Your search keyword '"Kim-Shapiro DB"' showing total 5 results

1. Mycobacterium tuberculosis DosS binds H 2 S through its Fe 3+ heme iron to regulate the DosR dormancy regulon.

Author

Sevalkar RR, Glasgow JN, Pettinati M, Marti MA, Reddy VP, Basu S, Alipour E, Kim-Shapiro DB, Estrin DA, Lancaster JR Jr, and Steyn AJC

Subjects

Animals, Bacterial Proteins genetics, Bacterial Proteins metabolism, Dioctyl Sulfosuccinic Acid metabolism, Gene Expression Regulation, Bacterial, Heme metabolism, Iron metabolism, Mammals genetics, Mammals metabolism, Protamine Kinase chemistry, Protamine Kinase genetics, Protamine Kinase metabolism, Regulon, Gasotransmitters metabolism, Mycobacterium tuberculosis genetics, Mycobacterium tuberculosis metabolism

Abstract

Mycobacterium tuberculosis (Mtb) senses and responds to host-derived gasotransmitters NO and CO via heme-containing sensor kinases DosS and DosT and the response regulator DosR. Hydrogen sulfide (H 2 S) is an important signaling molecule in mammals, but its role in Mtb physiology is unclear. We have previously shown that exogenous H 2 S can modulate expression of genes in the Dos dormancy regulon via an unknown mechanism(s). Here, we test the hypothesis that Mtb senses and responds to H 2 S via the DosS/T/R system. Using UV-Vis and EPR spectroscopy, we show that H 2 S binds directly to the ferric (Fe 3+ ) heme of DosS (K D app  = 5.30 μM) but not the ferrous (Fe 2+ ) form. No interaction with DosT(Fe 2+ -O 2 ) was detected. We found that the binding of sulfide can slowly reduce the DosS heme iron to the ferrous form. Steered Molecular Dynamics simulations show that H 2 S, and not the charged HS - species, can enter the DosS heme pocket. We also show that H 2 S increases DosS autokinase activity and subsequent phosphorylation of DosR, and H 2 S-mediated increases in Dos regulon gene expression is lost in Mtb lacking DosS. Finally, we demonstrate that physiological levels of H 2 S in macrophages can induce DosR regulon genes via DosS. Overall, these data reveal a novel mechanism whereby Mtb senses and responds to a third host gasotransmitter, H 2 S, via DosS(Fe 3+ ). These findings highlight the remarkable plasticity of DosS and establish a new paradigm for how bacteria can sense multiple gasotransmitters through a single heme sensor kinase., (Copyright © 2022 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2022

2. Erythrocytic bioactivation of nitrite and its potentiation by far-red light.

Author

Wajih N, Basu S, Ucer KB, Rigal F, Shakya A, Rahbar E, Vachharajani V, Guthold M, Gladwin MT, Smith LM, and Kim-Shapiro DB

Subjects

Animals, Blood Platelets metabolism, Blood Platelets radiation effects, Erythrocyte Membrane metabolism, Heme metabolism, Microvessels metabolism, Models, Biological, Nitric Oxide metabolism, Oxygen metabolism, Platelet Activation radiation effects, Rats, Sulfhydryl Compounds metabolism, Erythrocytes metabolism, Erythrocytes radiation effects, Light, Nitrites metabolism

