Your search keyword '"Kim-Shapiro DB"' showing total 10 results

1. Rat liver-mediated metabolism of hydroxyurea to nitric oxide.

Author

Huang J, Yakubu M, Kim-Shapiro DB, and King SB

Subjects

Animals, Catalase metabolism, Electron Spin Resonance Spectroscopy, Gas Chromatography-Mass Spectrometry, Luminescent Measurements, Microsomes, Liver metabolism, Rats, Hydroxyurea metabolism, Liver metabolism, Nitric Oxide metabolism

Abstract

Hydroxyurea is an approved treatment for sickle cell disease. Oxidation of hydroxyurea results in the formation of nitric oxide (NO), which also has drawn considerable interest as a sickle cell disease therapy. Although patients on hydroxyurea demonstrate elevated levels of nitric oxide-derived metabolites, little information regarding the site or mechanism of the in vivo conversion of hydroxyurea to nitric oxide exists. Chemiluminescence detection experiments show the ability of crude rat liver homogenate to convert hydroxyurea to nitrite/nitrate, evidence for NO production. Nitrite/nitrate form at therapeutic concentrations of hydroxyurea in a clinically relevant time frame. Electron paramagnetic resonance (EPR) studies show the formation of iron nitrosyl complexes during this incubation and experiments with labeled hydroxyurea show the NO derives from the drug. Gas chromatography-mass spectrometry measurements indicate the hydrolysis of hydroxyurea to hydroxylamine in this system. Incubation of hydroxylamine with crude rat liver homogenate also generates nitrite/nitrate and iron nitrosyl complexes. A line of evidence including inhibitor studies, EPR spectroscopy, and nitrite/nitrate detection identifies catalase as a possible oxidant for the conversion of hydroxyurea to NO. These results reveal the ability of liver tissue to convert hydroxyurea to nitric oxide and provide insight into the metabolism of this drug.

Published

2006

2. Catalase-mediated nitric oxide formation from hydroxyurea.

Author

Huang J, Kim-Shapiro DB, and King SB

Subjects

Electron Spin Resonance Spectroscopy, Ferric Compounds chemistry, Ferrous Compounds chemistry, Luminescent Measurements, Spectrophotometry, Ultraviolet, Catalase chemistry, Hydroxyurea chemistry, Nitric Oxide chemical synthesis, Nitric Oxide Donors chemistry

Abstract

Hydroxyurea reduces the incidence of painful crises in patients with sickle cell disease and has recently been approved for the treatment of this condition. A number of in vitro studies show that the oxidation of hydroxyurea results in the formation of nitric oxide, which also has drawn considerable interest as a sickle cell disease therapy. While patients on hydroxyurea demonstrate elevated levels of nitric oxide-derived metabolites, little information regarding the site or mechanism of the in vivo conversion of hydroxyurea to nitric oxide exists. Chemiluminescence detection experiments show the ability of catalase to catalyze the formation of nitrite and nitrate from hydroxyurea. Spectroscopic studies show that the reaction of hydroxyurea and catalase in the presence of a hydrogen peroxide generating system produces a ferrous-NO catalase complex. Trapping studies indicate the intermediacy of a nitroso species during this reaction. The proposed mechanism for this conversion includes initial hydrogen peroxide-dependent oxidation of hydroxyurea by catalase to form the nitroso species, hydrolysis of this nitroso species to produce nitroxyl, and reductive nitrosylation of the ferric heme of catalase by nitroxyl to yield the ferrous-NO catalase complex. Addition of Angeli's salt, a nitroxyl donor, to ferric catalase also produces the ferrous-NO catalase complex. Spectroscopic studies show that the ferrous-NO catalase complex releases nitric oxide as judged by the oxyhemoglobin assay and an NO specific EPR specific trap. These results demonstrate nitric oxide production from the ferric catalase oxidation of nitroxyl and identify a catalase-mediated pathway as a potential source of nitric oxide production from hydroxyurea.

Published

2004

3. Hydroxyurea analogues as kinetic and mechanistic probes of the nitric oxide producing reactions of hydroxyurea and oxyhemoglobin.

