Ribonucleotide reductase in dividing cells : purification and inhibition studies with 4-hydroxynonenal

Li, Li

January 1992

1). The effect of temperature, P450 inhibitors (pyrazole and imidazole), sulphydryl reagents (iodoacetamide and N-ethyl maleimide) and glutathione on the activation of CCl4 in rat liver microsomes was studied. Spin trapping of CCI3', covalent binding of CCl4 to protein and CCl4-dependent MDA formation were used as indices of CCl4 metabolism. Formation of PBN-CCI3' adduct, 14CCl4 covalent binding to protein and CCl4-dependent :MDA production were dependent on temperature range from 15-40°C. The transition temperature was at 26.7 -27 .5°C when the activation was measured by formation of PBNCCl3' adduct and specific 14CCl4 covalent binding. The transition temperature was found to be 34.3°C when CCl4 -dependent MDA production was taken as the index of the activation of CCI4. Pyrazole, imidazole and iodoacetamide inhibited CC14 -dependent MDA formation only at high concentrations (10-20 mM), whereas glutathione showed a strong inhibitory effect on CCl4-stimulated lipid peroxidation. MDA formation was nearly 100°;6 inhibited by 1 roM GSH. GSH also delayed the onset of lipid peroxidation. N-ethyl maleimide (NEM) exerted biphasic effects on CCl4 -dependent MDA formation. The lower concentration of NEM (0.5 mM-l mM) reduced the :MDA prodUction, while the higher concentration of NEM (5-10 mM) enhanced the MDA formation. 2). Ribonucleotide reductase was partially purified from juvenile normal rat liver. The enzyme was purified 30 fold after DEAE-cellulose chromatography. The CDP reductase activity in tissues with different growth states or rates was compared. The enzyme activity was developed well in juvenile rat liver, regenerating liver and hepatoma (cells), while the enzyme activity was undetectable in adult rat liver and sham-operated rat liver. The enzyme activity in Yoshida cells was 3-fold of the activity in Morris 5123tc tumours. Dithiothreitol (DIT) activated the activity of CDP reductase from 48h and 60h regenerating liver, but DIT did not activate the enzyme activity of juvenile 'normal rat liver. The possible mechanism of the activation of enzyme activity by DIT was discussed and a mechanism of regulation of the ribonucleotide reductase activity in regenerating liver was suggested. 3). The effect of the lipid peroxidation product 4-hydroxynonenal (HNE) on CDP reductase from juvenile normal rat liver was investigated. HNE inhibited the CDP reductase activity. The inhibition was dependent on the concentration of HNE and the incubation time. The enzyme activity was reduced 500/0 by 0.1 roM HNE. The inhibitory effect of HNE was irreversible. DIT protected the enzyme against HNE suggesting that HNE inhibited the activity of ribonucleotide reductase from rat liver through the mechanism of blockage of functional SH groups in the enzyme protein.

572

Nutrition parentérale du nouveau-né : modulation du stress oxydant et conséquences hépatiques

