Targeting the Nrf2/HO-1 aixs: A therapeutic strategy against regulated cell death in Alzheimer's disease.

Chapter 16 - Cell death in Alzheimer disease brain and tryptamine-treated cells: microscopy

From adaption to death: endoplasmic reticulum stress as a novel target of selective neurodegeneration?

Caspase-3 mediated cleavage of the amyloid precursor protein (APP) has been proposed as a putative mechanism underlying amyloidosis and neuronal cell death in Alzheimer's disease (AD). We utilized an antibody that selectively recognizes the neo epitope generated by caspase-3 mediated cleavage of APP (alphadeltaC(csp)-APP) to determine if this proteolytic event occurs in senile plaques in the inferior frontal gyrus and superior temporal gyrus of autopsied AD and age-matched control brains. Consistent with a role for caspase-3 activation in AD pathology, alphadeltaC(csp)-APP immunoreactivity colocalized with a subset of TUNEL-positive pyramidal neurons in AD brains. AlphadeltaC(csp)-APP immunoreactivity was found in neurons and glial cells, as well as in small- and medium-size particulate elements, resembling dystrophic terminals and condensed nuclei, respectively, in AD and age-matched control brains. There were a larger number of alphadeltaC(csp)-APP immunoreactive elements in the inferior frontal gyrus and superior temporal gyrus of subjects with AD pathology than age-matched controls. AlphadeltaC(csp)-APP immunoreactivity in small and medium size particulate elements were the main component colocalized with 30% of senile plaques in the inferior frontal gyrus and superior temporal gyrus of AD brains. In some control brains, alphadeltaC(csp)-APP immunoreactivity appeared to be associated with a clinical history of metabolic encephalopathy. Our results suggest that apoptosis contributes to cell death resulting from amyloidosis and plaque deposition in AD.

Regulated cell death is a genetically determined form of programmed cell death that commonly occurs during the development of living organisms. This process plays a crucial role in modulating homeostasis and is evolutionarily conserved across a diverse range of living organisms. Ferroptosis is a classic regulatory mode of cell death. Extensive studies of regulatory cell death in Alzheimer's disease have yielded increasing evidence that ferroptosis is closely related to the occurrence, development, and prognosis of Alzheimer's disease. This review summarizes the molecular mechanisms of ferroptosis and recent research advances in the role of ferroptosis in Alzheimer's disease. Our findings are expected to serve as a theoretical and experimental foundation for clinical research and targeted therapy for Alzheimer's disease.

Mitochondria are central in the regulation of cell death. Apart from providing the cell with ATP, mitochondria also harbor several death factors that are released upon apoptotic stimuli. Alterations in mitochondrial functions, increased oxidative stress, and neurons dying by apoptosis have been detected in Alzheimer's disease patients. These findings suggest that mitochondria may trigger the abnormal onset of neuronal cell death in Alzheimer's disease. We previously reported that presenilin 1 (PS1), which is often mutated in familial forms of Alzheimer's disease, is located in mitochondria and hypothesized that presenilin mutations may sensitize cells to apoptotic stimuli at the mitochondrial level. Presenilin forms an active gamma-secretase complex together with Nicastrin (NCT), APH-1, and PEN-2, which among other substrates cleaves the beta-amyloid precursor protein (beta-APP) generating the amyloid beta-peptide and the beta-APP intracellular domain. Here we have identified dual targeting sequences (for endoplasmic reticulum and mitochondria) in NCT and showed expression of NCT in mitochondria by immunoelectron microscopy. We also showed that NCT together with APH-1, PEN-2, and PS1 form a high molecular weight complex located in mitochondria. gamma-secretase activity in isolated mitochondria was demonstrated using C83 (alpha-secretase-cleaved C-terminal 83-residue beta-APP fragment from BD8 cells lacking presenilin and thus gamma-secretase activity) or recombinant C100-Flag (C-terminal 100-residue beta-APP fragment) as substrates. Both systems generated an APP intracellular domain, and the activity was inhibited by the gamma-secretase inhibitors l-685,458 or Compound E. This novel localization of NCT, PS1, APH-1, and PEN-2 expands the role and importance of gamma-secretase activity to mitochondria.

Evidence for the Involvement of Apoptosis-Inducing Factor–Mediated Caspase-Independent Neuronal Death in Alzheimer Disease

Unravelling neuronal death mechanisms: The role of cytokines and chemokines in immune imbalance in Alzheimer's disease progression.

Amyloid beta peptide (Aβ) oligomers increase intracellular reactive oxygen species (ROS) and calcium cation (Ca(2+)) concentrations, which causes neuronal cell death in Alzheimer's disease (AD). Thus, the use of neuroprotective agents with antioxidative activity might be effective in the treatment of AD. In the present study, the neuroprotective effects of the methanol extract from edible brown alga Eisenia bicyclis (Laminariaceae) and its solvent soluble fractions together with the isolated phlorotannins on Aβ-induced toxicity were assessed by cell viability, intracellular ROS, and Ca(2+) levels in PC12 cells. The addition of the methanol extract as well as its ethyl acetate and n-butanol fractions of E. bicyclis markedly reversed the Aβ-induced toxicity. Among six phlorotannins, including phloroglucinol (1), dioxinodehydroeckol (2), eckol (3), phlorofucofuroeckol A (4), dieckol (5), and 7-phloroeckol (6), isolated from the most active ethyl acetate fraction, 3-6 significantly decreased Aβ-induced cell death. Furthermore, these compounds also inhibited intracellular ROS generation and Ca(2+) generation, indicating the neuroprotective effects may be mediated through reduced intracellular ROS and Ca(2+) generation. Thus, the results of the present study imply that E. bicyclis and its active components attenuated the oxidative stress and reduced neuronal cell death, suggesting that it may be used as a dietary neuroprotective agent in AD.

