Your search keyword '"Implicit ligand sampling"' showing total 14 results

1. Multi‐scale simulation reveals that an amino acid substitution increases photosensitizing reaction inputs in Rhodopsins.

Author

Hernández‐Rodríguez, Erix W., Escorcia, Andrés M., Kamp, Marc W., Montero‐Alejo, Ana L., and Caballero, Julio

Subjects

*RHODOPSIN, *AMINO acids, *REACTIVE oxygen species, *EXCITED state energies, *DENSITY functional theory, *RETINAL degeneration

Abstract

Evaluating the availability of molecular oxygen (O2) and energy of excited states in the retinal binding site of rhodopsin is a crucial challenging first step to understand photosensitizing reactions in wild‐type (WT) and mutant rhodopsins by absorbing visible light. In the present work, energies of the ground and excited states related to 11‐cis‐retinal and the O2 accessibility to the β‐ionone ring are evaluated inside WT and human M207R mutant rhodopsins. Putative O2 pathways within rhodopsins are identified by using molecular dynamics simulations, Voronoi‐diagram analysis, and implicit ligand sampling while retinal energetic properties are investigated through density functional theory, and quantum mechanical/molecular mechanical methods. Here, the predictions reveal that an amino acid substitution can lead to enough energy and O2 accessibility in the core hosting retinal of mutant rhodopsins to favor the photosensitized singlet oxygen generation, which can be useful in understanding retinal degeneration mechanisms and in designing blue‐lighting‐absorbing proteic photosensitizers. [ABSTRACT FROM AUTHOR]

Published

2020

2. Atomistic Insights into Photoprotein Formation: Computational Prediction of the Properties of Coelenterazine and Oxygen Binding in Obelin.

Author

Griffiths, Thomas M., Oakley, Aaron J., and Yu, Haibo

Subjects

*SIMULATION methods & models, *BINDING energy, *OXYGEN, *MOLECULAR dynamics, *CARBON dioxide

Abstract

Bioluminescence in marine systems is dominated by the use of coelenterazine for light production. The bioluminescent reaction of coelenterazine is an enzyme catalyzed oxidative decarboxylation: coelenterazine reacts with molecular oxygen to form carbon dioxide, coelenteramide, and light. One such class is the Ca2+‐regulated photoproteins. These proteins bind coelenterazine and oxygen, and trap 2‐hydroperoxycoelenterazine, an intermediate along the reaction pathway. The reaction is halted until Ca2+ binding triggers the completion of the reaction. There are currently no reported experimental, atomistic descriptions of this ternary Michaelis complex. This study utilized computational techniques to develop an atomistic model of the Michaelis complex. Extensive molecular dynamics simulations were carried out to study the interactions between four tautomeric/protonation states of coelenterazine and wide‐type and mutant obelin. Only minor differences in binding modes were observed across all systems. Interestingly, no basic residues were identified in the vicinity of the N7‐nitrogen of coelenterazine. This observation was surprising considering that deprotonation at this position is a key mechanistic step in the proposed bioluminescent reaction. This work suggests that coelenterazine binds either as the O10H tautomer, or in the deprotonated form. Implicit ligand sampling simulations were used to identify potential O2 binding and migration pathways within obelin. A key oxygen binding site was identified close to the coelenterazine imidazopyrazinone core. The O2 binding free energy was observed to be dependent on the protonation state of coelenterazine. Taken together, the description of the obelin–coelenterazine‐O2 complexes established in this study provides the basis for future computational studies of the bioluminescent mechanism. © 2019 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2020

3. Multi‐scale simulation reveals that an amino acid substitution increases photosensitizing reaction inputs in Rhodopsins

Author

Erix W. Hernández-Rodríguez, Ana L. Montero-Alejo, Marc W. van der Kamp, Andrés M. Escorcia, and Julio Caballero

Subjects

Rhodopsin, Retinal binding, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, singlet oxygen, chemistry.chemical_compound, Molecular dynamics, retinitis pigmentosa, 0103 physical sciences, Humans, implicit ligand sampling, Photosensitizing Agents, 010304 chemical physics, biology, Singlet oxygen, Retinal, QM/MM calculations, General Chemistry, Ligand (biochemistry), 0104 chemical sciences, Computational Mathematics, HEK293 Cells, Amino Acid Substitution, chemistry, Excited state, Biophysics, biology.protein, Density functional theory, Photosensitization

