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Structure-Activity Relationship Studies of Imidazo[4,5-b]pyrazine Derivatives as Mitochondrial Uncouplers and their Potential in the Treatment of ObesitySantiago-Rivera, Jose Antonio 16 December 2021 (has links)
Mitochondrial uncouplers have the capacity of passively shuttling protons from the mitochondrial intermembrane space to the mitochondrial matrix, independent of ATP synthase. This results in the disruption of oxidative phosphorylation and increased rate of metabolism as a counter action from the mitochondria. Therefore, small molecule mitochondrial uncouplers have potential for the treatment of obesity, diabetes, non-alcoholic fatty liver disease (NAFLD), neurodegenerative disorders, amongst others.
A one-pot method for the synthesis of 1H-imidazo[4,5-b]pyrazines from [1,2,5]oxadiazolo[3,4-b]pyrazines is herein disclosed. In the presence of Fe, Yb(OTf)3, and the desired electrophile partner, in situ reduction of the oxadiazole fragment followed by cyclization afforded imidazolopyrazines in moderate to good yields. The selection of different orthoesters as electrophiles also allowed functionalization on the 2-position of the imidazole ring. This new method was used to synthesize 1H-imidazo[4,5-b]pyrazines to perform structure-activity relationship studies. Thus, a library of 75 compounds was synthesized and characterized for mitochondrial uncoupling activity. The biological activity of the compounds was demonstrated in oxygen consumption rate assays affording potent mitochondrial uncouplers. The method was further applied to the synthesis of 5-alkoxy-2-(trifluoromethyl)-1H-imidazo[4,5-b]pyrazin-6-amines, with over 50 derivatives synthesized. A structure-activity relationship study was performed using a variety of substituents to fine-tune the scaffold's potency. The installation of a methoxy group at the 5-position of the scaffold resulted in the discovery of compound 4.3.20, which exhibited the best activity with an EC50 of 3.6 ± 0.4 μM in rat L6 myoblasts and a half-life of 4.4 h in mice. Compound 4.3.20 displayed potential as an anti-obesity agent in a mouse model with an effective dose of 50 mg kg-1 without changes in food intake or lean mass. Tissue distribution studies revealed predominance in the liver and both white and brown adipose tissue. In addition, 4.3.20 improved serum markers of insulin sensitivity and hyperlipidemia such as insulin, glucose, triglycerides, cholesterol, and HOMA-IR. Taken together, compound 4.3.20 and related mitochondrial uncouplers show promise for further development in the treatment of obesity and other diseases. / Doctor of Philosophy / The mitochondria, which is an organelle within our cells, is where all the nutrients ingested in the form of food are metabolized, and either used for energy or stored as fat if they are not used. The latter is the main cause of obesity, carrying with it a myriad other comorbidities, such as high blood pressure, heart disease, diabetes, certain types of cancer. Obesity has become a great concern with an incidence of 42% in the US.
Mitochondrial uncouplers are molecules that target the mitochondria with a mechanism of action of converting some of the energy ingested in the form of nutrients to be lost as heat instead of being stored as fat. The potential result is a regulated form of weight-loss.
Herein, we developed a method for the synthesis of a novel mitochondrial uncoupler scaffold and disclose the mitochondrial uncoupler activity of over 150 molecules. In particular, compound 4.3.20 was tested in an obesity mouse model and was shown to induce fat loss with mice fed a high fat diet. Our investigations support potential use of mitochondrial uncouplers as a mechanism for the treatment and prevention of obesity and other metabolic diseases.
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Tumors attenuating the mitochondrial activity in T cells escape from PD-1 blockade therapy / T細胞ミトコンドリアを抑制するがんは PD-1阻害がん免疫治療から逃避するAlok, Kumar 27 July 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22694号 / 医博第4638号 / 新制||医||1045(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 生田 宏一, 教授 竹内 理, 教授 濵﨑 洋子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Structure-Activity Relationship Studies of Sphingosine Kinase Inhibitors and Mitochondrial UncouplersChildress, Elizabeth Saunders 19 July 2017 (has links)
Sphingosine 1-phosphate (S1P) is a cellular signaling molecule that has been implicated in a variety of diseases including cancer, fibrosis, Alzheimer's, and sickle cell disease. It is formed from the phosphorylation of sphingosine (Sph) by sphingosine kinase (SphK) and SphK exists as two isoforms-"SphK1 and SphK2, which differ with respect to their cellular activity and localization. As the key mediators in the synthesis of S1P, SphKs have attracted attention as viable targets for pharmaceutical inhibition. To validate their potential as therapeutic targets, we aimed to develop potent, selective, and in vivo active inhibitors of SphK.
Herein, we describe the design, synthesis and biological evaluation of SphK2 inhibitors. We first describe the development of six SphK2 inhibitors that assess the utility of replacing lipophilic tail groups with heterocyclic rings. These six compounds demonstrate that the lipid binding pocket for SphK2 cannot accommodate compounds with tail groups that are conformationally restricted or positively charged. We then describe the development of aminothiazole-based analogues of an SphK1-selective inhibitor. A library of 37 aryl-substituted aminothiazole tail groups were synthesized, revealing a structure-activity relationship study that examines electronic effects on the aryl-substituted aminothiazoles and the effect of modifying the amino portion of the aminothiazole. These molecules show surprisingly good potency and selectivity for SphK2. In particular, we highlight 3.20dd (SLC4101431), a biphenyl aminothiazole that is the post potent and selective SphK2 inhibitor to date, with an SphK2 Ki of 90 nM and 100-fold selectivity for SphK2. This molecule's in vivo activity will also be discussed.
