Vorkommen und metabolischer Transit alimentärer 1,2 Dicarbonylverbindungen

Degen, Julia

30 April 2014

1,2-Dicarbonylverbindungen spielen aufgrund ihrer Reaktivität gegenüber Aminosäureseitenketten von Proteinen eine Schlüsselrolle bei der Bildung von Maillard Reaktionsprodukten (MRP) und werden auch im Zusammenhang mit der Entstehung pathophysiologischer Konsequenzen bei metabolischen Erkrankungen diskutiert. Vor diesem Hintergrund stellt sich die Frage nach der physiologischen Relevanz alimentär aufgenommener 1,2 Dicarbonylverbindungen. Das Ziel der vorliegenden Arbeit war zunächst eine Bestandsaufnahme zum Vorkommen von 1,2-Dicarbonylverbindungen in einem Spektrum von Lebensmitteln, gefolgt von Untersuchungen zum metabolischen Transit von 3 Desoxyglucoson (3-DG) und Methylglyoxal (MGO) bzw. spezifischer Metabolite in Abhängigkeit der alimentären Aufnahme und zur Stabilität der Verbindungen während einer simulierten gastrointestinalen Verdauung. 1a Die 1,2-Dicarbonylverbindungen 3-DG, 3 Desoxygalactoson (3-DGal), MGO und Glyoxal (GO) sowie das Zuckerabbauprodukt 5-Hydroxymethylfurfural (HMF) als ein wichtiger Indikator für Erhitzungsprozesse in Lebensmitteln wurden in 173 Lebensmittelproben mittels einer optimierten RP-HPLC-Methode mit UV-Detektion bestimmt. Darunter waren neben alkoholfreien und alkoholischen Getränken auch süße Aufstriche, Brot- und Backwaren. In allen untersuchten Lebensmittelproben war 3 DG die quantitativ bedeutendste 1,2 Dicarbonylverbindung. Hohe 3-DG-Gehalte wurden in Bonbons, Honig und süßen Aufstrichen (Mediane: 165–626 mg/kg) und in Essig (Aceto balsamico bis 2622 mg/L) analysiert. Lebensmittel wie Fruchtsäfte, Bier, Brot- und Backwaren wiesen geringere 3 DG-Gehalte auf (Median: 27–129 mg/L bzw. mg/kg). In allen untersuchten Lebensmitteln lagen die Gehalte des 3-DG höher als die des HMF. 3-DGal konnte erstmals in nahezu allen Lebensmittel detektiert werden, mit einem Maximalwert von 162 mg/L in Aceto balsamico. In dieser Probe wurde auch ein hoher MGO-Gehalt (53 mg/L) gemessen. GO kommt in etwa gleichen Konzentrationsbereichen wie MGO vor. Generell lagen die Gehalte für 3-DGal höher als die für MGO. Eine Ausnahme stellt der untersuchte Manuka-Honig dar (463 mg MGO/kg). 1b Auf Basis der quantitativen Daten wurden Gehalte von 1,2-Dicarbonylverbindungen in verzehrüblichen Portionsgrößen verschiedener Lebensmittel berechnet und eine tägliche alimentäre Aufnahme von 20–160 mg (0,1–1,0 mmol) 3-DG und 5–20 mg (0,1–0,3 mmol) MGO abgeschätzt. 2a Der metabolische Transit von 3-DG und MGO wurde jeweils in einer dreitägigen Ernährungsstudie untersucht. Während der 3 Tage hatten die Probanden eine Dicarbonyl- und MRP-freie Diät (Rohkosternährung) einzuhalten. Am Morgen des zweiten Tages erhielten die Probanden eine definierte Menge 3-DG bzw. MGO (je 500 µmol), enthalten in Waldhonig bzw. Manuka-Honig. In den 24 h Urinproben der 3-DG-Interventionsstudie wurde 3-DG und dessen Metabolit 3-Desoxyfructose (3-DF) analysiert, außerdem Pyrralin und 3 DG-Hydroimidazolon (3-DG-H) als 3-DG-spezifisches MRP. In den 24 h Urinproben der MGO-Interventionsstudie wurde MGO und dessen Metabolit D-Lactat analysiert, außerdem MGO-Hydroimidazolon 1 (MG-H1) als charakteristisches MRP des MGO. Alle Verbindungen waren in den Urinproben nachweisbar. 2b Am ersten Tag der 3-DG-Interventionsstudie betrug der Median der renalen 3-DG- und 3 DF-Exkretion aller 9 Probanden 4,6 bzw. 77 µmol/d. Am Tag der definierten 3-DG-Aufnahme (Tag 2) stieg der Median der renalen 3-DG- und 3-DF-Exkretion signifikant auf 7,5 bzw. 147 µmol/d an. An Tag 3 unterschieden sich die täglichen renalen Ausscheidungen von 3-DG und 3-DF nicht signifikant von denen an Tag 1 (P > 0,05). Der Median der renalen Wiederfindung des an Tag 2 alimentär aufgenommenen 3-DG wurde mit 14 % abgeschätzt (Spannweite: 6–25 %). Der Median der renalen Exkretion von Pyrralin und 3-DG-H sank im Verlauf der dreitägigen Studie von 2,5 bzw. 1,0 auf 1,2 µmol/d bzw. 0,5 µmol/d. Diese Ergebnisse deuten erstmalig darauf hin, dass 3-DG aus der Nahrung resorbiert, resorbiertes 3 DG zu 3-DF metabolisiert und resorbiertes 3-DG hauptsächlich als 3-DF renal eliminiert wird. Die Exkretion der untersuchten MRP erwies sich in dieser Studie als nicht abhängig von der alimentären Aufnahme des 3 DG. 2c Die renale MGO- sowie D-Lactat-Ausscheidung wies keinen Zusammenhang mit der oralen Aufnahme einer hohen MGO-Menge auf. An allen 3 Tagen der MGO-Interventionsstudie lag die renale MGO-Exkretion aller 4 Probanden zwischen 0,11 und 0,30 µmol/d und die D-Lactat-Ausscheidung zwischen 52 und 224 µmol/d. Der Median der renalen MG-H1-Ausscheidung sank im Verlauf der dreitägigen Studie von 3,8 auf 1,2 µmol/d an Tag 3. Diese Ergebnisse deuten darauf hin, dass keine Resorption des MGO in die Zirkulation erfolgte. 3a Zur Beurteilung der Stabilität von 3-DG und MGO während der gastrointestinalen Verdauung wurde ein zweistufiges System von Hellwig et al. (2013b) adaptiert, bestehend aus einer zweistündigen „Magenstufe“ (Pepsin, pH = 2) und einer sechsstündigen „Darmstufe“ (Pankreatin/Trypsin, pH = 7,5). Für die Verdauungssimulation wurden jeweils wässrige 3 DG- und MGO-Standardlösungen mit Konzentrationen im lebensmittelrelevanten Bereich eingesetzt. Weiterhin wurde die simulierte Verdauung in Anwesenheit von Casein als Modellprotein, durchgeführt. 3b Nach achtstündiger simulierter Verdauung war im Verdauungsansatz noch 70 ± 10 % der initialen 3-DG-Menge bestimmbar. Die Anwesenheit des Caseins zeigte keinen Effekt auf die 3-DG-Konzentration. Damit dürfte nach gastrointestinaler Verdauung ein Großteil des alimentär aufgenommenen 3-DG zur Resorption zur Verfügung stehen. 3c Im Gegensatz zum 3-DG sank die MGO-Konzentration im Verlauf der achtstündigen simulierten Verdauung auf 15 ± 4 % der Ausgangskonzentration. In Anwesenheit von Casein verstärkte sich die Abnahme der MGO-Konzentration auf 9 ± 1 %. Es konnte gezeigt werden, dass die Abnahme der MGO-Konzentration auf Reaktionen mit den in den Verdauungsansätzen enthaltenen Enzymen und Proteinen zurückzuführen ist. MGO wird damit nach gastrointestinaler Verdauung nur noch in begrenztem Maße zur Resorption zur Verfügung. Die in der vorliegenden Arbeit gewonnenen Resultate lassen den Schluss zu, dass die biologische Verfügbarkeit alimentärer 1,2-Dicarbonylverbindungen gering (3-DG) bis vernachlässigbar (MGO) ist und selbst stark erhitzte Lebensmittel damit keinen maßgeblichen Beitrag zum „Gesamtpool“ an Dicarbonylverbindungen in vivo und den damit möglicherweise einhergehenden physiologischen Konsequenzen leisten.