Abstract

Evaluating the availability of molecular oxygen (O2) and energy of excited states in the retinalbinding site of rhodopsin is a crucial challenging first step to understand photosensitizing reactionsin wild-type (WT) and mutant rhodopsins by absorbing visible light. In the present work, energiesof the ground and excited states related to 11-cis-retinal and the O2 accessibility to the β-iononering are evaluated inside WT and human M207R mutant rhodopsins. Putative O2 pathways withinrhodopsins are identified by using molecular dynamics simulations, Voronoi-diagram analysis,and implicit ligand sampling while retinal energetic properties are investigated through densityfunctional theory, and quantum mechanical/molecular mechanical methods. Here, the predictionsreveal that an amino acid substitution can lead to enough energy and O2 accessibility in the corehosting retinal of mutant rhodopsins to favor the photosensitized singlet oxygen generation, whichcan be useful in understanding retinal degeneration mechanisms and in designing blue-lightingabsorbing proteic photosensitizers.

Published

2020

4. Transient pockets as mediators of gas molecules routes inside proteins: The case study of dioxygen pathway in homogentisate 1,2-dioxygenase and its implication in Alkaptonuria development

Author

Silvia Galderisi, Chukwudi Onyekachi Amarabom, Ottavia Spiga, Annalisa Santucci, and Andrea Bernini

Subjects

0301 basic medicine, Models, Molecular, Homogentisate 1, Protein Conformation, In silico, medicine.disease_cause, Alkaptonuria, Crystallography, X-Ray, Biochemistry, Dioxygenases, Diffusion, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Structural Biology, medicine, Humans, Homogentisic acid, Homogentisate 1,2-dioxygenase, chemistry.chemical_classification, Mutation, Homogentisate 1,2-Dioxygenase, biology, Organic Chemistry, Active site, Ligand (biochemistry), medicine.disease, Computational Mathematics, 030104 developmental biology, Enzyme, chemistry, 030220 oncology & carcinogenesis, biology.protein, Implicit ligand sampling, Thermodynamics, Oxygen diffusion pathways, Transient pockets, 2-dioxygenase

Abstract

Alkaptonuria (AKU) is an ultra-rare disease caused by mutations in homogentisate 1,2-dioxygenase (HGD) enzyme, characterized by the loss of enzymatic activity and the accumulation of its substrate, homogentisic acid (HGA) in different tissues, leading to ochronosis and organ degeneration. Although the pathological effects of HGD mutations are largely studied, less is known about the structure of the enzyme, in particular the pathways for dioxygen diffusion to the active site, required for the enzymatic reaction, are still uninvestigated. In the present project, the combination of two in silico techniques, Molecular Dynamics (MD) simulation and Implicit Ligand Sampling (ILS), was used to delineate gas diffusion routes in HGD enzyme. A route from the central opening of the hexameric structure of the enzyme to the back of the active site trough the protein moiety was identified as the path for dioxygen diffusion, also overlapping with a transient pocket, which then assumes an important role in dioxygen diffusion. Along the route the sequence location of the missense variant E401Q, responsible for AKU development, was also found, suggesting such mutation to be conducive of enzymatic activity loss by altering the flow dynamics of dioxygen. Our in silico approach allowed also to delineate the route of HGA substrate to the active site, until now only supposed.

Published

2020

5. Protonation of histidine 55 affects the oxygen access to heme in the alpha chain of the hemoglobin from the Antarctic fish Trematomus bernacchii.

Author

Boechi, Leonardo, Martì, Marcelo A., Vergara, Alessandro, Sica, Filomena, Mazzarella, Lelio, Estrin, Dario A., and Merlino, Antonello

