An important pathological hallmark of Alzheimer's disease (AD) is the deposition of amyloid‐beta (Aβ) peptides in the brain parenchyma, leading to neuronal death and impaired learning and memory. The protease γ‐secretase is responsible for the intramembrane proteolysis of the amyloid‐β precursor protein (APP), which leads to the production of the toxic Aβ peptides. Thus, an attractive therapeutic strategy to treat AD is the modulation of the γ‐secretase activity, to reduce Aβ42 production. Because phosphorylation of proteins is a post‐translational modification known to modulate the activity of many different enzymes, we used electrospray (LC‐MS/MS) mass spectrometry to identify new phosphosites on highly purified human γ‐secretase. We identified 11 new single or double phosphosites in two well‐defined domains of Presenilin‐1 (PS1), the catalytic subunit of the γ‐secretase complex. Next, mutagenesis and biochemical approaches were used to investigate the role of each phosphosite in the maturation and activity of γ‐secretase. Together, our results suggest that the newly identified phosphorylation sites in PS1 do not modulate γ‐secretase activity and the production of the Alzheimer's Aβ peptides. Individual PS1 phosphosites shall probably not be considered therapeutic targets for reducing cerebral Aβ plaque formation in AD.
Glutamate transport is a critical process in the brain that maintains low extracellular levels of glutamate to allow for efficient neurotransmission and prevent excitotoxicity. Loss of glutamate transport function is implicated in epilepsy, traumatic brain injury, and amyotrophic lateral sclerosis. It remains unclear whether or not glutamate transport can be modulated in these disease conditions to improve outcome. Here, we show that sirtuin (SIRT)4, a mitochondrial sirtuin, is up‐regulated in response to treatment with the potent excitotoxin kainic acid. Loss of SIRT4 leads to a more severe reaction to kainic acid and decreased glutamate transporter expression and function in the brain. Together, these results indicate a critical and novel stress response role for SIRT4 in promoting proper glutamate transport capacity and protecting against excitotoxicity.
Naked mole‐rats (NMRs) are the oldest‐living rodent species. Living underground in a thermally stable ecological niche, NMRs have evolved certain exceptional traits, resulting in sustained health spans, negligible cognitive decline, and a pronounced resistance to age‐related disease. Uncovering insights into mechanisms underlying these extraordinary traits involved in successful aging may conceivably provide crucial clues to extend the human life span and health span. One of the most fundamental processes inside the cell is the production of ATP, which is an essential fuel in driving all other energy‐requiring cellular activities. Not surprisingly, a prominent hallmark in age‐related diseases, such as neurodegeneration and cancer, is the impairment and dysregulation of metabolic pathways. Using a two‐dimensional polyacrylamide gel electrophoresis proteomics approach, alterations in expression and phosphorylation levels of metabolic proteins in the brains of NMRs, aged 2–24 years, were evaluated in an age‐dependent manner. We identified 13 proteins with altered levels and/or phosphorylation states that play key roles in various metabolic pathways including glycolysis, β‐oxidation, the malate‐aspartate shuttle, the Tricarboxylic Acid Cycle (TCA) cycle, the electron transport chain, NADPH production, as well as the production of glutamate. New insights into potential pathways involved in metabolic aspects of successful aging have been obtained by the identification of key proteins through which the NMR brain responds and adapts to the aging process and how the NMR brain adapted to resist age‐related degeneration.
Intravenous immunoglobulin (IVIG) contains anti‐amyloid‐β antibodies as well as antibodies providing immunomodulatory effects that may modify chronic inflammation in Alzheimer's disease. Answers to important questions about IVIG transport into the central nervous system and assessments of any impact amyloid‐β has on this transport can be provided by in vitro models of the blood–brain barrier. In this study, amyloid‐β[1‐42] was pre‐aggregated into fibrillar or oligomeric structures, and various concentrations were incubated in the brain side of the blood–brain barrier model, followed by IVIG administration in the blood side at the therapeutically relevant concentrations of 5 and 20 mg/mL. IVIG accumulated in the brain side at physiologically relevant levels, with amyloid‐β pre‐incubation increasing IVIG accumulation. The increased transport effect was dependent on amyloid‐β structural form, amyloid‐β concentration, and IVIG dose. IVIG was found to decrease monocyte chemotactic protein‐1 levels 6.5–18% when low amyloid‐β levels were present and increase levels 4.2–23% when high amyloid‐β levels were present. Therefore, the presence, concentration, and structure of amyloid‐β plays an important role in the effect of IVIG therapy in the brain.