info:eu-repo/classification/ddc/540

ddc:540

Studies on the Reaction of Dietary Methylglyoxal and Creatine during Simulated Gastrointestinal Digestion and in Human Volunteers

Treibmann, Stephanie, Groß, Julia, Pätzold, Susann, Henle, Thomas

18 April 2024

The reactive 1,2-dicarbonyl compound methylglyoxal (MGO) is consumed with food and its concentrations decrease during digestion. In the present paper, the reaction of MGO with creatine, arginine, and lysine during simulated digestion, and its reaction with creatine during the digestion in human volunteers, was studied. Therefore, simulated digestion experiments with a gastric and an intestinal phase were performed. Additionally, an intervention study with 12 subjects consuming MGO-containing Manuka honey and creatine simultaneously or separately was conducted. Derivatization with o-phenylenediamine and HPLC–UV was used to measure MGO, while creatine and glycated amino compounds were analyzed via HPLC–MS/MS. We show that MGO quickly reacts with creatine and arginine, but not lysine, during simulated digestion. Creatine reacts with 56% of MGO to form the hydroimidazolone MG-HCr, and arginine reacted with 4% of MGO to form the hydroimidazolone MG-H1. In the intervention study, urinary MG-HCr excretion is higher in subjects who consumed MGO and creatine simultaneously compared to subjects who ingested the substances separately. This demonstrates that the 1,2-dicarbonyl compound MGO reacts with amino compounds during human digestion, and glycated adducts are formed. These contribute to dietary glycation products consumed, and should be considered in studies investigating their physiological consequences.

info:eu-repo/classification/ddc/610

ddc:610

Development of an adductomic approach to identify electrophiles in vivo through their hemoglobin adducts