Miloudi, Khalil

10 1900

Introduction : Les enfants prématurés ont la particularité de naître alors que leur développement est souvent incomplet et nécessite la mise en œuvre de soins intensifs visant à poursuivre leur croissance en dehors de l’environnement utérin. Souvent cependant, le stade développemental de l’enfant ne lui permet pas d’assimiler une alimentation entérale du fait de l’immaturité de son système digestif. Le recours à une voie centrale délivrant les nutriments assurant le développement devient alors une nécessité. Ce type de nutrition, appelée nutrition parentérale (NP, ou total parenteral nutrition TPN), permet l’administration de molécules simples, directement dans le sang du prématuré. Il n’est toutefois pas exempt de risques puisqu’exposée à la lumière, la NP peut s’oxyder et générer des molécules oxydantes telles que des hydroperoxydes lipidiques susceptibles de se fragmenter par la suite en hydroxy-alkénals. Ceci devient problématique au vu de l’immaturité des systèmes de défenses antioxydants du nouveau-né prématuré. L’utilisation prolongée de la NP est d’ailleurs à l’origine de maladie hépatiques dans lesquelles le stress oxydant et la nécro-inflammation sont des composantes majeures. Nous avons émis l’hypothèse que l’infusion chez les enfants prématurés, d’aldéhydes d’origine lipidique est en relation avec le développement du stress oxydant et de l’inflammation hépatique. Objectif : Notre étude a consisté à évaluer la relation entre les quantités d’hydroxy-alkénals dans la NP et les effets hépatiques engendrés sur les marqueurs de stress oxydant et les voies de signalisation responsables d’une induction de processus inflammatoire. Dans ce but, nous avons cherché à mesurer la peroxydation lipidique dans l’émulsion lipidique de la NP et la conséquence de l’infusion en continue d’hydroxy-alkénals sur les marqueurs de stress oxydant, sur la voie de signalisation médiée par le Nuclear Factor κB et sur le déclenchement du processus inflammatoire hépatique. A la suite de ce travail, nous avons également travaillé sur des alternatives à la photoprotection, qui est la seule méthode réellement optimale pour réduire la peroxydation des lipides de la NP, mais cliniquement difficilement praticable. Résultats : Nos résultats ont mis en évidence la génération de 4-hydroxynonenal in vitro dans la NP, ce phénomène est augmenté par une exposition lumineuse. Dans ce cadre, nous avons montré l’inefficacité de l’ajout de multivitamines dans l’émulsion lipidique comme alternative à la photoprotection. Dans la validation biologique qui a suivi sur un modèle animal, nos résultats ont permis de démontrer que l’augmentation des adduits glutathion-hydroxynonenal était imputable à l’augmentation de 4-hydroxynonenal (4-HNE) dans la NP, et non à une peroxydation endogène. Nos données indiquent que la probable augmentation hépatique des niveaux de 4-HNE a conduit à une activation du NFκB responsable de l’activation de la transcription des gènes pro-inflammatoires du Tumour Necrosis Factor-α (TNF-α) et de l’interleukine-1 (IL-1). Nous avons alors évalué la capacité d’une émulsion lipidique enrichie en acides gras polyinsaturés (AGPI) n-3 à baisser les concentrations de 4-HNE dans la NP, mais également à moduler le stress oxydant et les marqueurs pro-inflammatoires. Enfin, nous avons démontré, en collaboration avec l’équipe du Dr Friel, que certains peptides isolés du lait humain (par un processus mimant la digestion) permettent également une modulation du stress oxydant et du processus inflammatoire. Conclusion : Le stress oxydant exogène issu de la NP a conduit par activation de facteurs de transcription intra-hépatiques au déclenchement d’un processus inflammatoire potentiellement responsable du développement de maladies hépatiques reliées à la NP telle que la cholestase. Dans ce sens, les AGPI n-3 et les peptides antioxydants peuvent se poser en tant qu’alternatives crédibles à la photoprotection. / Introduction: Premature infants usually born before full term require intensive care to continue to grow up outside the uterine environment. Premature newborns are born with gastrointestinal systems that are too immature to absorb nutrients safely. Therefore they receive their initial nutrients through intravenous feeding, called total parenteral nutrition which delivers simple nutrients directly into bloodstream. However, light exposed-TPN can generate oxidant molecules such as lipid hydroperoxides, which can potently break up into hydroxy-alkenals. Prolonged use of TPN is also a cause of liver disease in which oxidative stress and necro-inflammation are major components. Thus, we hypothesize that lipid aldehydes contained in TPN are associated with oxidative stress and hepatic inflammation developments. Objectives: The aim of our study is to assess the relationship between quantities of hydroxyl-alkenals generated in TPN and effects on oxidative stress biomarkers and cell-signalling pathways molecules implicated in hepatic inflammation induction. To this end, we measure lipid peroxidation in the TPN lipid emulsion in and the consequence of continuous infusion of hydroxy-alkenals on markers of oxidative stress, on cell-signaling pathway mediated by the NFkB, and on liver inflammation induction. Following these data, we also worked on alternatives of photoprotection, which is the only optimal method for preventing lipid peroxidation, but unfortunately clinically impractical. Results: In vitro studies have highlighted the generation of 4-HNE in the TPN, increased under light exposure. In this context, we have demonstrated that the addition of multivitamins in the lipid emulsion cannot be a valuable alternative to photoprotection. Concerning the biological validation in our guinea pig animal model, our results demonstrated that the increase of GS-HNE adducts was due to increased 4-HNE in the TPN, and does not provide from endogenous peroxidation. Our data also indicate that the increase of hepatic 4-HNE led to an activation of NFkB, responsible for the activation of the transcription of proinflammatory genes TNF-α, IL-1. In the next study, we have evaluated the ability of a lipid emulsion enriched with n-3 polyunsaturated fatty acids (PUFA) to reduce 4-HNE concentrations generated in TPN, and to modulate oxidative stress markers and pro-inflammatory process on the same animal model. We also have demonstrated, in collaboration with Dr Friel’s team, that two antioxidant peptides (derived from a process mimicking digestion process of human milk) allow also a modulation of oxidative stress and inflammatory process in the liver. Conclusion: This form of exogenous oxidative stress from the TPN led to an inflammatory process resulting from the activation of intrahepatic transcription, which is potentially responsible of liver disease development such as cholestasis. In this sense, the n-3 PUFA and antioxidant peptides may arise as a valuable alternative of photoprotection.

