SALICYLATE ACTIVATES AMPK AND SYNERGIZES WITH METFORMIN TO REDUCE THE SURVIVAL OF PROSTATE AND LUNG CANCERS EX VIVO THROUGH INHIBITION OF DE NOVO LIPOGENESIS

O'Brien, Andrew

06 1900

Background: Aspirin, the pro-drug of salicylate, is associated with reduced incidence of death from cancers and is commonly prescribed in combination with metformin in individuals with type 2 diabetes. Salicylate activates the AMP-activated protein kinase (AMPK) via Ser108 of the AMPK β1 subunit, a mechanism that is distinct from metformin, which increases AMP:ATP. Many cancers have high rates of fatty acid synthesis and AMPK inhibits this pathway through phosphorylation of acetyl-CoA carboxylase (ACC). It is unknown if targeting the AMPK-ACC-lipogenic pathway using salicylate and metformin may be effective for inhibiting cancer cell survival. Results: Salicylate suppresses clonogenic survival of prostate and lung cancer cells at therapeutic concentrations of aspirin. These clinically achievable concentrations of salicylate activated AMPK per the increasing phosphorylation of ACC and suppressing the activity of mTOR effectors kinase p70-S6 kinase and S6; effects that were enhanced with the addition of metformin and blunted in mouse embryonic fibroblasts (MEFS) deficient in AMPK β1. MEF cells deficient in AMPK β1 were more resistant to salicylates inhibitory effect on proliferation. Supplementation of media with fatty acids and mevalonate reverses the suppressive effects on cell survival indicating the inhibition of de novo lipogenesis is likely important. Conclusions: Salicylate increases ACC phosphorylation, reduces phosphorylation of mTOR targets and inhibits de novo lipogenesis in prostate and lung cancer cells, with concentrations of salicylate achievable through the ingestion of Aspirin (0.25-1.0mM) these effects are blunted in AMPK β1 deficient cells. Effects on AMPK activity via ACC phosphorylation as well as reductions in mTOR signalling targets and de novo lipogenesis are enhanced when used in combination with metformin. Suppressive effects on prostate and lung cancer cell survival are ameliorated when media is supplemented with mevalonate and fatty acids. Pre-clinical studies evaluating the use of salicylates alone and with metformin to inhibit de novo lipogenesis and the growth of prostate and lung cancers are warranted. / Thesis / Master of Science (MSc)

