Your search keyword '"Capece L"' showing total 6 results

1. Tertiary and quaternary structural basis of oxygen affinity in human hemoglobin as revealed by multiscale simulations.

Author

Bringas M, Petruk AA, Estrin DA, Capece L, and Martí MA

Subjects

Humans, Protein Binding, Protein Structure, Quaternary, Protein Structure, Tertiary, Hemoglobin A chemistry, Hemoglobin A metabolism, Oxygen metabolism

Abstract

Human hemoglobin (Hb) is a benchmark protein of structural biology that shaped our view of allosterism over 60 years ago, with the introduction of the MWC model based on Perutz structures of the oxy(R) and deoxy(T) states and the more recent Tertiary Two-State model that proposed the existence of individual subunit states -"r" and "t"-, whose structure is yet unknown. Cooperative oxygen binding is essential for Hb function, and despite decades of research there are still open questions related to how tertiary and quaternary changes regulate oxygen affinity. In the present work, we have determined the free energy profiles of oxygen migration and for HisE7 gate opening, with QM/MM calculations of the oxygen binding energy in order to address the influence of tertiary differences in the control of oxygen affinity. Our results show that in the α subunit the low to high affinity transition is achieved by a proximal effect that mostly affects oxygen dissociation and is the driving force of the allosteric transition, while in the β subunit the affinity change results from a complex interplay of proximal and distal effects, including an increase in the HE7 gate opening, that as shown by free energy profiles promotes oxygen uptake.

Published

2017

2. The first step of the dioxygenation reaction carried out by tryptophan dioxygenase and indoleamine 2,3-dioxygenase as revealed by quantum mechanical/molecular mechanical studies.

Author

Capece L, Lewis-Ballester A, Batabyal D, Di Russo N, Yeh SR, Estrin DA, and Marti MA

Subjects

Amines chemistry, Amines metabolism, Biocatalysis, Electrons, Feasibility Studies, Humans, Ligands, Oxygen chemistry, Protein Conformation, Protons, Xanthomonas campestris enzymology, Indoleamine-Pyrrole 2,3,-Dioxygenase chemistry, Indoleamine-Pyrrole 2,3,-Dioxygenase metabolism, Molecular Dynamics Simulation, Oxygen metabolism, Quantum Theory, Tryptophan Oxygenase chemistry, Tryptophan Oxygenase metabolism

Abstract

Tryptophan dioxygenase (TDO) and indoleamine 2,3-dioxygenase (IDO) are two heme-containing enzymes which catalyze the conversion of L: -tryptophan to N-formylkynurenine (NFK). In mammals, TDO is mostly expressed in liver and is involved in controlling homeostatic serum tryptophan concentrations, whereas IDO is ubiquitous and is involved in modulating immune responses. Previous studies suggested that the first step of the dioxygenase reaction involves the deprotonation of the indoleamine group of the substrate by an evolutionarily conserved distal histidine residue in TDO and the heme-bound dioxygen in IDO. Here, we used classical molecular dynamics and hybrid quantum mechanical/molecular mechanical methods to evaluate the base-catalyzed mechanism. Our data suggest that the deprotonation of the indoleamine group of the substrate by either histidine in TDO or heme-bound dioxygen in IDO is not energetically favorable. Instead, the dioxygenase reaction can be initiated by a direct attack of heme-bound dioxygen on the C(2)=C(3) bond of the indole ring, leading to a protein-stabilized 2,3-alkylperoxide transition state and a ferryl epoxide intermediate, which subsequently recombine to generate NFK. The novel sequential two-step oxygen addition mechanism is fully supported by our recent resonance Raman data that allowed identification of the ferryl intermediate (Lewis-Ballester et al. in Proc Natl Acad Sci USA 106:17371-17376, 2009). The results reveal the subtle differences between the TDO and IDO reactions and highlight the importance of protein matrix in modulating stereoelectronic factors for oxygen activation and the stabilization of both transition and intermediate states.

Published

2010

3. Dynamical characterization of the heme NO oxygen binding (HNOX) domain. Insight into soluble guanylate cyclase allosteric transition.

Author

Capece L, Estrin DA, and Marti MA

Subjects

Allosteric Regulation physiology, Animals, Bacterial Proteins genetics, Bacterial Proteins metabolism, Enzyme Activation physiology, Guanylate Cyclase, Heme metabolism, Histidine chemistry, Histidine genetics, Histidine metabolism, Humans, Iron chemistry, Iron metabolism, Nitric Oxide metabolism, Oxygen metabolism, Protein Binding physiology, Protein Structure, Secondary physiology, Protein Structure, Tertiary physiology, Signal Transduction, Structure-Activity Relationship, Thermoanaerobacter genetics, Bacterial Proteins chemistry, Computer Simulation, Heme chemistry, Models, Molecular, Nitric Oxide chemistry, Oxygen chemistry, Thermoanaerobacter enzymology

Abstract

Since the discovery of soluble guanylate cyclase (sGC) as the mammalian receptor for nitric oxide (NO), numerous studies have been performed in order to understand how sGC transduces the NO signal. However, the structural basis of sGC activation is still not completely elucidated. Spectroscopic and kinetic studies showed that the key step in the activation mechanism was the NO-induced breaking of the iron proximal histidine bond in the so-called 6c-NO to 5c-NO transition. The main breakthrough in the understanding of sGC activation mechanism came, however, from the elucidation of crystal structures for two different prokaryotic heme NO oxygen (HNOX) domains, which are homologues to the sGC heme domain. In this work we present computer simulation results of Thermoanaerobacter tencogensis HNOX that complement these structural studies, yielding molecular explanations to several poorly understood properties of these proteins. Specifically, our results explain the differential ligand binding patterns of the HNOX domains according to the nature of proximal and distal residues. We also show that the natural dynamics of these proteins is intimately related with the proposed conformational dependent activation process, which involves mainly the alphaFbeta1 loop and the alphaA-alphaC distal subdomain. The results from the sGC models also support this view and suggest a key role for the alphaFbeta1 loop in the iron proximal histidine bond breaking process and, therefore, in the sGC activation mechanism.

