoma SK-N-MC cells.

Calcitonin gene-related peptide (CGRP) is a highly potent vasodilator known to be involved in many physiological functions within the cardiovascular, gastrointestinal, immune, and nervous systems. This study assessed the desensitization of CGRP receptors by measuring agonist-mediated activation of adenylate cyclase in a model system employing human neuroblastoma-derived SK-N-MC cells. In these cells, we demonstrated that pre-incubation with CGRP (20 nM) induces a rapid desensitization of CGRP signaling (t(1/2)

Involvement of calpain in AMPA-induced toxicity to rat cerebellar Purkinje neurons.

AMPA receptor-elicited excitotoxicity is manifested as both a type of programmed cell death termed dark cell degeneration and edematous necrosis, both of which are linked to increased intracellular Ca2+ concentration. The appearance of marked cytoskeletal changes in response to abusive AMPA receptor activation, coupled with increased intracellular Ca2+ concentration suggests activation of various destructive enzymes such as calpains, a family of Ca2+-dependent cysteine proteases. Since calpains and AMPA have been linked to both necrotic cell death and programmed cell death, we sought to determine the role of calpains in mediating both types of AMPA-mediated toxicity in Purkinje neurons of the cerebellum. These studies employed immunohistochemistry for cytoskeletal breakdown products of calpain activity coupled with confocal microscopy and pharmacological interventions with calpain and AMPA receptor antagonists. The present study identifies an early involvement of calpains in mediating AMPA-induced dark cell degeneration, but not edematous necrosis, based upon the effectiveness of AMPA to generate calpain-derived alpha-spectrin cleavage products in cerebellar Purkinje neurons that express dark cell degeneration, and the effectiveness of calpain antagonists, PD150606 and MDL28170, to attenuate AMPA-induced dark cell degeneration. Moreover, the AMPA receptor antagonist CNQX, a proven inhibitor of AMPA-elicited dark cell degeneration, also blocked AMPA-induced increases in alpha-spectrin, further suggesting interplay between abusive AMPA receptor activation, calpain activation and dark cell degeneration. Since AMPA-induced dark cell degeneration possesses morphological changes that resemble those that occur following brain ischemia in vivo, hypoglycemia, or extended seizure episodes, the involvement of calpains as mediators of cell death is potentially far reaching and has widespread therapeutic implications in numerous CNS disorders.

Cannabinoid drugs and enhancement of endocannabinoid responses: strategies for a wide array of disease states.

The endogenous cannabinoid system has revealed potential avenues to treat many disease states. Medicinal indications of cannabinoid drugs including compounds that result in enhanced endocannabinoid responses (EER) have expanded markedly in recent years. The wide range of indications covers chemotherapy complications, tumor growth, addiction, pain, multiple sclerosis, glaucoma, inflammation, eating disorders, age-related neurodegenerative disorders, as well as epileptic seizures, traumatic brain injury, cerebral ischemia, and other excitotoxic insults. Indeed, a great effort has led to the discovery of agents that selectively activate the cannabinoid system or that enhance the endogenous pathways of cannabinergic signaling. The endocannabinoid system is comprised of three primary components: (i) cannabinoid receptors, (ii) endocannabinoid transport system, and (iii) hydrolysis enzymes that break down the endogenous ligands. Two known endocannabinoids, anandamide (AEA) and 2-arachidonoyl glycerol (2-AG), are lipid molecules that are greatly elevated in response to a variety of pathological events. This increase in endocannabinoid levels is suggested to be part of an on-demand compensatory response. Furthermore, activation of signaling pathways mediated by the endogenous cannabinoid system promotes repair and cell survival. Similar cell maintenance effects are elicited by EER through inhibitors of the endocannabinoid deactivation processes (i.e., internalization and hydrolysis). The therapeutic potential of the endocannabinoid system has yet to be fully determined, and the number of medical maladies that may be treated will likely continue to grow. This review will underline studies that demonstrate medicinal applications for agents that influence the endocannabinoid system.

