Metabolic changes and cell death in neural cells by "advanced glycation endproducts"

Advanced Glycation Endproducts (AGEs) entstehen aus nicht-enzymatisch glykierten Proteinen. In einer Folge von Dehydratations-, Kondensations- und Oxidationsschritten entsteht ein heterogenes Gemisch aus farbigen, fluoreszierenden Verbindungen. AGE-modifizierte Proteine sind unlöslich und proteaseresistent, bei ihrer Bildung entstehen freie Radikale und andere reaktive Intermediate. Von der AGE-Bildung betroffen sind vor allem langlebige Proteine mit geringem Umsatz wie Kollagen und Kristallin aber auch pathologische Proteinablagerungen, z.B. in der Alzheimer´schen Demenz (AD). Die Akkumulation von AGEs spielt in der Pathogenese von Komplikationen des Diabetes und der Hämodialyse eine Rolle, für die AD wird eine Beteiligung von AGEs am Krankheitsverlauf diskutiert. Die Alzheimer´sche Demenz ist gekennzeichnet durch den histologischen Nachweis seniler Plaques und neurofibrillärer Bündel in Hirngewebe der Patienten. Auf Ebene des Stoffwechsels kommt es zu einer Verringerung des zerebralen Glukoseumsatzes, es finden sich Marker sowohl für eine Akutphasenreaktion als auch für oxidativen Stress. In dieser Arbeit wurde gezeigt, dass die AGE-Bildung in vitro die Aggregation von ßA4, dem Hauptbestandteil der senilen Plaques in der AD, beschleunigt. Der geschwindigkeits-bestimmende Schritt ist dabei die Glykierung des ßA4-Monomers. Durch Zugabe von Übergangsmetall-ionen kann die Vernetzung weiter beschleunigt werden. Dies deutet darauf hin, dass AGEs zur Plaquebildung in der AD beitragen, redox-aktive Eisenionen sind in der AD mit den Plaques assoziiert. Mit Hilfe von Metallchelatoren, Antioxidantien oder mit Substanzen, welche die zur Vernetzung notwendigen Aminogruppen abblocken, lässt sich die Aggregation von ßA4 verlangsamen oder verhindern. AGEs wirken zytotoxisch auf BHK 21 Fibroblasten und humane SH-SY5Y Neuroblastoma Zellen. Die Toxizität unterschiedlicher Modell-AGEs ist abhängig von verschiedenen Faktoren, u.a. von dem zur Herstellung verwendeten Protein und vom Zucker. Die LD50 der Modell-AGEs korreliert mit dem AGE-Gehalt und der Radikalproduktion der Präparationen in vitro. Die AGE-Toxizität ist hauptsächlich radikalvermittelt. Oxidativer Stress lässt sich in AGE-behandelten Zellen durch die Bildung intrazellulärer Lipidperoxidationsprodukte nachweisen. Auf Ebene der Signaltransduktion konnte die Aktivierung des Transkriptions-faktors NfkB als Zeichen der Stressabwehr nachgewiesen werden. Die Gabe von Antioxidantien vor oder gleichzeitig mit den AGEs verringerte den Zelltod. Auch durch das Blockieren des Rezeptors für AGEs (RAGE) mit spezifischen Antikörpern konnte die Zahl überlebender Zellen gesteigert werden. Durch AGEs ausgelöster Stress führt in Neuroblastoma Zellen bereits in Konzentrationen unterhalb der LD50 zu Störungen im Redoxstatus, es kommt zur Depletion von GSH und zu Verschiebungen im Verhältnis GSH/GSSG. Damit einher gehen Veränderungen im Energiestoffwechsel der Zelle, nach anfänglich erhöhter Glukoseaufnahme kommt es im weiteren Verlauf der Inkubation zu einer Verringerung der Aufnahme von Glukose aus dem Medium, gefolgt von einer Zunahme der Laktatausschüttung. Ausserdem wurde eine Depletion von ATP um bis zu 50 Prozent nachgewiesen. Antioxidantien können die Störungen im Metabolismus der Zellen verhindern oder abschwächen, die meisten der getesteten Substanzen konnten Redoxstatus und ATP-Gehalt der Zellen zu normalisieren. Obwohl sich in AGE-gestressten Zellkulturen durch Annexin-Fluorescein-Markierung ein geringfügig erhöhter Prozentsatz apoptotischer Zellen nachweisen ließ und AGEs auch die Freisetzung von Cytochrom c ins Zytoplasma induzieren, verläuft der durch AGEs ausgelöste Zelltod verläuft offenbar insgesamt nekrotisch. Sowohl durch Radikalproduktion als auch über rezeptorvermittelte Signalwege verursachen AGEs oxidativen Stress und induzieren Veränderungen im Metabolismus der Zelle. Dies führt u. a. dazu, dass für die antioxidativen Schutzmechanismen der Zelle nicht mehr genügend Energie zur Verfügung steht. AGE-Stress trägt damit in einer selbstverstärkenden Reaktionskaskade zur Neurodegeneration bei und kann so an der Pathogenese der AD beteiligt sein. Antioxidantien und auch AGE-Inhibitoren könnten einen interessanten