Biological Applications of a Strongly Luminescent Platinum (II) Complex in Reactive Oxygen Species Scavenging and Hypoxia Imaging in Caenorhabditis elegans

Kinyanjui, Sophia Nduta

12 1900

Phosphorescent transition metal complexes make up an important group of compounds that continues to attract intense research owing to their intrinsic bioimaging applications that arise from bright emissions, relatively long excited state lifetimes, and large stokes shifts. Now for biomaging assay a model organism is required which must meet certain criteria for practical applications. The organism needs to be small, with a high turn-over of progeny (high fecundity), a short lifecycle, and low maintenance and assay costs. Our model organism C. elegans met all the criteria. The ideal phosphor has low toxicity in the model organism. In this work the strongly phosphorescent platinum (II) pyrophosphito-complex was tested for biological applications as a potential in vivo hypoxia sensor. The suitability of the phosphor was derived from its water solubility, bright phosphorescence at room temperature, and long excited state lifetime (~ 10 µs). The applications branched off to include testing of C. elegans survival when treated with the phosphor, which included lifespan and fecundity assays, toxicity assays including the determination of the LC50, and recovery after paraquat poisoning. Quenching experiments were performed using some well knows oxygen derivatives, and the quenching mechanisms were derived from Stern-Volmer plots. Reaction stoichiometries were derived from Job plots, while percent scavenging (or antioxidant) activities were determined graphically. The high photochemical reactivity of the complex was clearly manifested in these reactions.

C. elegans

phosphorescence

PtPOP

ROS scavenging

hypoxia

Caenorhabditis elegans.

Anoxemia.

Imaging systems in biology.

Luminescence spectroscopy.

Platinum -- Spectra.

Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 2: epidermal H2O2/ONOO−-mediated stress in vitiligo hampers indoleamine 2,3-dioxygenase and aryl hydrocarbon receptor-mediated immune response signaling.

Schallreuter, Karin U., Salem, Mohamed M.A., Gibbons, Nick C., Maitland, Derek J., Marsch, E., Elwary, Souna M.A., Healey, Andrew R.

06 1900

No / Vitiligo is characterized by a mostly progressive loss of the inherited skin color. The cause of the disease is still unknown, despite accumulating in vivo and in vitro evidence of massive oxidative stress via hydrogen peroxide (H2O2) and peroxynitrite (ONOO−) in the skin of affected individuals. The most favored hypothesis is based on autoimmune mechanisms. Since depletion of the essential amino acid l-tryptophan (Trp) severely affects various immune responses, we here looked at Trp metabolism and signaling in these patients. Our in vivo and in vitro data revealed total absence of epidermal Trp hydroxylase activities and the presence of H2O2/ONOO− deactivated indoleamine 2,3-dioxygenase. Aryl hydrocarbon receptor signaling is severely impaired despite the ligand (Trp dimer) being formed, as shown by mass spectrometry. Loss of this signal is supported by the absence of downstream signals (COX-2 and CYP1A1) as well as regulatory T-lymphocytes and by computer modeling. In vivo Fourier transform Raman spectroscopy confirmed the presence of Trp metabolites together with H2O2 supporting deprivation of the epidermal Trp pool by Fenton chemistry. Taken together, our data support a long-expressed role for in loco redox balance and a distinct immune response. These insights could open novel treatment strategies for this disease.—Schallreuter, K. U., Salem, M. A. E. L., Gibbons, N. C. J., Maitland, D. J., Marsch, E., Elwary, S., Healey, A. R. Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 2: epidermal H2O2/ONOO−-mediated stress in vitiligo hampers indoleamine 2,3-dioxygenase and aryl hydrocarbon receptor-mediated immune response signaling.

Vitiligo

Epidermal l-tryptophan metabolism

Immune response signaling

ROS scavenging

Hydrogen peroxide (H2O2)

Fenton chemistry

Peroxynitrite

Treg

IDO

Etude de l'effet de l'oxygène sur la physiologie et le métabolisme de la bactérie hyperthermophile anaérobie thermotoga maritima

