Importance de l'enveloppe cellulaire dans la régulation de la production de glutamate par Corynebacterium glutamicum 2262 au cours d'un procédé thermo-induit / Importance of Corynebacterium glutamicum 2262 cell envelop in the regulation of glutamate production during a temperature triggered producing process

Boulahya-Brihmouche, Kenza Amel

08 November 2010

Lors de ce travail, une étude comparative entre trois souches de C. glutamicum a été réalisée. Celles-ci sont C. glutamicum 2262, une souche surproductrice de glutamate suite à l’élévation de température du milieu de culture de 33 à 39°C, C. glutamicum 2262 NP un variant incapable d’excréter du glutamate dans ces mêmes conditions et C. glutamicum 2262 ∆pks13 un mutant dépourvu de bicouche mycolique externe. Un modèle métabolique original reprenant les différentes modifications physiologiques aboutissant à l’excrétion du glutamate au cours du procédé thermo-induit a été établi. La bicouche mycolique joue un rôle primordial puisque son absence affecte sévèrement la production du glutamate. Dans un premier temps, l’élévation de température serait ressentie au niveau de cette bicouche. Ce ressenti, visualisé par l’accumulation de protéines caractéristiques d’un stress thermique, est nécessaire pour que la bactérie soit en capacité de surproduire le glutamate. Par la suite, la production de glutamate est régulée au niveau de l’α-cétoglutarate déshydrogénase (ODH) grâce à la phosphoprotéine OdhI. Suite au changement de température, celle-ci est déphosphorylée ce qui lui permet d’interagir avec ODH et de provoquer l’inhibition de cette dernière. Ceci se traduit par la redirection sur flux carboné vers la synthèse du glutamate. Aucun de ces évènements n’est observé chez C. glutamicum 2262 ∆pks13. Par ailleurs, l’élévation de température induit une modification de la composition de l’enveloppe cellulaire qui semble intervenir dans le processus physiologique aboutissant à l’excrétion du glutamate puisque très peu de changements sont observés chez C. glutamicum 2262 NP / During this work, a comparative study between three strains of Corynebacterium glutamicum was carried out. These strains were C. glutamicum 2262 which overproduces glutamate after an increase in the culture temperature from 33 to 39°C, C. glutamicum 2262 NP which is unable to produce glutamate in the same culture conditions and C. glutamicum 2262 ∆pks13 devoid of outer corynomycolic acid bilayer. An original metabolic model describing the successive physiological modifications responsible for the glutamate excretion during the temperature-triggered process was established. The presence of the corynomycolic acid bilayer appeared to be necessary since its lack affected dramatically the glutamate production. The temperature increase would be first sensed at the level of the external corynomycolic acid layer. This sensing was visualised through the accumulation of thermal stress proteins. In C. glutamicum 2262 ∆pks13, the synthesis of these proteins was not induced. The glutamate production is regulated at the oxoglutarate dehydrogenase (ODH) level by the phosphoprotein OdhI. A consequence of the temperature increase was the dephosphorylation of this regulatory protein and its interaction with ODH, provoking its inhibition. The carbon flux was then reoriented toward the glutamate synthesis. In C. glutamicum 2262 ∆pks13, no dephosphorylation of OdhI and no change in the ODH activity were not determined. The thermal stress also induced a change in the composition of the corynomycolic acid layer which was correlated with the ability of C. glutamicum 2262 to overproduce glutamate. In C. glutamicum 2262 NP, the composition of the corynomycolic acid layer remained unchanged

C. glutamicum

Acides corynomycoliques

Α-cétoglutarate déshydrogénase

Pyruvate déshydrogénase

Protéines de stress

OdhI

Corynebacterium glutamicum

Cotynomycolic acids

Oxoglutarate dehydrogenase

Pyruvate dehydrogenase

Stress proteins

OdhI

Biochemical And Genetic Studies On The Pyruvate Branch Point Enzymes Of Rhizopus Oryzae

Acar, Seyda

01 January 2004

Rhizopus oryzae is a filamentous fungi which produces lactic acid and ethanol in fermentations. R. oryzae has numerous advantages for use industrial production of L-(+)-lactic acid but the yield of lactic acid produced on the basis of carbon consumed is low. Metabolic flux analysis of R. oryzae has shown that most of the pyruvate produced at the end of the glycolysis is channelled to ethanol, acetyl-CoA and oxaloacetate production. This study aimed to answer some questions addressed on the regulation of pyruvate branch point in R. oryzae and for this purpose biochemical characterisation of the enzymes acting at this branch point and cloning the genes coding for these enzymes have been done. Pyruvate decarboxylase was purified and characterised for the first time from R. oryzae. The purified enzyme has a Hill coefficient of 1.84 and the Km of the enzyme is 8.6 mM for pyruvate at pH 6.5. The enzyme is inhibited at pyruvate concentrations higher than 30 mM. The optimum pH for enzyme activity shows a broad range from 5.7 and 7.2. The monomer molecular weight was estimated as 59&plusmn / 2 kDa by SDS-PAGE analysis. Pyruvate decarboxylase (pdcA and pdcB) and lactate dehydrogenase (ldhA and ldhB) genes of R. oryzae have been cloned by PCR-cloning approach and the filamentous fungi Aspergillus niger was transformed with these genes. The A. niger transformed with either of the ldh genes of R. oryzae showed enhanced production of lactic acid compared to wild type. Citric acid production was also increased in these transformants while no gluconate production was observed Cloning of hexokinase gene from R. oryzae using degenerate primers was studied by the use of GenomeWalker kit (Clontech). The results of this study were evaluated by using some bioinformatics tools depending on the unassembled clone sequences of R. oryzae genome.