Ansatz zur Entwicklung alternativer Therapien in der AD darstellen.One of the most important post-translational modification of proteins is the non-enzymatic attachment of reducing sugars. Subsequent oxidations, dehydrations and rearrangements produce a heterogenous group of heterocyclic, coloured and fluorescent compounds termed "advanced glycation endproducts" (AGEs). In the course of their formation, free radicals and other reactive intermediates are created. AGE-modified proteins are resistant to proteases, their formation is irreversible. They accumulate on long-lived proteins with slow turn-over, e.g. on collagen or eye lens cristallin and on pathological protein deposits, e.g. in Alzheimer´s diease (AD). Accumulation of AGEs also occurs in the diabetic kidney and is discussed to be of importance in the etiology of AD. The pathology of Alzheimer´s disease involves accumulation of intra and extracellular protein aggregates like senile plaques and tangles. Further hallmarks are a reduction of glucose metabolism in the affected brain areas, together with signs for an acute phase response and for oxidative stress. In vitro experiments showed that AGEs accelerate the crosslinking of ßA4, the major component of senile plaques in AD. Since glycation of the peptide monomer is the first step of this reaction, this points to a participation of glycation in plaque-formation in AD. The formation of covalently crosslinked hight-weight ßA4 oligomers is further accelerated by micromolar amounts of copper and iron ions. Formation of these AGE-crosslinks can be inhibited by agents which are able of capping amino-groups, by metall chelators and by antioxidants, suggesting that these drugs may have the potential to slow down the formation of insoluble protein deposits in vivo AGEs have a direct toxic effect on BHK 21 fibroblasts and human SH-SY5Y neuroblastoma cells. AGE-modification renders proteins cytotoxic, the toxicity of a protein increases with the total AGE-content and depends from the modified protein. The LD50 of a model-AGE can be correlated with the in vitro radical production by the modified protein. On the level of signal transduction, AGEs induce the activation of the nuclear transcription factor kB as a stress response in neuroblastoma cells. AGEs enhance the formation of intracellular lipid-peroxidation products as markers for oxidative stress. AGE-toxicity is mediated by ROS and oxidative stress since various antioxidants were able to attenuate AGE-induced cell death. The receptor for AGEs (RAGE) appeared to be involved in AGE-toxicity as well, because blocking of RAGE with neutralizing antibodies increased the percentage of vital cells after AGE-treatment. The AGE-induced cell death shows signs of an initial apoptotic, final necrotic pathway. Though the percentage of annexin positive, apoptotic cells is slighly increased in cell cultures treated with sublethal amounts of AGEs and cytochrome c is released in the cytoplasma no activation of caspase-3 was found. AGE-induced stress leads to an imbalance in the cellular redox-status, recognizable by a shift in the GSH/GSSG ratio and a depletion of intracellular glutathione. This is accompanied by changes in the cells glucose metabolism and impairment of energy production. During the first hours of AGE-stress glucose uptake of the cells was increased. After this time point almost no further uptake of glucose from the medium was detectable but hight amounts of lactate were released. The ATP content of the cells was reduced up to 50 per cent. Administration of antioxidants together with or before administration of AGEs normalized ATP-levels as well as glucose uptake and lactate release. Interaction of AGEs with cells has been shown to cause oxidative stress, not only by receptor mediated pathways but also by production of free radicals by chemical oxidation and degradation of AGEs. This causes metabolic dysfunctions, energy depletion and impairment of the cells antioxidative defense. In the AD brain, this may lead to neurodegeneration and cell death, suggesting a role of AGEs in the pathogenesis of this disease. The results encourage the use of membrane permeable antioxidants in novel treatment strategies of AD. AGE-inhibitors may represent an interesting approach to slow down plaque formation