Carlsson, Henrik

January 2016

Humans are exposed to electrophilically reactive compounds, both formed endogenously and from exogenous exposure. Such compounds could react and form stable reaction products, adducts, at nucleophilic sites in proteins and DNA. The formation of adducts constitutes a risk for effects, such as cancer and contact allergy, and plays a role in ageing processes. Adducts to proteins offer a possibility to measure electrophilic compounds in vivo. Adductomic approaches aim to study the totality of adducts, to specific biomolecules, by mass spectrometric screening. This thesis describes the development and application of an adductomic approach for the screening of unknown adducts to N-terminal valine (Val) in hemoglobin (Hb) by liquid chromatography tandem mass spectrometry (LC/MS/MS). The adductomic approach is based on the FIRE procedure, a modified Edman procedure for the analysis of adducts to N-terminal Val in Hb by LC/MS/MS. The adduct screening was performed by stepwise scanning of precursor ions in small mass increments and monitoring four fragments common for derivatives of detached Val adducts, in the multiple reaction monitoring mode. Samples from 12 smokers/nonsmokers were screened with the adductomic approach, and seven previously identified adducts and 19 unknown adducts were detected. A semiquantitative approach was applied for approximate quantification of adduct levels. A strategy for identifying unknown Hb adducts using adductome LC/MS/MS data was formulated and applied for the identification of unknown adducts. Identifications were based on the observed m/z of precursor ions and retention times combined with databases and Log P calculations. Hypothesized adducts were generated in vitro for comparison and matching with the corresponding unknown adducts. Five identified adducts correspond to the precursor electrophiles ethyl vinyl ketone (EVK), glyoxal, methylglyoxal, acrylic acid, and 1-octen-3-one. These adducts, except the adducts corresponding to glyoxal and methylglyoxal, have not been observed as protein adducts before.  Probable exposure sources to these electrophiles are diet and/or endogenous formation. The observation of these adducts motivate further studies to evaluate possible contributions to health risks, as well as their potential as biomarkers of exposure. The adduct from EVK was quantitatively assessed through different experiments to estimate the daily internal dose (area under the concentration-time-curve, AUC). EVK is about 2 × 103 more reactive than the reference compound acrylamide. The EVK adduct was shown to be unstable, with a relatively short half-life. The daily AUC in humans of EVK was estimated to be about 20 times lower than the corresponding AUC of acrylamide from intake via food. To confirm the observation of the detected unknown adducts and obtain a statistical foundation, analysis of unknown adducts were performed in large sets of blood samples (n = 50–120) from human cohorts. The majority of the previously detected unknown adducts were found in all analyzed samples, and the levels of many adducts showed large variations between individuals. The cause and significance of these observed variations are not yet clarified, but are of importance for the directions of future studies. In conclusion, a new approach for identification of unknown human exposure to electrophiles was developed and successfully applied. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Submitted.</p>

Adductomics

Hemoglobin adducts

LC/MS/MS

Ethyl vinyl ketone

Glyoxal

Methylglyoxal

Acrylic acid

1-Octen-3-one

Toxicidade de aminoacetona e células produtoras de insulina / Cytotoxity of aminoacetone on insulin-producing cells

Sartori, Adriano

23 February 2010

Danos induzidos por hiperglicemia em tecidos no diabetes são caracterizados por quatro mecanismos conectados: aumento do fluxo metabólico através da via do poliol, ativação da proteína quinase C (PKC), aumento da atividade da via das hexosaminas e aumento da produção intracelular dos precursores dos produtos finais de glicação avançada (AGEs). Entre eles, os derivados de metilglioxal, um potente agente de modificação de proteínas e DNA, têm sido associados a complicações microvasculares no diabetes: nefropatia, retinopatia e neuropatia. O metilglioxal é produzido a partir das trioses fosfato, acetona e aminoacetona, um catabólito de treonina e glicina, gerado na matriz mitocondrial. A aminoacetona sofre oxidação enzimática, catalisada por aminoxidase sensível a semicarbazida (SSAO), ou química, catalisada por íons de cobre e ferro, produzindo metilglioxal, H2O2 e NH4 +. Sabendo que metilglioxal e H2O2 são capazes de induzir apoptose e/ou necrose em células produtoras de insulina (RINm5f) propomos uma possível atividade pró-oxidante da aminoacetona sobre células beta do pâncreas. O tratamento destas linhagens com aminoacetona/Cu(II) aumentou a morte celular, fluxo de Ca2+ intracelular, produção de NO, fragmentação do DNA, depleção dos níveis de glutationa reduzida (GSH), expressão gênica da proteína apoptótica Bax, enzimas antioxidantes - glutationa peroxidase (GPx), glutationa redutase (GRd), catalase e isoformas de superóxido dismutases (CuZnSOD e MnSOD) - e óxido nítrico sintase induzida (iNOS). Embora as concentrações normais e patológicas da aminoacetona, provavelmente seja muito menores que as usadas nos experimentos, sugerimos que, em tecidos de diabéticos, um acúmulo da aminoacetona em longo prazo pode conduzir a danos oxidativos e eventualmente morte das células beta do pâncreas / Tissue damages induced by hyperglycemia in diabetics are characterized by four linked mechanisms: increased flux through the polyol pathway, protein kinase C (PKC) activation, increased hexosamine pathway activity and intracellular production of advanced glycation end product (AGE) precursors. The production of AGEs by modifying proteins and DNA agent, such as methylglyoxal, has been implicated in microvascular complications in diabetes: nephropathy, retinopathy and neuropathy. Methylglyoxal is putatively produced in vivo from trioses phosphate, acetone and aminoacetone, a catabolite of threonine and glycine synthesized in the mitochondrial matrix. Aminoacetone has been reported to undergo semicarbazide sensitive amine oxidase- catalyzed and copper- and iron-catalyzed oxidations by molecular oxygen to methylglyoxal, NH4 + ion and H2O2. Considering that methylglyoxal and H2O2 have been found to promote apoptosis/necrosis to insulin-producing cells (RINm5f), we propose a possible pro-oxidant role of aminoacetone in pancreatic beta-cells. Treatment of RINm5f cells with aminoacetone plus Cu(II) ion promotes an increase of non-viable cells, influx of Ca2+ ions, NO production, DNA fragmentation, depletion of reduced glutathione (GSH) levels, and increased mRNA expression of pro-apoptotic protein (Bax), antioxidant enzymes - glutathione peroxidase (GPx), glutathione reductase (GRd), MnSOD, CuZnSOD and catalase - and inducible nitric oxide synthase (iNOS). Although both normal and pathological concentrations of aminoacetone are probably much lower than those used here, it is tempting to propose that excess aminoacetone in diabetic patients, at long term, may drive oxidative damage and eventually death of pancreatic beta-cells