The critical role of calpain versus caspase activation in excitotoxic injury induced by nitric oxide.

The pathogenesis of various acute and chronic neurodegenerative disorders has been linked to excitotoxic processes and excess generation of nitric oxide. We investigated the deleterious effects of calpain activation in nitric oxide-elicited neuronal apoptosis. In this model, nitric oxide triggers apoptosis of murine cerebellar granule cells by an excitotoxic mechanism requiring glutamate exocytosis and receptor-mediated intracellular calcium overload. Here, we found that calcium-dependent cysteine proteases, calpains, were activated early in apoptosis of cerebellar granule cells exposed to nitric oxide. Release of the proapoptogenic factors cytochrome c and apoptosis-inducing factor from mitochondria preceded neuronal death. However, caspases-3 was not activated. We observed that procaspase-9 was cleaved by calpains to proteolytically inactive fragments. Inhibition of calpains by different synthetic calpain inhibitors or by adenovirally mediated expression of the calpastatin inhibitory domain prevented mitochondrial release of cytochrome c and apoptosis-inducing factor, calpain-specific proteolysis and neuronal apoptosis. We conclude that (i) signal transduction pathways exist that prevent the entry of neurons into a caspase-dependent death after mitochondrial release of cytochrome c and (ii) that calpain activation links nitric oxide-triggered excitotoxic events with the execution of caspase-independent apoptosis in neurons.

Biphasic NF-kappaB activation in the excitotoxic hippocampus.

Excitotoxic stimulation of NMDA receptors results in the activation of a variety of cellular responses. The inducible transcription factor NF-kappaB is known to be involved in excitotoxic responses by neurons. Here, we show that NF-kappaB activation occurs in a biphasic manner in hippocampal slices following a 20-min N-methyl- d-aspartate (NMDA) exposure. The biphasic activation profile consists of an early, rapid phase at 0.5-1 h post-insult, and a delayed phase evident 10-24 h post-insult. Endogenous inhibitors of NF-kappaB, IkappaBs, were examined for their involvement in the biphasic activation. IkappaBbeta exhibited marked degradation in response to the excitotoxity, while changes in the levels of IkappaBalpha and p105 isoforms were not detected. The initial decline in IkappaBbeta occurred in as little as 30 min post-NMDA exposure, coinciding with early NF-kappaB activity. A second, more gradual phase of IkappaBbeta degradation was also evident, possibly giving rise to the delayed activation of the transcription factor. While both phases of NF-kappaB activation were disrupted by the NMDA receptor antagonist AP5, they were distinct with regard to the composition of activated complexes and their responsiveness to altered culture conditions. The two phases of NF-kappaB activity also were associated with distinct gene regulation events. Up-regulation of bcl-2 message occurred early after the excitotoxic insult and remained up-regulated for an extended period. In contrast, bax message initially remained unchanged after the insult, but then exhibited an increase 24 h later, corresponding with the second phase of the NF-kappaB response. These results indicate that distinct phases of NF-kappaB activation are generated in the excitotoxic hippocampus, and that the phases may be involved in opposing cellular responses.

Death mechanisms in status epilepticus-generated neurons and effects of additional seizures on their survival.

Status epilepticus (SE) increases neurogenesis in the subgranular zone (SGZ) of the adult dentate gyrus, but many of the newborn cells die, partly through caspase-induced apoptosis. Here we provide immunohistochemical evidence indicating that the caspase-evoked death of the new neurons involves the mitochondrial but not the death-receptor-mediated pathway. Cytochrome c released from mitochondria was found in a subset of progenitor cell progeny, while Fas ligand and tumor necrosis factor 1 receptor-associated domain as well as the mitochondria-related, caspase-independent apoptosis-inducing factor were not detected. We also show that additional seizures, induced at different stages during neuronal differentiation of progenitor cell progeny following SE, neither potentiate cell death mechanisms in the SGZ nor compromise the survival of the new cells. Thus, we found similar expression of cytochrome c, active caspase-3, caspase-cleaved PARP, and TUNEL/Hoechst-positive DNA fragmentation, as well as numbers of new cells in the SGZ in rats exposed to additional seizures at days 6 and 7 or days 33 and 34 following SE as in control animals only subjected to SE. We propose that the degree of survival of newly generated neurons is determined primarily by the initial SE insult and the ensuing pathology in the tissue environment, whereas spontaneous seizures play a minor role.