Subjects

*HEMOGLOBINS, *TREMATOMUS bernacchii, *OXYGEN, *HISTIDINE, *MOLECULAR dynamics

Abstract

The Root effect describes the drastic drop of oxygen affinity and loss of cooperativity at acidic pH expressed in the hemoglobins (Hb) of certain fish. The comparison between the deoxy structures of the Root effect Hb from the Antarctic fish Trematomus bernacchii (HbTb) at different pHs (pH = 6.2 and pH = 8.4) shows that the most significant differences are localized at the CDα region, where a salt bridge between Asp48 and His55 breaks during the low-to-high pH transition. In order to shed light on the relationship between pH, CDα loop structure and dynamics, and oxygen access to the active site in the alpha chain of HbTb, different computer simulation techniques were performed. Our results highlight the importance of the protonation of His55 in regulating oxygen access, underscoring its pivotal role in the structural and functional properties of HbTb. These data provide further support to the hypothesis that this residue might contribute to the release of Root protons in HbTb and underline the fact that an efficient transport of molecular oxygen in Hbs relies on a subtle balance of tertiary structure and protein conformational flexibility. © 2011 IUBMB IUBMB Life, 63(3): 175-182, 2011 [ABSTRACT FROM AUTHOR]

Published

2011

6. Finding molecular dioxygen tunnels in homoprotocatechuate 2,3-dioxygenase: implications for different reactivity of identical subunits.

Author

Liang Xu, Weijie Zhao, and Xicheng Wang

Subjects

*CATECHOL, *OXYGEN, *ATOMS, *SOLVENTS, *ENZYMES, *LIGANDS (Chemistry)

Abstract

Extradiol dioxygenases facilitate microbial aerobic degradation of catechol and its derivatives by activating molecular dioxygen and incorporating both oxygen atoms into their substrates. Experimental and theoretical studies have focused on the mechanism of the reaction at the active site. However, whether the catalytic rate is limited by O2 access to the active site has not yet been explored. Here, we choose a recently solved X-ray structure of homoprotocatechuate 2,3-dioxygenase as a typical example to determine potential pathways for O2 migration from the solvent into the enzyme center. On the basis of the trajectories of two 10-ns molecular dynamics simulations, implicit ligand sampling was used to calculate the 3D free energy map for O2 inside the protein. The energetically optimal routes for O2 diffusion were identified for each subunit of the homotetrameric protein structure. The O2 tunnels formed because of thermal fluctuations were also characterized by connecting elongated cavities inside the protein. By superimposing the favorable O2 tunnels on to the free energy map, both energetically and geometrically preferred O2 pathways were determined, as also were the amino acids that may be critical for O2 passage along these paths. Our results demonstrate that identical subunits possess quite distinct O2 tunnels. The order of O2 affinity of these tunnels is generally consistent with the order of the catalytic rate of each subunit. As a consequence, the probability of finding the reaction product is highest in the subunit containing the highest O2 affinity pathway. [ABSTRACT FROM AUTHOR]

Published

2010

7. Topology and thermodynamics of gaseous ligands diffusion paths in human neuroglobin

Author

Orlowski, Slawomir and Nowak, Wieslaw

Subjects

*GLOBIN, *THERMODYNAMICS, *TOPOLOGY, *LIGANDS (Biochemistry), *DIFFUSION, *LIGAND binding (Biochemistry)

Abstract

Abstract: The physiological role of recently discovered human neuroglobin (Ngb) is still unknown. Sound hypothesis says that it protects brain during hypoxia. In this paper the advanced potential of mean force by implicit ligand sampling (PMF/ILS) method is used to study the free energy landscape of Ngb for O2, NO and CO ligands. The multiple diffusion paths are discovered and four ligand binding cavities are determined. The data show that certain regions are easily accessible by O2 and NO but are protected from CO. Free energy landscapes provide realistic data for stochastic models of ligand diffusion in proteins. [Copyright &y& Elsevier]

Published

2008

8. Discovering oxygen channel topology in photosystem II using implicit ligand sampling and wavefront propagation.

Author

Zaraiskaya, Tatiana, Vassiliev, Sergey, and Bruce, Doug

Subjects

PHOTOSYSTEMS, TOPOLOGY, LIGANDS (Biochemistry), SMALL molecules, MOLECULAR dynamics

Abstract

Highlights: [•] We examine oxygen migration pathways in the large multi polypeptide photosystem II protein complex. [•] We introduce a new strategy for finding small molecule pathways in large multiprotein complexes. [•] Our approach combines molecular dynamics, implicit ligand sampling and wavefront propagation within a three dimensional free energy map. [•] Our results show the presence of two putative oxygen escape channels in photosystem II. [ABSTRACT FROM AUTHOR]

Published

2014

9. Shifting the boundaries of experimental studies in engineering enzymatic functions : combining the benefits of computational and experimental methods

