Nitric oxide and KLF4 protein epigenetically modify class II transactivator to repress Major histocompatibility complex II expression during Mycobacterium bovis Bacillus Calmette-Guerin infection

Pathogenic mycobacteria employ several immune evasion strategies such as inhibition of class II transactivator (CIITA) and MHC-II expression, to survive and persist in host macrophages. However, precise roles for specific signaling components executing down-regulation of CIITA/MHC-II have not been adequately addressed. Here, we demonstrate that Mycobacterium bovis bacillus Calmette-Guerin (BCG)-mediated TLR2 signaling-induced iNOS/NO expression is obligatory for the suppression of IFN-gamma-induced CIITA/MHC-II functions. Significantly, NOTCH/PKC/MAPK-triggered signaling cross-talk was found critical for iNOS/NO production. NO responsive recruitment of a bifunctional transcription factor, KLF4, to the promoter of CIITA during M. bovis BCG infection of macrophages was essential to orchestrate the epigenetic modifications mediated by histone methyltransferase EZH2 or miR-150 and thus calibrate CIITA/MHC-II expression. NO-dependent KLF4 regulated the processing and presentation of ovalbumin by infected macrophages to reactive T cells. Altogether, our study delineates a novel role for iNOS/NO/KLF4 in dictating the mycobacterial capacity to inhibit CIITA/MHC-II-mediated antigen presentation by infected macrophages and thereby elude immune surveillance.

Nitric oxide is the key mediator of death induced by fisetin in human acute monocytic leukemia cells

Nitric oxide ( NO) has been shown to be effective in cancer chemoprevention and therefore drugs that help generate NO would be preferable for combination chemotherapy or solo use. This study shows a new evidence of NO as a mediator of acute leukemia cell death induced by fisetin, a promising chemotherapeutic agent. Fisetin was able to kill THP-1 cells in vivo resulting in tumor shrinkage in the mouse xenograft model. Death induction in vitro was mediated by an increase in NO resulting in double strand DNA breaks and the activation of both the extrinsic and the intrinsic apoptotic pathways. Double strand DNA breaks could be reduced if NO inhibitor was present during fisetin treatment. Fisetin also inhibited the downstream components of the mTORC1 pathway through downregulation of levels of p70 S6 kinase and inducing hypo-phosphorylation of S6 Ri P kinase, eIF4B and eEF2K. NO inhibition restored phosphorylation of downstream effectors of mTORC1 and rescued cells from death. Fisetin induced Ca2+ entry through L-type Ca2+ channels and abrogation of Ca2+ influx reduced caspase activation and cell death. NO increase and increased Ca2+ were independent phenomenon. It was inferred that apoptotic death of acute monocytic leukemia cells was induced by fisetin through increased generation of NO and elevated Ca2+ entry activating the caspase dependent apoptotic pathways. Therefore, manipulation of NO production could be viewed as a potential strategy to increase efficacy of chemotherapy in acute monocytic leukemia.

