TARGETING DENDRITIC CELL METABOLISM TO INDUCE IMMUNE TOLERANCE

Wei, Hsi-Ju

01 February 2019

No description available.

Immunology

Cellular Biology

Medicine

Molecular Biology

Tolerogenic Dendritic Cells

Autoimmunity

Triterpenoids

Metabolism

Nrf2

Aplastic anemia

BBB-bypassing polysaccharide mini-GAGR activates the neuronal Nrf2- mediated antioxidant defense system for the treatment of Alzheimer’s disease

Murphy, Kelsey E.

January 2019

No description available.

Neurosciences

Intracellular Delivery of Functional Cargos Using Cell Penetrating Peptide Motifs

Salim, Heba

January 2021

No description available.

Chemistry

Biochemistry

Intracellular Delivery

Cell penetrating peptides

peptidyl inhibitor

Keap1-Nrf2 Interaction

Ras binding domain

Site-Specific Conjugation

Biological and Chemical Analysis of Small Molecule Activators of Anti-inflammatory and Antioxidant Nrf2-Keap1 Signaling

Gatbonton-Schwager, Tonibelle N.

11 June 2014

No description available.

Biology

Chemistry

Pharmacology

Immunology

triterpenoids

lipid peroxidation

inflammation

antioxidant

Nrf2

bryonolic acid

4-hydroxynonenal

macrophage

diversity oriented synthesis

Mechanotransduction in Living Bone: Effects of the Keap1-Nrf2 Pathway

Carlie Nicole Priddy (7023215)

15 August 2019

The Keap1-Nrf2 pathway regulates a wide range of cytoprotective genes, and has been found to serve a protective and beneficial role in many body systems. There is limited information available, however, about its role in bone homeostasis. While Nrf2 activation has been suggested as an effective method of increasing bone mass and quality, there have been conflicting reports which associate Keap1 deficiency with detrimental phenotypes. As Keap1 deletion is a common method of Nrf2 activation, further study should address the impacts of various methods of regulating Nrf2 expression. Also, little research has been conducted on the specific pathways by which Nrf2 activation improves bone quality. In this study, the effects of alterations to Nrf2 activation levels were explored in two specific and varied scenarios. In the first experiment, moderate Nrf2 activation was achieved via partial deletion of its sequestering protein, Keap1, in an aging mouse model. The hypothesis tested here is that moderate Nrf2 activation improves bone quality by affecting bone metabolism and response to mechanical loading. The results of this first experiment suggest a subtle, sex-specific effect of moderate Nrf2 activation in aging mice which improves specific indices of bone quality to varying degrees, but does not affect loading-induced bone formation. It is likely that the overwhelming phenotypic impacts associated with aging or the systemic effects of global Keap1 deficiency may increase the difficulty in parsing out significant effects that can be attributed solely to Nrf2 activation. In the second experiment, a cell-specific knockout of Nrf2 in the osteocytes was achieved using a Cre/Lox breeding system. The hypothesis tested here is that osteocyte-specific deletion of Nrf2 impairs bone quality by affecting bone metabolism and response to mechanical loading. The results of this experiment suggest an important role of Nrf2 in osteocyte function which improves certain indices of bone quality, which impacts male and female bones in different 7 ways, but did not significantly impact loading-induced bone formation. Further studies should modify the method of Nrf2 activation in an effort to refine the animal model, allowing the effects of Nrf2 to be isolated from the potential systemic effects of Keap1 deletion. Future studies should also utilize other conditional knockout models to elucidate the effects of Nrf2 in other specific cell types.

Cell Biology

Animal Cell and Molecular Biology

Nrf2

Keap1

Bone

Mechanotransduction

Bone Remodeling

cytoprotective

Osteoporosis

Antioxidant

Aging

Antiaging

Efeitos do sulforafano em parâmetros de estresse oxidativo em cultura de cardiomiócitos adultos

