Scaling the Andean Shilajit: A Novel Neuroprotective Agent for Alzheimer's Disease.

Alzheimer's disease (AD) is a multifactorial neurodegenerative disorder without a cure, despite the enormous number of investigations and therapeutic approaches. AD is a consequence of microglial responses to "damage signals", such as aggregated tau oligomers, which trigger a neuro-inflammatory reaction, promoting the misfolding of cytoskeleton structure. Since AD is the most prevalent cause of dementia in the elderly (>60 years old), new treatments are essential to improve the well-being of affected subjects. The pharmaceutical industry has not developed new drugs with efficacy for controlling AD. In this context, major attention has been given to nutraceuticals and novel bioactive compounds, such as molecules from the Andean Shilajit (AnSh), obtained from the Andes of Chile. Primary cultures of rat hippocampal neurons and mouse neuroblastoma cells were evaluated to examine the functional and neuroprotective role of different AnSh fractions. Our findings show that AnSh fractions increase the number and length of neuronal processes at a differential dose. All fractions were viable in neurons. The AnSh fractions inhibit tau self-aggregation after 10 days of treatment. Finally, we identified two candidate molecules in M3 fractions assayed by UPLC/MS. Our research points to a novel AnSh-derived fraction that is helpful in AD. Intensive work toward elucidation of the molecular mechanisms is being carried out. AnSh is an alternative for AD treatment or as a coadjuvant for an effective treatment.

The Natural Product Curcumin as a Potential Coadjuvant in Alzheimer's Treatment.

Alzheimer's disease (AD) is a neurodegenerative disease characterized by a progressive cognitive impairment of patients, affecting around 12% of people older than 65 years old. WHO estimated that over 48.6 million all over the world suffer this disease. On the basis of cumulative results on our research, we have postulated the neuroimmunomodulation hypothesis that appears to provide a reasonable explanation of both the preclinical and clinical observations. In this context, the long-term activation of the innate immune system triggers an anomalous cascade of molecular signals, finally leading to tau oligomerization in the pathway to neuronal degeneration. In the present scenario of the failure of many anti-AD drugs, nutraceutical compounds provide an avenue for AD prevention and possibly as coadjuvants in the treatment of this disease. Recent discoveries point to the relevance of curcumin, a natural anti-inflammatory agent, in controlling oxidative stress and improving cholinergic function in the brain, even though the mechanisms underlying these actions are unknown. We investigated the effects of curcumin in cultures of neuronal cells. For this study, we exposed cells to prooxidant conditions, both in the presence and absence of curcumin. Our data reveal that curcumin exert a strong neuroprotective effect in N2a cells, thus preventing toxicity by oxidative agents H2O2 and Fe+3. This is supported by results that indicate that curcumin control the neurodegenerative effects of both oxidative agents, relieving cells from the loss of neuritogenic processes induced by prooxidants. In addition, curcumin was able to slow down the tau aggregation curve and disassemble tau pathological oligomeric structures. Data suggest that curcumin could be a potential compound for prevention of cognitive disorders associated with AD.

La teoría de la neuroinmunomodulación en enfermedades neurodegenerativas: nuevas evidencias científicas / Neuroinmmunomodulation in neurodegenerative diseases: new scientific evidence

Microglial cells play a major role in the innate immunity of the central nervous system. Alterations in the normal cross-talks between microglia and brain neuronal cells may lead to serious disturbances and neurodegenerative diseases. We have postulated that neuroinflammatory processes are a critical factor triggering the pathological cascade leading to neuronal degeneration. In our neuroimmunomodulation theory, external or internal damage signals activate microglial cells, producing cytotoxic factors that induce neuronal degeneration. These factors activate protein-kinases, that lead to tau hyperphosphorylation, and its consequent oligomerization. The tau aggregates released into the extracellular medium favor a positive feedback mechanism that determines neurodegeneration. Nowadays, natural components with a string anti-inflammatory activity and that cross the blood brain barrier appears as candidates for prevention and treatment of degenerative brain disorders such as Alzheimers'disease.

Las células microgliales juegan un papel importante en la inmunidad innata del sistema nervioso central. Las alteraciones en la normal diafonía celular, entre microglias y células neuronales cerebrales, pueden conducir a graves disturbios y enfermedades neurodegenerativas. En este contexto, hemos postulado que los procesos neuroinflamatorios son un factor crítico a desencadenar la cascada patológica que conduce a la degeneración neuronal. En nuestra teoría Neuroinmunomoduladora, señales de daños externos o internos activan las células microgliales, favoreciendo la producción de factores citotóxicos que inducen la degeneración neuronal. Estos factores activan la proteína-quinasas, que conducen a la hiperfosforilación de la proteína tau, y su consecuente oligomerización. Estos agregados de tau liberados al medio extracelular, al activar a la célula microglial, provocarían un mecanismo de retroalimentación positiva favoreciendo la neurodegeneración. Hoy en día, compuestos de origen natural con una fuerte actividad anti-inflamatoria, capaces de cruzar la barrera hematoencefálica del cerebro, aparecen como candidatos para la prevención y el tratamiento de trastornos neurodegenerativos tales como la enfermedad de Alzheimer.

