Cket distances between the mass center of residues 12?3 and the 15900046 mass center of residues 32?34 for WT, G12D, and G13D, respectively. (PDF) Figure S4 Analysis of atomic fluctuations in the secondrepeated MD simulations. The structures of (A) WT, (B) G12D and, (C) G13D KRAS proteins are drawn in (-)-Calyculin A manufacturer cartoon putty representations at the P-loop, switch I and II regions; blue represents the lowest and red the highest B-factor value. In addition, the size of the tube reflects the value of the B-factor, in that the larger the B-factor, the thicker the tube. The structures in the other regions are colored in white and displayed in cartoon tube representation, where the size of the tube is independent of the B-factors. (PDF)Figure SAcknowledgmentsWe are grateful for both hardware and software support from the Structural Bioinformatics Core Facility at National Chiao Tung University. We are also thankful to Junta de Castillay Leony Cajade Burgos for the grants to MHV. In addition, we appreciate Dr. Raquel Campos for helping with the statistical analysis.Author ContributionsConceived and designed the experiments: CCC TKE JKH MJB MR EGT MHV. Performed the experiments: CCC TKE MHV. Analyzed the data: CCC TKE YYL JKH MJB MR EGT MHV. Contributed reagents/ materials/analysis tools: CCC MHV. Wrote the paper: CCC TKE YYL JKH MJB MR EGT MHV.The third repeated molecular dynamics trajectories for: (A) Comparison of the RMSD plots of the sensitive sites (P-loop, switch I and II regions) of WT, G12D and G13D structures with respect to the initial conformation during
Scuba diving can result in the production of venous gas emboli due to the release of inert gas originally held in solution in the form of a free gas phase from peripheral tissues during decompression. When bubbles are excessively generated in blood and tissues, signs and symptoms referred to as decompression sickness (DCS) may occur [1]. Neurological damage in the spinal cord and brain underlies the most serious symptoms of DCS [2]. Even after standard treatment with hyperbaric oxygen, 20?0 of the divers affected by neurological DCS had incomplete recovery at discharge [3]. Bubble formation in blood induces activate the vascular endothelium, stimulate prothrombotic phenomena and induce inflammation: platelet and leukocyte activation have been observed, associated with elevated production of cytokines and cell adhesion stimulators [2,4,5]. It is now accepted that severe DCS is a systemic pathophysiological process that may induce tissue reaction that promotes ischemic damage in the spinal cord or the brain [6,7,8]. Recent clinical trials suggest that fluoxetine may have a neuroprotective role in stroke [9,10]. Fluoxetine, the active compound in ProzacTM, prevents the reuptake of serotonin (5hydroxytryptamine, 5-HT) and increases the concentration of circulating serotonin [11] by inhibiting serotonin transporters (SERT) located in neurons, platelets [12] and leukocytes[13,14,15]. The uptake mechanism of platelet SERT regulates plasma 5-HT levels and secures stable blood flow by decreasing the possibility of platelet activation [16]. Fluoxetine is recognized as having anti-inflammatory effects by suppressing the production of IFN gamma and stimulating that of IL-10 [17]. Moreover, neuroprotective effects in the setting of cerebral ischemia are also described. Fluoxetine attenuates 58-49-1 kainic acid-induced neuronal cell death in the mouse hippocampus and suppresses proinflammatory markers (COX-2, IL-1 beta, TNF.Cket distances between the mass center of residues 12?3 and the 15900046 mass center of residues 32?34 for WT, G12D, and G13D, respectively. (PDF) Figure S4 Analysis of atomic fluctuations in the secondrepeated MD simulations. The structures of (A) WT, (B) G12D and, (C) G13D KRAS proteins are drawn in cartoon putty representations at the P-loop, switch I and II regions; blue represents the lowest and red the highest B-factor value. In addition, the size of the tube reflects the value of the B-factor, in that the larger the B-factor, the thicker the tube. The structures in the other regions are colored in white and displayed in cartoon tube representation, where the size of the tube is independent of the B-factors. (PDF)Figure SAcknowledgmentsWe are grateful for both hardware and software support from the Structural Bioinformatics Core Facility at National Chiao Tung University. We are also thankful to Junta de Castillay Leony Cajade Burgos for the grants to MHV. In addition, we appreciate Dr. Raquel Campos for helping with the statistical analysis.Author ContributionsConceived and designed the experiments: CCC TKE JKH MJB MR EGT MHV. Performed the experiments: CCC TKE MHV. Analyzed the data: CCC TKE YYL JKH MJB MR EGT MHV. Contributed reagents/ materials/analysis tools: CCC MHV. Wrote the paper: CCC TKE YYL JKH MJB MR EGT MHV.The third repeated molecular dynamics trajectories for: (A) Comparison of the RMSD plots of the sensitive sites (P-loop, switch I and II regions) of WT, G12D and G13D structures with respect to the initial conformation during
Scuba diving can result in the production of venous gas emboli due to the release of inert gas originally held in solution in the form of a free gas phase from peripheral tissues during decompression. When bubbles are excessively generated in blood and tissues, signs and symptoms referred to as decompression sickness (DCS) may occur [1]. Neurological damage in the spinal cord and brain underlies the most serious symptoms of DCS [2]. Even after standard treatment with hyperbaric oxygen, 20?0 of the divers affected by neurological DCS had incomplete recovery at discharge [3]. Bubble formation in blood induces activate the vascular endothelium, stimulate prothrombotic phenomena and induce inflammation: platelet and leukocyte activation have been observed, associated with elevated production of cytokines and cell adhesion stimulators [2,4,5]. It is now accepted that severe DCS is a systemic pathophysiological process that may induce tissue reaction that promotes ischemic damage in the spinal cord or the brain [6,7,8]. Recent clinical trials suggest that fluoxetine may have a neuroprotective role in stroke [9,10]. Fluoxetine, the active compound in ProzacTM, prevents the reuptake of serotonin (5hydroxytryptamine, 5-HT) and increases the concentration of circulating serotonin [11] by inhibiting serotonin transporters (SERT) located in neurons, platelets [12] and leukocytes[13,14,15]. The uptake mechanism of platelet SERT regulates plasma 5-HT levels and secures stable blood flow by decreasing the possibility of platelet activation [16]. Fluoxetine is recognized as having anti-inflammatory effects by suppressing the production of IFN gamma and stimulating that of IL-10 [17]. Moreover, neuroprotective effects in the setting of cerebral ischemia are also described. Fluoxetine attenuates kainic acid-induced neuronal cell death in the mouse hippocampus and suppresses proinflammatory markers (COX-2, IL-1 beta, TNF.