Corssac, Giana Blume

January 2017

O sulforafano (SFN) é um composto natural que possui propriedades antioxidantes, estimulando, principalmente, o sistema antioxidante endógeno celular. Este composto está associado a uma via clássica de ativação, a via do fator eritroide nuclear tipo 2 (Nrf2). Entretanto, estudos mais recentes têm demonstrado que a ação do SFN também pode se dar pela via do coativador 1-alfa do receptor ativado por proliferador do peroxissoma (PGC-1α). A diferença da via de ativação pelo SFN parece ter relação com o tempo de exposição das células a este composto. Visto que o SFN é uma importante estratégia terapêutica no combate ao estresse oxidativo, que está relacionado ao desenvolvimento de diversas doenças cardiovasculares, a investigação do seu mecanismo de ação é necessária. A análise in vitro é uma ferramenta importante para a investigação das vias e tempos de incubação envolvidos na ação antioxidante do SFN. Sendo assim, a cultura primária de cardiomiócitos de ratos adultos é um dos modelos que pode ser utilizado, sendo a sua principal vantagem, o fato da fisiologia destas células se aproximar mais das condições fisiológicas in vivo. O objetivo deste estudo, então, foi analisar a estimulação de defesas antioxidantes feita pelo SFN, através das vias do Nrf2 e do PGC-1α, em tempos diferentes, utilizando a técnica de cultura de cardiomiócitos adultos. Ratos Wistar machos foram eutanasiados, para que seus corações fossem retirados e submetidos ao processo de isolamento de células cardíacas, em aparelho de Langendorff modificado. As células foram isoladas através da perfusão do coração com solução de Krebs e colagenase tipo II, por um período de 30 minutos. Após isso, as células isoladas foram plaqueadas e mantidas em incubadora a 37°C e 5% de CO2. Foi realizado o tratamento com 5 μM de SFN e/ou 5 μM de peróxido de hidrogênio (H2O2). As células foram divididas nos seguintes grupos experimentais: Controle, SFN, H2O2 e SFN+H2O2. Os grupos foram subdivididos em dois tempos de incubação: 1 e 24 horas. Foram realizadas as análises dos níveis totais de espécies reativas de oxigênio (ROS) e de lipoperoxidação (LPO); atividade das enzimas antioxidantes superóxido dismutase (SOD), catalase (CAT) e glutationa s-transferase (GST); expressão proteica das isoformas citosólica (SOD-1) e mitocondrial (SOD-2) da SOD, e dos fatores Nrf2 e PGC-1α. Os resultados do trabalho mostram que, em relação ao tempo de 1 hora, o SFN incubado por 24 horas aumentou em 59% a atividade da SOD, 55% a expressão proteica da SOD-1, 24% a expressão proteica da SOD-2 e 69% a expressão proteica do PGC-1α. A expressão do Nrf2 foi 17% maior no tempo de 1 hora, em relação a 24 horas. Em relação à atividade da catalase e aos níveis de ROS e de LPO, houve diferença somente nos grupos incubados por 1 hora, nos quais a atividade da CAT foi menor no grupo H2O2, os níveis de ROS estavam diminuídos no grupo SFN, e os níveis de LPO estavam maiores no grupo H2O2. Não foram encontradas diferenças em relação à atividade da GST. Como conclusão, o SFN demonstrou um papel protetor nos grupos 1 hora, impedindo a geração de ROS e de dano a lipídeos, apesar de não apresentar um efeito expressivo sobre as enzimas antioxidantes. O efeito dos tempos de incubação na expressão do Nrf2 (aumentada em 1 hora) e do PGC-1α (aumentada em 24 horas) mostrou que realmente há uma relação temporal entre a sinalização destas duas vias, ativadas pelo SFN. Este resultado é instigante para que futuras análises dessa relação temporal das vias do SFN sejam realizadas. / Sulforaphane (SFN) is a natural compound that has antioxidant properties, mainly stimulating the endogenous cellular antioxidant system. This compound is associated with a classical pathway of activation, the nuclear erythroid factor 2 (Nrf2) pathway. However, more recent studies have shown that the action of SFN can also occur through the peroxisome proliferator-activated receptor coactivator 1-alpha (PGC-1α). The difference in the pathway of activation by SFN seems to be related to the time of exposure of the cells to this compound. Since SFN is an important therapeutic strategy in the fight against oxidative stress, which is related to the development of various cardiovascular diseases, the investigation of its mechanism of action is necessary. In vitro analysis is an important tool for investigating the pathways and incubation times involved in the antioxidant action of SFN. Thus, a primary culture of adult mouse cardiomyocytes is one of the models that can be used, the main advantage being that the physiology of these cells are closer to the physiological conditions in vivo. The objective of this study was to use adult cardiomyocyte culture technique to analyze the stimulation of antioxidant defenses by SFN through Nrf2 and PGC-1α pathways at different times. Male Wistar rats were euthanized, so that their hearts were removed and submitted to the process of isolation of cardiac cells, in modified Langendorff apparatus. Cells were isolated by perfusion of the heart with Krebs solution and type II collagenase for a period of 30 minutes. After that, the isolated cells were plated and incubated at 37°C and 5% CO2. Treatment was performed with 5μM SFN and/or 5μM hydrogen peroxide (H2O2). Cells were divided into the following experimental groups: Control, SFN, H2O2 and SFN+H2O2. The groups were subdivided into two incubation times: 1 and 24 hours. Analyzes of total oxygen reactive species (ROS) and lipoperoxidation (LPO) levels were performed; activity of antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and glutathione s-transferase (GST); protein expression of citosolic (SOD-1) and mitochondrial (SOD-2) isoforms of SOD, as well as Nrf2 and PGC-1α factors. The results of this work show that, compared to 1 hour time, SFN incubated for 24 hours increased SOD activity by 59%, SOD-1 protein expression by 55%, SOD-2 protein expression by 24%, and 69% PGC-1α protein expression. Expression of Nrf2 was 17% higher at 1 hour, over 24 hours of incubation. Regarding catalase activity and ROS and LPO levels, there were differences only in the groups incubated for 1 hour, in which the CAT activity was lower in H2O2 group, the ROS levels were decreased in SFN group, and levels of LPO were higher in H2O2 group. No differences were found in relation to GST activity. In summary, SFN demonstrated a protective role in 1 hour groups, preventing generation of ROS and lipid damage, although it does not present an expressive effect on the expression of antioxidant enzymes. The effect of incubation times on expression of Nrf2 (increased by 1 hour) and PGC-1α (increased by 24 hours) showed that there is actually a temporal relationship between the signaling of these two pathways, activated by SFN. This result is instigating for future analyzes of this temporal relationship of SFN pathways to be performed.

