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Background: Amyloid precursor protein (APP) processing is central to Alzheimer’s disease (AD) etiology. As early cognitive alterations in AD are strongly correlated to abnormal information processing due to increasing synaptic impairment, it is crucial to characterize how peptides generated through APP cleavage modulate synapse function. We previously described a novel APP processing pathway producing η-secretase-derived peptides (Aη) and revealed that Aη–α, the longest form of Aη produced by η-secretase and α-secretase cleavage, impaired hippocampal long-term potentiation (LTP) ex vivo and neuronal activity in vivo.
Methods: With the intention of going beyond this initial observation, we performed a comprehensive analysis to further characterize the effects of both Aη-α and the shorter Aη-β peptide on hippocampus function using ex vivo field electrophysiology, in vivo multiphoton calcium imaging, and in vivo electrophysiology.
Results: We demonstrate that both synthetic peptides acutely impair LTP at low nanomolar concentrations ex vivo and reveal the N-terminus to be a primary site of activity. We further show that Aη-β, like Aη–α, inhibits neuronal activity in vivo and provide confirmation of LTP impairment by Aη–α in vivo.
Conclusions: These results provide novel insights into the functional role of the recently discovered η-secretase-derived products and suggest that Aη peptides represent important, pathophysiologically relevant, modulators of hippocampal network activity, with profound implications for APP-targeting therapeutic strategies in AD.
To understand neurodegenerative diseases is one of the major challenges of the 21st century. This also includes Alzheimer´s disease (AD), which represents a chronic neurodegenerative disorder, with long preclinical and prodromal phases (approx. 20 years) and an average clinical duration of 8–10 years. In the early phase of this disease, patients show deterioration of memory, difficulties in finding the right words for everyday objects or mood swings. The risk of AD grows exponentially with age, doubling approximately every 5 to 6 years. AD may contribute to 60–70% of all dementia cases, being the most common cause of this disease. Dementia is one of the major causes of disability and dependency among older people worldwide. The causes of the sporadic form of AD with late onset (LOAD) are not yet known, but it seems to be a result of multiple factors. Neuropathological features are extracellular senile plaques, containing beta-amyloid peptides (Aβ) and intracellular neurofibrillary tangles, containing paired helical tau proteins, which have been associated with neuronal loss and atrophy of the cerebral cortex. Thus, misfolded proteins seem to contribute to the pathogenesis, but are not the only players in the disease process. Developing feasible therapies is difficult due to the multifactorial pathology of AD. Currently approved drugs only attenuate symptoms, but do not cure the disease. Research into AD also has had several failures in terms of developing disease-modifying therapies. Thus, new therapeutic targets in order to develop a causal therapy are desperately needed. Since AD starts many years far before the first symptoms occur, new scientific approaches focus on the early stage, which are discussed to be important in aging and the onset of AD. Today, the hypothesis of the advanced mitochondrial cascade becomes more and more the leading model for LOAD, integrating physiological aging as the main risk factor. Thus, new interventions targeting mitochondrial dysfunction are of substantial interest. Accordingly, the efficacy of Dimebon and TRO19622 to ameliorate mitochondrial dysfunction in cellular and murine models of AD were investigated. Dimebon (Latrepirdine) was, originally developed in Russia as an H1-antiallergic drug. It might specifically interfere with mechanisms relevant for the cognitive decline, especially by improving impaired mitochondrial function and/or dynamics in AD. TRO19622 (Olesoxim) has been identified in a phenotypic screening approach to promote the survival of primary motor neurons. Olesoxim is easily absorbed by cells and accumulates in mitochondria. Olesoxim’s mode of action is not fully understood, however it has been shown to modulate mitochondrial membranes and interact with the voltage-dependent anion channel (VDAC) and the translocator protein (TSPO; also known as PBR). Thereby it inhibits mitochondrial permeability transition. In this study, the