QD Biochemistry 415-436

Myoglobin redox form stabilization: role of metabolic intermediates and NIR detection

Mohan, Anand

January 1900

Doctor of Philosophy / Food Science Institute / Melvin C. Hunt / Several experiments were conducted to evaluate factors affecting myoglobin redox forms stability and detection of myoglobin redox forms using near infrared (NIR) spectroscopy. In experiment 1, we investigated the relationship between metmyoglobin (MMb) reduction and oxidation of malate to α-ketoglutarate with regeneration of reduced nicotinamide adenine dinucleotide (NADH) via malate dehydrogenase (MDH). Our specific objectives for this experiment were: (1) to examine the interaction of malate and MDH to reduce MMb in vitro, (2) to determine the influence of pH, temperature, NAD[superscript]+, and malate concentration on MDH enzyme activity and MMb reduction, and (3) to determine the effects of malate on NADH generation, metmyoglobin reducing activity, and color stability using beef muscles (Longissimus lumborum, Psoas major, and Semitendinosus) extracts. We observed that, nonenzymatic reduction of horse MMb in vitro in a malate-MDH-NADH system increased with increasing NAD[superscript]+ and L-malate concentrations. Our findings further confirmed that reduction of MMb in beef extract was NAD[superscript]+ and malate concentration dependent (p < 0.05). A model system was described for studying mechanisms of enzymatic reduction of metmyoglobin reduction as a means to improve meat color and the results support the hypothesis that malate can replenish NADH via MDH activity, ultimately resulting in stabilizing myoglobin redox chemistry.In experiment 2, we assessed the ability of mitochondrial and cytoplasmic malate dehydrogenase present in postrigor bovine skeletal muscle to utilize malate as fuel for NADH regeneration and MMb reduction via the malate-NAD-MMb system. Furthermore, addition of lactate to beef mitochondrial and cytoplasmic isolates was evaluated to determine if interactions between malate and lactate increased MMb reduction. Addition of malate to isolated beef mitochondrial and cytoplasmic isolates at pH 7.2 increased (p < 0.05) MMb reduction. MMb reduction resulting from the addition of malate and lactate was equal or greater than MMb reduction resulting from malate alone. The findings from this study provided evidence that mitochondria and cytoplasmic proteins isolated from beef skeletal muscles of different metabolic origin differ substantially in their enzymatic composition. Malate-MDH assisted-MMb reduction using Mitochondrial and cytoplasmic isolates from the three beef skeletal muscles exhibited substantial differences in enzymatic compositions and their ability to reduce MMb in vitro. Differences were also observed in the enzymatic characteristics of MDH-assisted-MMb among the three beef muscles. In experiment 3, we investigated the effects of three glycolytic and tricarboxylic acid cycle metabolites on myoglobin redox forms and their in influence on meat color stability. Eighteen combinations of malate (M), lactate (L), and pyruvate (P) were added to beef Longissimus lumborum, Psoas major, and Semitendinosus muscle homogenates to study their effects on metmyoglobin formation during incubation at 25 °C. Changes in surface color at 0, 2, 4, 8, and 12 hrs were evaluated using refecto-spectrophotometry [both L*a*b* and wavelengths specific for MMb]. Results from this study suggests that at 2% concentrations level of the individual metabolites (M, L, or P), the most effective metabolite at retarding MMb formation was L > M > P in the ST, and M > L > P in the PM and LL muscles. MMB was reduced most effectively with combination of metabolites where M+L > M+P > L+P. Enhancement of meat with these metabolites can effectively extend color life of postrigor meat apparently by providing more reducing conditions for myoglobin, thus increasing myoglobin redox form stability. Experiment 4 was conducted to determine how near-infrared (NIR) tissue oximeter measurements of post-rigor beef skeletal muscle relate with the more established methods of quantifying myoglobin redox states. Surface color differences were created by packaging steaks in vacuum (VAC), 80% O[subscript]2 and 20% CO[subscript]2 modified atmosphere packaging (HiOx MAP), polyvinyl chloride film overwrap (PVC), and HiOx MAP converted to PVC (HiOx-PVC) after 2 days. Changes in surface color and sub-surface pigments during display (0,2, 4, 10, and 15 days at 2 °C) were characterized by using a reflectance-spectrophotometer and a near-infrared tissue oximeter, respectively. Fiber orientation, storage, and packaging affected (p < 0.05) color, total pigment, deoxymyoglobin, and oxymyoglobin content. Tissue oximetry measurements appear to have potential for real-time monitoring of myoglobin redox forms and oxygen status of packaged meat, but fiber orientation needs to be controlled. In experiment 5, we investigated the response of frequency-domain multidistance (FDMD) NIR tissue oximetry for detecting absolute amounts of myoglobin (Mb) redox forms and their relationship to meat color stability. Four packaging formats were used to create different blends of Mb redox forms and meat colors during display. Changes in surface color and subsurface pigment forms during simulated display (0, 2, 4, and 10 d at 2 °C) were evaluated using surface reflecto-spectrophotometry (both L*a*b* and specific wavelengths) and FDMD NIR tissue oximetry. Data for both methods of direct measurement of oxymyoglobin and deoxymyoglobin were strongly related and accounted for 86 to 94% of the display variation in meat color. Indirect estimates of metmyoglobin ranged from r[superscript]2 = 59 to 85%. It appears that NIR tissue oximetry has potential as a noninvasive, rapid method for the assessment of meat color traits and may help improve our understanding of meat color chemistry in post-rigor skeletal muscle.