Estresse oxidativo

Miócitos cardíacos

Compostos fitoquímicos

Fator 2 relacionado a NF-E2

Sequência rica em GC

Primary culture

Oxidative stress

PGC-1α

Nrf2

Sulforaphane

Adult cardiomyocyte

INVESTIGATIONS INTO MODULATION OF BRAIN OXIDATIVE STRESS BY VARIOUS INTERVENTIONS

Harris, Jessica Lynn

01 January 2012

In this thesis study we examined glycogen synthase kinase-3β (GSK-3β) and its effects over Nrf2 and Pin 1 as it relates to Alzheimer’s disease (AD). AD is a neurodegenerative disease characterized by a prolonged high oxidative environment. Transcription factor Nrf2 is vital in the brain’s defense against oxidative insults through its up-regulation of over 100 antioxidants. Depletion of the brain’s antioxidant defense system results in intolerance to an oxidative environment, contributing to the progression of AD. The regulatory Pin 1 protein promotes cellular homeostasis, and when down-regulated results in increased deposits of neurofibrillary tangles (NFTs) and amyloid-β (Aβ) plaques, the two pathological hallmarks of AD. Using aged SAMP8 mice treated with antisense oligonucleotide (AO) directed at GSK-3β and random AO, the data presented here demonstrate decreased oxidative stress and increased Nrf2 transcriptional activity and Pin 1 levels as a result of the down-regulation of GSK-3β. Collectively, these results implicate GSK-3β activity in the increased oxidative stress of AD and support its inhibition as a possible therapeutic treatment for the disease. Further, we elucidate a possible mechanism connecting GSK-3β to the loss of tolerance to an oxidative environment and increased deposits of NFTs and Aβ plaques observed in AD.