Mitochondrial uncouplers are small molecules that shuttle protons from the inter membrane space to the mitochondrial matrix independent of ATP synthase, which disrupts oxidative phosphorylation and promotes increased nutrient metabolism for homeostasis to be maintained. Consequently, small molecule mitochondrial uncouplers have been pursued as probes for mitochondrial function and as potential therapeutics for the treatment of obesity and type 2 diabetes.
Herein, we describe the design, synthesis, and biological evaluation of small molecule mitochondrial uncouplers. We report a library of 52 compounds that have good mitochondrial uncoupling activity over a wide therapeutic range, including 5.16t (SHC4111522) and 5.17i (SHC4091665), which have EC50 values of 0.63 uM and 1.53 uM, respectively, and achieve at least 2-fold increase in oxygen consumption rates relative to basal levels. With these molecules, we demonstrate that pKa and cLogP significantly contribute to uncoupling activity and must be accounted for when developing new generation small molecule mitochondrial uncouplers. / Ph. D. / Sphingosine kinase 1 and 2 (SphK1 and SphK2) are enzymes that facilitate the production of the biomolecule sphingosine 1-phosphate (S1P), which plays an essential role in cell growth and survival. However, overproduction of S1P has been linked to a number of diseases including cancer, Alzheimer’s, and sickle cell disease. Therefore, because S1P is involved in these diseases, the amount of available S1P must be controlled. This work describes the design, development, and biological study of over 40 compounds that could be used as potential inhibitors of SphK2 to help control S1P levels and, therefore, hopefully alleviate the effects of disease. In particular, this work describes molecules that probe the SphK2 binding pocket and demonstrates that the molecules cannot be rigid or positively charged when binding to the hydrophobic portion of the SphK2 binding pocket. Additionally, this work describes the most potent and selective reported SphK2 inhibitor to date, 3.20dd (SLC4101431).
Mitochondrial uncouplers are compounds that target our body's mitochondria and aim to make ATP production challenging, causing the mitochondria to burn extra energy in the form of glucose and fatty acids to allow normal levels of ATP to be produced. By making the mitochondria burn extra energy, mitochondrial uncouplers have the potential to be treatments for diseases such as obesity and diabetes. This works describes the design, development, and biological study of over 50 mitochondrial uncouplers that are capable of increasing mitochondrial activity over a wide concentration range, including 5.16t (SHC4111522) and 5.17i (SHC4091665), which are very potent and effective uncouplers.
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USE OF HYBRID DIFFUSE OPTICAL SPECTROSCOPIES IN CONTINUOUS MONITORING OF BLOOD FLOW, BLOOD OXYGENATION, AND OXYGEN CONSUMPTION RATE IN EXERCISING SKELETAL MUSCLEGurley, Katelyn 01 January 2012 (has links)
This study combines noninvasive hybrid diffuse optical spectroscopies [near-infrared spectroscopy (NIRS) and diffuse correlation spectroscopy (DCS)] with occlusive calibration for continuous measurement of absolute blood flow (BF), tissue blood oxygenation (StO2), and oxygen consumption rate (VO2) in exercising skeletal muscle. Subjects performed rhythmic dynamic handgrip exercise, while an optical probe connected to a hybrid NIRS/DCS flow-oximeter directly monitored oxy-, deoxy-, and total hemoglobin concentrations ([HbO2], [Hb], and [tHb]), StO2, relative BF (rBF), and relative VO2 (rVO2) in the forearm flexor muscles. Absolute baseline BF and VO2 were obtained through venous and arterial occlusions, respectively, and used to calibrate continuous relative parameters. Previously known problems with muscle fiber motion artifact in optical measurements were mitigated with a novel dynamometer-based gating algorithm. Nine healthy young subjects were measured and results validated against previous literature findings. Ten older subjects with fibromyalgia and thirteen age-matched healthy controls were then successfully measured to observe differences in hemodynamic and metabolic response to exercise. This study demonstrates a novel application of NIRS/DCS technology to simultaneously evaluate quantitative hemodynamic and metabolic parameters in exercising skeletal muscle. This method has broad application to research and clinical assessment of disease (e.g. peripheral vascular disease, fibromyalgia), treatment evaluation, and sports medicine.