effects of Aβ overproduction on mitochondrial function were investigated. The effects of Dimebon and Olesoxim were examined, using a HEK cell line stably transfected with the Swedish APP double mutation (HEKsw) and un-transfected control cells (HEKut). Mitochondrial membrane potential, ATP concentrations, and respirometry were measured. Western Blot analysis of marker proteins for fission & fusion, autophagy, mitogenesis and mPTP formation were performed. Confocal laser scanning microscopy was introduced as a novel method to visualize mitochondrial dynamics. Olesoxim was also tested in Thy-1-C57BJ/6-APPSL mice representing a murine model of AD. For the in vivo model mitochondria from brain tissue were isolated and dissociated brain cells were prepared to determine respiration, lipid peroxidation, MMP, and ATP-levels. Both, the in vitro and in vivo models were compared and discussed in relation to human post-mortem data. The research was conducted in frame of the EU-project entitled „MITOTARGET“ (Mitochondrial dysfunction in neurodegenerative diseases: towards new therapeutics) funded under FP7-Health (http://cordis.europa.eu/result/rcn/54471_en.html). HEKsw cells showed an overall reduction in the mitochondrial respiration, a significant lower MMP, and significantly reduced ATP levels compared to HEKut cells. Mitochondrial mass was equal in both cell lines. In addition most mitochondria in HEKsw cells showed truncated morphology, followed by punctuated mitochondria. Levels of the fission related protein Drp were significantly elevated in HEKsw cells whereas protein levels of fusion related OPA were strongly reduced, leading to a shift in the distribution pattern towards shorter mitochondria. Moreover, HEKsw cells showed reduced mitochondrial density. Protein levels of the translocase of the inner mitochondrial membrane (TIMM50) were strongly diminished in HEKsw cells. The OXPHOS machinery is located in the inner membrane, where the MMP is build up and ATP is generated. Reduced TIMM50 levels in HEKsw indicated a reduction of the inner mitochondrial membrane, which could explain the described deficits in OXPHOS, MMP, ATP and mitochondrial morphology and density. Concentration of both mPTP markers, the voltage-depended anion channel (VDAC) and the peripheral benzodiazepine receptor (PBR), were broadly increased in HEKsw cells. Thy1-APPSL transgenic mice were characterized as in vivo model of AD. Those mice are modified to express the human form of APP, containing both, the Swedish (KM670/671NL) and the London (V717L) double mutations under the murine Thy1 promotor. Beginning at the age of 3 months, Thy1-APPSL mice develop elevated Aβ levels and mitochondrial dysfunction. Mitochondria isolated from brains of Thy-1-C57BJ/6-APPSL mice showed significant impaired respiration, resulting in a reduced MMP. However, ATP levels in dissociated brain cells did not differ compared to controls. Protein levels of FIS were unchanged, whereas Drp levels were significantly increased. Levels of the mitochondrial fusion marker optic atrophie-1 (Opa) protein were significantly reduced. Peroxisome proliferation-activated receptor gamma coactivator 1-alpha (PGC1) is a transcription factor, which represents a master regulator of mitochondrial biogenesis. PGC1 expression was significantly elevated in brains of Thy-1-C57BJ/6-APPSL mice. However, mitochondrial mass seemed to be equal in both mouse lines. Both LC3-Isoforms, the cytosolic and the autophagosomal form, were not changed in brains of Thy-1-C57BJ/6-APPSL mice, which indicates equal mitophagic activity. In brain homogenates, isolated from Thy-1-C57BJ/6-APPSL mice, both mPTP marker, VDAC and PBR, were considerably increased, which is in accordance with the findings in HEKsw cells. In conclusion, both, the cellular (HEKsw) and the animal model of AD (Thy1-APPSL) broadly match pathophysiological features, which have been found in post-mortem samples from AD patients. Thus, HEKsw cells and Thy1-APPSL mice seem to be suitable models to study new treatments against AD. Incubation of HEKsw cells with Dimebon resulted in a remarkable increase in respiratory activity and restored the MMP after impairing the cells with rotenon. Dimebon had no effects on ATP levels in both cell lines, neither after challenging cells with rotenon, nor under basal conditions. By adding Dimebon, citrate synthase (CS) activity in HEKsw cells was increased and mitochondrial morphology was shifted to a tubular shape. Dimebon further enhanced protein levels of Drp and resulted in the compensation