Thrombolysis with tissue plasminogen activator (tPA) increases matrix metalloproteinase‐9 (MMP‐9) activity in the ischemic brain, which exacerbates blood‐brain barrier injury and increases the risk of symptomatic cerebral hemorrhage. The mechanism through which tPA enhances MMP‐9 activity is not well understood. Here we report an important role of caveolin‐1 in mediating tPA‐induced MMP‐9 synthesis. Brain microvascular endothelial cell line bEnd3 cells were incubated with 5 or 20 μg/ml tPA for 24 hrs before analyzing MMP‐9 levels in the conditioned media and cellular extracts by gelatin zymography. tPA at a dose of 20 μg/mL tPA, but not 5 μg/mL, significantly increased MMP‐9 level in cultured media while decreasing it in cellular extracts. Concurrently, tPA treatment induced a 2.3‐fold increase of caveolin‐1 protein levels in endothelial cells. Interestingly, knockdown of Cav‐1 with siRNA inhibited tPA‐induced MMP‐9 mRNA up‐regulation and MMP‐9 increase in the conditioned media, but did not affect MMP‐9 decrease in cellular extracts. These results suggest that caveolin‐1 critically contributes to tPA‐mediated MMP‐9 up‐regulation, but may not facilitate MMP‐9 secretion in endothelial cells.
Vanishing white matter (VWM) is a recessive neurodegenerative disease caused by mutations in translation initiation factor eIF2B and leading to progressive brain myelin deterioration, secondary axonal damage, and death in early adolescence. Eif2b5R132H/R132H mice exhibit delayed developmental myelination, mild early neurodegeneration and a robust remyelination defect in response to cuprizone‐induced demyelination. In the current study we used Eif2b5R132H/R132H mice for mass‐spectrometry analyses, to follow the changes in brain protein abundance in normal‐ versus cuprizone‐diet fed mice during the remyelination recovery phase. Analysis of proteome profiles suggested that dysregulation of mitochondrial functions, altered proteasomal activity and impaired balance between protein synthesis and degradation play a role in VWM pathology. Consistent with these findings, we detected elevated levels of reactive oxygen species in mutant‐derived primary fibroblasts and reduced 20S proteasome activity in mutant brain homogenates. These observations highlight the importance of tight translational control to precise coordination of processes involved in myelin formation and regeneration and point at cellular functions that may contribute to VWM pathology.
Parkinson's disease (PD) and diabetes belong to the most common neurodegenerative and metabolic syndromes, respectively. Epidemiological links between these two frequent disorders are controversial. The neuropathological hallmarks of PD are protein aggregates composed of amyloid‐like fibrillar and serine‐129 phosphorylated (pS129) α‐synuclein (AS). To study if diet‐induced obesity could be an environmental risk factor for PD‐related α‐synucleinopathy, transgenic (TG) mice, expressing the human mutant A30P AS in brain neurons, were subjected after weaning to a lifelong high fat diet (HFD). The TG mice became obese and glucose‐intolerant, as did the wild‐type controls. Upon aging, HFD significantly accelerated the onset of the lethal locomotor phenotype. Coinciding with the premature movement phenotype and death, HFD accelerated the age of onset of brainstem α‐synucleinopathy as detected by immunostaining with antibodies against pathology‐associated pS129. Amyloid‐like neuropathology was confirmed by thioflavin S staining. Accelerated onset of neurodegeneration was indicated by Gallyas silver‐positive neuronal dystrophy as well as astrogliosis. Phosphorylation of the activation sites of the pro‐survival signaling intermediate Akt was reduced in younger TG mice after HFD. Thus, diet‐induced obesity may be an environmental risk factor for the development of α‐synucleinopathies. The molecular and cellular mechanisms remain to be further elucidated.