myoglobin

malate

lactate

pyruvate

malate dehydrogenase

Functions of Extracellular Pyruvate Kinase M2 in Tissue Repair and Regeneration

Zhang, Yinwei

09 May 2016

Pyruvate kinase M2 (PKM2) is a glycolytic enzyme expressed in highly proliferating cells. Studies of PKM2 have been focused on its function of promoting cell proliferation in cancer cells. Our laboratory previously discovered that extracellular PKM2 released from cancer cells promoted angiogenesis by activating endothelial cell proliferation and migration. PKM2 activated endothelial cells through integrin αvβ3. Angiogenesis and myofibroblast differentiation are key processes during wound healing. In this dissertation, I demonstrate that extracellular PKM2 released from activated neutrophils promotes angiogenesis and myofibroblast differentiation during wound healing. PKM2 activates dermal fibroblasts through integrin αvβ3 and PI3K signaling pathway. I also claim that extracellular PKM2 plays a role during liver fibrosis. PKM2 protects hepatic stellate cells from apoptosis by activating the survival signaling pathway.

Pyruvate kinase M2

Wound healing

Angiogenesis

Myofibroblast differentiation

Liver fibrosis

Apoptosis

Phosphoenolpyruvate (PEP) metabolism in roots and nodules of Lupinus angustifolius under P stress