Aminoacetona

Aminoacetone

Células RINm5f

Diabetes

Diabetes

Estresse oxidativo

Hydrogen peroxide

Methylglyoxal

Metilglioxal

Oxidative sress

Peróxido de hidrogênio

RINm5f cells

Mecanismos da reação de metabólitos &#945;-dicarbonílicos com peroxinitrito: geração de radicais livres e oxigênio singlete. Possíveis implicações biológicas / Reaction mechanisms of &#945;-dicarbonyl metabolites with peroxynitrite: generation of free radicals and singlet oxygen. Potential biological implications

Massari Filho, Júlio

12 May 2014

Peroxinitrito é um potente agente oxidante, nitrante e nucleofilico formado in vivo pela reação difusional do radical ânion superóxido com óxido nítrico, cuja produção exacerbada em situações de estresse oxidativo e nitrosativo pode resultar em danos a biomoléculas e estruturas sub-celulares. Por outro lado, vários compostos carbonílicos reativos tais como acroleína e compostos &#945;-dicarbonílicos são descritos como citotóxicos e genotóxicos, pois reagem com biomoléculas aminadas resultando em perda de funções nativas, situação esta denominada de \"estresse carbonílico\". Dentre os metabólitos &#945;-dicarbonílicos, altamente suscetíveis a adições nucleofílicas, destacam-se o biacetilo, derivado do metabolismo hepático de etanol e contaminante de alimentos, e metilglioxal e glioxal, ambos catabólitos de glicose, proteínas e lipídios acumulados em doenças relacionadas ao envelhecimento. Neste trabalho, observou-se que, em tampão fosfato normalmente aerado de pH próximo à neutralidade, (i) estes três compostos sofrem adição nucleofílica de peroxinitrito com constantes de velocidade de segunda ordem uma a três ordens de grandeza acima dos valores relatados para compostos monocarbonílicos (k2 &#8776; 4-100 M-1s-1); (ii) os sistemas biacetilo ou metilglioxal/peroxinitrito consomem o oxigênio dissolvido com produção de acetato ou acetato e formiato, respectivamente, via radical acetila capaz de acetilar histidina, lisina e 2\'-desoxiguanosina se adicionados à mistura reacional; e (iii) o sistema glioxal/peroxinitrito gera sucessivamente radical formila e radical formilhidroperoxila, cujo desproporcionamento a formiato e gás carbônico é acompanhado da emissão de luz no infra-vermelho próximo (&#955;max = 1270 nm), atribuída a oxigênio molecular no estado singlete (O21&#916;g) (Reação de Russell). Estes estudos evidenciam que a reação de metabólitos &#945;-dicarbonílicos com peroxinitrito gera radicais livres e embasam a hipótese de que possam contribuir para a acetilação radicalar, não-enzimática intracelular, de proteínas (epigenética) e DNA, portanto potencialmente implicadas na fisiologia e patologia do envelhecimento e desordens metabólicas, nas quais a participação de espécies reativas de oxigênio, nitrogênio e compostos carbonílicos foi relatada. Deve-se ainda notar que a descoberta de acetilação radicalar de biomoléculas por metabólitos &#945;-dicarbonilicos e peroxinitrito prepara o caminho para a identificação de novas reações químicas de biomoléculas, não catalisadas por enzimas, que possam eventualmente revelar novos biomarcadores teciduais em doenças adquiridas e inatas. / Peroxynitrite is a strong biological oxidant, nitrating and nucleophilic agent, formed by the diffusion-controlled reaction of the superoxide anion radical with nitric oxide, whose exacerbated production in oxidative and nitrosative stress leads to chemical damage to biomolecules and sub-cellular structures. On the other hand, various reactive carbonyl compounds like acrolein and &#945;-dicarbonyls are reportedly cytotoxic and genotoxic for their ability to react with amino biomolecules resulting in loss of native functions, a situation named \"carbonyl stress\". Among very reactive &#945;-dicarbonyls highly prone to nucleophilic additions, we highlight biacetyl, a hepatic alcohol metabolite and food contaminant, and methylglyoxal and glyoxal, both catabolites of glucose, proteins and lipids that accumulate in ageing-related disorders. Here, we report that, in normally aerated phosphate buffer near the physiological pH, (i) these three dicarbonyls undergo nucleophilic addition of peroxynitrite whose second order rate constants are one to three orders of magnitude than those documented for monocarbonyls (k2 &#8776; 4-100 M-1s-1); (ii) the biacetyl or methylglyoxal/peroxynitrite systems consume the dissolved oxygen yielding the acetate anion or acetate plus formate anion, respectively, from acetyl radical intermediate which was found to acetylate added histidine, lysine and 2\'-deoxyguanosine; and (iii) the glyoxal/peroxynitrite system ultimately generate formyl radical and formylperoxyl radical, whose dismutation to formate and carbonic oxide is accompanied by near infrared monomol emission (&#955;max = 1270 nm) characteristic of singlet molecular oxygen (O21&#916;g) (Russell reaction). Our studies strongly attest that the reaction of &#945;-dicarbonyls with peroxynitrite release free radicals that can potentially contribute for the radical, non-enzymatic acetylation of proteins (epigenetics) and DNA bases possibly implicated in the ageing physiopathology and metabolic disorders, where participation of reactive oxygen, nitrogen and carbonyl species is well recognized. Also noteworthy is that our findings may pave the way to the discovery of novel biochemical reactions whose products can eventually be useful as biomarkers of acquired and innate maladies.