Prématurité

Nutrition parentérale

Peroxydation lipidique

Stress oxydant

Inflammation

4-hydroxynonenal

Prematurity

Parenteral nutrition

Lipid peroxidation

Oxidative stress

Inflammation

4-hydroxynonenal

Nutrition parentérale du nouveau-né : modulation du stress oxydant et conséquences hépatiques

Miloudi, Khalil

10 1900

Introduction : Les enfants prématurés ont la particularité de naître alors que leur développement est souvent incomplet et nécessite la mise en œuvre de soins intensifs visant à poursuivre leur croissance en dehors de l’environnement utérin. Souvent cependant, le stade développemental de l’enfant ne lui permet pas d’assimiler une alimentation entérale du fait de l’immaturité de son système digestif. Le recours à une voie centrale délivrant les nutriments assurant le développement devient alors une nécessité. Ce type de nutrition, appelée nutrition parentérale (NP, ou total parenteral nutrition TPN), permet l’administration de molécules simples, directement dans le sang du prématuré. Il n’est toutefois pas exempt de risques puisqu’exposée à la lumière, la NP peut s’oxyder et générer des molécules oxydantes telles que des hydroperoxydes lipidiques susceptibles de se fragmenter par la suite en hydroxy-alkénals. Ceci devient problématique au vu de l’immaturité des systèmes de défenses antioxydants du nouveau-né prématuré. L’utilisation prolongée de la NP est d’ailleurs à l’origine de maladie hépatiques dans lesquelles le stress oxydant et la nécro-inflammation sont des composantes majeures. Nous avons émis l’hypothèse que l’infusion chez les enfants prématurés, d’aldéhydes d’origine lipidique est en relation avec le développement du stress oxydant et de l’inflammation hépatique. Objectif : Notre étude a consisté à évaluer la relation entre les quantités d’hydroxy-alkénals dans la NP et les effets hépatiques engendrés sur les marqueurs de stress oxydant et les voies de signalisation responsables d’une induction de processus inflammatoire. Dans ce but, nous avons cherché à mesurer la peroxydation lipidique dans l’émulsion lipidique de la NP et la conséquence de l’infusion en continue d’hydroxy-alkénals sur les marqueurs de stress oxydant, sur la voie de signalisation médiée par le Nuclear Factor κB et sur le déclenchement du processus inflammatoire hépatique. A la suite de ce travail, nous avons également travaillé sur des alternatives à la photoprotection, qui est la seule méthode réellement optimale pour réduire la peroxydation des lipides de la NP, mais cliniquement difficilement praticable. Résultats : Nos résultats ont mis en évidence la génération de 4-hydroxynonenal in vitro dans la NP, ce phénomène est augmenté par une exposition lumineuse. Dans ce cadre, nous avons montré l’inefficacité de l’ajout de multivitamines dans l’émulsion lipidique comme alternative à la photoprotection. Dans la validation biologique qui a suivi sur un modèle animal, nos résultats ont permis de démontrer que l’augmentation des adduits glutathion-hydroxynonenal était imputable à l’augmentation de 4-hydroxynonenal (4-HNE) dans la NP, et non à une peroxydation endogène. Nos données indiquent que la probable augmentation hépatique des niveaux de 4-HNE a conduit à une activation du NFκB responsable de l’activation de la transcription des gènes pro-inflammatoires du Tumour Necrosis Factor-α (TNF-α) et de l’interleukine-1 (IL-1). Nous avons alors évalué la capacité d’une émulsion lipidique enrichie en acides gras polyinsaturés (AGPI) n-3 à baisser les concentrations de 4-HNE dans la NP, mais également à moduler le stress oxydant et les marqueurs pro-inflammatoires. Enfin, nous avons démontré, en collaboration avec l’équipe du Dr Friel, que certains peptides isolés du lait humain (par un processus mimant la digestion) permettent également une modulation du stress oxydant et du processus inflammatoire. Conclusion : Le stress oxydant exogène issu de la NP a conduit par activation de facteurs de transcription intra-hépatiques au déclenchement d’un processus inflammatoire potentiellement responsable du développement de maladies hépatiques reliées à la NP telle que la cholestase. Dans ce sens, les AGPI n-3 et les peptides antioxydants peuvent se poser en tant qu’alternatives crédibles à la photoprotection. / Introduction: Premature infants usually born before full term require intensive care to continue to grow up outside the uterine environment. Premature newborns are born with gastrointestinal systems that are too immature to absorb nutrients safely. Therefore they receive their initial nutrients through intravenous feeding, called total parenteral nutrition which delivers simple nutrients directly into bloodstream. However, light exposed-TPN can generate oxidant molecules such as lipid hydroperoxides, which can potently break up into hydroxy-alkenals. Prolonged use of TPN is also a cause of liver disease in which oxidative stress and necro-inflammation are major components. Thus, we hypothesize that lipid aldehydes contained in TPN are associated with oxidative stress and hepatic inflammation developments. Objectives: The aim of our study is to assess the relationship between quantities of hydroxyl-alkenals generated in TPN and effects on oxidative stress biomarkers and cell-signalling pathways molecules implicated in hepatic inflammation induction. To this end, we measure lipid peroxidation in the TPN lipid emulsion in and the consequence of continuous infusion of hydroxy-alkenals on markers of oxidative stress, on cell-signaling pathway mediated by the NFkB, and on liver inflammation induction. Following these data, we also worked on alternatives of photoprotection, which is the only optimal method for preventing lipid peroxidation, but unfortunately clinically impractical. Results: In vitro studies have highlighted the generation of 4-HNE in the TPN, increased under light exposure. In this context, we have demonstrated that the addition of multivitamins in the lipid emulsion cannot be a valuable alternative to photoprotection. Concerning the biological validation in our guinea pig animal model, our results demonstrated that the increase of GS-HNE adducts was due to increased 4-HNE in the TPN, and does not provide from endogenous peroxidation. Our data also indicate that the increase of hepatic 4-HNE led to an activation of NFkB, responsible for the activation of the transcription of proinflammatory genes TNF-α, IL-1. In the next study, we have evaluated the ability of a lipid emulsion enriched with n-3 polyunsaturated fatty acids (PUFA) to reduce 4-HNE concentrations generated in TPN, and to modulate oxidative stress markers and pro-inflammatory process on the same animal model. We also have demonstrated, in collaboration with Dr Friel’s team, that two antioxidant peptides (derived from a process mimicking digestion process of human milk) allow also a modulation of oxidative stress and inflammatory process in the liver. Conclusion: This form of exogenous oxidative stress from the TPN led to an inflammatory process resulting from the activation of intrahepatic transcription, which is potentially responsible of liver disease development such as cholestasis. In this sense, the n-3 PUFA and antioxidant peptides may arise as a valuable alternative of photoprotection.