Methylglyoxal impairs glucose metabolism and leads to energy depletion in neuronal cells—protection by carbonyl scavengers

Advanced glycation end products (AGEs) are found in various intraneuronal protein deposits such as neurofibrillary tangles in Alzheimer's disease and Lewy bodies in Parkinson's disease. Among the many reactive carbonyl compounds and AGE precursors, methylglyoxal is most likely to contribute to intracellular AGE formation, since it is extremely reactive and constantly produced by degradation of triosephosphates. Furthermore, methylglyoxal levels increase under pathophysiological conditions, for example, when trisosephosphate levels are elevated, the expression or activity of glyoxalase I is decreased, as is the case when the concentration of reduced glutathione, the rate-determining co-factor of glyoxalase I, is low. However, the effects of methylglyoxal on mitochondrial function and energy levels have not been studied in detail. In this study, we show that methylglyoxal increases the formation of intracellular reactive oxygen species and lactate in SH-SY5Y neuroblastoma cells. Methylglyoxal also decreases mitochondrial membrane potential and intracellular ATP levels, suggesting that carbonyl stress-induced loss of mitochondrial integrity could contribute to the cytotoxicity of methylglyoxal. The methylglyoxal-induced effects such as ATP depletion and mitochondrial dysfunction can be prevented by pre-incubation of the cells with the carbonyl scavengers aminoguanidine and tenilsetam. In a clinical context, these compounds could not only offer a promising therapeutic strategy to reduce intracellular AGE-accumulation, but also to decrease the dicarbonyl-induced impairment of energy production in aging and neurodegeneration

The carbonyl scavengers aminoguanidine and tenilsetam protect against the neurotoxic effects of methylglyoxal

Advanced glycation end products (AGEs) have been identified in age-related intracellular protein deposits of Alzheimer’s disease (amyloid plaques and neurofibrillary tangles) and Parkinson disease (Lewy bodies), suggesting that these protein deposits have been exposed to AGE precursors such as the reactive dicarbonyl compound methylglyoxal. In ageing tissue and under diabetic pseudohypoxia, intracellular methylglyoxal levels rise through an impairment of triosephosphate utilization. Furthermore, methylglyoxal detoxification is impaired when reduced glutathione levels are low, conditions, which have all been described in Alzheimer’s disease. However, there is less known about the toxicity of methylglyoxal, particularly about therapeutic strategies to scavenge such dicarbonyl compounds and attenuate their toxicity. In our study, extracellularly applied methylglyoxal was shown to be toxic to human neuroblastoma cells in a dose-dependent manner above concentrations of 150 µM with a LD50 of approximately 1.25 mM. Pre-incubation of methylglyoxal with a variety of carbonyl scavengers such as aminoguanidine or tenilsetam and the thiol antioxidant lipoic acid significantly reduced its toxicity. In summary, carbonyl scavengers might offer a promising therapeutic strategy to reduce the neurotoxicity of reactive carbonyl compounds, providing a potential benefit for patients with age-related neurodegenerative diseases