Alzheimer’s disease

AD

oxidative stress

glycogen synthase kinase-3β

GSK-3β

nuclear factor-E2-related factor 2

Nrf2

Pin 1

Biochemistry

Chemistry

Neuroscience and Neurobiology

Efeitos do sulforafano em parâmetros de estresse oxidativo em cultura de cardiomiócitos adultos

Corssac, Giana Blume

January 2017

O sulforafano (SFN) é um composto natural que possui propriedades antioxidantes, estimulando, principalmente, o sistema antioxidante endógeno celular. Este composto está associado a uma via clássica de ativação, a via do fator eritroide nuclear tipo 2 (Nrf2). Entretanto, estudos mais recentes têm demonstrado que a ação do SFN também pode se dar pela via do coativador 1-alfa do receptor ativado por proliferador do peroxissoma (PGC-1α). A diferença da via de ativação pelo SFN parece ter relação com o tempo de exposição das células a este composto. Visto que o SFN é uma importante estratégia terapêutica no combate ao estresse oxidativo, que está relacionado ao desenvolvimento de diversas doenças cardiovasculares, a investigação do seu mecanismo de ação é necessária. A análise in vitro é uma ferramenta importante para a investigação das vias e tempos de incubação envolvidos na ação antioxidante do SFN. Sendo assim, a cultura primária de cardiomiócitos de ratos adultos é um dos modelos que pode ser utilizado, sendo a sua principal vantagem, o fato da fisiologia destas células se aproximar mais das condições fisiológicas in vivo. O objetivo deste estudo, então, foi analisar a estimulação de defesas antioxidantes feita pelo SFN, através das vias do Nrf2 e do PGC-1α, em tempos diferentes, utilizando a técnica de cultura de cardiomiócitos adultos. Ratos Wistar machos foram eutanasiados, para que seus corações fossem retirados e submetidos ao processo de isolamento de células cardíacas, em aparelho de Langendorff modificado. As células foram isoladas através da perfusão do coração com solução de Krebs e colagenase tipo II, por um período de 30 minutos. Após isso, as células isoladas foram plaqueadas e mantidas em incubadora a 37°C e 5% de CO2. Foi realizado o tratamento com 5 μM de SFN e/ou 5 μM de peróxido de hidrogênio (H2O2). As células foram divididas nos seguintes grupos experimentais: Controle, SFN, H2O2 e SFN+H2O2. Os grupos foram subdivididos em dois tempos de incubação: 1 e 24 horas. Foram realizadas as análises dos níveis totais de espécies reativas de oxigênio (ROS) e de lipoperoxidação (LPO); atividade das enzimas antioxidantes superóxido dismutase (SOD), catalase (CAT) e glutationa s-transferase (GST); expressão proteica das isoformas citosólica (SOD-1) e mitocondrial (SOD-2) da SOD, e dos fatores Nrf2 e PGC-1α. Os resultados do trabalho mostram que, em relação ao tempo de 1 hora, o SFN incubado por 24 horas aumentou em 59% a atividade da SOD, 55% a expressão proteica da SOD-1, 24% a expressão proteica da SOD-2 e 69% a expressão proteica do PGC-1α. A expressão do Nrf2 foi 17% maior no tempo de 1 hora, em relação a 24 horas. Em relação à atividade da catalase e aos níveis de ROS e de LPO, houve diferença somente nos grupos incubados por 1 hora, nos quais a atividade da CAT foi menor no grupo H2O2, os níveis de ROS estavam diminuídos no grupo SFN, e os níveis de LPO estavam maiores no grupo H2O2. Não foram encontradas diferenças em relação à atividade da GST. Como conclusão, o SFN demonstrou um papel protetor nos grupos 1 hora, impedindo a geração de ROS e de dano a lipídeos, apesar de não apresentar um efeito expressivo sobre as enzimas antioxidantes. O efeito dos tempos de incubação na expressão do Nrf2 (aumentada em 1 hora) e do PGC-1α (aumentada em 24 horas) mostrou que realmente há uma relação temporal entre a sinalização destas duas vias, ativadas pelo SFN. Este resultado é instigante para que futuras análises dessa relação temporal das vias do SFN sejam realizadas. / Sulforaphane (SFN) is a natural compound that has antioxidant properties, mainly stimulating the endogenous cellular antioxidant system. This compound is associated with a classical pathway of activation, the nuclear erythroid factor 2 (Nrf2) pathway. However, more recent studies have shown that the action of SFN can also occur through the peroxisome proliferator-activated receptor coactivator 1-alpha (PGC-1α). The difference in the pathway of activation by SFN seems to be related to the time of exposure of the cells to this compound. Since SFN is an important therapeutic strategy in the fight against oxidative stress, which is related to the development of various cardiovascular diseases, the investigation of its mechanism of action is necessary. In vitro analysis is an important tool for investigating the pathways and incubation times involved in the antioxidant action of SFN. Thus, a primary culture of adult mouse cardiomyocytes is one of the models that can be used, the main advantage being that the physiology of these cells are closer to the physiological conditions in vivo. The objective of this study was to use adult cardiomyocyte culture technique to analyze the stimulation of antioxidant defenses by SFN through Nrf2 and PGC-1α pathways at different times. Male Wistar rats were euthanized, so that their hearts were removed and submitted to the process of isolation of cardiac cells, in modified Langendorff apparatus. Cells were isolated by perfusion of the heart with Krebs solution and type II collagenase for a period of 30 minutes. After that, the isolated cells were plated and incubated at 37°C and 5% CO2. Treatment was performed with 5μM SFN and/or 5μM hydrogen peroxide (H2O2). Cells were divided into the following experimental groups: Control, SFN, H2O2 and SFN+H2O2. The groups were subdivided into two incubation times: 1 and 24 hours. Analyzes of total oxygen reactive species (ROS) and lipoperoxidation (LPO) levels were performed; activity of antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and glutathione s-transferase (GST); protein expression of citosolic (SOD-1) and mitochondrial (SOD-2) isoforms of SOD, as well as Nrf2 and PGC-1α factors. The results of this work show that, compared to 1 hour time, SFN incubated for 24 hours increased SOD activity by 59%, SOD-1 protein expression by 55%, SOD-2 protein expression by 24%, and 69% PGC-1α protein expression. Expression of Nrf2 was 17% higher at 1 hour, over 24 hours of incubation. Regarding catalase activity and ROS and LPO levels, there were differences only in the groups incubated for 1 hour, in which the CAT activity was lower in H2O2 group, the ROS levels were decreased in SFN group, and levels of LPO were higher in H2O2 group. No differences were found in relation to GST activity. In summary, SFN demonstrated a protective role in 1 hour groups, preventing generation of ROS and lipid damage, although it does not present an expressive effect on the expression of antioxidant enzymes. The effect of incubation times on expression of Nrf2 (increased by 1 hour) and PGC-1α (increased by 24 hours) showed that there is actually a temporal relationship between the signaling of these two pathways, activated by SFN. This result is instigating for future analyzes of this temporal relationship of SFN pathways to be performed.