Chronic stress represents a major environmental risk factor for mood disorders in vulnerable individuals. The neurobiological mechanisms underlying these disorders involve serotonergic and endocannabinoid systems. In this study, we have investigated the relationships between these two neurochemical systems in emotional control using genetic and imaging tools. CB1 cannabinoid receptor knockout mice (KO) and wild‐type littermates (WT) were exposed to chronic restraint stress. Depressive‐like symptoms (anhedonia and helplessness) were produced by chronic stress exposure in WT mice. CB1 KO mice already showed these depressive‐like manifestations in non‐stress conditions and the same phenotype was observed after chronic restraint stress. Chronic stress similarly impaired long‐term memory in both genotypes. In addition, brain levels of serotonin transporter (5‐HTT) were assessed using positron emission tomography. Decreased brain 5‐HTT levels were revealed in CB1 KO mice under basal conditions, as well as in WT mice after chronic stress. Our results show that chronic restraint stress induced depressive‐like behavioral alterations and brain changes in 5‐HTT levels similarly to those revealed in CB1 KO mice in non‐stressed conditions. These results underline the relevance of chronic environmental stress on serotonergic and endocannabinoid transmission for the development of depressive symptoms.
The parkin‐associated endothelial‐like receptor (PAELR, GPR37) is an orphan G protein‐coupled receptor that interacts with and is degraded by parkin‐mediated ubiquitination. Mutations in parkin are thought to result in PAELR accumulation and increase neuronal cell death in Parkinson's disease. In this study, we find that the protein interacting with C‐kinase (PICK1) interacts with PAELR. Specifically, the Postsynaptic density protein‐95/Discs large/ZO‐1 (PDZ) domain of PICK1 interacted with the last three residues of the c‐terminal (ct) located PDZ motif of PAELR. Pull‐down assays indicated that recombinant and native PICK1, obtained from heterologous cells and rat brain tissue, respectively, were retained by a glutathione S‐transferase fusion of ct‐PAELR. Furthermore, coimmunoprecipitation studies isolated a PAELR‐PICK1 complex from transiently transfected cells. PICK1 interacts with parkin and our data showed that PICK1 reduces PAELR expression levels in transiently transfected heterologous cells compared to a PICK1 mutant that does not interact with PAELR. Finally, PICK1 over‐expression in HEK293 cells reduced cell death induced by PAEALR over‐expression during rotenone treatment and these effects of PICK1 were attenuated during inhibition of the proteasome. These results suggest a role for PICK1 in preventing PAELR‐induced cell toxicity.
Soluble N‐ethylmaleimide sensitive factor attachment protein receptors (SNAREs) are crucial for exocytosis, trafficking, and neurite outgrowth, where vesicular SNAREs are directed toward their partner target SNAREs: synaptosomal‐associated protein of 25 kDa and syntaxin. SNARE proteins are normally membrane bound, but can be cleaved and released by botulinum neurotoxins. We found that botulinum proteases types C and D can easily be transduced into endocrine cells using DNA‐transfection reagents. Following administration of the C and D proteases into normally refractory Neuro2A neuroblastoma cells, the SNARE proteins were cleaved with high efficiency within hours. Remarkably, botulinum protease exposures led to cytotoxicity evidenced by spectrophotometric assays and propidium iodide penetration into the nuclei. Direct delivery of SNARE fragments into the neuroblastoma cells reduced viability similar to botulinum proteases' application. We observed synergistic cytotoxic effects of the botulinum proteases, which may be explained by the release and interaction of soluble SNARE fragments. We show for the first time that previously observed cytotoxicity of botulinum neurotoxins/C in neurons could be achieved in cells of neuroendocrine origin with implications for medical uses of botulinum preparations.
Tumor necrosis factor alpha (TNF‐α) is known to exacerbate ischemic brain injury; however, the mechanism is unknown. Previous studies have evaluated the effects of TNF‐α on neurons with long exposures to high doses of TNF‐α, which is not pathophysiologically relevant. We characterized the rapid effects of TNF‐α on basal respiration, ATP production, and maximal respiration using pathophysiologically relevant, post‐stroke concentrations of TNF‐α. We observed a reduction in mitochondrial function as early as 1.5 h after exposure to low doses of TNF‐α, followed by a decrease in cell viability in HT‐22 cells and primary neurons. Subsequently, we used the HT‐22 cell line to determine the mechanism by which TNF‐α causes a rapid and profound reduction in mitochondrial function. Pre‐treating with TNF‐R1 antibody, but not TNF‐R2 antibody, ameliorated the neurotoxic effects of TNF‐α, indicating that TNF‐α exerts its neurotoxic effects through TNF‐R1. We observed an increase in caspase 8 activity and a decrease in mitochondrial membrane potential after exposure to TNF‐α which resulted in a release of cytochrome c from the mitochondria into the cytosol. These novel findings indicate for the first time that an acute exposure to pathophysiologically relevant concentrations of TNF‐α has neurotoxic effects mediated by a rapid impairment of mitochondrial function.
