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The Rule of Law

Pietro Costa ; Danilo Zolo (eds.)

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Institución detectada Año de publicación Navegá Descargá Solicitá
No detectada 2007 SpringerLink

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Tipo de recurso:

libros

ISBN impreso

978-1-4020-5744-1

ISBN electrónico

978-1-4020-5745-8

Editor responsable

Springer Nature

País de edición

Reino Unido

Fecha de publicación

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© Springer Netherlands 2007

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Tabla de contenidos

The Rule of Law: A Critical Reappraisal

Danilo Zolo

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part I - Introductory Essays | Pp. 3-71

The Rule of Law: A Historical Introduction

Pietro Costa

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part I - Introductory Essays | Pp. 73-149

The Rule of Law and the “Liberties of the English”: The Interpretation of Albert Venn Dicey

Emilio Santoro

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part II - The Rule of Law in Europe and The United States | Pp. 153-199

Popular Sovereignty, the Rule of Law, and the “Rule of Judges” in the United States

Brunella Casalini

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part II - The Rule of Law in Europe and The United States | Pp. 201-236

Rechtsstaat and Individual Rights in German Constitutional History

Gustavo Gozzi

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part II - The Rule of Law in Europe and The United States | Pp. 237-259

État de Droit and National Sovereignty in France

Alain Laquièze

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part II - The Rule of Law in Europe and The United States | Pp. 261-291

Rechtsstaat and Constitutional Justice in Austria: Hans Kelsen's Contribution

Giorgio Bongiovanni

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part II - The Rule of Law in Europe and The United States | Pp. 293-319

The Past and the Future of the Rule of Law

Luigi Ferrajoli

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part III - The Contemporary Debate | Pp. 323-352

Beyond the Rule of Law: Judges' Tyranny or Lawyers' Anarchy?

Pier Paolo Portinaro

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part III - The Contemporary Debate | Pp. 353-369

The Rule of Law and Gender Difference

Anna Loretoni

The rich mechanistic enzymology of the cytochrome P450s has occupied chemists, biochemists, pharmacologists, and toxicologists for over three decades. Are we near to a detailed molecular understanding? We have attempted to convey in this chapter of the recent discoveries that fill many of the lacunas in our understanding of P450-catalyzed substrate oxidations. We now have a precise three-dimensional structure of the ferrous-oxygenated state, and ample spectroscopic characterization of the ferric-peroxo anion and ferric-hydroperoxo intermediates. In the exogenous oxidant driven pathway, an archaeal P450 allowed facile observation of the formation and breakdown of the “Compound I” ferryl-oxo state. Yet much remains. Stabilization and characterization of the “Compound I” state in the dioxygen reaction has not yet been achieved. With the ability to separate, through time and temperature, the population of multiple “active oxygen” intermediates in P4 50 catalysis, it remains to precisely define the reactivity profiles of each state and thereby realize a mapping of observed metabolic profiles to specific states in the reaction cycle. An overriding revelation has been the subtle way in which Nature controls the reactivity of atmospheric dioxygen, electrons, and transition metal through delicate hydrogen-bonding interactions. Thus, in a Periclesian control of mechanism, the cytochromes P450 utilize a variety of proton pathways to finely tune this versatile catalyst for critical physiological processes.

Part III - The Contemporary Debate | Pp. 371-386