Author

Huang J, Zou Z, Kim-Shapiro DB, Ballas SK, and King SB

Subjects

Electrochemistry, Electron Spin Resonance Spectroscopy, Glycated Hemoglobin chemical synthesis, Hydroxyurea chemistry, Kinetics, Nitrates chemistry, Nitric Oxide chemical synthesis, Nitric Oxide Donors chemistry, Nitrites chemistry, Structure-Activity Relationship, Hydroxyurea analogs & derivatives, Hydroxyurea chemical synthesis, Nitric Oxide Donors chemical synthesis, Oxyhemoglobins chemistry

Abstract

Derivatives of N-hydroxyurea that contain an N-hydroxy group react with oxyhemoglobin to form methemoglobin and variable amounts of nitrite/nitrate. Compounds with an unsubstituted -NHOH group produce the most nitrite/nitrate, which provides evidence for nitric oxide formation. The rate of reaction of these N-hydroxyurea derivatives with oxyhemoglobin correlates well with that compound's oxidation potential. Aromatic N-hydroxyureas react 25-80-fold faster with oxyhemoglobin than with N-hydroxyurea, suggesting other N-hydroxyurea analogues may be superior nitric oxide donors. Electron paramagnetic resonance spectroscopy shows that the formation of a low-spin methemoglobin-hydroxyurea complex is critical for iron nitrosyl hemoglobin formation. These results show that iron nitrosyl hemoglobin formation from the reaction of hydroxyureas and hemoglobin requires an unsubstituted -NHOH group and that the nitrogen atom of the non-N-hydroxy group must contain at least a single hydrogen atom. These results should guide the development of new hydroxyurea-based nitric oxide donors and sickle cell disease therapies.

Published

2003

4. Urease enhances the formation of iron nitrosyl hemoglobin in the presence of hydroxyurea.

Author

Lockamy VL, Huang J, Shields H, Ballas SK, King SB, and Kim-Shapiro DB

Subjects

Electron Spin Resonance Spectroscopy, Humans, Nitrates analysis, Nitrites analysis, Spectrophotometry, Antisickling Agents pharmacology, Blood drug effects, Hemoglobins chemistry, Hydroxyurea pharmacology, Urease pharmacology

Abstract

Although it has been shown that hydroxyurea (HU) therapy produces measurable amounts of nitric oxide (NO) metabolites, including iron nitrosyl hemoglobin (HbNO) in patients with sickle cell disease, the in vivo mechanism for formation of these is not known. Much in vitro data and some in vivo data indicates that HU is the NO donor, but other studies suggest a role for nitric oxide synthase (NOS). In this study, we confirm that the NO-forming reactions of HU with hemoglobin (Hb) or other blood constituents is too slow to account for NO production measured in vivo. We hypothesize that, in vivo, HU is partially metabolized to hydroxylamine (HA), which quickly reacts with Hb to form methemoglobin (metHb) and HbNO. We show that addition of urease, which converts HU to HA, to a mixture of blood and HU, greatly enhances HbNO formation.

Published

2003

5. Horseradish peroxidase catalyzed nitric oxide formation from hydroxyurea.

Author

Huang J, Sommers EM, Kim-Shapiro DB, and King SB

Subjects

Catalysis, Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Horseradish Peroxidase metabolism, Hydroxyurea metabolism, Nitric Oxide biosynthesis, Oxidation-Reduction, Spectrophotometry, Ultraviolet, Horseradish Peroxidase chemistry, Hydroxyurea chemistry, Nitric Oxide chemistry

Abstract

Hydroxyurea represents an approved treatment for sickle cell anemia and a number of cancers. Chemiluminescence and electron paramagnetic resonance spectroscopic studies show horseradish peroxidase catalyzes the formation of nitric oxide from hydroxyurea in the presence of hydrogen peroxide. Gas chromatographic headspace analysis and infrared spectroscopy also reveal the production of nitrous oxide in this reaction, which provides evidence for nitroxyl, the one-electron reduced form of nitric oxide. These reactions also generate carbon dioxide, ammonia, nitrite, and nitrate. None of these products form within 1 h in the absence of hydrogen peroxide or horseradish peroxidase. Electron paramagnetic resonance spectroscopy and trapping studies show the intermediacy of a nitroxide radical and a C-nitroso species during this reaction. Absorption spectroscopy indicates that both compounds I and II of horseradish peroxidase act as one-electron oxidants of hydroxyurea. Nitroxyl, generated from Angeli's salt, reacts with ferric horseradish peroxidase to produce a ferrous horseradish peroxidase-nitric oxide complex. Electron paramagnetic resonance experiments with a nitric oxide specific trap reveal that horseradish peroxidase is capable of oxidizing nitroxyl to nitric oxide. A mechanistic model that includes the observed nitroxide radical and C-nitroso compound intermediates has been forwarded to explain the observed product distribution. These studies suggest that direct nitric oxide producing reactions of hydroxyurea and peroxidases may contribute to the overall pharmacological properties of this drug.