Acetyl radical

Biacetilo

Biacetyl

Estresse oxidativo

Glioxal

Glyoxal

Methylglyoxal

Metilglioxal

Oxidative stress

Oxigênio singlete

Peroxinitrito

Peroxynitrite

Radical acetila

Singlet oxyge

Mycobacterium bovis BCG chaperonin 60.1 contributes to adaptations under stresses: implication for escaping isoniazid bactericidal mechanism and for mycobacterial biofilm growth

Zeng, Sheng

29 April 2019

Tuberculosis, caused by Mycobacterium tuberculosis, still poses a huge global health threat today. During infection, the bacilli are believed to confront with various stresses, including hypoxia. Hypoxia is known to trigger the bacteria to adapt into a nonreplicating dormant state associated with reduced drug susceptibility. In addition to dormancy, mycobacteria, like other bacteria, may switch to sessile biofilm growth that is generally associated with augmented drug and stress tolerance. Bacterial biofilm is physically heterogeneous and may harbor cells displaying distinct metabolic activities. It is therefore likely that some cell populations within an established biofilm are in a nonreplicating dormant state. A better understanding of mycobacterial dormancy establishment and biofilm growth could unveil crucial bacillary survival strategies that will provide insights into a rational design of chemotherapy regimen.The mycobacterial chaperonin 60.1 (Cpn60.1, also known as GroEL1), a probable chaperonin and/or nucleoid associated protein, is necessary for mycobacterial cell wall virulence lipid biosynthesis, which was reported to be enhanced at the early stage of mycobacterial hypoxic adaptation, and for reduced drug susceptibility under aerobic condition. We therefore investigated whether Cpn60.1 was essential for mycobacterial adaptation to hypoxic dormancy using Mycobacterium bovis BCG as the model organism. We found that Cpn60.1, although nonessential for mycobacterial survival, reduced isoniazid (INH) susceptibility under hypoxia. Unexpectedly and interestingly, INH’s bactericidal activity was found to involve electron transport chain perturbation (e.g. enhanced oxygen consumption and increased adenosine triphosphate level) via NADH dehydrogenases, succinate dehydrogenases, cytochrome bc1 and F0F1 ATP synthase. Moreover, respiratory reprogramming to cytochrome bd was observed to protect against INH-induced killing.Intriguingly, we found that Cpn60.1 was required for respiratory and energetic downregulation under excess glycerol as well as in response to drugs (such as Q203 inhibiting cytochrome bc1). Cpn60.1 also played a role in lipidomic adaptation under excess glycerol (e.g. enhanced phthiocerol dimycocerosate and glycerol-based lipids synthesis but repressed trehalose-based lipids synthesis). Defective energetic downregulation in the absence of Cpn60.1 compromised the establishment of the Crabtree effect characterized by respiratory downregulation, glycolytic enhancement and secretion of several metabolites (i.e. pyruvate, succinate, acetate and glutamate). The Crabtree effect was necessary for mycobacterial adaptation to excess glycerol and biofilm growth. Due to a compromised Crabtree effect, a Cpn60.1-deficient Mycobacterium bovis BCG strain, i.e. the Δcpn60.1 strain, suffered from methylglyoxal-induced growth stasis under excess glycerol, leading to the biofilm defect under the standard biofilm medium. Given the essentiality for Cpn60.1 in mycobacterial respiratory adaptation under stresses, it is likely that the enhanced INH susceptibility of the Δcpn60.1 strain under hypoxia was due to a problematic respiratory reprogramming.In summary, Mycobacterium bovis BCG Cpn60.1 is not required for bacillary survival under hypoxic dormancy. However, it participates in various adaptations (e.g. respiratory downregulation) necessary for mycobacterial biofilm growth and for escaping INH’s bactericidal mechanism. / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished