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STABILIZATION OF EXTENDED DIFFUSE OPTICAL SPECTROSCOPY MEASUREMENTS ON IN VIVO HUMAN SKELETAL MUSCLE DURING DYNAMIC EXERCISEHenry, Brad A. 01 January 2014 (has links)
This research investigates various applications of diffuse correlation spectroscopy (DCS) on in-vivo human muscle tissue, both at rest and during dynamic exercise. Previously suspected muscle tissue relative blood flow (rBF) baseline shift during extended measurement with DCS and DCS-Near infrared spectroscopy (NIRS) hybrid optical systems are verified, quantified, and resolved by redesign of optical probe and alteration in optical probe attachment methodology during 40 minute supine bed rest baseline measurements. We then translate previously developed occlusion techniques, whereby rBF and relative oxygen consumption rV̇O2 are calibrated to initial resting absolute values by use of a venous occlusion (VO) and arterial occlusion (AO) protocol, respectively, to the lower leg (gastrocnemius) and these blood flows are cross validated at rest by strain gauge venous plethysmography (SGVP). Methods used to continuously observe 0.5Hz, 30% maximum voluntary isometric contraction (MVIC) plantar flexion exercise via dynamometer are adapted for our hybrid DCS-Imagent diffuse optical flow-oximeter in the medial gastrocnemius. We obtain healthy control muscle tissue hemodynamic profiles for key parameters BF, V̇O2, oxygen saturation (StO2), deoxyhemoglobin, oxyhemoglobin, and total hemoglobin concentrations ([Hb], [HbO2], and THC respectively), as well as systemic mean arterial pressure (MAP) and pulse rate (PR), at rest, during VO/AO, during dynamic exercise and during 15 minute recovery periods. Next, we began investigation of muscle tissue hemodynamic disease states by performing a feasibility pilot study using limited numbers of controls and peripheral arterial disease (PAD) patients using the translated methods/techniques to determine the ability of our technology to assess differences in these populations.
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Interferon Signaling-Dependent Contribution of Glycolysis to Rubella Virus InfectionSchilling, Erik, Wald, Maria Elisabeth, Schulz, Juliane, Werner, Lina Emilia, Claus, Claudia 31 August 2023 (has links)
Interferons (IFNs) are an essential part of innate immunity and contribute to adaptive immune responses. Here, we employed a loss-of-function analysis with human A549 respiratory epithelial cells with a knockout (KO) of the type I IFN receptor (IFNAR KO), either solely or together with the receptor of type III IFN (IFNAR/IFNLR1 KO). The course of rubella virus (RuV) infection on the IFNAR KO A549 cells was comparable to the control A549. However, on the IFNAR/IFNLR1 KO A549 cells, both genome replication and the synthesis of viral proteins were significantly enhanced. The generation of IFN β during RuV infection was influenced by type III IFN signaling. In contrast to IFNAR KO A549, extracellular IFN β was not detected on IFNAR/IFNLR1 KO A549. The bioenergetic profile of RuV-infected IFNAR/IFNLR1 KO A549 cells generated by extracellular flux analysis revealed a significant increase in glycolysis, whereas mitochondrial respiration was comparable between all three cell types. Moreover, the application of the glucose analogue 2-deoxy-D-glucose (2-DG) significantly increased viral protein synthesis in control A549 cells, while no effect was noted on IFNAR/IFNLR KO A549. In conclusion, we identified a positive signaling circuit of type III IFN signaling on the generation of IFN β during RuV infection and an IFN signaling-dependent contribution of glycolysis to RuV infection. This study on epithelial A549 cells emphasizes the interaction between glycolysis and antiviral IFN signaling and notably, the antiviral activity of type III IFNs against RuV infection, especially in the absence of both type I and III IFN signaling, the RuV replication cycle was enhanced.
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The Interferon Response Dampens the Usutu Virus Infection-Associated Increase in GlycolysisWald, Maria Elisabeth, Sieg, Michael, Schilling, Erik, Binder, Marco, Vahlenkamp, Thomas Wilhelm, Claus, Claudia 03 April 2023 (has links)
The mosquito-borne Usutu virus (USUV) is a zoonotic flavivirus and an emerging
pathogen. So far therapeutical options or vaccines are not available in human and
veterinary medicine. The bioenergetic profile based on extracellular flux analysis
revealed an USUV infection-associated significant increase in basal and stressed
glycolysis on Vero and with a tendency for basal glycolysis on the avian cell line TME-R
derived from Eurasian blackbirds. On both cell lines this was accompanied by a significant
drop in the metabolic potential of glycolysis. Moreover, glycolysis contributed to
production of virus progeny, as inhibition of glycolysis with 2-deoxy-D-glucose reduced
virus yield on Vero by one log10 step. Additionally, the increase in glycolysis observed on
Vero cells after USUV infection was lost after the addition of exogenous type I interferon
(IFN) b. To further explore the contribution of the IFN response pathway to the impact of
USUV on cellular metabolism, USUV infection was characterized on human A549
respiratory cells with a knockout of the type I IFN receptor, either solely or together with
the receptor of type III IFN. Notably, only the double knockout of types I and III IFN receptor
increased permissiveness to USUV and supported viral replication together with an
alteration of the glycolytic activity, namely an increase in basal glycolysis to an extent
that a further increase after injection of metabolic stressors during extracellular flux
analysis was not noted. This study provides evidence for glycolysis as a possible target
for therapeutic intervention of USUV replication. Moreover, presented data highlight type I
and type III IFN system as a determinant for human host cell permissiveness and for the
infection-associated impact on glycolysis.
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