Published

2002

6. Iron nitrosyl hemoglobin formation from the reactions of hemoglobin and hydroxyurea.

Author

Huang J, Hadimani SB, Rupon JW, Ballas SK, Kim-Shapiro DB, and King SB

Subjects

Electron Spin Resonance Spectroscopy, Hemoglobin A chemistry, Hemoglobins metabolism, Humans, Hydroxyurea blood, Iron blood, Methemoglobin chemistry, Models, Chemical, Nitric Oxide blood, Nitrogen Oxides blood, Oxyhemoglobins chemistry, Spectrophotometry, Hemoglobins chemistry, Hydroxyurea chemistry, Iron chemistry, Nitric Oxide chemistry, Nitrogen Oxides chemistry

Abstract

Hydroxyurea represents an approved treatment for sickle cell anemia and acts as a nitric oxide donor under oxidative conditions in vitro. Electron paramagnetic resonance spectroscopy shows that hydroxyurea reacts with oxy-, deoxy-, and methemoglobin to produce 2-6% of iron nitrosyl hemoglobin. No S-nitrosohemoglobin forms during these reactions. Cyanide and carbon monoxide trapping studies reveal that hydroxyurea oxidizes deoxyhemoglobin to methemoglobin and reduces methemoglobin to deoxyhemoglobin. Similar experiments reveal that iron nitrosyl hemoglobin formation specifically occurs during the reaction of hydroxyurea and methemoglobin. Experiments with hydroxyurea analogues indicate that nitric oxide transfer requires an unsubstituted acylhydroxylamine group and that the reactions of hydroxyurea and deoxy- and methemoglobin likely proceed by inner-sphere mechanisms. The formation of nitrate during the reaction of hydroxyurea and oxyhemoglobin and the lack of nitrous oxide production in these reactions suggest the intermediacy of nitric oxide as opposed to its redox form nitroxyl. A mechanistic model that includes a redox cycle between deoxyhemoglobin and methemoglobin has been forwarded to explain these results that define the reactivity of hydroxyurea and hemoglobin. These direct nitric oxide producing reactions of hydroxyurea and hemoglobin may contribute to the overall pathophysiological properties of this drug.

Published

2002

7. In vitro exposure to hydroxyurea reduces sickle red blood cell deformability.

Author

Huang Z, Louderback JG, King SB, Ballas SK, and Kim-Shapiro DB

Subjects

Erythrocyte Membrane drug effects, Fetal Hemoglobin drug effects, Hemoglobins metabolism, Humans, Methemoglobin metabolism, Oxidation-Reduction, Oxyhemoglobins drug effects, Anemia, Sickle Cell blood, Erythrocyte Deformability drug effects, Erythrocytes, Abnormal drug effects, Hydroxyurea pharmacology

Abstract

Hydroxyurea is a drug that is used to treat some patients with sickle cell disease. We have measured the deformability of sickle erythrocytes incubated in hydroxyurea in vitro and found that hydroxyurea acts to decrease the deformability of these cells. The deformability of normal erythrocytes was not significantly affected by hydroxyurea except at very high concentrations. Hydroxyurea also did not consistently reduce the deformability of sickle erythrocyte ghosts. We propose that the decreased deformability, observed in vitro, is due to the formation of methemoglobin and other oxidative processes resulting from the reaction of hydroxyurea and oxyhemoglobin. Although the reaction with normal hemoglobin is similar to that of sickle hemoglobin, the sickle erythrocytes are affected more. We propose that the sickle erythrocyte membrane is more susceptible to the reaction products of the reaction of hemoglobin and hydroxyurea. An earlier report has shown that hydroxyurea increases the deformability of erythrocytes in patients on hydroxyurea. Taken together, these data suggest that the improved rheological properties of sickle erythrocytes in vivo are due to the elevated numbers of F cells [cells with fetal hemoglobin]. The presence of the nitrosyl hemoglobin or methemoglobin from the reaction with hydroxyurea may also benefit patients in vivo by reducing sickling., (Copyright 2001 Wiley-Liss, Inc.)