Le Roux, Marcellous Remarque

03 1900

Thesis (MSc)--Stellenbosch University, 2004. / ENGLISH ABSTRACT: This study investigated the activities of several of the enzymes involved in the alternative route of PEP metabolism via PEPc (EC 4.1.1.31). This reaction circumvents the adenyl ate-controlled PK (EC 2.7.1.40) reaction of the conventional glycolytic network under conditions of P stress. It was hypothesized that the synthesis of pyruvate under Pi stress would induce the PEPc alternative route and that C for pyruvate synthesis would primarily be imported via this route. This was assessed by looking at how total enzyme activities are perturbed under P stress and also by following the route of radioactive labelled 14C02 under sufficient (2 mM) and deficient P (2 JlM) conditions in either roots or nodules. The significance of the pathway under P stress, was further assessed by determining pool sizes of pyruvate that was synthesized from PEPc-derived C. The experiments were conducted under glasshouse conditions, as two separate studies: one to investigate the phenomenon of Pi stress and its consequences for PEPc-derived C metabolism, and the other one to study the enzymes involved. Seeds of Lupinus angustifolius (cv. Wonga) were inoculated with Rhizobium sp. (Lupinus) bacteria and grown in hydroponic culture. Tanks were supplied with either 2 JlM P04 (LP) or 2 mM P04 (control) and air containing 360 ppm CO2. Roots experienced pronounced P stress with a greater decline in Pi, compared to nodules. LP roots synthesized more pyruvate from malate than LP nodules, indicating the engagement of the PEPc route under Pi stress. In this regard, pyruvate is considered as a key metabolite under Pi stress. The role of pyruvate accumulation under Pi stress, was further highlighted by the metabolism of PEP via both the PK and PEPc routes. The enhanced PK activities supported these high pyruvate levels. Under P stress, PEPc activities increased in roots but not in nodules and these changes were not related to the expression of the enzyme. Root and nodular PEPc were not regulated by expression, but possibly by posttranslational control. The novelty of our results for symbiotic roots demonstrates that using metabolically available Pi is indeed a more sensitive indicator ofP stress. These results show that under Pi stress, nodules are able to maintain their Pi and adenylate levels, possibly at the expense of the root. It is suggested that nodules do not experience P stress to the same extent as roots or alternatively function optimally under conditions of low P availability. The increase in concentration of pyruvate synthesized from malate, indeed suggest that under LP conditions there is an increase requirement for pyruvate. It is clear from this data that the operation of bypass route in nodules should be investigated further. Nevertheless, this study provided incentives for understanding the role of C pathways in Ni-fixation, in particular under conditions ofP limitation. / AFRIKAANSE OPSOMMING: Die doel van hierdie studie was om die aktiwiteite van verskeie ensieme van die alternatiewe metaboliese roete via phosphoenolpirovaat karboksilase (pEPc, EC 4.1.1.31) te ondersoek. Dié reaksie omseil die adenilaat-beheerde pirovaatkinase (PK, EC 2.7.1.40) reaksie van die konvensionele glikolitiese weg onder toestande van fosfaat (P) stremming. Dit is gepostuleer dat die sintese van pirovaat onder toestande van Pstremming die alternatiewe roete via PEPc sou induseer en dat die koolstof (C) vir pirovaatsintese gevolglik hoofsaaklik vanaf hierdie roete sou kom. Dit is bepaal deur die veranderinge in die totale ensiemaktiwiteite wat sou plaasvind onder P-stremming te ondersoek. Daar is ook gekyk na die roete' wat radioaktiewe C C4C02) sou volg in wortles en wortelknoppies wat behandel is deur blootsteling aan eerder lae fosfaat (2 1lM) of genoegsame fosfaat (2 mM; kontrole), Die betekenis van die alternatiewe roete is ook ondersoek deur die poel-groottes van pirovaat, soos gesintetiseer via die PEPc reaksie, te bepaal. Twee eksperimente is in 'n glashuis uitgevoer. Eerstens is die verskynsel van Pstremming, asook die invloed daarvan op PEPc-afgeleide C-metabolisme, bepaal. Tweedens is die betrokke ensieme bestudeer. Sade van Lupinus angustifolius (cv. Wonga) is geïnokuleer met Rhizobium sp. (Lupinus) bakterieë en in 'n waterkultuur gekweek. Die houers is voorsien met óf2 IlM P04 (LP) óf 2 mM P04 (HP) en lug wat 360 ppm C02 bevat het. Wortels, anders as wortelknoppies, het 'n betekenisvolle afname in anorganiese P (Pi) ervaar. Onder P-stremming, het lae fosfaat wortels meer pirovaat vanaf malaat gesintetiseer as wortelknoppies, wat 'n definitiewe bydrae vanaf die PEPc roete impliseer. Hiervolgens is pirovaat 'n sleutel metaboliet onder P-stremming. Die belangrikheid van die akkumulering van pirovaat onder P-stremmende toestande is verder beklemtoon deur die toename in metabolisme van PEP via beide die PK- en die PEPcreaksies. Die toename in PK-aktiwiteite is goed gekorreleer met die verhoogde produksie van pirovaat. Onder toestande van P-stremming het die aktiwiteit van PEPc in wortels verhoog, maar nie in wortelknoppies nie. Dit was nie die gevolg van 'n verhoogde uitdrukking van die ensiem nie. Wortel- en wortelknoppie- uitdrukking van PEPc is derhalwe nie gereguleer deur die uitdrukking daarvan nie, maar eerder deur post-tranlasie kontrole. Hierdie resultate vir wortels met wortelknoppies demonstreer dat metaboliese Pi 'n beter maatstaf is om P-stres aan te dui. Hierdie resultate toon dat wortelknoppies beter daartoe instaat is om hul Pi-vlakke en adenilaatvlakke te reguleer, en dit mag ten koste van die gasheerwortel wees. Ons stel voor dat wortelknoppies nie P-stremming tot dieselfde mate ervaar as die gasheerwortel nie en dat dié knoppies optimaal funksioneer by lae Pi vlakke. Die verhoogde konsentrasie van pirovaat, wat vanaf malaat gesintetiseer is, impliseer dat daar 'n groter vereiste is vir dié metaboliet onder toestande van Pstremming. Hierdie studie het die rol van koolstofmetabolismein stikstofbindende organismes, spesifiek onder toestande van fosfaat-tekort, beklemtoon.

Lupinus angustifolius -- Roots

Pyruvate kinase

Root-tubercles

Étude de l'implication des navettes du pyruvate découlant du métabolisme mitochondrial du glucose dans la régulation de la sécrétion d'insuline par les cellules bêta pancréatiques