Prématurité

Nutrition parentérale

Peroxydation lipidique

Stress oxydant

Inflammation

4-hydroxynonenal

Prematurity

Parenteral nutrition

Lipid peroxidation

Oxidative stress

Inflammation

4-hydroxynonenal

Investigating Organic Nitrate Tolerance and Alzheimer's Disease: Roles for Aldehyde Dehydrogenase 2 and 4-Hydroxynonenal

D'Souza, YOHAN

04 June 2013

Organic nitrates, such as glyceryl trinitrate (GTN), have been used clinically for more than a century. However optimal nitrate therapy is hindered by the development of tolerance, which is associated with a desensitized response to GTN, oxidative stress, and the inactivation of aldehyde dehydrogenase 2 (ALDH2). This thesis evaluated the ALDH2 inactivation hypothesis of GTN tolerance and investigated the role of oxidative stress in GTN tolerance mediated by the lipid peroxidation product, 4-hydroxynonenal (HNE). Evidence for a direct role of ALDH2 in nitrate action was sought using a stably transfected cell line that overexpressed ALDH2, or siRNA to deplete endogenous ALDH2. Neither manipulation altered GTN-induced cGMP formation, indicating that ALDH2 does not mediate GTN bioactivation and tolerance. In a second study using an in vivo GTN tolerance model and a cell culture model of nitrate action, a marked increase in HNE adduct formation was detected in GTN-tolerant tissues, and treatment with HNE reduced the cGMP and vasodilator responses to GTN, thus mimicking GTN-tolerance. Together, the results suggest a primary role for HNE in the development of GTN tolerance, and provide the framework for a unified hypothesis that accommodates the previous findings of sulfhydryl depletion, ALDH2 inactivation and oxidative stress that are associated with nitrate tolerance. Studies have implicated oxidative stress and increased HNE formation in the pathogenesis of Alzheimer’s disease (AD). It was hypothesized that the gene deletion of ALDH2 would result in increased HNE-adduct formation leading to impaired cognitive function, and AD-like pathological changes. We observed a marked increase in HNE-adduct formation in Aldh2-/- mouse hippocampi as well as hyperphosphorylated tau, activated caspases, age-related changes in hippocampal amyloid βeta1-42 (Aβ1-42), post-synaptic density protein 95 (PSD95) and phosphorylated cyclic adenosine monophosphate response element binding protein (pCREB) expression, endothelial dysfunction and other vascular pathologies. These data provide further evidence for the importance of HNE and oxidative stress in AD pathogenesis, and establish Aldh2-/- mice as a new, oxidative stress-based animal model of age-related cognitive impairment and AD. / Thesis (Ph.D, Pharmacology & Toxicology) -- Queen's University, 2013-05-31 11:10:58.145

