Your search keyword '"Steered molecular dynamic"' showing total 6 results

1. Mechanical dissociation of the M-band titin/obscurin complex is directionally dependent.

Author

Caldwell, Tracy A., Sumner, Isaiah, and Wright, Nathan T.

Subjects

*DISSOCIATION (Chemistry), *OBSCURIN, *MUSCLE proteins, *CHEMICAL peel, *PHYSIOLOGIC strain

Abstract

Titin and obscurin, two giant muscle proteins, bind to each other in an antiparallel Ig–Ig fashion at the M-band. This interaction must be able to withstand the mechanical strain that the M-band typically experiences and remain intact. The mechanical force on these domains is likely exerted along one of two axes: a longitudinal axis, resulting in a ‘shearing’ force, or a lateral axis, resulting in a ‘peeling’ force. Here we present molecular dynamics data suggesting that these forces result in distinct unraveling pathways of the titin/obscurin complex and that peeling the domains apart requires less work and force. [ABSTRACT FROM AUTHOR]

Published

2015

2. Chemoenzymatic synthesis of 2,6-disubstituted tetrahydropyrans with high σ1 receptor affinity, antitumor and analgesic activity

Author

Nicole Kopp, Erik Laurini, Hans-Ulrich Humpf, Dirk Schepmann, Carmen Almansa, Francisco R. Nieto, Sabrina Pricl, Gianluca Civenni, Domenico Marson, Carlo V. Catapano, Bernhard Wünsch, Kopp, N., Civenni, G., Marson, D., Laurini, E., Pricl, S., Catapano, C. V., Humpf, H. -U., Almansa, C., Nieto, F. R., Schepmann, D., and Wunsch, B.

Subjects

Steered molecular dynamics, Analgesic activity, Eudysmic ratio, Molecular dynamic, Stereochemistry, receptor, Molecular dynamics, Neuropathic pain, Kinetic resolution, chemistry.chemical_compound, σ, Drug Discovery, Chiral HPLC, Moiety, Chemoenzymatic synthesis, Selectivity, Docking studies, Binding site, Steered molecular dynamic, Structure affinity relationship, Pharmacology, 2,6-Disubstituted tetrahydropyrans, Androgen negative human prostate cancer cell line DU145, Antiallodynic activity, Antitumor activity, CD spectroscopy, Structure affinity relationships, 1, receptor affinity, Organic Chemistry, General Medicine, Tetrahydropyran, 2,6-Disubstituted tetrahydropyran, Ligand (biochemistry), Chiral column chromatography, chemistry, 6-Disubstituted tetrahydropyrans, Docking studie, Chemoenzymatic synthesi, Enantiomer

Abstract

1,3-Dioxanes 1 and cyclohexanes 2 bearing a phenyl ring and an aminoethyl moiety in 1,3-relationship to each other represent highly potent σ1 receptor antagonists. In order to increase the chemical stability of the acetalic 1,3-dioxanes 1 and the polarity of the cyclohexanes 2, tetrahydropyran derivatives 3 equipped with the same substituents were designed, synthesized and pharmacologically evaluated. The key step of the synthesis was a lipase-catalyzed enantioselective acetylation of the alcohol (R)-5 leading finally to enantiomerically pure test compounds 3a-g. With respect to σ1 receptor affinity and selectivity over a broad range of related (σ2, PCP binding site) and further targets, the enantiomeric benzylamines 3a and cyclohexylmethylamines 3b represent the most promising drug candidates of this series. However, the eudismic ratio for σ1 binding is only in the range of 2.5–3.3. Classical molecular dynamics (MD) simulations confirmed the same binding pose for both the tetrahydropyran 3 and cyclohexane derivatives 2 at the σ1 receptor, according to which: i) the protonated amino moiety of (2S,6R)-3a engages the same key polar interactions with Glu172 (ionic) and Phe107 (π-cation), ii) the lipophilic parts of (2S,6R)-3a are hosted in three hydrophobic regions of the σ1 receptor, and iii) the O-atom of the tetrahydropyran derivatives 3 does not show a relevant interaction with the σ1 receptor. Further in silico evidences obtained by the application of free energy perturbation and steered MD techniques fully supported the experimentally observed difference in receptor/ligand affinities. Tetrahydropyrans 3 require a lower dissociative force peak than cyclohexane analogs 2. Enantiomeric benzylamines 3a and cyclohexylmethylamines 3b were able to inhibit the growth of the androgen negative human prostate cancer cell line DU145. The cyclohexylmethylamine (2S,6R)-3b showed the highest σ1 affinity (Ki(σ1) = 0.95 nM) and the highest analgesic activity in vivo (67%).