Redox-regulation of starch and lipid synthesis in leaves

Kolbe, Anna

January 2005

Post-translational redox-regulation is a well-known mechanism to regulate enzymes of the Calvin cycle, oxidative pentose phosphate cycle, NADPH export and ATP synthesis in response to light. The aim of the present thesis was to investigate whether a similar mechanism is also regulating carbon storage in leaves. <br><br> Previous studies have shown that the key-regulatory enzyme of starch synthesis, ADPglucose pyrophosphorylase (AGPase) is inactivated by formation of an intermolecular disulfide bridge between the two catalytic subunits (AGPB) of the heterotetrameric holoenzyme in potato tubers, but the relevance of this mechanism to regulate starch synthesis in leaves was not investigated. The work presented in this thesis shows that AGPase is subject to post-translational redox-regulation in leaves of pea, potato and Arabidopsis in response to day night changes. Light was shown to trigger posttranslational redox-regulation of AGPase. AGPB was rapidly converted from a dimer to a monomer when isolated pea chloroplasts were illuminated and from a monomer to a dimer when preilluminated leaves were darkened. Conversion of AGPB from dimer to monomer was accompanied by an increase in activity due to changes in the kinetik properties of the enzyme. Studies with pea chloroplast extracts showed that AGPase redox-activation is mediated by thioredoxins f and m from spinach in-vitro. In a further set of experiments it was shown that sugars provide a second input leading to AGPase redox activation and increased starch synthesis and that they can act as a signal which is independent from light. External feeding of sugars such as sucrose or trehalose to Arabidopsis leaves in the dark led to conversion of AGPB from dimer to monomer and to an increase in the rate of starch synthesis, while there were no significant changes in the level of 3PGA, an allosteric activator of the enyzme, and in the NADPH/NADP+ ratio. Experiments with transgenic Arabidopsis plants with altered levels of trehalose 6-phosphate (T6P), the precursor of trehalose synthesis, provided genetic evidence that T6P rather than trehalose is leading to AGPase redox-activation. Compared to Wt, leaves expressing E.coli trehalose-phosphate synthase (TPS) in the cytosol showed increased activation of AGPase and higher starch level during the day, while trehalose-phosphate phosphatase (TPP) overexpressing leaves showed the opposite. These changes occurred independently of changes in sugar and sugar-phosphate levels and NADPH/NADP+ ratio. External supply of sucrose to Wt and TPS-overexpressing leaves led to monomerisation of AGPB, while this response was attenuated in TPP expressing leaves, indicating that T6P is involved in the sucrose-dependent redox-activation of AGPase. To provide biochemical evidence that T6P promotes redox-activation of AGPase independently of cytosolic elements, T6P was fed to intact isolated chloroplasts for 15 min. incubation with concentrations down to 100 µM of T6P, but not with sucrose 6-phosphate, sucrose, trehalose or Pi as controls, significantly and specifically increased AGPB monomerisation and AGPase activity within 15 minutes, implying T6P as a signal reporting the cytosolic sugar status to the chloroplast. The response to T6P did not involve changes in the NADPH/NADP+ ratio consistent with T6P modulating redox-transfer to AGPase independently of changes in plastidial redox-state. <br><br> Acetyl-CoA carboxylase (ACCase) is known as key-regulatory enzyme of fatty acid and lipid synthesis in plants. At the start of the present thesis there was mainly in vitro evidence in the literature showing redox-regulation of ACCase by DTT, and thioredoxins f and m. In the present thesis the in-vivo relevance of this mechanism to regulate lipid synthesis in leaves was investigated. ACCase activity measurement in leaf tissue collected at the end of the day and night in Arabidopsis leaves revealed a 3-fold higher activation state of the enzyme in the light than in the dark. Redox-activation was accompanied by change in kinetic properties of ACCase, leading to an increase affinity to its substrate acetyl-CoA . In further experiments, DTT as well as sucrose were fed to leaves, and both treatments led to a stimulation in the rate of lipid synthesis accompanied by redox-activation of ACCase and decrease in acetyl-CoA content. <br><br> In a final approach, comparison of metabolic and transcript profiling after DTT feeding and after sucrose feeding to leaves provided evidence that redox-modification is