Oxidative stress

Organic Nitrates

4-Hydroxynonenal

Nitrate Tolerance

Alzheimer's Disease

Nitroglycerin

Aldehyde Dehydrogenase

Investigating Organic Nitrate Tolerance and Alzheimer's Disease: Roles for Aldehyde Dehydrogenase 2 and 4-Hydroxynonenal

D'Souza, YOHAN

04 June 2013

Organic nitrates, such as glyceryl trinitrate (GTN), have been used clinically for more than a century. However optimal nitrate therapy is hindered by the development of tolerance, which is associated with a desensitized response to GTN, oxidative stress, and the inactivation of aldehyde dehydrogenase 2 (ALDH2). This thesis evaluated the ALDH2 inactivation hypothesis of GTN tolerance and investigated the role of oxidative stress in GTN tolerance mediated by the lipid peroxidation product, 4-hydroxynonenal (HNE). Evidence for a direct role of ALDH2 in nitrate action was sought using a stably transfected cell line that overexpressed ALDH2, or siRNA to deplete endogenous ALDH2. Neither manipulation altered GTN-induced cGMP formation, indicating that ALDH2 does not mediate GTN bioactivation and tolerance. In a second study using an in vivo GTN tolerance model and a cell culture model of nitrate action, a marked increase in HNE adduct formation was detected in GTN-tolerant tissues, and treatment with HNE reduced the cGMP and vasodilator responses to GTN, thus mimicking GTN-tolerance. Together, the results suggest a primary role for HNE in the development of GTN tolerance, and provide the framework for a unified hypothesis that accommodates the previous findings of sulfhydryl depletion, ALDH2 inactivation and oxidative stress that are associated with nitrate tolerance. Studies have implicated oxidative stress and increased HNE formation in the pathogenesis of Alzheimer’s disease (AD). It was hypothesized that the gene deletion of ALDH2 would result in increased HNE-adduct formation leading to impaired cognitive function, and AD-like pathological changes. We observed a marked increase in HNE-adduct formation in Aldh2-/- mouse hippocampi as well as hyperphosphorylated tau, activated caspases, age-related changes in hippocampal amyloid βeta1-42 (Aβ1-42), post-synaptic density protein 95 (PSD95) and phosphorylated cyclic adenosine monophosphate response element binding protein (pCREB) expression, endothelial dysfunction and other vascular pathologies. These data provide further evidence for the importance of HNE and oxidative stress in AD pathogenesis, and establish Aldh2-/- mice as a new, oxidative stress-based animal model of age-related cognitive impairment and AD. / Thesis (Ph.D, Pharmacology & Toxicology) -- Queen's University, 2013-05-31 11:10:58.145