Electron flow through cytochrome P450

The cytochromes P450 (P450s) are a remarkable class of heme enzymes that catalyze the metabolism of xenobiotics and the biosynthesis of signaling molecules. Controlled electron flow into the thiolate-ligated heme active site allows P450s to activate molecular oxygen and hydroxylate aliphatic C–H bonds via the formation of high-valent metal-oxo intermediates (compounds I and II). Due to the reactive nature and short lifetimes of these intermediates, many of the fundamental steps in catalysis have not been observed directly. The Gray group and others have developed photochemical methods, known as “flash-quench,” for triggering electron transfer (ET) and generating redox intermediates in proteins in the absence of native ET partners. Photo-triggering affords a high degree of temporal precision for the gating of an ET event; the initial ET and subsequent reactions can be monitored on the nanosecond-to-second timescale using transient absorption (TA) spectroscopies. Chapter 1 catalogues critical aspects of P450 structure and mechanism, including the native pathway for formation of compound I, and outlines the development of photochemical processes that can be used to artificially trigger ET in proteins. Chapters 2 and 3 describe the development of these photochemical methods to establish electronic communication between a photosensitizer and the buried P450 heme. Chapter 2 describes the design and characterization of a Ru-P450-BM3 conjugate containing a ruthenium photosensitizer covalently tethered to the P450 surface, and nanosecond-to-second kinetics of the photo-triggered ET event are presented. By analyzing data at multiple wavelengths, we have identified the formation of multiple ET intermediates, including the catalytically relevant compound II; this intermediate is generated by oxidation of a bound water molecule in the ferric resting state enzyme. The work in Chapter 3 probes the role of a tryptophan residue situated between the photosensitizer and heme in the aforementioned Ru-P450 BM3 conjugate. Replacement of this tryptophan with histidine does not perturb the P450 structure, yet it completely eliminates the ET reactivity described in Chapter 2. The presence of an analogous tryptophan in Ru-P450 CYP119 conjugates also is necessary for observing oxidative ET, but the yield of heme oxidation is lower. Chapter 4 offers a basic description of the theoretical underpinnings required to analyze ET. Single-step ET theory is first presented, followed by extensions to multistep ET: electron “hopping.” The generation of “hopping maps” and use of a hopping map program to analyze the rate advantage of hopping over single-step ET is described, beginning with an established rhenium-tryptophan-azurin hopping system. This ET analysis is then applied to the Ru-tryptophan-P450 systems described in Chapter 2; this strongly supports the presence of hopping in Ru-P450 conjugates. Chapter 5 explores the implementation of flash-quench and other phototriggered methods to examine the native reductive ET and gas binding events that activate molecular oxygen. In particular, TA kinetics that demonstrate heme reduction on the microsecond timescale for four Ru-P450 conjugates are presented. In addition, we implement laser flash-photolysis of P450 ferrous–CO to study the rates of CO rebinding in the thermophilic P450 CYP119 at variable temperature. Chapter 6 describes the development and implementation of air-sensitive potentiometric redox titrations to determine the solution reduction potentials of a series of P450 BM3 mutants, which were designed for non-native cyclopropanation of styrene in vivo. An important conclusion from this work is that substitution of the axial cysteine for serine shifts the wild type reduction potential positive by 130 mV, facilitating reduction by biological redox cofactors in the presence of poorly-bound substrates. While this mutation abolishes oxygenation activity, these mutants are capable of catalyzing the cyclopropanation of styrene, even within the confines of an E. coli cell. Four appendices are also provided, including photochemical heme oxidation in ruthenium-modified nitric oxide synthase (Appendix A), general protocols (Appendix B), Chapter-specific notes (Appendix C) and Matlab scripts used for data analysis (Appendix D).

I. The rate and mechanism of the vapor-phase reaction between water and parts-per-million concentrations of nitrogen dioxide. II. The rate and mechanism of the air oxidation of parts-per-million concentrations of nitric oxide in the presence of water vapor.

Part I

A study of the thermal reaction of water vapor and parts-per-million concentrations of nitrogen dioxide was carried out at ambient temperature and at atmospheric pressure. Nitric oxide and nitric acid vapor were the principal products. The initial rate of disappearance of nitrogen dioxide was first order with respect to water vapor and second order with respect to nitrogen dioxide. An initial third-order rate constant of 5.5 (± 0.29) x 10⁴ liter² mole^-2 sec^-1 was found at 25˚C. The rate of reaction decreased with increasing temperature. In the temperature range of 25˚C to 50˚C, an activation energy of -978 (± 20) calories was found.

The reaction did not go to completion. From measurements as the reaction approached equilibrium, the free energy of nitric acid vapor was calculated. This value was -18.58 (± 0.04) kilocalories at 25˚C.

The initial rate of reaction was unaffected by the presence of oxygen and was retarded by the presence of nitric oxide. There were no appreciable effects due to the surface of the reactor. Nitric oxide and nitrogen dioxide were monitored by gas chromatography during the reaction.

Part II

The air oxidation of nitric oxide, and the oxidation of nitric oxide in the presence of water vapor, were studied in a glass reactor at ambient temperatures and at atmospheric pressure. The concentration of nitric oxide was less than 100 parts-per-million. The concentration of nitrogen dioxide was monitored by gas chromatography during the reaction.

For the dry oxidation, the third-order rate constant was 1.46 (± 0.03) x 10⁴ liter² mole^-2 sec^-1 at 25˚C. The activation energy, obtained from measurements between 25˚C and 50˚C, was -1.197 (±0.02) kilocalories.

The presence of water vapor during the oxidation caused the formation of nitrous acid vapor when nitric oxide, nitrogen dioxide and water vapor combined. By measuring the difference between the concentrations of nitrogen dioxide during the wet and dry oxidations, the rate of formation of nitrous acid vapor was found. The third-order rate constant for the formation of nitrous acid vapor was equal to 1.5 (± 0.5) x 10⁵ liter² mole^-2 sec^-1 at 40˚C. The reaction rate did not change measurably when the temperature was increased to 50˚C. The formation of nitric acid vapor was prevented by keeping the concentration of nitrogen dioxide low.