Métabolisme

Electron transport chain

Metabolic pathway

Dormancy

Methylglyoxal

Bedaquiline

Q203

TCA

Glycolysis

Biofilm marker

TARGETING METHYLGLYOXAL AND PPAR GAMMA TO ALLEVIATE NEUROPATHIC PAIN ASSOCIATED WITH TYPE 2 DIABETES

Griggs, Ryan B.

01 January 2015

Neuropathic pain affects up to 50% of the 29 million diabetic patients in the United States. Neuropathic pain in diabetes manifests as a disease of the peripheral and central nervous systems. The prevalence of type 2 diabetes is far greater than type 1 (90%), yet the overwhelming focus on type 1 models this has left the mechanisms of pain in type 2 diabetes largely unknown. Therefore I aimed to improve the current mechanistic understanding of pain associated with type 2 diabetes using two preclinical rodent models: Zucker Diabetic Fatty rats and db/db mice. In addition, I highlight the translational importance of simultaneous measurement of evoked/sensory and non-evoked/affective pain-related behaviors in preclinical models. This work is the first to show a measure of motivational-affective pain in a model of type 2 diabetes. I used methodological approaches including: (1) immunohistochemical and calcium imaging to assess stimulus-evoked sensitization; (2) measurement nociceptive behaviors and evoked sensory thresholds as well as pain affect using novel mechanical conflict avoidance and conditioned place preference/aversion assays; (3) pharmacological and genetic manipulation of methylglyoxal, TRPA1, AC1, and PPARγ. I hypothesized that the thiazolidinedione class of peroxisome proliferator-activated receptor gamma (PPARγ) agonists would reduce neuropathic pain-like behavior and spinal neuron sensitization in traumatic nerve injury and type 2 diabetes. As PPARγ is a nuclear receptor, and already targeted clinically to promote cellular insulin sensitization to reduce hyperglycemia, sustained changes in gene expression are widely believed to be the mechanism of pain reduction. In two separate research aims, I challenged this view and tested whether the PPARγ agonist pioglitazone would (1) rapidly alleviate neuropathic pain through a non-genomic mechanism and (2) reduce painful sensitization in nociceptive and neuropathic pain models independent from lowering blood glucose. I aimed to investigate the contribution of the glucose metabolite methylglyoxal to painful type 2 diabetes. I tested the hypothesis that methylglyoxal produces nociceptive, evoked, and affective pain that is dependent on activation of the sensory neuron cation channel TRPA1 and the secondary messenger enzyme AC1. I also tested whether pioglitazone or the novel methylglyoxal scavenging peptide GERP10 could alleviate painful type 2 diabetes.

painful type 2 diabetes

pioglitazone

chronic neuropathic pain

methylglyoxal

TRPA1

PPAR gamma

Behavioral Neurobiology

Medical Neurobiology

Molecular and Cellular Neuroscience

Neurosciences

Enhanced methylglyoxal formation in cystathionine &gamma;-lyase knockout mice

Untereiner, Ashley Anne

24 June 2011

<p>Methylglyoxal (MG) is a reactive glucose metabolite and a known causative factor for hypertension and diabetes. Hydrogen sulfide (H₂S), on the other hand, is a gasotransmitter with multifaceted physiological functions, including anti-oxidant and vasodilatory properties. The present study demonstrates that MG and H₂S can interact with and modulate each other's functions. Upon <i>in vitro</i> incubations, we found that MG and H₂S can directly interact to form three possible MG-H₂S adducts. Furthermore, the endogenous production level of MG or H₂S was significantly reduced in a concentration-dependent manner in rat vascular smooth muscle cells (A-10 cells) treated with NaHS, a H₂S donor, or MG, respectively. Indeed, MG-treated A-10 cells exhibited a concentration-dependent down-regulation of the protein and activity level of cystathionine &gamma;-lyase (CSE), the main H₂S-generating enzyme in the vasculature. Moreover, H₂S can induce the inhibition of MG-generated ROS production in a concentration-dependent manner in A-10 cells. In 6-22 week-old CSE knockout male mice (CSE^-/-), mice with lower levels of vascular H₂S, we observed a significant elevation in MG levels in both plasma and renal extracts. Renal triosephosphates were also significantly increased in the 6-22 week-old CSE^-/- mice. To identify the source of the elevated renal MG levels, we found that the activity of fructose-1,6-bisphosphatase (FBPase), the rate-limiting enzyme in gluconeogenesis, was significantly down-regulated, along with lower levels of its product (fructose-6-phosphate) and higher levels of its substrate (fructose-1,6-bisphosphate) in the kidney of 6-22 week-old CSE^-/- mice. We have also observed lower levels of the gluconeogenic regulator, peroxisome proliferator-activated receptor-&gamma; coactivator (PGC)-1&alpha;, and its down-stream targets, FBPase-1 and -2, phosphoenolpyruvate carboxykinase (PEPCK), and estrogen-related receptor (ERR)&alpha; mRNA expression levels in renal extracts from 6-22 week-old CSE^-/- mice. Likewise, FBPase-1 and -2 mRNA levels were also significantly down-regulated in aorta tissues from 14-16 week-old CSE^-/- mice. Administration of 30 and 50 &#x00B5;M NaHS induced a significant increase in FBPase-1 and PGC-1&alpha; in rat A-10 cells. We have also observed a significant up-regulation of PEPCK and ERR&alpha; mRNA expression levels in 50 &#x00B5;M NaHS-treated A-10 cells, further confirming the involvement of H₂S in regulating the rate of gluconeogenesis and MG formation. Overall, this unique study demonstrates the existence of a negative correlation between MG and H₂S in the vasculature. Further elucidation of this cross-talk phenomenon between MG and H₂S could lead to more elaborate and effective therapeutic regimens to combat metabolic syndrome and its related health complications.</p>