Cyclosporin A prevents calpain activation despite increased intracellular calcium concentrations, as well as translocation of apoptosis-inducing factor, cytochrome c and caspase-3 activation in neurons exposed to transient hypoglycemia.

Blockade of mitochondrial permeability transition protects against hypoglycemic brain damage. To study the mechanisms downstream from mitochondria that may cause neuronal death, we investigated the effects of cyclosporin A on subcellular localization of apoptosis-inducing factor and cytochrome c, activation of the cysteine proteases calpain and caspase-3, as well as its effect on brain extracellular calcium concentrations. Redistribution of cytochrome c occurred at 30 min of iso-electricity, whereas translocation of apoptosis-inducing factor to nuclei occurred at 30 min of recovery following 30 min of iso-electricity. Active caspase-3 and calpain-induced fodrin breakdown products were barely detectable in the dentate gyrus and CA1 region of the hippocampus of rat brain exposed to 30 or 60 min of insulin-induced hypoglycemia. However, 30 min or 3 h after recovery of blood glucose levels, fodrin breakdown products and active caspase-3 markedly increased, concomitant with a twofold increase in caspase-3-like enzymatic activity. When rats were treated with neuroprotective doses of cyclosporin A, but not with FK 506, the redistribution of apoptosis-inducing factor and cytochrome c was reduced and fodrin breakdown products and active caspase-3 immuno-reactivity was diminished whereas the extracellular calcium concentration was unaffected. We conclude that hypoglycemia leads to mitochondrial permeability transition which, upon recovery of energy metabolism, mediates the activation of caspase-3 and calpains, promoting cell death.

Lysosomal activation is a compensatory response against protein accumulation and associated synaptopathogenesis--an approach for slowing Alzheimer disease?

Previous reports suggest that age-related lysosomal disturbances contribute to Alzheimer-type accumulations of protein species, blockage of axonal/dendritic transport, and synaptic decline. Here, we tested the hypothesis that lysosomal enzymes are upregulated as a compensatory response to pathogenic protein accumulation. In the hippocampal slice model, tau deposits and amyloidogenic fragments induced by the lysosomal inhibitor chloroquine were accompanied by disrupted microtubule integrity and by corresponding declines in postsynaptic glutamate receptors and the presynaptic marker synaptophysin. In the same slices, cathepsins B, D, and L, beta-glucuronidase, and elastase were upregulated by 70% to 135%. To address whether this selective activation of the lysosomal system represents compensatory signaling, N-Cbz-L-phenylalanyl-L-alanyl-diazomethylketone (PADK) was used to enhance the lysosome response, generating 4- to 8-fold increases in lysosomal enzymes. PADK-mediated lysosomal modulation was stable for weeks while synaptic components remained normal. When PADK and chloroquine were co-infused, chloroquine no longer increased cellular tau levels. To assess pre-existing pathology, chloroquine was applied for 6 days after which its removal resulted in continued degeneration. In contrast, enhancing lysosomal activation by replacing chloroquine after 6 days with PADK led to clearance of accumulated protein species and restored microtubule integrity. Transport processes lost during chloroquine exposure were consequently re-established, resulting in marked recovery of synaptic components. These data indicate that compensatory activation of lysosomes follows protein accumulation events, and that lysosomal modulation represents a novel approach for treating Alzheimer disease and other protein deposition diseases.