Oxidative stress

Organic Nitrates

4-Hydroxynonenal

Nitrate Tolerance

Alzheimer's Disease

Nitroglycerin

Aldehyde Dehydrogenase

MITOCHONDRIAL AND NEUROPROTECTIVE EFFECTS OF PHENELZINE RELATED TO SCAVENGING OF NEUROTOXIC LIPID PEROXIDATION PRODUCTS

Cebak, John

01 January 2015

Lipid peroxidation is a key contributor to the pathophysiology of traumatic brain injury (TBI). Traditional antioxidant therapies are intended to scavenge the free radicals responsible for either the initiation or propagation of lipid peroxidation (LP). However, targeting free radicals after TBI is difficult as they rapidly react with other cellular macromolecules, and thus has a limited post-injury time window in which they may be intercepted by a radical scavenging agent. In contrast, our laboratory has begun testing an antioxidant approach that scavenges the final stages of LP i.e. formation of carbonyl-containing breakdown products. By scavenging breakdown products such as the highly reactive and neurotoxic aldehydes (often referred to as “carbonyls”) 4-hydroxynonenal (4-HNE) and acrolein (ACR), we are able to prevent the covalent modification of cellular proteins that are largely responsible for posttraumatic neurodegeneration. Without intervention, carbonyl additions render cellular proteins non-functional which initiates the loss of ionic homeostasis, mitochondrial failure, and subsequent neuronal death. Phenelzine (PZ) is an FDA-approved monoamine oxidase (MAO) inhibitor traditionally used for the treatment of depression. Phenelzine also possesses a hydrazine functional group capable of covalently binding neurotoxic carbonyls. The hypothesis of this dissertation is that carbonyl scavenging with PZ will exert an antioxidant neuroprotective effect in the traumatically injured rat brain mechanistically related to PZ’s hydrazine moiety reacting with the lipid peroxidation (LP)-derived reactive aldehydes 4-hydroxynonenal (4-HNE) and acrolein (ACR). Data from our ex vivo experiments demonstrate that the exogenous application of 4-HNE or ACR significantly reduced respiratory function and increased markers of oxidative damage in isolated non-injured rat cortical mitochondria, whereas PZ pre-treatment significantly prevented mitochondrial dysfunction and oxidative modification of mitochondrial proteins in a concentration-related manner. Additionally, PZ’s neuroprotective scavenging mechanism was confirmed to require the presence of a hydrazine moiety based on experiments with a structurally similar MAO inhibitor, pargyline, which lacks the hydrazine group and did not protect the isolated mitochondria from 4-HNE and ACR. Our in vivo work demonstrates that subcutaneous injections of PZ following TBI in the rat are able to significantly protect brain mitochondrial respiratory function, decrease markers of oxidative damage, protect mitochondrial calcium buffering capacity, and increase cortical tissue sparing without decreasing neuronal cytoskeletal spectrin degradation. These results confirm that PZ is capable of protecting mitochondrial function and providing neuroprotection after experimental TBI related to scavenging of neurotoxic LP degradation products.

phenelzine

lipid peroxidation

4-hydroxynonenal

acrolein

brain mitochondria

Medical Neurobiology

Medical Pharmacology

Neurosciences

TRPA1 CHANNELS IN COCHLEAR SUPPORTING CELLS REGULATE HEARING SENSITIVITY AFTER NOISE EXPOSURE

Velez-Ortega, Alejandra C

01 January 2014

TRPA1 channels are sensors for noxious stimuli in a subset of nociceptive neurons. TRPA1 channels are also expressed in cells of the mammalian inner ear, but their function in this tissue remains unknown given that Trpa1–/– mice exhibit normal hearing, balance and sensory mechanotransduction. Here we show that non-sensory (supporting) cells of the hearing organ in the cochlea detect tissue damage via the activation of TRPA1 channels and subsequently modulate cochlear amplification through active cellshape changes. We found that cochlear supporting cells of wild type but not Trpa1–/– mice generate inward currents and robust long-lasting Ca2+ responses after stimulation with TRPA1 agonists. These Ca2+ responses often propagated between different types of supporting cells and were accompanied by prominent tissue displacements. The most prominent shape changes were observed in pillar cells which here we show possess Ca2+-dependent contractile machinery. Increased oxidative stress following acoustic overstimulation leads to the generation of lipid peroxidation byproducts such as 4-hydroxynonenal (4-HNE) that could directly activate TRPA1. Therefore, we exposed mice to mild noise and found a longer-lasting inhibition of cochlear amplification in wild type than in Trpa1–/– mice. Our results suggest that TRPA1-dependent changes in pillar cell shape can alter the tissue geometry and affect cochlear amplification. We believe this novel mechanism of cochlear regulation may protect or fine-tune the organ of Corti after noise exposure or other cochlear injuries.

Transient receptor potential A1 channel

cochlear supporting cells

reactive oxygen species

cochlear amplification

4-hydroxynonenal

Cellular and Molecular Physiology

Red meat and colorectal cancer : lipid peroxidation-derived products induce different apoptosis, autophagy and Nrf2-related responses in normal and preneoplastic colon cells / Cancer colorectal et viande rouge : les produits dérivés de la lipoperoxydation induisent différentes réponses d'apoptose, d'autophagie et de Nrf2 dans des cellules coliques normales et prénéoplasiques