Estresse oxidativo

Miócitos cardíacos

Compostos fitoquímicos

Fator 2 relacionado a NF-E2

Sequência rica em GC

Primary culture

Oxidative stress

PGC-1α

Nrf2

Sulforaphane

Adult cardiomyocyte

Efeitos do sulforafano em parâmetros de estresse oxidativo em cultura de cardiomiócitos adultos

Corssac, Giana Blume

January 2017

O sulforafano (SFN) é um composto natural que possui propriedades antioxidantes, estimulando, principalmente, o sistema antioxidante endógeno celular. Este composto está associado a uma via clássica de ativação, a via do fator eritroide nuclear tipo 2 (Nrf2). Entretanto, estudos mais recentes têm demonstrado que a ação do SFN também pode se dar pela via do coativador 1-alfa do receptor ativado por proliferador do peroxissoma (PGC-1α). A diferença da via de ativação pelo SFN parece ter relação com o tempo de exposição das células a este composto. Visto que o SFN é uma importante estratégia terapêutica no combate ao estresse oxidativo, que está relacionado ao desenvolvimento de diversas doenças cardiovasculares, a investigação do seu mecanismo de ação é necessária. A análise in vitro é uma ferramenta importante para a investigação das vias e tempos de incubação envolvidos na ação antioxidante do SFN. Sendo assim, a cultura primária de cardiomiócitos de ratos adultos é um dos modelos que pode ser utilizado, sendo a sua principal vantagem, o fato da fisiologia destas células se aproximar mais das condições fisiológicas in vivo. O objetivo deste estudo, então, foi analisar a estimulação de defesas antioxidantes feita pelo SFN, através das vias do Nrf2 e do PGC-1α, em tempos diferentes, utilizando a técnica de cultura de cardiomiócitos adultos. Ratos Wistar machos foram eutanasiados, para que seus corações fossem retirados e submetidos ao processo de isolamento de células cardíacas, em aparelho de Langendorff modificado. As células foram isoladas através da perfusão do coração com solução de Krebs e colagenase tipo II, por um período de 30 minutos. Após isso, as células isoladas foram plaqueadas e mantidas em incubadora a 37°C e 5% de CO2. Foi realizado o tratamento com 5 μM de SFN e/ou 5 μM de peróxido de hidrogênio (H2O2). As células foram divididas nos seguintes grupos experimentais: Controle, SFN, H2O2 e SFN+H2O2. Os grupos foram subdivididos em dois tempos de incubação: 1 e 24 horas. Foram realizadas as análises dos níveis totais de espécies reativas de oxigênio (ROS) e de lipoperoxidação (LPO); atividade das enzimas antioxidantes superóxido dismutase (SOD), catalase (CAT) e glutationa s-transferase (GST); expressão proteica das isoformas citosólica (SOD-1) e mitocondrial (SOD-2) da SOD, e dos fatores Nrf2 e PGC-1α. Os resultados do trabalho mostram que, em relação ao tempo de 1 hora, o SFN incubado por 24 horas aumentou em 59% a atividade da SOD, 55% a expressão proteica da SOD-1, 24% a expressão proteica da SOD-2 e 69% a expressão proteica do PGC-1α. A expressão do Nrf2 foi 17% maior no tempo de 1 hora, em relação a 24 horas. Em relação à atividade da catalase e aos níveis de ROS e de LPO, houve diferença somente nos grupos incubados por 1 hora, nos quais a atividade da CAT foi menor no grupo H2O2, os níveis de ROS estavam diminuídos no grupo SFN, e os níveis de LPO estavam maiores no grupo H2O2. Não foram encontradas diferenças em relação à atividade da GST. Como conclusão, o SFN demonstrou um papel protetor nos grupos 1 hora, impedindo a geração de ROS e de dano a lipídeos, apesar de não apresentar um efeito expressivo sobre as enzimas antioxidantes. O efeito dos tempos de incubação na expressão do Nrf2 (aumentada