Guay, Claudiane

01 1900

Le diabète est une maladie métabolique qui se caractérise par une résistance à l’insuline des tissus périphériques et par une incapacité des cellules β pancréatiques à sécréter les niveaux d’insuline appropriés afin de compenser pour cette résistance. Pour mieux comprendre les mécanismes déficients dans les cellules β des patients diabétiques, il est nécessaire de comprendre et de définir les mécanismes impliqués dans le contrôle de la sécrétion d’insuline en réponse au glucose. Dans les cellules β pancréatiques, le métabolisme du glucose conduit à la production de facteurs de couplage métabolique, comme l’ATP, nécessaires à la régulation de l’exocytose des vésicules d’insuline. Le mécanisme par lequel la production de l’ATP par le métabolisme oxydatif du glucose déclenche l’exocytose des vésicules d’insuline est bien décrit dans la littérature. Cependant, il ne peut à lui seul réguler adéquatement la sécrétion d’insuline. Le malonyl-CoA et le NADPH sont deux autres facteurs de couplage métaboliques qui ont été suggérés afin de relier le métabolisme du glucose à la régulation de la sécrétion d’insuline. Les mécanismes impliqués demeurent cependant à être caractérisés. Le but de la présente thèse était de déterminer l’implication des navettes du pyruvate, découlant du métabolisme mitochondrial du glucose, dans la régulation de la sécrétion d’insuline. Dans les cellules β, les navettes du pyruvate découlent de la combinaison des processus d’anaplérose et de cataplérose et permettent la transduction des signaux métaboliques provenant du métabolisme du glucose. Dans une première étude, nous nous sommes intéressés au rôle de la navette pyruvate/citrate dans la régulation de la sécrétion d’insuline en réponse au glucose, puisque cette navette conduit à la production dans le cytoplasme de deux facteurs de couplage métabolique, soit le malonyl-CoA et le NADPH. De plus, la navette pyruvate/citrate favorise le flux métabolique à travers la glycolyse en réoxydation le NADH. Une étude effectuée précédemment dans notre laboratoire avait suggéré la présence de cette navette dans les cellules β pancréatique. Afin de tester notre hypothèse, nous avons ciblé trois étapes de cette navette dans la lignée cellulaire β pancréatique INS 832/13, soit la sortie du citrate de la mitochondrie et l’activité de l’ATP-citrate lyase (ACL) et l’enzyme malique (MEc), deux enzymes clés de la navette pyruvate/citrate. L’inhibition de chacune de ces étapes par l’utilisation d’un inhibiteur pharmacologique ou de la technologie des ARN interférant a corrélé avec une réduction significative de la sécrétion d’insuline en réponse au glucose. Les résultats obtenus suggèrent que la navette pyruvate/citrate joue un rôle critique dans la régulation de la sécrétion d’insuline en réponse au glucose. Parallèlement à notre étude, deux autres groupes de recherche ont suggéré que les navettes pyruvate/malate et pyruvate/isocitrate/α-cétoglutarate étaient aussi importantes pour la sécrétion d’insuline en réponse au glucose. Ainsi, trois navettes découlant du métabolisme mitochondrial du glucose pourraient être impliquées dans le contrôle de la sécrétion d’insuline. Le point commun de ces trois navettes est la production dans le cytoplasme du NADPH, un facteur de couplage métabolique possiblement très important pour la sécrétion d’insuline. Dans les navettes pyruvate/malate et pyruvate/citrate, le NADPH est formé par MEc, alors que l’isocitrate déshydrogénase (IDHc) est responsable de la production du NADPH dans la navette pyruvate/isocitrate/α-cétoglutarate. Dans notre première étude, nous avions démontré l’importance de l’expression de ME pour la sécrétion adéquate d’insuline en réponse au glucose. Dans notre deuxième étude, nous avons testé l’implication de IDHc dans les mécanismes de régulation de la sécrétion d’insuline en réponse au glucose. La diminution de l’expression de IDHc dans les INS 832/13 a stimulé la sécrétion d’insuline en réponse au glucose par un mécanisme indépendant de la production de l’ATP par le métabolisme oxydatif du glucose. Ce résultat a ensuite été confirmé dans les cellules dispersées des îlots pancréatiques de rat. Nous avons aussi observé dans notre modèle que l’incorporation du glucose en acides gras était augmentée, suggérant que la diminution de l’activité de IDHc favorise la redirection du métabolisme de l’isocitrate à travers la navette pyruvate/citrate. Un mécanisme de compensation à travers la navette pyruvate/citrate pourrait ainsi expliquer la stimulation de la sécrétion d’insuline observée en réponse à la diminution de l’expression de IDHc. Les travaux effectués dans cette deuxième étude remettent en question l’implication de l’activité de IDHc, et de la navette pyruvate/isocitrate/α-cétoglutarate, dans la transduction des signaux métaboliques reliant le métabolisme du glucose à la sécrétion d’insuline. La navette pyruvate/citrate est la seule des navettes du pyruvate à conduire à la production du malonyl-CoA dans le cytoplasme des cellules β. Le malonyl-CoA régule le métabolisme des acides gras en inhibant la carnitine palmitoyl transférase 1, l’enzyme limitante dans l’oxydation des acides gras. Ainsi, l’élévation des niveaux de malonyl-CoA en réponse au glucose entraîne une redirection du métabolisme des acides gras vers les processus d’estérification puis de lipolyse. Plus précisément, les acides gras sont métabolisés à travers le cycle des triglycérides/acides gras libres (qui combinent les voies métaboliques d’estérification et de lipolyse), afin de produire des molécules lipidiques signalétiques nécessaires à la modulation de la sécrétion d’insuline. Des études effectuées précédemment dans notre laboratoire ont démontré que l’activité lipolytique de HSL (de l’anglais hormone-sensitive lipase) était importante, mais non suffisante, pour la régulation de la sécrétion d’insuline. Dans une étude complémentaire, nous nous sommes intéressés au rôle d’une autre lipase, soit ATGL (de l’anglais adipose triglyceride lipase), dans la régulation de la sécrétion d’insuline en réponse au glucose et aux acides gras. Nous avons démontré que ATGL est exprimé dans les cellules β pancréatiques et que son activité contribue significativement à la lipolyse. Une réduction de son expression dans les cellules INS 832/13 par RNA interférant ou son absence dans les îlots pancréatiques de souris déficientes en ATGL a conduit à une réduction de la sécrétion d’insuline en réponse au glucose en présence ou en absence d’acides gras. Ces résultats appuient l’hypothèse que la lipolyse est une composante importante de la régulation de la sécrétion d’insuline dans les cellules β pancréatiques. En conclusion, les résultats obtenus dans cette thèse suggèrent que la navette pyruvate/citrate est importante pour la régulation de la sécrétion d’insuline en réponse au glucose. Ce mécanisme