Surya, Reggie

05 September 2016

La viande rouge est un facteur de risque du cancer colorectal, considérée comme probablement cancérigène chez l'Homme. Le lien entre la viande rouge et le cancer colorectal impliquerait la lipoperoxydation induite par le fer héminique, aboutissant à la formation d'aldéhydes cytotoxiques présents dans les eaux fécales des rats ayant consommé de l'hème, dont le 4-hydroxynonénal (HNE). Ces eaux fécales ont préférentiellement induit la mort cellulaire dans des cellules coliques murines normales plutôt que dans des cellules coliques murines mutées pour le gène APC (adenomatous polyposis coli), considérées comme prénéoplasiques. Cette résistance des cellules prénéoplasiques est associée à une activité plus élevée du Nrf2 (Nuclear factor (erythroid-derived)-like 2) par rapport aux cellules normales, mise en evidence par l'invalidation du Nrf2. Afin de valider l'importance des aldéhydes néoformés derives de la lipoperoxydation, nous avons optimisé la depletion des composes carbonyls dans les eaux fécales qui a aboli le différentiel de mortalité entre les cellules normales et prénéoplasiques. En utilisant des cellules épithéliales coliques humaines (CECH) afin de se rapprocher de la physiologie humaine, nous avons confirmé que le HNE et les eaux fécales des rats ayant consommé de l'hème ont aussi induit une mortalité plus élevée dans les CECHs normales que dans celles invalidées pour APC ; et qu'une activité de Nrf2 plus élevée est aussi observée dans ces dernières. L'autophagie, dont le niveau est plus élevé dans les CECHs invalidées pour APC, exercerait des effets protecteurs contre la toxicité du HNE et des eaux fécales en activant Nrf2. Globalement, nos résultats suggèrent que le Nrf2 et l'autophagie seraient impliqués dans la résistance des cellules prénéoplasiques suite à une exposition aux eaux fécales des rats ayant consommé de l'hème. Ce différentiel de résistance pourrait expliquer l'effet promoteur de la viande rouge sur la cancérogenèse colorectale, en établissant une sélection positive des cellules prénéoplasiques au détriment des cellules normales. / Red meat is a factor risk for colorectal cancer, considered as probably carcinogenic to humans. Red meat is associated to colorectal cancer through the oxidative properties of heme iron released in the colon. This latter is a potent catalyst for lipid peroxidation, resulting in the neoformation of deleterious aldehydes present in the fecal water of heme-fed rats, including 4-hydroxynonenal (HNE). Fecal water of heme-fed rats preferentially induced mortality in mouse normal colon epithelial cells than in those harboring mutation on APC (adenomatous polyposis coli) gene, considered as preneoplastic. This relative resistance of preneoplastic cells to fecal water of heme-fed rats was associated with their higher activity of Nrf2 (Nuclear factor (erythroid-derived 2)-like 2) compared to normal cells, as evidenced by Nrf2 invalidation. To investigate the importance of secondary aldehydes derived from lipid peroxidation, depletion of carbonyl compounds in the fecal water was optimized and this turned out to abolish the difference of mortality between normal and preneoplastic cells. By using human colon epithelial cell (HCEC) lines to approach human physiology, we confirmed that HNE and fecal water of heme-fed rats also induced higher mortality in normal HCECs compared to APC-invalidated HCECs, and that higher Nrf2 activity in APC-invalidated HCECs was also associated with such a difference. Furthermore, autophagy, found to be up-regulated in APC-invalidated HCECs, was suggested to exert protective effects against HNE and fecal water toxicity by activating Nrf2. Taken together, these findings suggest that Nrf2 and autophagy were potentially involved in the resistance of preneoplastic cells upon exposure to HNE or fecal water of heme-fed rats. This different resistance could explain the promoting effect of red meat and heme-enriched diet on colorectal cancer, by initiating positive selection of preneoplastic cells over normal cells.

Cancer colorectal

Fer héminique

Lipoperoxydation

4-hydroxynonénal

Nrf2

Autophagie

Colorectal cancer

Heme iron

Lipid peroxidation

4-hydroxynonenal

Nrf2

Autophagy

Le 4-hydroxynonénal, un produit d'oxydation des lipides alimentaires : étude du métabolisme et du rôle dans l'inflammation et la cancérogénèse colorectale / 4-hydroxynonenal, an oxidation product of dietary lipids by heme iron : study of metabolism and role in inflammation and colorectal carcinogenesis