Abstract

Background: Nitrite is reduced by heme-proteins and molybdenum-containing enzymes to form the important signaling molecule nitric oxide (NO), mediating NO signaling. Substantial evidence suggests that deoxygenated hemoglobin within red blood cells (RBCs) is the main erythrocytic protein responsible for mediating nitrite-dependent NO signaling. In other work, infrared and far red light have been shown to have therapeutic potential that some attribute to production of NO. Here we explore whether a combination of nitrite and far red light treatment has an additive effect in NO-dependent processes, and whether this effect is mediated by RBCs., Methods and Results: Using photoacoustic imaging in a rat model as a function of varying inspired oxygen, we found that far red light (660 nm, five min. exposure) and nitrite feeding (three weeks in drinking water at 100 mg/L) each separately increased tissue oxygenation and vessel diameter, and the combined treatment was additive. We also employed inhibition of human platelet activation measured by flow cytometry to assess RBC-dependent nitrite bioactivation and found that far red light dramatically potentiates platelet inhibition by nitrite. Blocking RBC-surface thiols abrogated these effects of nitrite and far-red light. RBC-dependent production of NO was also shown to be enhanced by far red light using a chemiluminescence-based nitric oxide analyzer. In addition, RBC-dependent bioactivation of nitrite led to prolonged lag times for clotting in platelet poor plasma that was enhanced by exposure to far red light., Conclusions: Our results suggest that nitrite leads to the formation of a photolabile RBC surface thiol-bound species such as an S-nitrosothiol or heme-nitrosyl (NO-bound heme) for which far red light enhances NO signaling. These findings expand our understanding of RBC-mediated NO production from nitrite. This pathway of NO production may have therapeutic potential in several applications including thrombosis, and, thus, warrants further study., (Copyright © 2018 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2019

3. Potential therapeutic action of nitrite in sickle cell disease.

Author

Wajih N, Basu S, Jailwala A, Kim HW, Ostrowski D, Perlegas A, Bolden CA, Buechler NL, Gladwin MT, Caudell DL, Rahbar E, Alexander-Miller MA, Vachharajani V, and Kim-Shapiro DB

Subjects

Animals, Blood Platelets cytology, Blood Platelets drug effects, Calcium metabolism, Disease Models, Animal, Human Umbilical Vein Endothelial Cells, Humans, Leukocytes, Mononuclear cytology, Leukocytes, Mononuclear drug effects, Mice, Nitrites pharmacology, Platelet Adhesiveness drug effects, Platelet Aggregation Inhibitors pharmacology, Anemia, Sickle Cell blood, Anemia, Sickle Cell drug therapy, Nitrites administration & dosage, Platelet Aggregation Inhibitors administration & dosage

Abstract

Sickle cell disease is caused by a mutant form of hemoglobin that polymerizes under hypoxic conditions, increasing rigidity, fragility, calcium influx-mediated dehydration, and adhesivity of red blood cells. Increased red cell fragility results in hemolysis, which reduces nitric oxide (NO) bioavailability, and induces platelet activation and inflammation leading to adhesion of circulating blood cells. Nitric Oxide inhibits adhesion and platelet activation. Nitrite has emerged as an attractive therapeutic agent that targets delivery of NO activity to areas of hypoxia through bioactivation by deoxygenated red blood cell hemoglobin. In this study, we demonstrate anti-platelet activity of nitrite at doses achievable through dietary interventions with comparison to similar doses with other NO donating agents. Unlike other NO donating agents, nitrite activity is shown to be potentiated in the presence of red blood cells in hypoxic conditions. We also show that nitrite reduces calcium associated loss of phospholipid asymmetry that is associated with increased red cell adhesion, and that red cell deformability is also improved. We show that nitrite inhibits red cell adhesion in a microfluidic flow-channel assay after endothelial cell activation. In further investigations, we show that leukocyte and platelet adhesion is blunted in nitrite-fed wild type mice compared to control after either lipopolysaccharide- or hemolysis-induced inflammation. Moreover, we demonstrate that nitrite treatment results in a reduction in adhesion of circulating blood cells and reduced red blood cell hemolysis in humanized transgenic sickle cell mice subjected to local hypoxia. These data suggest that nitrite is an effective anti-platelet and anti-adhesion agent that is activated by red blood cells, with enhanced potency under physiological hypoxia and in venous blood that may be useful therapeutically., (Copyright © 2017 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2017