Alzheimer's disease (AD) pathology is characterized by cognitive impairment, increased acetylcholinesterase (AChE) activity, and impaired neuronal communication. Clinically, AChE inhibitors are being used to treat AD patients; however, these remain unable to prevent the disease progression. Therefore, further development of new therapeutic molecules is required having broad spectrum effects on AD-related various neurodegenerative events. Since repurposing is a quick mode to search the therapeutic molecules; henceforth, this study was conducted to evaluate the anti-Alzheimer activity of drug guanabenz which is already in use for the management of high blood pressure in clinics. The study was performed employing both cellular and rat models of AD along with donepezil as reference drug. Guanabenz treatment in both the experimental models showed significant protection against AD-specific behavioral and pathological indicators like AChE activity, tau phosphorylation, amyloid precursor protein, and memory retention. In conjunction, guanabenz also attenuated the AD-related oxidative stress, impaired mitochondrial functionality (MMP, cytochrome-c translocation, ATP level, and mitochondrial complex I activity), endoplasmic reticulum stress (GRP78, GADD153, cleaved caspase-12), neuronal apoptosis (Bcl-2, Bax, cleaved caspase-3), and DNA fragmentation. In conclusion, findings suggested the panoptic protective effect of guanabenz on disease-related multiple degenerative markers and signaling. Furthermore, clinical trial may shed light and expedite the availability of new therapeutic anti-Alzheimer's molecule for the wellbeing of AD patients.

Neuronal cell dysfunction and death are cardinal features of Alzheimer disease and a great deal of effort is being expended not only to understand factors involved in the cause and progression of disease (i.e., disease initiators and propagators) but, ultimately, the precise mechanism by which neurons die (for want of a better word, the terminators). Understanding each and every component of the complex pathway that ultimately leads to disease (a clinical phenotype) is clearly of paramount importance for the development of effective therapeutic strategies. Of particular intrigue for many scientists, perhaps the more macabre among us, has been to decipher the final event - namely cell death. Broadly speaking, cell death falls into two categories, apoptotic and necrotic. The former, apoptosis, by definition, is a controlled event; thereby offering the potential for intervention, whereas necrosis is a more stochastic process. Since many of the propagators and exacerbators involved in Alzheimer disease are pro-apoptotic, it is not surprising that certain aspects of apoptosis are evident. However, it would be a mistake to call this apoptosis. In fact, as reviewed herein, the chronic course of disease together with the necessarily slow rate of neuronal death makes apoptotic cell death in Alzheimer disease a mathematical improbability. The numbers simply do not add up.

Alzheimer's disease (AD) poses a huge challenge for society and health care worldwide as molecular pathogenesis of the disease is poorly understood and curative treatment does not exist. The mechanisms leading to accelerated neuronal cell death in AD are still largely unknown, but accumulation of misfolded disease-specific proteins has been identified as potentially involved. In the present review, we describe the essential role of endoplasmic reticulum (ER) in AD. Despite the function that mitochondria may play as the central major player in the apoptotic process, accumulating evidence highlights ER as a critical organelle in AD. Stress that impairs ER physiology leads to accumulation of unfolded or misfolded proteins, such as amyloid β (Aβ) peptide, the major component of amyloid plaques. In an attempt to ameliorate the accumulation of unfolded proteins, ER stress triggers a protective cellular mechanism, which includes the unfolded protein response (UPR). However, when activation of the UPR is severe or prolonged enough, the final cellular outcome is pathologic apoptotic cell death. Distinct pathways can be activated in this process, involving stress sensors such as the JNK pathway or ER chaperones such as Bip/GRP94, stress modulators such as Bcl-2 family proteins, or even stress effectors such as caspase-12. Here, we detail the involvement of the ER and associated stress pathways in AD and discuss potential therapeutic strategies targeting ER stress.

Amyloid Precursor Proteins Inhibit Heme Oxygenase Activity and Augment Neurotoxicity in Alzheimer's Disease

Role and relation of cell death in Alzheimer's disease.

2 Discovery of Cep-1347/Kt-7515, an Inhibitor of the Jnk/Sapk Pathway for the Treatment of Neurodegenerative Diseases

The etiology of Alzheimer's disease (AD) as well as its exact pathogenesis are unknown. Eventhough the deposition of beta A4 and the formation of neurofibrillary tangles represent impressive morphological hallmarks of the disease, several lines of evidence suggest that both lesions are not sufficient as causes of the neurodegenerative process. On the other hand, in vitro studies have shown that beta A4 is neurotoxic and is able to induce apoptotic cell death in neuronal cell cultures. Cells dying by apoptosis (programmed cell death) can be visualized in the tissue with a molecular biologic technique detecting fragmented nuclear DNA. Using this method, we have detected 50 x more neurons and 25 x more glial cells with nuclear DNA fragmentation in the brains of patients with AD than in non-demented controls. In contrast to previous studies, most of these cells did not reveal the characteristic morphological hallmarks of apoptosis. Most dying cells were not located within amyloid deposits and most dying cells did not bear a tangle. On the other hand, being in physical contact with an amyloid deposit increased the risk of a cell to dye by factor 5.7 and carrying a neurofibrillary tangle imposed a 3 times higher risk compared to unaffected nerve cells. Taken together, these data indicate that nerve cell death in AD occurs via a mechanism of programmed cell death different from classical apoptosis. Eventhough plaques and tangles increase the risk of cells to degenerate, both lesions are not the sole responsibles of the degenerative process, suggesting the existence of other factors that trigger the initiation of the cell death program in AD.