Keller, Julia

08 December 2016

Le 4-hydroxy-2-nonénal (HNE), un aldéhyde --insaturé, produit secondaire de la peroxydation des acides gras polyinsaturés en n-6 qui est cytotoxique et génotoxique in vitro. Cet aldéhyde a été largement étudié dans divers états pathologiques dans lesquels sa formation est la conséquence d’un stress oxydant associé à un état inflammatoire. Cependant, outre sa formation endogène, le HNE peut également être formé à partir des lipides alimentaires, entraînant sa présence dans les aliments mais également sa néoformation dans le tractus digestif. Ainsi, le rôle du HNE est suspecté dans la cancérogénèse colorectale induite par le fer héminique. L’effet promoteur du fer héminique, présent en grande quantité dans la viande rouge, a été démontré dans des modèles animaux, aux stades prénéoplasique et tumoral et a également été associé à la lipoperoxydation luminale. Ce travail a eu pour vocation la caractérisation du métabolisme du HNE alimentaire et l’étude de son rôle dans la cancérogénèse colorectale associée à la consommation de viande rouge, en explorant un possible effet proinflammatoire. Au préalable, nous avons démontré expérimentalement l’effet initiateur du fer héminique dans la cancérogénèse colorectale en plus de l’effet promoteur déjà validé. Concernant l’étude de métabolisme, nous avons identifié et caractérisé les métabolites du HNE présents dans l’urine suite à une exposition par voie orale chez le rat grâce à une méthode de suivi isotopique. Les voies majeures de métabolisation du HNE ont été identifiées et quantifiées. De plus, de nouveaux métabolites urinaires tel que des conjugués thiométhyles et glucuronides ont été mis en évidence pour la première fois. Les études de cancérogénèse ont porté sur les effets co-initiateurs ou promoteurs des régimes. De plus, les liens entre l’inflammation et le cancer du côlon étant souvent évoqués dans la littérature, nous avons également testé les effets du HNE sur l’inflammation colique. Au cours d’études court terme chez le rat F344, nous avons démontré l’absence d’effet du HNE sur l’inflammation et la perméabilité colique. Dans l’étude de co-initiation testant l’effet d’un régime alimentaire contenant du fer héminique ou du HNE pendant 15 jours suivi d’une initiation chimique par l’azoxyméthane, nous avons démontré pour la première fois un effet co-initiateur du fer héminique mais pas du HNE sur la cancérogénèse colorectale, au stade prénéoplasique. Dans l’étude de promotion de la cancérogénèse colorectale sur rats chimio-induits, nous avons également démontré une absence d’effet au stade prénéoplasique d’un régime riche en HNE donné pendant 100 jours après la chimio-induction. En conclusion, cette thèse apporte : (i) une description précise des métabolites urinaires du HNE absorbé par voie orale, (ii) une première démonstration expérimentale de l’effet co-initiateur du fer héminique sous forme hémine, (iii) une démonstration de l’absence d’effet du HNE seul et aux doses testées sur la cancérogénèse colorectale et l’inflammation colique. / This thesis focuses on 4-hydroxynonenal (HNE), an --unsaturated aldehyde by-product of polyunsaturated fatty acids n-6 peroxidation, which is demonstrated to be cytotoxic and genotoxic in vitro. This aldehyde has been extensively studied in various pathological conditions in which its formation is the result of oxidative stress associated to inflammation. However, in addition to its endogenous formation, the HNE can also be formed from dietary fats, leading to its presence in food but also to its new formation in the digestive tract. The role of HNE is suspected in heme iron induced colorectal carcinogenesis. Indeed, it has been experimentally shown that heme iron, found in large amounts in red meat, increases the incidence of preneoplastic lesions in animal models concomitantly with luminal lipoperoxidation. This work aims at characterizing the metabolism of dietary HNE and at studying its role in colorectal carcinogenesis associated with red meat consumption, because HNE is suspected to be one of reactive intermediates between heme iron and the development of this cancer. Suspected pro-inflammatory effects have also been tested. Beforehand, we have experimentally validated the initiating effect of heme iron in colorectal carcinogenesis in addition to its promoting effect already demonstrated. Regarding the metabolism study, we identified and characterized HNE metabolites in urine following oral exposure in rats using a stable isotope tracking method. The major routes of metabolism of HNE were identified as oxidation of carbons 1 and 9 (ALDH and P450 CYP 4A), - oxidation and mercapturic acids derivatives. In addition, new urinary metabolites such as glucuronide conjugates and thiomethyl were highlighted for the first time. Regarding carcinogenicity studies on the co-initiating or promoting effect of diet, we used doses of heme iron or HNE that are representative of a diet rich in meat or of a highly peroxidized diet. Furthermore, as the links between inflammation and colon cancer are often mentioned in the literature, we also tested the effects of HNE on colonic inflammation. First of all, during 2 short term studies of 2 and 3 weeks in F344 rats, we demonstrated the lack of effect of HNE on colonic inflammation and permeability. In the co-initiation study in which rats where fed for 15 days with a diet rich in heme iron or HNE, followed by chemical initiation azoxymethane, we demonstrated a co-initiating effect of heme iron but not of HNE on colorectal carcinogenesis. In the promotion study, we also have shown the lack of effect of a diet rich in HNE given for 100 days using a chemically-induced carcinogenesis model in rats. In conclusion, this thesis provides: (i) a precise description of urinary metabolites of HNE absorbed orally, (ii) a first experimental demonstration of the co-initating effect of heme iron in hemin form, (iii) a demonstration of the lack of effect of HNE on colorectal carcinogenesis and inflammation.

4-hydroxynonénal

Fer héminique

Lipoperoxydation

Métabolisme

Cancer colorectal

Inflammation

4-hydroxynonenal

Heme iron

Lipoperoxydation

Metabolism

Colorectal cancer

Inflammation

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