an important regulatory mechanism in central metabolic pathways such as TCA cycle and amino acid synthesis, which acts independently of transcript levels. / Es ist bereits seit längerem bekannt, dass viele Enzyme des Calvinzyklus, des oxidativen Pentosephosphatwegs, des NAD(P)H-Exports und der ATP-Synthese durch post-translationale Redox-Modifikation in Antwort auf Licht reguliert werden. In der vorliegenden Arbeit sollte untersucht werden, ob ein ähnlicher Mechanismus auch die Kohlenstoffspeicherung in Blättern reguliert. <br><br> Vorangegangene Studien mit Kartoffelknollen zeigten, dass das Schlüsselenzym der Stärkesynthese ADP-Glukose-Pyrophosphorylase (AGPase) durch die Bildung einer Disulfidbrücke zwischen den zwei kleinen Untereinheiten (AGPB) des tetrameren Proteins inaktiviert wird, die Bedeutung dieses Mechanismus für die Stärkesynthese in Blättern blieb jedoch bislang ungeklärt. Die vorliegenden Arbeiten zeigen, das AGPase in Erbsen-, Kartoffel- und Arabidopsis-Blättern über post-translationale Redox-Modifikation in Antwort auf Tag-Nacht Änderungen reguliert wird. Dies erfolgt über ein Licht-abhängiges Signal, da, erstens, AGPB in isolierten Chloroplasten durch Belichtung sehr schnell von Dimer zu Monomer umgewandelt wird und, zweitens, ein Abdunkeln der Blätter zu einer schnellen Umwandlung von AGPB von Monomer zu Dimer führt. Die Monomerisierung von AGPB ging mit Änderungen in den kinetischen Eigenschaften des Enzyms einher, die zu einer Aktivierung führten. Studien mit Extrakten aus Erbsenchloroplasten zeigten, dass die AGPase-Redoxaktivierung in-vitro durch die Thioredoxine f und m aus Spinat vermittelt wird. In einem weiteren experimentellen Ansatz konnte gezeigt werden, dass auch Zucker zu Redox-Aktivierung der AGPase und erhöhter Stärkesynthese in Blättern führen, und dass diese unabhängig von Licht wirken. Externe Zugabe von Zuckern wie Saccharose oder Trehalose an Arabidopsis-Blätter im Dunkeln führten zu Monomerisierung von AGPB und einer Erhöhung der Stärkesyntheserate / während die Spiegel des allosterischen Aktivators 3PGA unverändert blieben und keine Änderungen im NADPH/NADP+-Verhältnis auftraten. Experimente mit transgenen Arabidopsis-Pflanzen mit veränderten Spiegeln des Vorläufers der Trehalosesynthese, Trehalose-6-phosphat (T6P), zeigten, dass T6P und nicht Trehalose zu Redox-Aktivierung von AGPase führt. Expression einer E. coli T6P synthase (TPS) im Zytosol führte zu erhöhter Redox-Aktivierung von AGPase und erhöhter Stäreksynthese in Blättern, während die Expression einer T6P-Phosphatase (TPP) gegenteilige Änderungen bewirkte. Diese Auswirkungen erfolgten unabhängig von Änderungen in den Spiegeln von Zuckern und Zuckerphosphaten oder im NADPH/NADP+-Verhältnis. Externe Zugabe von Saccharose führte zu Monomerisierung von AGPB in Wildtyp und TPS exprimierenden Blättern, während diese Antwort in TPP exprimierenden Blättern stark abgeschwächt war. Dies zeigt, dass T6P eine wesentliche Komponente darstellt, die die Redox-Aktivierung der AGPase in Antwort auf Saccharose vermittelt. T6P wurde auch für 15 min direkt an intakte, isolierte Erbsenchloroplasten gefüttert. T6P Konzentrationen im Bereich von 100 µM bis 10 mM führten zu einem signifikanten und spezifischen Anstieg der AGPB-Monomersierung und der AGPase Aktivität. Dies zeigt, dass T6P auch ohne zytosolische Elemente die Redox-Aktivierung der AGPase stimuliert und somit ein Signal zwischen Zytosol und Plastid darstellt. Diese Antwort erfolgte ohne Änderungen im NADPH/NADP+-Verhältnis, was zeigt, dass T6P eher den Redox-Transfer zu AGPase als den Redoxzustand des Chloroplasten moduliert. <br><br> Acetyl-CoA-Carboxylase (ACCase) ist als Schlüsselenzym der Fettsäure- und Lipidsynthese in Pflanzen bekannt. Zu Beginn der vorliegenden Arbeit lagen hauptsächlich in-vitro Befunde vor, die zeigten, dass ACCase durch DTT und thioredoxine f und m über Redox-Modulation reguliert wird. In der Arbeit sollte daher die in-vivo Relevanz dieses Mechanismus für die Regulation der Lipidsynthese in Blättern untersucht werden. ACCase zeigte einen höheren Redox-Aktivierungszustand in Arabidopsis-Blätter, die während des Tages im Vergleich zur Nacht geerntet wurden. Die Redox-Aktivierung der ACCase wurde von Änderungen in den kinetischen Eigenschaften begleitet und führte zu einer erhöhten Affinität des Enzymes gegenüber Acetyl-CoA als Substrat. <br><br> In weiteren Versuchen wurde sowohl DTT als auch Saccharose an Blätter gefüttert, und beide Behandlungen führten zu Redox-Aktivierung von ACCase, was mit erhöhten Lipidsynthesraten und einem Rückgang des Acetyl-CoA-Spiegels einherging.