Surface effects were appreciable for the wet tests. Below 35˚C, the rate of appearance of nitrogen dioxide increased with increasing surface. Above 40˚C, the effect of surface was small.

Alterações eritrocitárias induzidas pelo exercício físico

Evidências crescentes têm demonstrado que o exercício prejudica a estrutura da membrana eritrocitária, como consequência do aumento do estresse físico e químico. O óxido nítrico (NO) derivado dos eritrócitos afeta a fluidez da membrana e a sua biodisponibilidade depende do equilíbrio entre a sua síntese e eliminação por espécies reativas de oxigênio. Nós investigamos se o exercício realizado em diferentes intensidades afetaria biodisponibilidade do NO eritrocitário e se levaria a um quadro de estresse oxidativo. Dez homens (26 4 anos, VO2pico 44,1 4,3 mL.kg-1.min-1) realizaram um teste cardiopulmonar máximo em esteira e um teste de exercício submáximo a 70% VO2pico durante 30 min. O sangue foi coletado em repouso e imediatamente após os exercícios para isolamento dos eritrócitos. O exercício máximo aumentou a contagem de eritrócitos, hemoglobina e hematócrito, sem levar a qualquer alteração na massa corporal que pudesse sugerir hemoconcentração devido a uma redução do volume plasmático. Observou-se uma diminuição do influxo de L-arginina depois do teste submáximo, mas não no teste máximo. No entanto, a atividade da óxido nítrico sintase, ou seja, a produção de NO, foi aumentada após o teste máximo. Os níveis de GMPc não se alteraram após ambos os teste de exercício. Em relação aos biomarcadores de estresse oxidativo, o exercício submáximo reduziu a oxidação proteica e aumentou a atividade da catalase e a expressão da glutationa peroxidase, enquanto que o exercício máximo levou a uma maior peroxidação lipídica e diminuição da atividade da SOD. Nem a atividade glutationa peroxidase ou a expressão NADPH oxidase foram afetadas pelo exercício. Estes resultados sugerem que o exercício induziu alterações no estresse oxidativo de eritrócitos, que parecem estar mais associadas com a intensidade do que a duração do execicio. Além disso, nas intensidades recomendadas para a promoção da saúde, o exercício mostrou ser protetor, aumentando a atividade e a expressão de enzimas antioxidantes importantes e reduzindo os danos oxidativos.

O papel do óleo de peixe na via L-arginina-óxido nítrico e no estresse oxidativo em eritrócitos: um estudo dose-resposta

Os ácidos graxos poli-insaturados n-3 derivados do óleo de peixe estão associados a benefícios cardiovasculares, que podem ser decorrentes da ativação da óxido nítrico sintase (NOS). Assim como as células endoteliais, os eritrócitos possuem NOS endotelial (eNOS) e induzível (iNOS) e, portanto, são capazes de sintetizar óxido nítrico (NO). O presente estudo testou a capacidade que diferentes concentrações de óleo de peixe tem de ativar a via L-arginina-NO e, em seguida, alterar os níveis de guanosina monofosfato cíclica (GMPc) em eritrócitos de camundongos alimentados com dieta hiperlipídica. Além disso, foram analisados os marcadores de estresse oxidativo nos eritrócitos, objetivando investigar a biodisponibilidade do NO. O transporte de L-arginina, avaliado através da incubação com L-[3H]-arginina, mostrou-se ativado quando da administração de dietas contendo elevadas concentrações de óleo de peixe, em comparação com as dietas contendo baixas concentrações e controle. A atividade da NOS, medida pela conversão de L-[3H]-arginina em L-[3H]-citrulina, e a expressão da eNOS também aumentaram nos animais que se alimentaram com dietas ricas em óleo de peixe. Apesar da ativação da via L-arginina-óxido nítrico observada em nossos experimentos, os níveis de GMPc intraeritrocitário não foram afetados. O dano oxidativo nos eritrócitos aumentou linearmente conforme o óleo de peixe era acrescido na dieta, sem afetar a atividade das enzimas antioxidantes. Além do endotélio, os eritrócitos contribuem para o metabolismo do NO. Desta forma, a ativação da via L-arginina-NO nessas células pode ser benéfica para saúde cardiovascular. Estudos futuros poderão investigar outros marcadores de estresse oxidativo durante o consumo de óleo de peixe para assegurar que o seu uso não resulta em efeitos prejudiciais secundários e para garantir a biodisponibilidade de NO.