Published

2001

8. The reactions of myoglobin, normal adult hemoglobin, sickle cell hemoglobin and hemin with hydroxyurea.

Author

Rupon JW, Domingo SR, Smith SV, Gummadi BK, Shields H, Ballas SK, King SB, and Kim-Shapiro DB

Subjects

Adult, Animals, Cysteine chemistry, Electron Spin Resonance Spectroscopy, Horses, Humans, Hydroxyurea pharmacology, Kinetics, Oxyhemoglobins chemistry, Protein Conformation, Spectrophotometry, Hemin chemistry, Hemoglobin A chemistry, Hemoglobin, Sickle chemistry, Hydroxyurea chemistry, Myoglobin chemistry

Abstract

The kinetics of the reaction of hydroxyurea (HU) with myoglobin (Mb), hemin, sickle cell hemoglobin (HbS), and normal adult hemoglobin (HbA) were determined using optical absorption spectroscopy as a function of time, wavelength, and temperature. Each reaction appeared to follow pseudo-first order kinetics. Electron paramagnetic resonance spectroscopy (EPR) experiments indicated that each reaction produced an FeNO product. Reactions of hemin and the ferric forms of HbA, HbS, and myoglobin with HU also formed the NO adduct. The formation of methemoglobin and nitric oxide-hemoglobin from these reactions may provide further insight into the mechanism of how HU benefits sickle cell patients.

Published

2000

9. The reaction of deoxy-sickle cell hemoglobin with hydroxyurea.

Author

Kim-Shapiro DB, King SB, Shields H, Kolibash CP, Gravatt WL, and Ballas SK

Subjects

Electron Spin Resonance Spectroscopy, Glycated Hemoglobin chemical synthesis, Hemoglobin, Sickle genetics, Hemoglobins chemical synthesis, Kinetics, Methemoglobin chemical synthesis, Nitric Oxide chemical synthesis, Oxyhemoglobins chemistry, Spectrophotometry, Vasodilator Agents chemical synthesis, Antisickling Agents chemistry, Hemoglobin, Sickle chemistry, Hydroxyurea chemistry

Abstract

In addition to its capacity to increase fetal hemoglobin levels, other mechanisms are implicated in hydroxyurea's ability to provide beneficial effects to patients with sickle cell disease. We hypothesize that the reaction of hemoglobin with hydroxyurea may play a role. It is shown that hydroxyurea reacts with deoxy-sickle cell hemoglobin (Hb) to form methemoglobin (metHb) and nitrosyl hemoglobin (HbNO). The products of the reaction as well as the kinetics are followed by absorption spectroscopy and electron paramagnetic resonance (EPR) spectroscopy. Analysis of the kinetics shows that the reaction can be approximated by a pseudo-first order rate constant of 3.7x10(-4) (1/(s.M)) for the disappearance of deoxy-sickle cell hemoglobin. Further analysis shows that HbNO is formed at an observed average rate of 5.25x10(-5) (1/s), three to four times slower than the rate of formation of metHb. EPR spectroscopy is used to show that the formation of HbNO involves the specific transfer of NO from the NHOH group of hydroxyurea. The potential importance of this reaction is discussed in the context of metHb and HbNO being able to increase the delay time for sickle cell hemoglobin polymerization and HbNO's vasodilating capabilities through conversion to S-nitrosohemoglobin.

Published

1999

10. Time resolved absorption study of the reaction of hydroxyurea with sickle cell hemoglobin.

Author

Kim-Shapiro DB, King SB, Bonifant CL, Kolibash CP, and Ballas SK

Subjects

Anemia, Sickle Cell blood, Anemia, Sickle Cell drug therapy, Hemeproteins chemistry, Hemeproteins drug effects, Hemeproteins metabolism, Hemoglobin, Sickle metabolism, Humans, In Vitro Techniques, Methemoglobin chemistry, Methemoglobin drug effects, Methemoglobin metabolism, Oxyhemoglobins chemistry, Oxyhemoglobins drug effects, Oxyhemoglobins metabolism, Spectrophotometry, Antisickling Agents pharmacology, Hemoglobin, Sickle chemistry, Hemoglobin, Sickle drug effects, Hydroxyurea pharmacology

Abstract

Hydroxyurea has been mixed with hemoglobin S and the reaction was studied using electronic absorption spectroscopy as a function of time and wavelength. The rate of conversion of oxyhemoglobin S to other species was determined and the nature of the reaction products was studied. We also report the formation of methemoglobin (and other reaction products) when deoxyhemoglobin S is combined with hydroxyurea. The probable increase in the formation of methemoglobin, and other potential reaction products such as nitric oxide-hemoglobin, in patients with sickle cell anemia who are taking hydroxyurea as a therapeutic drug is discussed in terms of the pathophysiology of the disease. It is proposed that methemoglobin and possibly nitric oxide-hemoglobin formation may partially explain beneficial effects observed in these patients before their levels of fetal hemoglobin have increased.

Published

1998