Hydrogen sulfide

Fructose-1 6-bisphosphatase

Vascular smooth muscle cells

Methylglyoxal

Reactive oxygen species

Enhanced methylglyoxal formation in cystathionine &gamma;-lyase knockout mice

Untereiner, Ashley Anne

24 June 2011

<p>Methylglyoxal (MG) is a reactive glucose metabolite and a known causative factor for hypertension and diabetes. Hydrogen sulfide (H₂S), on the other hand, is a gasotransmitter with multifaceted physiological functions, including anti-oxidant and vasodilatory properties. The present study demonstrates that MG and H₂S can interact with and modulate each other's functions. Upon <i>in vitro</i> incubations, we found that MG and H₂S can directly interact to form three possible MG-H₂S adducts. Furthermore, the endogenous production level of MG or H₂S was significantly reduced in a concentration-dependent manner in rat vascular smooth muscle cells (A-10 cells) treated with NaHS, a H₂S donor, or MG, respectively. Indeed, MG-treated A-10 cells exhibited a concentration-dependent down-regulation of the protein and activity level of cystathionine &gamma;-lyase (CSE), the main H₂S-generating enzyme in the vasculature. Moreover, H₂S can induce the inhibition of MG-generated ROS production in a concentration-dependent manner in A-10 cells. In 6-22 week-old CSE knockout male mice (CSE^-/-), mice with lower levels of vascular H₂S, we observed a significant elevation in MG levels in both plasma and renal extracts. Renal triosephosphates were also significantly increased in the 6-22 week-old CSE^-/- mice. To identify the source of the elevated renal MG levels, we found that the activity of fructose-1,6-bisphosphatase (FBPase), the rate-limiting enzyme in gluconeogenesis, was significantly down-regulated, along with lower levels of its product (fructose-6-phosphate) and higher levels of its substrate (fructose-1,6-bisphosphate) in the kidney of 6-22 week-old CSE^-/- mice. We have also observed lower levels of the gluconeogenic regulator, peroxisome proliferator-activated receptor-&gamma; coactivator (PGC)-1&alpha;, and its down-stream targets, FBPase-1 and -2, phosphoenolpyruvate carboxykinase (PEPCK), and estrogen-related receptor (ERR)&alpha; mRNA expression levels in renal extracts from 6-22 week-old CSE^-/- mice. Likewise, FBPase-1 and -2 mRNA levels were also significantly down-regulated in aorta tissues from 14-16 week-old CSE^-/- mice. Administration of 30 and 50 &#x00B5;M NaHS induced a significant increase in FBPase-1 and PGC-1&alpha; in rat A-10 cells. We have also observed a significant up-regulation of PEPCK and ERR&alpha; mRNA expression levels in 50 &#x00B5;M NaHS-treated A-10 cells, further confirming the involvement of H₂S in regulating the rate of gluconeogenesis and MG formation. Overall, this unique study demonstrates the existence of a negative correlation between MG and H₂S in the vasculature. Further elucidation of this cross-talk phenomenon between MG and H₂S could lead to more elaborate and effective therapeutic regimens to combat metabolic syndrome and its related health complications.</p>

Hydrogen sulfide

Fructose-1 6-bisphosphatase

Vascular smooth muscle cells

Methylglyoxal

Reactive oxygen species

Neuropatia diabética : estudo dos mecanismos moleculares envolvidos com a neurotoxicidade do metilglioxal e do glicolaldeído em células diferenciadas de neuroblastoma humano SH-SY5Y