Lakhal, Raja

15 July 2011

La bactérie hyperthermophile Thermotoga maritima a été cultivée dans un fermenteur dans lequel la concentration en O2 a été rigoureusement contrôlée. A 80°C et pH 7, il a été démontré que T. maritima pouvait survivre à des expositons de durées variables à l’O2 et qu’elle était capable de le consommer. La vitesse spécifique de consommation de l’O2 a été estimée à 73.6 µmoles O2.min-1.g protéines-1 lors d’une courte exposition à l’O2 (30 min). De longues expositions à l’O2 (20 h) nous ont permis de démontrer que la présence d’O2 ralentissait la croissance de T. maritima et conduisait à un shift du métabolisme vers la production de lactate aux dépens de l’acétate et à un arrêt de production d’H2. Dans ces conditions, il a été constaté que 73% du glucose était consommé selon un métabolisme partiellement oxydatif faisant intervenir simultanément les deux voies Embden-Meyerhof et Entner-Doudoroff de la glycolyse. En l’occurrence, l’oxydation incomplète du glucose est corrélée à la réduction de l’O2 en eau. Les études transcriptomiques ont montré que cette réduction de l’O2 résultait d’une cascade de réactions intermédiaires faisant intervenir des enzymes de type peroxydases [activation de l’expression des enzymes Ahp (alkyl hydroperoxyde réductase), Bcp1 et Bcp2 (thiol peroxydase thioredoxin-dépendante)] qui acheminent les électrons libérés via les radicaux libres. D’autres enzymes comme la rubréryhtrine et la neelarédoxine interviendraient pour détoxiquer les espèces réactives d’O2. Les électrons libérés seraient au final utilisés pour réduire l’O2 en H2O par l’enzyme FprA, dont l’expression varie en fonction du potentiel redox du milieu de culture. Ce schéma est proposé comme un des éléments essentiels du dispositif enzymatique permettant la consommation de l’O2 et la protection des cellules contre les effets des espèces réactives de l’oxygène chez T. maritima. / Batch cultures of the hyperthermophilic bacterium Thermotoga maritima were performed in a bioreactor where O2 concentrations in the gas phase were strictly controlled. At 80°C and pH 7, we demonstrated that T. maritima survived despite being exposed to oxygen at different times and that it consumed it. O2 uptake rate was estimated at 73.6 µmoles O2 min-1g proteins-1 during a short exposure to O2 (30 minutes). A long time exposure of T. maritima cultures to oxygen (20h) led to a drastic reduction in growth, together with a shift in glucose metabolism towards lactate instead of acetate production and a stop in H2 production. Under these conditions, it has been observed that 73% of glucose was partially oxidised by using both Embden-Meyerhof and Entner-Doudoroff glycolytic payhways. Uncomplete oxidation of glucose is correlated to a reduction of O2 to H2O. Transcription analyses revealed that this reductive process of O2 involved enzymes like peroxidases [activation of alkyl hydroperoxide reductase (ahp), bcp1 and thioredoxin-dependent thiol peroxidase (bcp 2)]. Moreover, genes encoding reactive oxygen species (ROS)-scavenging systems (neelaredoxin and rubrerythrin), were found to be upregulated during oxygen exposure. The oxygen reductase FprA, which expression was shown to depend on the redox level of the culture medium, is proposed as a primary consumer of O2. All these enzymes are essential for T. maritima to consume O2 consumption and to fight against the toxic effects of ROS in cells.

Thermotoga maritima

Oxygène

Stress oxydant

Métabolisme oxydatif

Espèces réactives de l’oxygène

Thermotoga maritima

Oxygen

Oxidative stress

Oxygen uptake rate

Oxidatif metabolism

ROS scavenging

Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 1: epidermal H2O2/ONOO−-mediated stress abrogates tryptophan hydroxylase and dopa decarboxylase activities, leading to low serotonin and melatonin levels.

Schallreuter, Karin U., Salem, Mohamed M.A., Gibbons, Nick C., Martinez, A., Slominski, Radomir, Lüdemann, J., Rokos, Hartmut

06 1900

No / Vitiligo is characterized by a progressive loss of inherited skin color. The cause of the disease is still unknown. To date, there is accumulating in vivo and in vitro evidence for massive oxidative stress via hydrogen peroxide (H2O2) and peroxynitrite (ONOO−) in the skin of affected individuals. Autoimmune etiology is the favored theory. Since depletion of the essential amino acid l-tryptophan (Trp) affects immune response mechanisms, we here looked at epidermal Trp metabolism via tryptophan hydroxylase (TPH) with its downstream cascade, including serotonin and melatonin. Our in situ immunofluorescence and Western blot data reveal significantly lower TPH1 expression in patients with vitiligo. Expression is also low in melanocytes and keratinocytes under in vitro conditions. Although in vivo Fourier transform-Raman spectroscopy proves the presence of 5-hydroxytryptophan, epidermal TPH activity is completely absent. Regulation of TPH via microphthalmia-associated transcription factor and l-type calcium channels is severely affected. Moreover, dopa decarboxylase (DDC) expression is significantly lower, in association with decreased serotonin and melatonin levels. Computer simulation supports H2O2/ONOO−-mediated oxidation/nitration of TPH1 and DDC, affecting, in turn, enzyme functionality. Taken together, our data point to depletion of epidermal Trp by Fenton chemistry and exclude melatonin as a relevant contributor to epidermal redox balance and immune response in vitiligo.

Vitiligo

Epidermal l-tryptophan metabolism

Melatonin

Immune response signaling

ROS scavenging

Hydrogen peroxide (H2O2)

Fenton chemistry

Peroxynitrite

MITF

Calcium channel

DNA

Oxidative stress