4. The role of red blood cell S-nitrosation in nitrite bioactivation and its modulation by leucine and glucose.

Author

Wajih N, Liu X, Shetty P, Basu S, Wu H, Hogg N, Patel RP, Furdui CM, and Kim-Shapiro DB

Subjects

Glucose metabolism, Humans, Leucine metabolism, Nitrosation, Vasodilation, Erythrocytes metabolism, Nitric Oxide metabolism, Nitrites metabolism, Oxygen metabolism

Abstract

Previous work has shown that red blood cells (RBCs) reduce nitrite to NO under conditions of low oxygen. Strong support for the ability of red blood cells to promote nitrite bioactivation comes from using platelet activation as a NO-sensitive process. Whereas addition of nitrite to platelet rich plasma in the absence of RBCs has no effect on inhibition of platelet activation, when RBCs are present platelet activation is inhibited by an NO-dependent mechanism that is potentiated under hypoxia. In this paper, we demonstrate that nitrite bioactivation by RBCs is blunted by physiologically-relevant concentrations of nutrients including glucose and the important signaling amino acid leucine. Our mechanistic investigations demonstrate that RBC mediated nitrite bioactivation is largely dependent on nitrosation of RBC surface proteins. These data suggest a new expanded paradigm where RBC mediated nitrite bioactivation not only directs blood flow to areas of low oxygen but also to areas of low nutrients. Our findings could have profound implications for normal physiology as well as pathophysiology in a variety of diseases including diabetes, sickle cell disease, and arteriosclerosis., (Copyright © 2016 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2016

5. Mechanism of faster NO scavenging by older stored red blood cells.

Author

Liu C, Liu X, Janes J, Stapley R, Patel RP, Gladwin MT, and Kim-Shapiro DB

Subjects

Blood Transfusion, Cell Membrane Permeability, Erythrocyte Deformability, Erythrocytes physiology, Hemoglobins metabolism, Humans, Imaging, Three-Dimensional, Models, Molecular, Blood Preservation methods, Erythrocytes cytology, Nitric Oxide metabolism

Abstract

Unlabelled: The blood storage lesion involves morphological and biochemical changes of red blood cells (RBCs) that occur during storage. These include conversion of the biconcave disc morphology to a spherical one, decreased mean corpuscular hemoglobin concentration, varied mean corpuscular volume, reduced integrity of the erythrocyte membrane with formation of microparticles, and increased cell-free hemoglobin. We studied the extent that older stored red blood cells scavenge nitric oxide (NO) faster than fresher stored red blood cells. Using electron paramagnetic resonance spectroscopy and stopped-flow absorption spectroscopy to measure the rate of NO uptake and reaction with hemoglobin in red cells, we found that older stored red blood cells scavenge NO about 1.8 times faster than fresher ones. Based on these experimental data, we simulated NO scavenging by fresher or older stored red blood cells with a biconcave or spherical geometry, respectively, in order to explore the mechanism of NO scavenging related to changes that occur during blood storage. We found that red blood cells with a spherical geometry scavenges NO about 2 times slower than ones with a biconcave geometry, and a smaller RBC hemoglobin concentration or volume increases NO scavenging by red blood cells. Our simulations demonstrate that even the most extreme possible changes in mean corpuscular hemoglobin concentration and mean corpuscular volume that favor increased NO scavenging are insufficient to account for what is observed experimentally. Therefore, RBC membrane permeability must increase during storage and we find that the permeability is likely to increase between 5 and 70 fold. Simulations using a two-dimensional blood vessel show that even a 5-fold increase in membrane permeability to NO can reduce NO bioavailability at the smooth muscle., Background: Transfusion of older stored blood may be harmful., Results: Older stored red blood cells scavenge nitric oxide more than fresher cells., Conclusion: As stored red blood cells age, structural and biochemical changes occur that lead to faster scavenging., Significance: Increased nitric oxide scavenging by red blood cells as a function of storage age contributes to deleterious effects upon transfusion.

Published

2014