impliquerait la production du NADPH et du malonyl-CoA dans le cytoplasme en fonction du métabolisme du glucose. Cependant, nos travaux remettent en question l’implication de la navette pyruvate/isocitrate/α-cétoglutarate dans la régulation de la sécrétion d’insuline. Le rôle exact de IDHc dans ce processus demeure cependant à être déterminé. Finalement, nos travaux ont aussi démontré un rôle pour ATGL et la lipolyse dans les mécanismes de couplage métabolique régulant la sécrétion d’insuline. / Diabetes is a metabolic disorder characterized by a combination of insulin resistance in peripheral tissues with an inappropriate amount of insulin secreted by the pancreatic β-cells to overcome this insulin resistance. In order to help find a cure for diabetic patients, we need to elucidate the mechanisms underlying the proper control of insulin secretion in response to glucose. In pancreatic β-cells, glucose metabolism leads to the production of metabolic coupling factors, like ATP, implicated in the regulation of insulin vesicle exocytosis. The mechanism linking ATP production by the oxidative metabolism of glucose to the triggering of insulin release that involves Ca2+ and metabolically sensitive K+ channels is relatively well known. Other mechanisms are also involved in the regulation of insulin secretion in response to glucose and other nutrients, such as fatty acids and some amino acids. Malonyl-CoA and NADPH are two metabolic coupling factors that have been suggested to be implicated in the transduction of metabolic signaling coming from glucose metabolism to control the release of insulin granules. However, the mechanisms implicated remained to be defined. The goal of the present thesis was to further our understanding of the role of the pyruvate shuttles, derived from mitochondrial glucose metabolism, in the regulation of insulin secretion. In pancreatic β-cells, pyruvate shuttles are produced by the combination of anaplerosis and cataplerosis processes and are thought to link glucose metabolism to the regulation of insulin secretion by the production metabolic coupling factors. In our first study, we wished to determine the role of the pyruvate/citrate shuttle in the regulation of glucose-induced insulin secretion. The pyruvate/citrate shuttle leads to the production in the cytoplasm of both malonyl-CoA and NADPH and also stimulates the metabolic flux through the glycolysis by re-oxidating NADH. A previous study done in the group of Dr Prentki has suggested the feasibility of the pyruvate/citrate shuttle in pancreatic β-cells. To investigate our hypothesis, we inhibited three different steps of this shuttle in INS 832/13 cells, a pancreatic β-cell line. Specifically, we repressed, using pharmacological inhibitors or RNA interference technology, the mitochondrial citrate export to the cytoplasm and the expression of malic enzyme (MEc) and ATP-citrate lyase (ACL), two key enzymes implicated in the pyruvate/citrate shuttle. The inhibition of each of those steps resulted in a reduction of glucose-induced insulin secretion. Our results underscore the importance of the pyruvate/citrate shuttle in the pancreatic β-cell signaling and the regulation of insulin secretion in response to glucose. Other research groups are also interested in studying the implication of pyruvate cycling processes in the regulation of insulin exocytosis. They suggested a role for the pyruvate/malate and the pyruvate/isocitrate/α-ketoglutarate shuttles. Therefore, three different shuttles derived from the mitochondrial glucose metabolism could be implicated in the regulation of glucose-induced insulin release. All those three shuttles can produce NADPH in the cytoplasm. In the pyruvate/malate and the pyruvate/citrate shuttles, the NADPH is formed by cytosolic malic enzyme (MEc), whereas in the pyruvate/isocitrate/α-ketoglutarate, NADPH is produced by cytosolic isocitrate dehydrogenease (IDHc). In our first study, we established the importance of MEc expression in the regulation of insulin secretion. In our second study, we wanted to investigate the importance of IDHc expression in glucose-induced insulin secretion. The reduction of IDHc expression in INS 832/13 cells stimulated insulin release in response to glucose by a mechanism independent of ATP production coming from glucose oxidative metabolism. This stimulation was also observed in isolated rat pancreatic cells. IDHc knockdown cells showed elevated glucose incorporation into fatty acids, suggesting that isocitrate metabolism could be redirected into the pyruvate/citrate shuttle in these cells. Taken together, these results suggest that IDHc is not essential for glucose-induced insulin secretion and that a compensatory mechanism, probably involving the pyruvate/citrate shuttle, explains the enhanced insulin secretion in IDHc knockdown cells . The pyruvate/citrate shuttle is the only pyruvate shuttle that is linked to the production of malonyl-CoA. Malonyl-CoA is a known inhibitor of carnitine palmitoyl transferase 1, the rate-limiting step in fatty acid oxidation. Therefore, the raising level of malonyl-CoA in response to glucose redirects the metabolism of fatty acids into the triglycerides/free fatty acids cycle which combine esterification and lipolysis processes. Previous studies done in the laboratory of Dr Prentki supported the concept that lipolysis of endogenous lipid stores is an important process for the appropriate regulation of insulin secretion. A first lipase, hormone-sensitive lipase (HSL), has been identified in pancreatic β-cells. HSL expression is important, but not sufficient, for the β-cell lipolysis activity. In a complementary study, we have investigated the role of another lipase, adipose triglyceride lipase (ATGL), in the regulation of insulin secretion in response to glucose and to fatty acids. We first demonstrated the expression and the activity of ATGL in pancreatic β-cells. Reducing ATGL expression using shRNA in INS 832/13 cells caused a reduction in insulin secretion in response to glucose and to fatty acids. Pancreatic islets from ATGL null mice also showed defect in insulin release in response to glucose and to fatty acids. The results demonstrate the importance of ATGL and intracellular lipid signaling in the regulation of insulin secretion. In conclusion, the work presented in this thesis suggests a role for the pyruvate/citrate shuttle in the regulation of insulin secretion in response to glucose. This mechanism possibly implicates the production of NADPH and malonyl-CoA in the cytoplasm. The results also points to a re-evaluation of the role of IDHc in glucose-induced insulin secretion. The precise role of IDHc in pancreatic β-cells needs to be determined. Finally, the data have also documented a role of lipolysis and ATGL in the coupling mechanisms of insulin secretion in response to both fuel and non-fuel stimuli.