Author

Ebert, Maximilian and Pelletier, Joelle

Subjects

Ingénierie des protéines, CYP102A1, Ensembles structuraux, Enzyme kinetics, Dihydrofolate reductase, Cytochrome P450, Simulation de dynamique moléculaire in silico, Protein dynamics, Migration gazeuse, Structural ensembles, β-lactamase, Dihydrofolate réductase, Dynamique des protéines, In-silico molecular dynamics simulations, Adaptive biasing force, Directed evolution, Implicit ligand sampling, Cinétique enzymatique, Échantillonnage implicite de ligand, Force de polarisation adaptative, Protein engineering, Évolution dirigée, Gas migration

Abstract

L'industrie chimique mondiale est en pleine mutation, cherchant des solutions pour rendre la synthèse organique classique plus durable. Une telle solution consiste à passer de la catalyse chimique classique à la biocatalyse. Bien que les avantages des enzymes incluent leur stéréo, régio et chimiosélectivité, cette sélectivité réduit souvent leur promiscuité. Les efforts requis pour adapter la fonction enzymatique aux réactions désirées se sont révélés d'une efficacité modérée, de sorte que des méthodes rapides et rentables sont nécessaires pour générer des biocatalyseurs qui rendront la production chimique plus efficace. Dans l’ère de la bioinformatique et des outils de calcul pour soutenir l'ingénierie des enzymes, le développement rapide de nouvelles fonctions enzymatiques devient une réalité. Cette thèse commence par un examen des développements récents sur les outils de calcul pour l’ingénierie des enzymes. Ceci est suivi par un exemple de l’ingénierie des enzymes purement expérimental ainsi que de l’évolution des protéines. Nous avons exploré l’espace mutationnel d'une enzyme primitive, la dihydrofolate réductase R67 (DHFR R67), en utilisant l’ingénierie semi-rationnelle des protéines. La conception rationnelle d’une librarie de mutants, ou «Smart library design», impliquait l’association covalente de monomères de l’homotétramère DHFR R67 en dimères afin d’augmenter la diversité de la librairie d’enzymes mutées. Le criblage par activité enzymatique a révélé un fort biais pour le maintien de la séquence native dans un des protomères tout en tolérant une variation de séquence élevée pour le deuxième. Il est plausible que les protomères natifs procurent l’activité observée, de sorte que nos efforts pour modifier le site actif de la DHFR R67 peuvent n’avoir été que modérément fructueux. Les limites des méthodes expérimentales sont ensuite abordées par le développement d’outils qui facilitent la prédiction des points chauds mutationnels, c’est-à-dire les sites privilégiés à muter afin de moduler la fonction. Le développement de ces techniques est intensif en termes de calcul, car les protéines sont de grandes molécules complexes dans un environnement à base d’eau, l’un des solvants les plus difficiles à modéliser. Nous présentons l’identification rapide des points chauds mutationnels spécifiques au substrat en utilisant l'exemple d’une enzyme cytochrome P450 industriellement pertinente, la CYP102A1. En appliquant la technique de simulation de la dynamique moléculaire par la force de polarisation adaptative, ou «ABF», nous confirmons les points chauds mutationnels connus pour l’hydroxylation des acides gras tout en identifiant de nouveaux points chauds mutationnels. Nous prédisons également la conformation du substrat naturel, l’acide palmitique, dans le site actif et nous appliquons ces connaissances pour effectuer un criblage virtuel d'autres substrats de cette enzyme. Nous effectuons ensuite des simulations de dynamique moléculaire pour traiter l’impact potentiel de la dynamique des protéines sur la catalyse enzymatique, qui est le sujet de discussions animées entre les experts du domaine. Avec la disponibilité accrue de structures cristallines dans la banque de données de protéines (PDB), il devient clair qu’une seule structure de protéine n’est pas suffisante pour élucider la fonction enzymatique. Nous le démontrons en analysant quatre structures cristallines que nous avons obtenues d’une enzyme β-lactamase, parmi lesquelles un réarrangement important des résidus clés du site actif est observable. Nous avons réalisé de longues simulations de dynamique moléculaire pour générer un ensemble de structures suggérant que les structures cristallines ne reflètent pas nécessairement la conformation de plus basse énergie. Enfin, nous étudions la nécessité de compléter de manière informatisée un hémisphère où l’expérimental n’est actuellement pas possible, à savoir la prédiction de la migration des gaz dans les enzymes. À titre d'exemple, la réactivité des enzymes cytochrome P450 dépend de la disponibilité des molécules d’oxygène envers l’hème du site actif. Par le biais de simulations