em 1 hora) e do PGC-1α (aumentada em 24 horas) mostrou que realmente há uma relação temporal entre a sinalização destas duas vias, ativadas pelo SFN. Este resultado é instigante para que futuras análises dessa relação temporal das vias do SFN sejam realizadas. / Sulforaphane (SFN) is a natural compound that has antioxidant properties, mainly stimulating the endogenous cellular antioxidant system. This compound is associated with a classical pathway of activation, the nuclear erythroid factor 2 (Nrf2) pathway. However, more recent studies have shown that the action of SFN can also occur through the peroxisome proliferator-activated receptor coactivator 1-alpha (PGC-1α). The difference in the pathway of activation by SFN seems to be related to the time of exposure of the cells to this compound. Since SFN is an important therapeutic strategy in the fight against oxidative stress, which is related to the development of various cardiovascular diseases, the investigation of its mechanism of action is necessary. In vitro analysis is an important tool for investigating the pathways and incubation times involved in the antioxidant action of SFN. Thus, a primary culture of adult mouse cardiomyocytes is one of the models that can be used, the main advantage being that the physiology of these cells are closer to the physiological conditions in vivo. The objective of this study was to use adult cardiomyocyte culture technique to analyze the stimulation of antioxidant defenses by SFN through Nrf2 and PGC-1α pathways at different times. Male Wistar rats were euthanized, so that their hearts were removed and submitted to the process of isolation of cardiac cells, in modified Langendorff apparatus. Cells were isolated by perfusion of the heart with Krebs solution and type II collagenase for a period of 30 minutes. After that, the isolated cells were plated and incubated at 37°C and 5% CO2. Treatment was performed with 5μM SFN and/or 5μM hydrogen peroxide (H2O2). Cells were divided into the following experimental groups: Control, SFN, H2O2 and SFN+H2O2. The groups were subdivided into two incubation times: 1 and 24 hours. Analyzes of total oxygen reactive species (ROS) and lipoperoxidation (LPO) levels were performed; activity of antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and glutathione s-transferase (GST); protein expression of citosolic (SOD-1) and mitochondrial (SOD-2) isoforms of SOD, as well as Nrf2 and PGC-1α factors. The results of this work show that, compared to 1 hour time, SFN incubated for 24 hours increased SOD activity by 59%, SOD-1 protein expression by 55%, SOD-2 protein expression by 24%, and 69% PGC-1α protein expression. Expression of Nrf2 was 17% higher at 1 hour, over 24 hours of incubation. Regarding catalase activity and ROS and LPO levels, there were differences only in the groups incubated for 1 hour, in which the CAT activity was lower in H2O2 group, the ROS levels were decreased in SFN group, and levels of LPO were higher in H2O2 group. No differences were found in relation to GST activity. In summary, SFN demonstrated a protective role in 1 hour groups, preventing generation of ROS and lipid damage, although it does not present an expressive effect on the expression of antioxidant enzymes. The effect of incubation times on expression of Nrf2 (increased by 1 hour) and PGC-1α (increased by 24 hours) showed that there is actually a temporal relationship between the signaling of these two pathways, activated by SFN. This result is instigating for future analyzes of this temporal relationship of SFN pathways to be performed.