Cellules bêta pancréatiques

Sécrétion insuline

Métabolisme du glucose

Anaplérose

Navettes du pyruvate

Navette pyruvate/citrate

Facteurs de couplage métabolique

NADPH

Pancreatic beta cells

Insulin secretion

Glucose metabolism

Anaplerosis

Pyruvate cycling

Pyruvate/citrate shuttle

metabolic coupling factors

NADPH

Preclinical evaluation of pharmacological strategies designed to enhance the activity of established and novel anti-cancer drugs : synopsis - evaluation of pharmacological strategies designed to modulate the Warburg effect, enhance the activity of tyrosine kinase inhibitors and novel analogues of Temozolomide

Saleem, Mohammed Umer

January 2014

Whilst progress has been made in reducing mortality in some cancers, mortality rates remain high in many cancers and there is a need to develop novel therapeutic strategies. In this thesis, various pharmacological strategies designed to enhance the activity of existing therapeutic drugs were evaluated. Cancer cells are dependent upon aerobic glycolysis (the Warburg effect) and glutamine uptake. Using clinically approved tyrosine kinase inhibitors and Bortezomib, significant enhancement of chemosensitivity was observed when used in combination with inhibitors of lactate dehydrogenase (Gossypol) and pyruvate kinase dehydrogenase (Dichloroacetate). In contrast, depletion of glutamine from media had to be extensive in order to induce cell death and cell death only occurred after prolonged exposure to glutamine-deprived conditions. This suggests that glutamine depletion strategies alone are unlikely to be successful but may be useful in combination with other agents targeting glutamine addiction in cancer cells. Finally, Temozolomide (TMZ) is an important drug in the treatment of glioblastomas but its activity is reduced by resistance mechanisms including O6 methyl guanine methyltransferase (MGMT) and mismatch repair (MMR). This thesis has identified analogues of TMZ (EA02-45, EA02-59, EA02-64 and EA02-65) that are MGMT and MMR independent in terms of inducing cell kill in vitro. These compounds are promising leads for future development. In conclusion, this thesis has demonstrated that interfering with the metabolic phenotype of cancer can enhance the activity of existing drugs and identified novel analogues of TMZ that circumvent drug resistance mechanisms that hamper the efficacy of TMZ.