de la dynamique moléculaire de type Simulation Implicite du Ligand (ILS), nous dérivons le paysage de l’énergie libre de petites molécules neutres de gaz pour cartographier les canaux potentiels empruntés par les gaz dans les cytochromes P450 : CYP102A1 et CYP102A5. La comparaison pour les gaz CO, N2 et O2 suggère que ces enzymes évoluent vers l’exclusion du CO inhibiteur. De plus, nous prédisons que les canaux empruntés par les gaz sont distincts des canaux empruntés par le substrat connu et que ces canaux peuvent donc être modifiés indépendamment les uns des autres., The chemical industry worldwide is at a turning point, seeking solutions to make classical organic synthesis more sustainable. One such solution is to shift from classical catalysis to biocatalysis. Although the advantages of enzymes include their stereo-, regio-, and chemoselectivity, their selectivity often reduces versatility. Past efforts to tailor enzymatic function towards desired reactions have met with moderate effectiveness, such that fast and cost-effective methods are in demand to generate biocatalysts that will render the production of fine and bulk chemical production more benign. In the wake of bioinformatics and computational tools to support enzyme engineering, the fast development of new enzyme functions is becoming a reality. This thesis begins with a review of recent developments on computational tools for enzyme engineering. This is followed by an example of purely experimental enzyme engineering and protein evolution. We explored the mutational space of a primitive enzyme, the R67 dihydrofolate reductase (DHFR), using semi-rational protein engineering. ‘Smart library design’ involved fusing monomers of the homotetrameric R67 DHFR into dimers, to increase the diversity in the resulting mutated enzyme libraries. Activity-based screening revealed a strong bias for maintenance of the native sequence in one protomer with tolerance for high sequence variation in the second. It is plausible that the native protomers procure the observed activity, such that our efforts to modify the enzyme active site may have been only moderately fruitful. The limitations of experimental methods are then addressed by developing tools that facilitate computational mutational hotspot prediction. Developing these techniques is computationally intensive, as proteins are large molecular objects and work in aqueous media, one of the most complex solvents to model. We present the rapid, substrate-specific identification of mutational hotspots using the example of the industrially relevant P450 cytochrome CYP102A1. Applying the adaptive biasing force (ABF) molecular dynamics simulation technique, we confirm the known mutational hotspots for fatty acid hydroxylation and identify a new one. We also predict a catalytic binding pose for the natural substrate, palmitic acid, and apply that knowledge to perform virtual screening for further substrates for this enzyme. We then perform molecular dynamics simulations to address the potential impact of protein dynamics on enzyme catalysis, which is the topic of heated discussions among experts in the field. With the availability of more crystal structures in the Protein Data Bank, it is becoming clear that a single protein structure is not sufficient to elucidate enzyme function. We demonstrate this by analyzing four crystal structures we obtained of a β-lactamase enzyme, among which a striking rearrangement of key active site residues was observed. We performed long molecular dynamics simulations to generate a structural ensemble that suggests that crystal structures do not necessarily reflect the conformation of lowest energy. Finally, we address the need to computationally complement an area where experimentation is not currently possible, namely the prediction of gas migration into enzymes. As an example, the reactivity of P450 cytochrome enzymes depends on the availability of molecular oxygen at the active-site heme. Using the Implicit Ligand Sampling (ILS) molecular dynamics simulation technique, we derive the free energy landscape of small neutral gas molecules to map potential gas channels in cytochrome P450 CYP102A1 and CYP102A5. Comparison of CO, N2 and O2 suggests that those enzymes evolved towards exclusion of the inhibiting CO. In addition, we predict that gas channels are distinct from known substrate channels and therefore can be engineered independently from one another., Cette thèse comporte quatre fichiers vidéo. This thesis comes with four video files.

Published

2017

10. Transient pockets as mediators of gas molecules routes inside proteins: The case study of dioxygen pathway in homogentisate 1,2-dioxygenase and its implication in Alkaptonuria development.