Estresse oxidativo

Miócitos cardíacos

Compostos fitoquímicos

Fator 2 relacionado a NF-E2

Sequência rica em GC

Primary culture

Oxidative stress

PGC-1α

Nrf2

Sulforaphane

Adult cardiomyocyte

The physiological role of Nrf2 in diabetic kidney disease

Zhao, Shuiling

08 1900

La néphropathie diabétique (DN) est l’une des premières causes de maladie rénale en phase terminale (ESKD). L’ESKD est un important facteur de risque d'insuffisance cardiaque et d'accidents vasculaires cérébraux. La dysfonction du système rénine-angiotensine intrarénal (iRAS) est considérée comme étant l'une des principales causes du développement de la DN. Tous les composants du iRAS sont identifiés dans les cellules épithéliales des tubules rénaux proximaux (RPTCs), y compris l'angiotensinogène (Agt), le seul précurseur de toutes les angiotensines. Notre laboratoire a rapporté précédemment que la surexpression spécifique de l’Agt dans les RPTCs provoque l’hypertension, la protéinurie, la fibrose rénale, l’apoptose et des lésions rénales. Nrf2 (Nuclear factor erythroid 2-related factor 2) est un facteur de transcription qui est exprimé de façon abondante dans les RPTCs et a été considéré comme étant un régulateur central de l'équilibre redox dans les réponses cytoprotectrices cellulaires. Le rôle de l’activation du Nrf2 dans la DN, toutefois, est controversé. L’objectif général de cette thèse est de comprendre le rôle physiologique du Nrf2 dans la DN et d’étudier le(s) mécanisme(s) moléculaire(s) de l’action de Nrf2. Premièrement, nous avons démontré que la délétion génétique de Nrf2 ou l’inhibition pharmacologique de Nrf2 avec de la trigonelline chez les souris Akita diabétiques de type 1 régule à la hausse la voie Ace2/MasR et supprime l’expression de Agt/ACE dans les RPTCs, ce qui a pour effet d'atténuer l’hypertension systémique et les lésions rénales. Conformément, dans les cellules immoratalisées de tubule proximal de rat (IRPTC) en culture, la transfection de ARNsi ou le traitement à la trigonelline empêche la régulation positive de Agt/ACE induite par le HG, avec une baisse subséquente de l’expression des gènes Ace2/MasR. Ces données identifient un nouveau mécanisme dans lequel l’activation de Nrf2 stimule l’expression et l’activation des gènes du iRAS, menant au développement de l’hypertension et de la néphropathie dans le diabète. Deuxièmement, nous avons généré des souris Nrf2 transgéniques qui surexprime spécifiquement Nrf2 dans les RPTCs (souris Nrf2RPTC Tg), sous le contôle du promoteur KAP (kidney specific androgen-regulated protein). Nous avons ensuite croisé les souris Nrf2RPTC Tg avec les 6 souris Akita Nrf2-/- pour générer des souris Akita Nrf2-/- /Nrf2RPTC Tg. Nous avons trouvé que la surexpression de Nrf2 dans les RPTCs des souris Akita Nrf2-/- augmentait significativement l’expression du gène SGLT2, entraînant une élévation du glucose sanguin, du taux de filtration glomérulaire, du rapport albumine/créatinine urinaire et de la fibrose tubulo-interstitielle. Dans les cellules tubulaires proximales humaines immortalisées (HK2), le traitement à l’oltipraz ou la transfection de l’ADNc du NRF2 stimule l’expression de l’ARNm du SGLT2 et l’activité de son promoteur. De plus, des tests de retard sur gel et d’immunoprécipitation de chromatine ont montrés que NRF2 se lie au NRF2-RE du promoteur du SGLT2. En outre, une expression plus élevée de NRF2 et SGLT2 est observée dans les RPTCs de reins de patients diabétiques que dans les reins de patients non diabétiques. Ces données ont établi un nouveau mécanisme de la régulation du NRF2 sur l’expression et l’activation du gène SGLT2, menant à une exacerbation du glucose sanguin, de