Ammonia is considered to be the main neurotoxin responsible for hepatic encephalopathy resulting from liver failure. Liver failure has been reported to alter expression and activity of P‐glycoprotein (P‐gp) and multidrug resistance‐associated protein 2 (Mrp2) at the blood–brain barrier (BBB). The aim of this study was to investigate whether ammonia is involved in abnormalities of expression and activity of P‐gp and Mrp2 at the BBB. Hyperammonemic rats were developed by an intraperitoneal injection of ammonium acetate (NH4Ac, 4.5 mmol/kg). Results showed that Mrp2 function markedly increased in cortex and hippocampus of rats at 6 h following NH4Ac administration. Significant increase in function of P‐gp was observed in hippocampus of rats. Meanwhile, such alterations were in line with the increase in mRNA and protein levels of P‐gp and Mrp2. Significant increase in levels of nuclear amount of nuclear factor‐κB (NF‐κB) p65 was also observed. Primarily cultured rat brain microvessel endothelial cells (rBMECs) were used for in vitro study. Data indicated that 24 h exposure to ammonia significantly increased function and expression of P‐gp and Mrp2 in rBMECs, accompanied with activation of NF‐κB. Furthermore, such alterations induced by ammonia were reversed by NF‐κB inhibitor. In conclusion, this study demonstrates that hyperammonemia increases the function and expression of P‐gp and Mrp2 at the BBB via activating NF‐κB pathway.
Sports‐related head impact and injury has become a very highly contentious public health and medico‐legal issue. Near‐daily news accounts describe the travails of concussed athletes as they struggle with depression, sleep disorders, mood swings, and cognitive problems. Some of these individuals have developed chronic traumatic encephalopathy, a progressive and debilitating neurodegenerative disorder. Animal models have always been an integral part of the study of traumatic brain injury in humans but, historically, they have concentrated on acute, severe brain injuries. This review will describe a small number of new and emerging animal models of sports‐related head injury that have the potential to increase our understanding of how multiple mild head impacts, starting in adolescence, can have serious psychiatric, cognitive and histopathological outcomes much later in life.
The positron emission tomography (PET) ligand 11C‐labeled Pittsburgh compound B (PIB) is used to image β‐amyloid (Aβ) deposits in the brains of living subjects with the intent of detecting early stages of Alzheimer's disease (AD). However, deposits of human‐sequence Aβ in amyloid precursor protein transgenic mice and non‐human primates bind very little PIB. The high stoichiometry of PIB:Aβ binding in human AD suggests that the PIB‐binding site may represent a particularly pathogenic entity and/or report local pathologic conditions. In this study, 3H‐PIB was employed to track purification of the PIB‐binding site in > 90% yield from frontal cortical tissue of autopsy‐diagnosed AD subjects. The purified PIB‐binding site comprises a distinct, highly insoluble subfraction of the Aβ in AD brain with low buoyant density because of the sodium dodecyl sulfate‐resistant association with a limited subset of brain proteins and lipids with physical properties similar to lipid rafts and to a ganglioside:Aβ complex in AD and Down syndrome brain. Both the protein and lipid components are required for PIB binding. Elucidation of human‐specific biological components and pathways will be important in guiding improvement of the animal models for AD and in identifying new potential therapeutic avenues.
Cellular interactions mediated by the neural cell adhesion molecule (NCAM) are critical in cell migration, differentiation and plasticity. Switching of the NCAM‐interaction mode, from adhesion to signalling, is determined by NCAM carrying a particular post‐translational modification, polysialic acid (PSA). Regulation of cell‐surface PSA‐NCAM is traditionally viewed as a direct consequence of polysialyltransferase activity. Taking advantage of the polysialyltransferase Ca2+‐dependent activity, we demonstrate in TE671 cells that downregulation of PSA‐NCAM synthesis constitutes a necessary but not sufficient condition to reduce cell‐surface PSA‐NCAM; instead, PSA‐NCAM turnover required internalization of the molecule into the cytosol. PSA‐NCAM internalization was specifically triggered by collagen in the extracellular matrix (ECM) and prevented by insulin‐like growth factor (IGF1) and insulin. Our results pose a novel role for IGF1 and insulin in controlling cell migration through modulation of PSA‐NCAM turnover at the cell surface.
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