Author

Bernini, Andrea, Galderisi, Silvia, Spiga, Ottavia, Amarabom, Chukwudi Onyekachi, and Santucci, Annalisa

Subjects

*DIOXYGENASES, *DIFFUSION, *BINDING sites, *MOIETIES (Chemistry), *MOLECULAR dynamics, *SMALL molecules

Abstract

• By use of Implicit Ligand Sampling, approach routes for dioxygen to the active site of homogentisate 1,2-dioxygenase were delineated. • Along the dioxygen route the E401Q variant, responsible for the rare disease Alkaptonuria, disrupts the gas diffusion path. • The diffusion of dioxygen is mediated by a transient pocket, suggesting transient geometry has to be taken into account for small molecules diffusion trough protein moiety. Alkaptonuria (AKU) is an ultra-rare disease caused by mutations in homogentisate 1,2-dioxygenase (HGD) enzyme, characterized by the loss of enzymatic activity and the accumulation of its substrate, homogentisic acid (HGA) in different tissues, leading to ochronosis and organ degeneration. Although the pathological effects of HGD mutations are largely studied, less is known about the structure of the enzyme, in particular the pathways for dioxygen diffusion to the active site, required for the enzymatic reaction, are still uninvestigated. In the present project, the combination of two in silico techniques, Molecular Dynamics (MD) simulation and Implicit Ligand Sampling (ILS), was used to delineate gas diffusion routes in HGD enzyme. A route from the central opening of the hexameric structure of the enzyme to the back of the active site trough the protein moiety was identified as the path for dioxygen diffusion, also overlapping with a transient pocket, which then assumes an important role in dioxygen diffusion. Along the route the sequence location of the missense variant E401Q, responsible for AKU development, was also found, suggesting such mutation to be conducive of enzymatic activity loss by altering the flow dynamics of dioxygen. Our in silico approach allowed also to delineate the route of HGA substrate to the active site, until now only supposed. [ABSTRACT FROM AUTHOR]

Published

2020

11. Comparing and combining implicit ligand sampling with multiple steered molecular dynamics to study ligand migration processes in heme proteins

Author

Flavio Forti, Leonardo Boechi, Marcelo A. Martí, and Darío A. Estrin

Subjects

Hemeproteins, Work (thermodynamics), ILS, PROTEINS, O2, FREE ENERGY PROFILE, Molecular Dynamics Simulation, Ligands, Nitric Oxide, Kinetic energy, NO, Molecular dynamics, DOCKING SITES, Computational chemistry, NITROPHORIN, TUNNELS, Topology (chemistry), Carbon Monoxide, biology, Chemistry, Ligand, MD, Otras Ciencias Químicas, TRUNCATED HAEMOGLOBIN, Ciencias Químicas, XENON SITES, Active site, Energy landscape, General Chemistry, Oxygen, CO, MSMD, Kinetics, MULTIPLE STEERED MOLECULAR DYNAMICS, Computational Mathematics, Range (mathematics), IMPLICIT LIGAND SAMPLING, biology.protein, Thermodynamics, MOLECULAR DYNAMICS, AMBER, CAVITIES, Biological system, LIGAND MIGRATION, CIENCIAS NATURALES Y EXACTAS

Abstract

The ubiquitous heme proteins perform a wide variety of tasks that rely on the subtle regulation of their affinity for small ligands like O2, CO, and NO. Ligand affinity is characterized by kinetic association and dissociation rate constants, that partially depend on ligand migration between the solvent and active site, mediated by the presence of internal cavities or tunnels. Different computational methods have been developed to study these processes which can be roughly divided in two strategies: those costly methods in which the ligand is treated explicitly during the simulations, and the free energy landscape of the process is computed; and those faster methods that use prior computed Molecular Dynamics simulation without the ligand, and incorporate it afterwards, called implicit ligand sampling (ILS) methods. To compare both approaches performance and to provide a combined protocol to study ligand migration in heme proteins, we performed ILS and multiple steered molecular dynamics (MSMD) free energy calculations of the ligand migration process in three representative and well theoretically and experimentally studied cases that cover a wide range of complex situations presenting a challenging benchmark for the aim of the present work. Our results show that ILS provides a good description of the tunnel topology and a reasonable approximation to the free energy landscape, while MSMD provides more accurate and detailed free energy profile description of each tunnel. Based on these results, a combined strategy is presented for the study of internal ligand migration in heme proteins. © 2011 Wiley Periodicals, Inc. Fil: Forti, Flavio. Universidad de Barcelona; España Fil: Boechi, Leonardo. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Instituto de Química, Física de los Materiales, Medioambiente y Energía. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Instituto de Química, Física de los Materiales, Medioambiente y Energía; Argentina Fil: Estrin, Dario Ariel. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Instituto de Química, Física de los Materiales, Medioambiente y Energía. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Instituto de Química, Física de los Materiales, Medioambiente y Energía; Argentina Fil: Marti, Marcelo Adrian. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Instituto de Química, Física de los Materiales, Medioambiente y Energía. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Instituto de Química, Física de los Materiales, Medioambiente y Energía; Argentina