of reduced OPA levels. Moreover, Dimebon restored the increased expression levels of the mPTP markers VDAC and PBR. Aβ1-40 levels were significantly decreased in HEKsw cells. However, changes in Aβ1-40 levels seemed to be too small, to solely explain the much larger effects of Dimebon on impaired mitochondrial function. In conclusion, Dimebon treatment restored diverse defects in Aβ overexpressing cells: Aβ levels were reduced, autophagy marker were increased, mitophagy as repair and renewal mechanism was elevated, mitochondrial mass and density were increased, OXPHOS capacity was restored, mitochondrial dynamics were balanced, mitochondrial shape showed a normal distribution, expression levels of the mPTP constituents were reduced, TIMM50 levels augmented to control levels and stress induced MMP and ROS levels were reduced. All these effects were observed after incubation of cells with a rather low concentration of 100 nmol/L. Based on these findings and in addition to already existing literature, Dimebon presents a potential therapeutic option for diseases with accompanied mitochondrial dysfunction. Although, clinical findings published so far are inconsistent. Olesoxim induced a general increase in respiratory activity and enhanced the electron transport (ETS) capacity in HEKsw cells. In addition it normalized the OXPHOS activity almost to control levels. However, incubation using different Olesoxim concentrations led to a dose independent decline in the MMP and decreased ATP levels. Adding Olesoxim caused a dose-dependent change in the length of mitochondria strongly shifting the pattern towards longer mitochondria. In HEKsw cells a reduced mitochondrial density was observed which was reversed by Olesoxim dose-dependently. Olesoxim completely compensated the severely reduced expression levels of TIMM50, but had no effects on TOMM22 levels. An unexpected finding was that 10 µM Olesoxim significantly increased Aβ1-40 levels. Effects of Olesoxim were also tested in vivo. Treatment of Thy-1-C57BJ/6-APPSL mice with Olesoxim restored the impaired MMP in dissociated brain cells, but had no effects on ATP-levels. Olesoxim increased the respiratory activity in isolated brain mitochondria and restored impaired respiration complex activities almost to control levels, without having an effect on CS activity. However, treatment with Olesoxim caused an increase of PGC1 protein levels in brains of Thy-1-C57BJ/6-APPSL mice,beyond basal levels of littermate controls. The mPTP marker proteins voltage-depended anion channel (VDAC) and peripheral benzodiazepine receptor (PBR) were significantly reduced. As well as in the cell models, treatment of Thy-1-C57 BJ/6-APPSL mice with Olesoxim significantly enhanced total human, soluble human and soluble mouse Aβ1-40 levels. Further investigation needs the observation that Olesoxim caused partly negative effects in controls. For instance, Olesoxim reduced the OXPHOS capacity and enhanced protein levels of VADAC and PBR in brains of C57BJ/6 littermate control mice, which could limit the applicability of Olesoxim in further preclinical studies.
Synaptic dysfunction and synapse loss are key features of Alzheimer's pathogenesis. Previously, we showed an essential function of APP and APLP2 for synaptic plasticity, learning and memory. Here, we used organotypic hippocampal cultures to investigate the specific role(s) of APP family members and their fragments for dendritic complexity and spine formation of principal neurons within the hippocampus. Whereas CA1 neurons from APLP1-KO or APLP2-KO mice showed normal neuronal morphology and spine density, APP-KO mice revealed a highly reduced dendritic complexity in mid-apical dendrites. Despite unaltered morphology of APLP2-KO neurons, combined APP/APLP2-DKO mutants showed an additional branching defect in proximal apical dendrites, indicating redundancy and a combined function of APP and APLP2 for dendritic architecture. Remarkably, APP-KO neurons showed a pronounced decrease in spine density and reductions in the number of mushroom spines. No further decrease in spine density, however, was detectable in APP/APLP2-DKO mice. Mechanistically, using APPsalpha-KI mice lacking transmembrane APP and expressing solely the secreted APPsalpha fragment we demonstrate that APPsalpha expression alone is sufficient to prevent the defects in spine density observed in APP-KO mice. Collectively, these studies reveal a combined role of APP and APLP2 for dendritic architecture and a unique function of secreted APPs for spine density.