Published

2008

4. Oxygen affinity controlled by dynamical distal conformations: the soybean leghemoglobin and the Paramecium caudatum hemoglobin cases.

Author

Martí MA, Capece L, Bikiel DE, Falcone B, and Estrin DA

Subjects

Animals, Binding Sites, Computer Simulation, Hemoglobins metabolism, Kinetics, Models, Molecular, Plant Proteins metabolism, Protein Conformation, Protozoan Proteins metabolism, Glycine max metabolism, Truncated Hemoglobins, Hemoglobins chemistry, Leghemoglobin chemistry, Leghemoglobin metabolism, Oxygen metabolism, Paramecium caudatum metabolism, Plant Proteins chemistry, Protozoan Proteins chemistry

Abstract

The binding of diatomic ligands, such as O(2), NO, and CO, to heme proteins is a process intimately related with their function. In this work, we analyzed by means of a combination of classical Molecular Dynamics (MD) and Hybrid Quantum-Classical (QM/MM) techniques the existence of multiple conformations in the distal site of heme proteins and their influence on oxygen affinity regulation. We considered two representative examples: soybean leghemoglobin (Lba) and Paramecium caudatum truncated hemoglobin (PcHb). The results presented in this work provide a molecular interpretation for the kinetic, structural, and mutational data that cannot be obtained by assuming a single distal conformation., ((c) 2007 Wiley-Liss, Inc.)

Published

2007

5. Heme protein oxygen affinity regulation exerted by proximal effects.

Author

Capece L, Marti MA, Crespo A, Doctorovich F, and Estrin DA

Subjects

Binding Sites, Computer Simulation, Ferrous Compounds chemistry, Ferrous Compounds metabolism, Histidine chemistry, Histidine metabolism, Kinetics, Models, Molecular, Quantum Theory, Thermodynamics, Leghemoglobin chemistry, Leghemoglobin metabolism, Myoglobin chemistry, Myoglobin metabolism, Oxygen chemistry, Oxygen metabolism

Abstract

Heme proteins are found in all living organisms and are capable of performing a wide variety of tasks, requiring in many cases the binding of diatomic ligands, namely, O(2), CO, and/or NO. Therefore, subtle regulation of these diatomic ligands' affinity is one of the key issues for determining a heme protein's function. This regulation is achieved through direct H-bond interactions between the bound ligand and the protein, and by subtle tuning of the intrinsic heme group reactivity. In this work, we present an investigation of the proximal regulation of oxygen affinity in Fe(II) histidine coordinated heme proteins by means of computer simulation. Density functional theory calculations on heme model systems are used to analyze three proximal effects: charge donation, rotational position, and distance to the heme porphyrin plane of the proximal histidine. In addition, hybrid quantum-classical (QM-MM) calculations were performed in two representative proteins: myoglobin and leghemoglobin. Our results show that all three effects are capable of tuning the Fe-O(2) bond strength in a cooperative way, consistently with the experimental data on oxygen affinity. The proximal effects described herein could operate in a large variety of O(2)-binding heme proteins-in combination with distal effects-and are essential to understand the factors determining a heme protein's O(2) affinity.

Published

2006

6. Dioxygen affinity in heme proteins investigated by computer simulation.

Author

Marti MA, Crespo A, Capece L, Boechi L, Bikiel DE, Scherlis DA, and Estrin DA

Subjects

Animals, Binding Sites, Hemeproteins metabolism, Hemoglobins chemistry, Hemoglobins metabolism, Humans, Kinetics, Ligands, Models, Molecular, Myoglobin chemistry, Myoglobin metabolism, Oxygen metabolism, Quantum Theory, Computer Simulation, Hemeproteins chemistry, Oxygen chemistry

Abstract

We present an investigation of the molecular basis of the modulation of oxygen affinity in heme proteins using computer simulation. QM-MM calculations are applied to explore distal and proximal effects on O(2) binding to the heme, while classical molecular dynamics simulations are employed to investigate ligand migration across the polypeptide to the active site. Trends in binding energies and in the kinetic constants are illustrated through a number of selected examples highlighting the virtues and the limitations of the applied methodologies. These examples cover a wide range of O(2)-affinities, and include: the truncated-N and truncated-O hemoglobins from Mycobacterium tuberculosis, the mammalian muscular O(2) storage protein: myoglobin, the hemoglobin from the parasitic nematode Ascaris lumbricoides, the oxygen transporter in the root of leguminous plants: leghemoglobin, the Cerebratulus lacteus nerve tissue hemoglobin, and the Alcaligenes xyloxidans cytochrome c'.

Published

2006