Published

2011

12. Finding molecular dioxygen tunnels in homoprotocatechuate 2,3-dioxygenase: implications for different reactivity of identical subunits

Author

Xu, Liang, Zhao, Weijie, and Wang, Xicheng

Published

2010

13. Molecular dynamics simulations reveal highly permeable oxygen exit channels shared with water uptake channels in photosystem II.

Author

Vassiliev S, Zaraiskaya T, and Bruce D

Subjects

Molecular Dynamics Simulation, Oxidation-Reduction, Permeability, Photosystem II Protein Complex chemistry, Protein Conformation, Energy Metabolism, Oxygen metabolism, Photosystem II Protein Complex metabolism, Water metabolism

Abstract

Photosystem II (PSII) catalyzes the oxidation of water in the conversion of light energy into chemical energy in photosynthesis. Water delivery and oxygen removal from the oxygen evolving complex (OEC), buried deep within PSII, are critical requirements to facilitate the reaction and minimize reactive oxygen damage. It has often been assumed that water and oxygen travel through separate channels within PSII, as demonstrated in cytochrome c oxidase. This study describes all-atom molecular dynamics simulations of PSII designed to investigate channels by fully characterizing the distribution and permeation of both water and oxygen. Interestingly, most channels found in PSII were permeable to both oxygen and water, however individual channels exhibited different energetic barriers for the two solutes. Several routes for oxygen diffusion within PSII with low energy permeation barriers were found, ensuring its fast removal from the OEC. In contrast, all routes for water showed significant energy barriers, corresponding to a much slower permeation rate for water through PSII. Two major factors were responsible for this selectivity: (1) hydrogen bonds between water and channel amino acids, and (2) steric restraints. Our results reveal the presence of a shared network of channels in PSII optimized to both facilitate the quick removal of oxygen and effectively restrict the water supply to the OEC to help stabilize and protect it from small water soluble inhibitors., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

14. Comparing and combining implicit ligand sampling with multiple steered molecular dynamics to study ligand migration processes in heme proteins.

Author

Forti F, Boechi L, Estrin DA, and Marti MA

Subjects

Carbon Monoxide chemistry, Kinetics, Molecular Dynamics Simulation, Nitric Oxide chemistry, Oxygen chemistry, Thermodynamics, Hemeproteins chemistry, Ligands

Abstract

The ubiquitous heme proteins perform a wide variety of tasks that rely on the subtle regulation of their affinity for small ligands like O2, CO, and NO. Ligand affinity is characterized by kinetic association and dissociation rate constants, that partially depend on ligand migration between the solvent and active site, mediated by the presence of internal cavities or tunnels. Different computational methods have been developed to study these processes which can be roughly divided in two strategies: those costly methods in which the ligand is treated explicitly during the simulations, and the free energy landscape of the process is computed; and those faster methods that use prior computed Molecular Dynamics simulation without the ligand, and incorporate it afterwards, called implicit ligand sampling (ILS) methods. To compare both approaches performance and to provide a combined protocol to study ligand migration in heme proteins, we performed ILS and multiple steered molecular dynamics (MSMD) free energy calculations of the ligand migration process in three representative and well theoretically and experimentally studied cases that cover a wide range of complex situations presenting a challenging benchmark for the aim of the present work. Our results show that ILS provides a good description of the tunnel topology and a reasonable approximation to the free energy landscape, while MSMD provides more accurate and detailed free energy profile description of each tunnel. Based on these results, a combined strategy is presented for the study of internal ligand migration in heme proteins., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2011