Londero, Giovana Ferreira

January 2012

Neuropatia é a complicação mais comum e mais debilitante da Diabetes Mellitus, a longo prazo presente em mais de 50% dos pacientes que possuem a doença. A hiperglicemia induz estresse oxidativo nos neurônios de diabéticos acarretando a ativação de múltiplas vias bioquímicas, as quais são potenciais alvos terapêuticos para a neuropatia diabética. Está claro que compostos carbonil reativos são mediadores glicotóxicos do estresse oxidativo através da formação de produtos finais de glicação avançada como resultado direto da hiperglicemia. Metilglioxal e glicolaldeído são compostos carbonil reativos inevitavelmente produzidos pelo metabolismo, os quais são encontrados em maior quantidade em situações de hiperglicemia. Recentemente, tem sido dada muita atenção para o envolvimento de espécies reativas na toxicidade do metilglioxal e do glicolaldeído, e tem-se demonstrado que essas glicotoxinas têm potencial para induzir estresse oxidativo, parar o crescimento celular e promover morte por apoptose ou necrose. O metilglioxal e o glicolaldeído interagem com grupamentos sulfidril de moléculas de glutationa e de enzimas, inibindo sua atividade; entretanto, os mecanismos moleculares relacionados aos efeitos tóxicos dessas glicotoxinas e as vias pelas quais elas levam a formação de espécies reativas não estão completamente elucidados. Neste estudo nós buscamos esclarecer a relação entre o metabolismo do metilglioxal e do glicolaldeído e a produção de espécies reativas, e investigamos as possíveis rotas de morte celular envolvidas. Utilizamos a linhagem celular de neuroblastoma humano SH-SY5Y diferenciada, pois este é um modelo neuronal bem caracterizado para estudos de compostos neurotóxicos. Nós avaliamos a produção de espécies reativas induzida por metilglioxal e glicolaldeído através da técnica da diclorofluoresceína, e avaliamos, também, seus efeitos sob o conteúdo de glutationa celular. Além disso, investigamos a ativação das caspase-3, -8 e -9 e a contribuição de diferentes sistemas peroxidases (glutationa-redutase e a tioredoxina-redutase), na defesa neuronal contra essas glicotoxinas. Como resultados encontramos que o tratamento com ambas glicotoxinas rapidamente provocou um aumento na produção de espécies reativas e diminuição do conteúdo de glutationa, com concomitante ativação das caspases-8 e -9 e, posteriormente, também houve ativação da caspase-3 pelo tratamento com metilglioxal. Vimos que a tioredoxina-redutase possui um papel mais importante na defesa celular contra a toxicidade do metilglioxal do que contra o glicolaldeído, enquanto que a glutationa-redutase tem papel semelhante na defesa celular contra ambas glicotoxinas. Nossos resultados demonstraram que o estresse oxidativo é um importante mecanismo da toxicidade do metilglioxal e do glicolaldeído nas células diferenciadas SHSY5Y e, que enzimas redutoras de grupamentos sulfidril contribuem de diferentes formas na defesa celular contra cada uma dessas glicotoxinas. / Neuropathy is the most common and debilitating complication of Diabetes Mellitus present in more than 50% of the patients with long-standing disease. Hyperglycemia induces oxidative stress in neurons from diabetic patients and results in activation of multiple biochemical pathways. These activated pathways are a major source of damage and are potential therapeutic targets in diabetic neuropathy. A large body of evidence has implicated reactive carbonyl compounds as glycotoxic mediators of oxidative stress by forming advanced glycation endproducts as a direct result of hyperglycemia. Methylglyoxal and glycolaldehyde are reactive carbonil compounds inevitably produced by the metabolism, but they are found in increased rates under hyperglycemia condition. Recently, the attention has been focused on the involvement of reactive species in methylglyoxal and glycolaldehyde toxicities, resulting in oxidative stress and leading to cell growth arrest, apoptotic or necrosis death. These glycotoxins interact with sulfhydryl-groups of glutathione molecules enzymes, inhibiting their activity; however, the molecular mechanism underlying methylglyoxal and glycolaldehyde cytotoxic effects and reactive species generation are not fully understood. In this study we have pursued to establish the role of methylglyoxal and glycolaldehyde metabolisms and reactive species production, and have looked for the possible death routes involved with the toxic effects of these glycotoxins. Here we used the differentiated human neuroblastoma SH-SY5Y cells as neuronal experimental model to investigate the pathological effects of various neurotoxic compounds. We have evaluated the methylglyoxal and glycolaldehyde capacity to reactive species generation by dichlorofluorescein assay and their effects upon cellular glutathione content. Also, we have assessed the caspase-3, -8 and -9 activation and the contribution of different peroxidases systems (glutathione reductase and thioredoxin reductase) in the neuronal defense against methylglyoxal and glycolaldehyde cytotoxicities. We found that both glycotoxins promptly provoke reactive species generation and decrease the cell glutathione content, as well induce caspase-8 and -9 activation. Later caspase-3 activation was found in methylglyoxal treatment. We demonstrate that thioredoxin reductase has a most important role in cell defense against methylglyoxal toxicity than against glycolaldehyde, meanwhile there is no difference in the glutathione reductase role. Our results show that oxidative stress is an important mechanism in the methylglyoxal and glycolaldehyde toxicities and sulfhydryl reductases contributes differently in the cellular defense against these glycotoxins.

Neuropatias diabéticas

Estresse oxidativo

Metilglioxal

Neuroblastoma

Neurotoxicidade

Diabetes neuropathy

Oxidative stress

Methylglyoxal

Glycolaldehyde

Neurotoxicity

SH-SY5Y cells