l’hyperfiltration et des lésions rénales dans le diabète. En somme, cette thèse a démontré que le stress oxidatif (hyperglycémie) induisait l’activation du Nrf2 qui stimulait le iRAS et l’expression de SGLT2, contribuant ainsi à la progression de la DN. Ces études suggèrent que le Nrf2 pourrait être une cible thérapeutique potentielle dans le traitement de la DN et pourront fournir de valabless données pré-cliniques pour les essais cliniques en cours avec le bardoxolone méthyle (un activateur de Nrf2). / Diabetic nephropathy (DN) is one of the leading causes of end-stage kidney disease (ESKD). ESKD is a major risk factor for heart failure and stroke. Dysfunction of intrarenal renin angiotensin system (iRAS) is considered as one of the main reasons that caused the DN. All components of the iRAS are identified in the renal proximal tubule cells (RPTCs), including angiotensinogen (Agt), the sole precursor of all angiotensins. Our lab has previously reported that specific overexpression of Agt in RPTCs induces hypertension, proteinuria, kidney fibrosis, apoptosis and kidney injury. Nuclear factor erythroid 2-related factor 2 (Nrf2) is a transcription factor that abundantly expresses in RPTCs and has been considered as a master regulator of redox balance in cellular cytoprotective responses. The role of Nrf2 activation in DN, however, is not clear. The overall aim of this study is to understand the physiological role of Nrf2 in DN and investigate the molecular mechanism(s) of Nrf2 action. First, we have demonstrated that genetic deletion of Nrf2 or pharmacological blockade of Nrf2 with trigonelline in type 1 diabetic Akita mice effectively upregulates Ace2/MasR and suppresses Agt/ACE expression in isolated RPTCs, resulting in attenuation of systemic hypertension and kidney injury. Consistently, in cultured IRPTCs, Nrf2 siRNA transfection or trigonelline treatment prevents high glucose-induced upregulation of Agt/ACE with downregulation of Ace2/MasR gene expression. These data identified a novel mechanism in which Nrf2 activation stimulates iRAS gene expression and activation, leading to the development of hypertension and nephropathy in diabetes. Second, we have generated Nrf2 transgenic mice under the kidney specific androgen regulated protein (KAP) promoter which specifically overexpress Nrf2 in RPTCs (Nrf2RPTC Tg mice). We further crossbred the Nrf2RPTC Tg mice with Akita Nrf2-/- mice to generate Akita Nrf2-/- /Nrf2RPTC Tg mice. We have found that overexpression of Nrf2 in RPTCs of Akita Nrf2-/- mice significantly unregulated sodium-glucose transporter-2 (SGLT2) expression, resulting in elevation of blood glucose, glomerular filtration rate, albumin-creatinine ratio and tubulointerstitial fibrosis. In 8 immortalized human proximal tubular cells (HK2), oltipraz treatment or NRF2 cDNA transfection stimulated SGLT2 mRNA expression and its promoter activity. Furthermore, NRF2 bound to NRF2- RE of SGLT2 promoter were identified by gel mobility shift assay and chromatin immunoprecipitation assay. Moreover, human diabetic kidneys exhibited higher expression of NRF2 and SGLT2 in RPTCs than non-diabetic kidneys. These data established a novel mechanism of NRF2’s regulation on SGLT2, leading to exacerbation of blood glucose, hyperfiltration and kidney injury in diabetes. In summary, this study documented that activation of Nrf2 in hyperglycemia contributed to the progression of DN via regulation of iRAS and SGLT2, suggesting that Nrf2 might be a potential therapeutic target in the treatment of DN.

Nrf2

stress oxidatif

néphropathie diabétique

SGLT2

Oxidative stress

Diabetic nephropathy

Intrarenal renin-angiotensin system