Redoxreaktion

Thioredoxine

ADP-Glukosepyrophosphorylase

Acetyl-CoA carboxylase

Trehalose-6-Phosphat

Lipid Synthese

Stärke Synthese

Lipid synthesis

Starch synthesis

thioredoxin

redox

Life sciences

Alterações do metabolismo energético de camundongos geneticamente dislipidêmicos = participação da AMPK e do canal de potássio mitocondrial sensível ao ATP / Changes in energy metabolism in genetically dyslipidemic mice : involvement of AMPK and mitochondrial potassium channel sensitive to ATP

Kato, Larissa Sayuri, 1984-

19 August 2018

Orientador: Helena Coutinho Franco de Oliveira / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-19T14:08:09Z (GMT). No. of bitstreams: 1 Kato_LarissaSayuri_M.pdf: 3085711 bytes, checksum: 2c9b592f72e52ceb332be3af215a87fe (MD5) Previous issue date: 2011 / Resumo: O estudo das vias de sinalização envolvidas no metabolismo energético é de grande relevância fisiológica, uma vez que um desequilíbrio da homeostase energética pode resultar em obesidade e/ou síndrome metabólica e aumento da mortalidade por doença cardiovascular. Estudos recentes de nosso grupo em três modelos experimentais que exibem distintos tipos de dislipidemias revelaram alterações significativas da composição corporal, gasto energético e padrão de ingestão alimentar. Neste trabalho estudamos a homeostase energética desses modelos dislipidêmicos avaliando: (1) a expressão e fosforilação da proteína quinase dependente de AMP (AMPK), um importante regulador do metabolismo energético, bem como de seu alvo, a enzima acetil-CoA carboxilase (ACC), em fígado e músculo esquelético de camundongos hipoalfalipoproteinêmicos e hipercolesterolêmicos e (2) o efeito da alimentação pareada em animais hipertrigliceridêmicos que apresentam alterações de comportamento alimentar, metabolismo corporal e maior atividade do canal mitocondrial de potássio sensível ao ATP (mitoKATP). Considerando os animais hipoalfalipoproteinêmicos (transgênicos para CETP), os quais apresentam aumento de gasto energético global, verificamos que estes apresentam redução da massa relativa dos depósitos adiposos quando comparados os controles wild type (WT). O estudo da ativação da AMPK e da ACC mostra que o estado energético dos tecidos muscular e hepático parece não diferir nos animais CETP e WT. Tanto no fígado como no músculo dos animais CETP não houve alteração da massa e do estado de ativação da AMPK e da ACC. Estes resultados sugerem que não ocorrem variações significativas na síntese, armazenamento e "exportação" de lípides no fígado destes animais. Em relação ao músculo sóleo, pode-se concluir que não há alteração de síntese e catabolismo lipídico nos animais CETP. De modo geral, podemos dizer que a sinalização da AMPK não está ativada nestes tecidos e, portanto, que o maior metabolismo corporal observado nestes animais deve estar sendo causado por outros tecidos do organismo, por exemplo, o próprio tecido adiposo. Em animais machos e fêmeas hipercolesterolêmicas (LDLR0) observamos redução da massa corporal, porém sem alteração significativa da massa relativa dos depósitos adiposos quando comparados aos animais controles wild type. Os resultados sobre ativação da AMPK e da ACC mostram que o estado energético em tecidos periféricos é diferente nos animais LDLR0 e controles (WT). No fígado das fêmeas hipercolesterolêmicas observamos aumento da ativação da AMPK sem alteração significativa da fosforilação da ACC. Isso significa que não houve inibição da lipogênese ou ativação da beta-oxidação no fígado dos animais hipercolesterolêmicos, embora possa ter havido aumento de catabolismo de outros nutrientes. No músculo sóleo das fêmeas e dos machos não houve alteração de fosforilação de ambas AMPK e ACC. Pode-se então concluir que não há deprivação energética no músculo destes animais. Considerando o estudo em animais hipertrigliceridêmicos (HTG), quando submetidos ao regime de paired feeding (PF) observamos uma redução de 17% no consumo alimentar nas fêmeas e nos machos HTG quando comparados aos HTG alimentados ad libitum (ad lib). Isso levou a uma redução significativa do ganho de peso dos HTG-PF comparados aos WT-ad lib, em ambos os sexos. Os animais HTG-PF mantiveram a massa dos depósitos adiposos da carcaça semelhantes aos WT-ad lib e HTG-ad lib. No entanto, o depósito adiposo visceral das fêmeas HTG-ad lib é menor que dos WT-ad lib, enquanto nos machos, os HGT-PF apresentaram maior