616.99

Effects of low-load repetitive work and mental load on sensitising substances and metabolism in the trapezius muscle

Flodgren, Gerd

January 2007

Low-load repetitive work (LLRW) and mental load are important risk factors for the development of workrelated muscle pain. The link between these risk factors and the development of pain is still not understood, but stimulation of chemo-sensitive receptors in the muscle probably plays an important role. It has been suggested that sensitising substances may accumulate in the muscle during LLRW, especially when combined with mental load. The overall purpose of this thesis was to try to shed some light on the effects of LLRW on the concentration of sensitising substances (glutamate, prostaglandin E2 (PGE2), norepinephrine (NE)) and on metabolism (lactate, pyruvate and oxygenation) in the trapezius muscle of healthy controls (CON) and subjects with trapezius myalgia (TM). A first step was to investigate whether females with TM exhibit higher absolute concentrations of glutamate and PGE2 in the affected muscle during rest. Using Microdialysis (MD) females with TM and asymptomatic controls were studied during four hours of rest. [Glutamate] and [PGE2] during rest did not differ between groups. A second step was to investigate, in a simulated occupational setting, the effects of LLRW on the concentration of sensitising substances and metabolism in the trapezius muscle of TM and CON, and whether increased work duration resulted in a progressive effect. Asymptomatic females were studied during baseline rest, 30 versus 60 min work and recovery, using MD and near infrared spectroscopy (NIRS). Subjects with TM were studied during baseline rest, 30 min work and recovery. [Glutamate] and [lactate] increased in response to work, but not progressively with increased work duration. [Glutamate] was at all time points significantly lower in TM. [PGE2]and oxygenation remained unchanged during work for CON, while for TM oxygenation decreased significantly during work. In TM [pyruvate] increased during both work and recovery, and a significant interaction between groups was found for [pyruvate] during recovery; while moderately increased in CON it increased progressively in TM. The effects of LLRW with and without superimposed mental load on intramuscular [NE], muscle activity and oxygen saturation in the trapezius were also investigated and compared. Using MD, electromyography and NIRS, healthy females were studied on two occasions; during 30 min LLRW and during 30 min LLRW with superimposed mental load. During work [NE], and muscle activity, were increased, while oxygenation decreased, but no differences between occasions. However, recovery of [NE] to baseline was slower after LLRW with superimposed mental load. The findings of the present thesis suggest: (i) no inflammation, or increased interstitial [glutamate] in TM; (ii) LLRW causes an increased anaerobic metabolism in both TM and CON; (iii) no effect of work duration was found; (iv) a significant difference in the effects of LLRW on the interstitial milieu of the trapezius muscle in TM as compared to CON; (v) LLRW causes a significant increase in [NE], but superimposed mental load does not cause a further increase; (vi) LLRW with a superimposed mental load may result in a slower recovery to baseline [NE] as compared with LLRW alone.

work-related muscle pain

microdialysis

near-infrared spectroscopy

electromyography

glutamate

lactate

pyruvate

prostaglandin E2

norepinephrine

Dynamic Interleaved Imaging of Pyruvate Metabolism with Hyperpolarized 13C

Leung, Kevin Kai-Chi

24 May 2011

Dynamic nuclear polarization and dissolution of 13C-labeled metabolite allows dynamic imaging of metabolism in-vivo. However, the spatial and temporal resolutions of magnetic resonance spectroscopic imaging are limited by the duration of free-induction decay acquisitions and the T1-based, non-recoverable polarization decay. This thesis describes the implementation of a spectral-spatial radiofrequency excitation pulse with a `flyback' echo-planar readout trajectory to dynamically image [1-13C]-pyruvate and [1-13C]-lactate in an interleaved manner. This technique excites a single resonance of either [1-13C]-pyruvate or [1-13C]-lactate and generates dynamic images with 5mm in-plane resolution. Metabolite dynamics extracted from the images and the corresponding non-localized spectroscopic data reveal similar kinetic rates upon fitting to a kinetic model. This demonstrates the feasibility of probing metabolism in heterogeneous tissues in-vivo with dynamic interleaved 13C MR imaging.

13C

hyperpolarized

metabolism

pyruvate

spectral-spatial

DNP

MR metabolic imaging

cancer

0760

0574

0719

0992

0541

Dynamic Interleaved Imaging of Pyruvate Metabolism with Hyperpolarized 13C

Leung, Kevin Kai-Chi

24 May 2011

Dynamic nuclear polarization and dissolution of 13C-labeled metabolite allows dynamic imaging of metabolism in-vivo. However, the spatial and temporal resolutions of magnetic resonance spectroscopic imaging are limited by the duration of free-induction decay acquisitions and the T1-based, non-recoverable polarization decay. This thesis describes the implementation of a spectral-spatial radiofrequency excitation pulse with a `flyback' echo-planar readout trajectory to dynamically image [1-13C]-pyruvate and [1-13C]-lactate in an interleaved manner. This technique excites a single resonance of either [1-13C]-pyruvate or [1-13C]-lactate and generates dynamic images with 5mm in-plane resolution. Metabolite dynamics extracted from the images and the corresponding non-localized spectroscopic data reveal similar kinetic rates upon fitting to a kinetic model. This demonstrates the feasibility of probing metabolism in heterogeneous tissues in-vivo with dynamic interleaved 13C MR imaging.

13C

hyperpolarized

metabolism

pyruvate

spectral-spatial

DNP

MR metabolic imaging

cancer

0760

0574

0719

0992

0541