The deposition of the amyloid β-protein (Aβ) is one of the pathological hallmarks of Alzheimer's disease (AD). Aβ-deposits show the morphology of senile plaques and cerebral amyloid angiopathy (CAA). Senile plaques and vascular Aβ-deposits occur first in neocorti-cal areas. Then, they expand hierarchically into further brain regions. The distribution of Aβ plaques throughout the entire brain, thereby correlates with the clinical status of the patients. Imaging techniques for Aβ make use of the hierarchical distribution of Aβ to distinguish AD patients from non-AD patients. However, pathology seen in AD patients represents a late stage of a pathological process starting 10–30 years earlier in cognitively normal individuals. In addition to the fibrillar amyloid of senile plaques, oligomeric and monomeric Aβ is found in the brain. Recent studies revealed that oligomeric Aβ is presumably the most toxic Aβ-aggregate, which interacts with glutamatergic synapses. In doing so, dendrites are presumed to be the primary target for Aβ-toxicity. In addition, vascular Aβ-deposits can lead to capillary occlusion and blood flow disturbances presumably contributing to the alteration of neurons in addition to the direct neurotoxic effects of Aβ. All these findings point to an important role of Aβ and its aggregates in the neurodegenerative process of AD. Since there is already significant neuron loss in AD patients, treatment strategies aimed at reducing the amyloid load will presumably not cure the symptoms of dementia but they may stop disease progression. Therefore, it seems to be necessary to protect the brain from Aβ-toxicity already in stages of the disease with minor neuron loss before the onset of cognitive symptoms.
The hypothesis that oxidative stress plays a role in the pathogenesis of Alzheimer’s disease (AD) was tested by studying oxidative damage, acitvities of antioxidant enzymes and levels of reactive oxygen species (ROS) in several models. To this end, mouse models transgenic for mutant presenilin (PS1M146L) as well as mutant amyloid precursor protein (APP) and human post mortem brain tissue from sporadic AD patients and age-matched controls were studied. Aging leads to an upregulation of antioxidant enzyme activities of Cu/Zn-superoxide dismutase (Cu/Zn-SOD), glutathione peroxidase (GPx) and glutathione reductase (GR) in brains from C57BL/6J mice. Simultaneously, levels of lipid peroxidation products malondialdehyde MDA and 4-hydroxynonenal HNE were reduced. Additionally, pronounced gender effects were observed, as female mice display better protection against oxidative damage due to higher activity of GPx. Hence, antioxidant enzymes provide an important contribution to the protection against oxidative damage. In PS1M146L transgenic mice oxidative damage was only detectable in 19-22 months old mice, arguing for an additive effect of aging and the PS1 mutation. Both HNE levels in brain tissue as well as mitochondrial and cytosolic levels of ROS in splenic lymphocytes were increased in PS1M146L mice. Antioxidant defences were unaltered. In PDGF-APP and PDGF-APP/PS1 trangenic mice no changes in any of the parameters studied were observed in any age group. In contrast, Thy1-APP transgenic mice display oxidative damage as assessed by increased HNE levels. Reduced activity of Cu/Zn-SOD may explain this observation. Additionally, gender modified this effect, as female APP transgenic mice display higher b-secretase cleavage of APP and simultaneously increased HNE levels and reduced Cu/Zn-SOD activity earlier than male mice, i.e. from an age of 3 months and before the formation of Ab plaques. Reduced Cu/Zn-SOD activity was also found in another APP transgenic mouse model, in APP23 mice. In post mortem brain tissue from sporadic AD patients activities of Cu/Zn-SOD and GPx were however increased, and changes were most pronounced in temporal cortex. Simultaneously, levels of HNE but not MDA were elevated. Additionally, in vitro stimulation of lipid peroxidation led to increased MDA formation in samples from AD patients, indicating that increased activity of Cu/Zn-SOD and GPx are insufficient to protect against oxidative damage. Furthermore, the observed changes were subject to a gender effect, as samples from female AD patients showed increased activities of Cu/Zn-SOD and GPx as well as increased HNE levels, indicating that brain tissue from females is more sensitive towards oxidative damage. Levels of soluble Ab1-40 were positively correlated with with MDA levels and activities of Cu/Zn-SOD and GPx. Additionally, levels of lipid peroxidation products MDA and HNE are gene-dose-dependently modulated by the Apolipoprotein E4 allele, the most important genetic risk factor for AD known so far. While MDA levels were negatively correlated with MMSE scores, a measure for cognitive function, HNE levels were highest in AD patients with moderate cognitive impairment. Hence, increased HNE levels may play an important role in neurodegenerative events at an early disease stage. In summary, oxidative damage, as assessed by increased HNE levels, could be detected in sporadic AD patients and in different transgenic mouse models. The results of this thesis therefore support the further research of pharmacological targets aiming at augmentation of antioxidant defences for therapy or prophylaxis of Alzheimer’s disease.