Neuroinflammation in the pathogenesis of Alzheimer's disease. A rational framework for the search of novel therapeutic approaches.

Alzheimer disease (AD) is the most common cause of dementia in people over 60 years old. The molecular and cellular alterations that trigger this disease are still diffuse, one of the reasons for the delay in finding an effective treatment. In the search for new targets to search for novel therapeutic avenues, clinical studies in patients who used anti-inflammatory drugs indicating a lower incidence of AD have been of value to support the neuroinflammatory hypothesis of the neurodegenerative processes and the role of innate immunity in this disease. Neuroinflammation appears to occur as a consequence of a series of damage signals, including trauma, infection, oxidative agents, redox iron, oligomers of τ and ß-amyloid, etc. In this context, our theory of Neuroimmunomodulation focus on the link between neuronal damage and brain inflammatory process, mediated by the progressive activation of astrocytes and microglial cells with the consequent overproduction of proinflammatory agents. Here, we discuss about the role of microglial and astrocytic cells, the principal agents in neuroinflammation process, in the development of neurodegenerative diseases such as AD. In this context, we also evaluated the potential relevance of natural anti-inflammatory components, which include curcumin and the novel Andean Compound, as agents for AD prevention and as a coadjuvant for AD treatments.

Tau oligomers and fibrils induce activation of microglial cells.

Neuroinflammation is a process related to the onset of several neurodegenerative disorders, including Alzheimer's disease (AD). Increasing sets of evidence support the major role of deregulation of the interaction patterns between glial cells and neurons in the pathway toward neuronal degeneration, a process we are calling neuroimmunomodulation in AD. On the basis of the hypothesis that pathological tau aggregates induce microglial activation with the subsequent events of the neuroinflammatory cascade, we have studied the effects of tau oligomeric species and filamentous structures over microglial cells in vitro. Tau oligomers and fibrils were induced by arachidonic acid and then their actions assayed upon addition to microglial cells. We showed activation of the microglia, with significant morphological alterations as analyzed by immunofluorescence. The augmentation of nitrites and the proinflammatory cytokine IL-6 was evaluated in ELISA assays. Furthermore, conditioned media of stimulated microglia cells were exposed to hippocampal neurons generating altered patterns in these cells, including shortening of neuritic processes and cytoskeleton reorganization.

The revitalized tau hypothesis on Alzheimer's disease.

Many hypotheses have been raised regarding the pathophysiology of Alzheimer's disease (AD). Because amyloid beta peptide (Abeta) deposition in senile plaques appears as a late, nonspecific event, recent evidence points to tau phosphorylation and aggregation as the final common pathway in this multifactorial disease. Current approaches that provide evidence in favor of neuroimmunomodulation in AD and the roles of tau pathological modifications and aggregation into oligomers and filamentous forms are presented. We propose an integrative model on the pathogenesis of AD that includes several damage signals such as Abeta oligomers, oxygen free radicals, iron overload, homocysteine, cholesterol and LDL species. These activate microglia cells, releasing proinflammatory cytokines and producing neuronal degeneration and tau pathological modifications. Altered and aggregated forms of tau appear to act as a toxic stimuli contributing to neurodegeneration. Recent findings provide further support to the central role of tau in the pathogenesis of AD, so this protein has turned into a diagnostic and therapeutic target for this disease.

Neuroimmunomodulation in the pathogenesis of Alzheimer's disease.

Evidence has been cumulated on the role of microglia cells deregulation and alterations in their interaction patterns with brain neurons, in the pathway towards neurodegeneration in Alzheimer's disease (AD). After the failure of the amyloid hypothesis to explain AD pathogenesis, current hypotheses focus on tau self-polymerization into pathological oligomers and filaments as a major culprit for neurofibrillary degeneration. It is worth pointing out that formation of tau polymers is consistent with the clinical and neuropathological observations, and that tangles are pathognomonic of AD and related tau disorders. In this context, inflammatory processes play a major role in neuronal degeneration. On the basis of studies on microglia and neuronal cultures, together with experiments in animal models, and the clinical evidence, we postulated that a series of endogenous damage signals activate microglia cells, inducing NFkappa-beta with the consequent release of cytokine mediators such as TNF-alpha, IL-6 and IL-1beta. An overexpression of these mediators may trigger signaling cascades in neurons leading to activation of protein kinases gsk3beta, cdk5, abl kinases, along with inactivation of phosphatases such as PP1, with the resulting hyperphosphorylation and self-aggregation of tau protein into neurotoxic oligomeric species.