adiposo visceral que os HTG-ad lib. Quando comparados aos WT-ad lib, verificamos que as fêmeas HTG-PF mantiveram aumento significativo da atividade (abertura) do canal de potássio mitocondrial sensível ao ATP (mitoKATP) e da produção corporal de CO2. No entanto, nos machos HTG-PF houve fechamento dos mitoKATP, redução da produção de CO2 e manutenção da massa corporal. Assim, pode-se inferir que o metabolismo corporal (produção de CO2) reflete o aumento do metabolismo celular causado por aumento da atividade do mitoKATP que desacopla levemente as mitocôndrias e que estas adaptações são revertidas pela restrição alimentar nos machos, mas não nas fêmeas HTG / Abstract: An imbalance of energy homeostasis can result in obesity and/or metabolic syndrome and increased mortality from cardiovascular disease. Recent studies by our group in three experimental models that exhibit different types of dyslipidemia have shown significant changes in body composition, energy expenditure and food intake. In this work we studied the energy homeostasis in these models through: (1) quantifying the expression and phosphorylation of AMP-dependent protein kinase (AMPK), a key regulator of energy metabolism, as well as its target, the enzyme acetyl-CoA carboxylase (ACC) in liver and skeletal muscle in hypoalphalipoproteinemic and hypercholesterolemic mice and (2) the effect of paired feeding regimen on hypertriglyceridemic mice that present increased food intake, body CO2 production and increased activity of the mitochondrial potassium channel sensitive to ATP (mitoKATP). Considering the hypoalphalipoproteinemic mice (transgenic for CETP), which show an increased overall energy expenditure, we found that these mice have reduced relative fat depot mass when compared to wild type controls (WT). Western blot analyses showed that, in both tissues, liver and muscle, there were no changes in mass and state of activation of AMPK and ACC in CETP compared to WT mice. These results suggest that no significant variations in the synthesis, storage and secretion of lipids in the liver of these mice. Regarding the soleus muscle, these results suggest that there is no change in lipid synthesis and catabolism in CETP mice. Overall we may say that AMPK signaling is not activated in liver and muscle tissues and, therefore, that the increased body metabolism observed in these CETP mice must be caused by other body tissues, for example, the adipose tissue itself. In hypercholesterolemic male and female mice (LDLR0) we observed a reduction in body mass, but no significant change in the relative mass of fat depots when compared to WT. The results on activation of AMPK and ACC show that the liver of LDLR0 females had increased activation of AMPK without significant change in the phosphorylation of ACC. This means that there was no inhibition of lipogenesis and activation of ?-oxidation in the liver of hypercholesterolemic mice, although there may have been increased catabolism of other nutrients. In the soleus muscle of females and males there were no changes in the phosphorylation state of both AMPK and ACC. Then, we can conclude that there is no energy deprivation in the muscle of these LDLR0 mice. Considering the study with hypertriglyceridemic (HTG) mice, when subjected to the paired feeding (PF) we observed a 17% reduction in food intake of females and males when compared to HTG mice fed ad libitum (ad lib). This led to a significant reduction in HTG-PF weight gain compared to WT-ad lib in both sexes. HTG-PF mice retained the mass of carcass fat deposits similar to WT and HTG ad lib. Compared to WT-ad lib, HTG-PF mice maintained significant increased activity (opening) of the mitoKATP and body CO2 production. These data showed that the regimen of paired feeding in which HTG mice were submitted did not change the high rate body metabolism and mitochondrial resting respiration observed in HTG-ad lib mice. These results suggest that the metabolic adaptation of HTG (higher activity of mitoKATP) is not sensitive to changes in food restriction and compromises the rate of body growth / Mestrado / Fisiologia / Mestre em Biologia Funcional e Molecular

Hipoalfalipoproteinemias

Hipercolesterolemia

Hipertrigliceridemia

Proteínas quinases ativadas por AMP

Acetil-CoA carboxilase

Hypoalphalipoproteinemias

Hypercholesterolemia

Hypertriglyceridemia

AMP-activated protein kinase

Acetyl-CoA carboxylase