Published

2021

3. Molecular basis of the recognition of arachidonic acid by cytochrome P450 2E1 along major access tunnel.

Author

Cui, Ying‐Lu, Zheng, Qing‐Chuan, Zhang, Ji‐Long, and Zhang, Hong‐Xing

Abstract

ABSTRACT Cytochrome P450 2E1 is widely known for its ability to oxidize both low molecular weight xenobiotics and endogenous fatty acids (e.g., arachidonic acid (AA)). In this study, we investigated the structural features of the AA-bound CYP2E1 complex utilizing molecular dynamics (MD) and found that the distinct binding modes for both AA and fatty acid analog are conserved. Moreover, multiple random acceleration MD simulations and steered MD simulations uncovered the most possible tunnel for fatty acids. The main attractions are derived from three key residues, His107, Ala108, and His109, whose side chains reorient to keep ligands bound via hydrogen bonds during the initial unbinding process. More importantly, based on the calculated binding free energy results, we hypothesize that the hydrogen bonds between the receptor and the ligand are the most important contributors involved in the binding affinity. Thus, it is inferred that the hydrogen bonds between these three residues and the ligand may help offer insights into the structural basis of the different ligand egress mechanisms for fatty acids and small weight compounds. Our investigation provides detailed atomistic insights into the structural features of human CYP2E1-fatty acid complex structures. Furthermore, the ligand-binding characteristics obtained in the present study are helpful for both experimental and computational studies of CYPs and may allow future researchers to achieve desirable changes in enzymatic activities. © 2014 Wiley Periodicals, Inc. Biopolymers 103: 53-66, 2015. [ABSTRACT FROM AUTHOR]

Published

2015

4. Control over the fibrillization yield by varying the oligomeric nucleation propensities of self-assembling peptides

Author

Lau, Chun Yin Jerry, Fontana, Federico, Mandemaker, Laurens D. B., Wezendonk, Dennie, Vermeer, Benjamin, Bonvin, Alexandre M. J. J., De Vries, Renko, Zhang, Heyang, Remaut, Katrien, Van Den Dikkenberg, Joep, Medeiros-silva, João, Hassan, Alia, Perrone, Barbara, Kuemmerle, Rainer, Gelain, Fabrizio, Hennink, Wim E., Weingarth, Markus, Mastrobattista, Enrico, Afd Pharmaceutics, Sub NMR Spectroscopy, Sub Inorganic Chemistry and Catalysis, Pharmaceutics, Lau, C, Fontana, F, Mandemaker, L, Wezendonk, D, Vermeer, B, Bonvin, A, de Vries, R, Zhang, H, Remaut, K, van den Dikkenberg, J, Medeiros-Silva, J, Hassan, A, Perrone, B, Kuemmerle, R, Gelain, F, Hennink, W, Weingarth, M, Mastrobattista, E, Lau, Chun, Afd Pharmaceutics, Sub NMR Spectroscopy, Sub Inorganic Chemistry and Catalysis, and Pharmaceutics

Subjects

PROTEINS, Supramolecular chemistry, Nucleation, Peptide, 02 engineering and technology, 010402 general chemistry, Fibril, 01 natural sciences, Biochemistry, Cryo-TEM, lcsh:Chemistry, Steered Molecular Dynamic, SIDE-CHAINS, chemistry.chemical_compound, Molecular dynamics, ssNMR, SYSTEMS, Medicine and Health Sciences, Materials Chemistry, Side chain, Life Science, Environmental Chemistry, VLAG, chemistry.chemical_classification, STABILITY, Chemistry, Self-assembling Peptide, Biology and Life Sciences, General Chemistry, SEQUENCE DETERMINANTS, 021001 nanoscience & nanotechnology, 0104 chemical sciences, MODEL, Hydrogel, Monomer, lcsh:QD1-999, MOLECULAR-DYNAMICS, Self-healing hydrogels, Biophysics, 0210 nano-technology, Physical Chemistry and Soft Matter, Coarse-Grained Molecular Dynamic

Abstract

Self-assembling peptides are an exemplary class of supramolecular biomaterials of broad biomedical utility. Mechanistic studies on the peptide self-assembly demonstrated the importance of the oligomeric intermediates towards the properties of the supramolecular biomaterials being formed. In this study, we demonstrate how the overall yield of the supramolecular assemblies are moderated through subtle molecular changes in the peptide monomers. This strategy is exemplified with a set of surfactant-like peptides (SLPs) with different β-sheet propensities and charged residues flanking the aggregation domains. By integrating different techniques, we show that these molecular changes can alter both the nucleation propensity of the oligomeric intermediates and the thermodynamic stability of the fibril structures. We demonstrate that the amount of assembled nanofibers are critically defined by the oligomeric nucleation propensities. Our findings offer guidance on designing self-assembling peptides for different biomedical applications, as well as insights into the role of protein gatekeeper sequences in preventing amyloidosis.

Published

2020

5. Impact of siRNA overhangs for dendrimer-mediated siRNA delivery and gene silencing

Author

Sabrina Pricl, Paola Posocco, Chao Chen, Domenico Marson, Maurizio Fermeglia, Ling Peng, Erik Laurini, Cheng Liu, Palma Rocchi, Xiaoxuan Liu, Centre Interdisciplinaire de Nanoscience de Marseille (CINaM), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Posocco, Paola, Liu, X, Laurini, Erik, Marson, Domenico, Chen, C, Liu, C, Fermeglia, Maurizio, Rocchi, P, Pricl, Sabrina, Peng, L., and Cinam, Hal

Subjects

Male, Small interfering RNA, Dendrimers, Concatemer, Pharmaceutical Science, Cooperativity, free energy of binding, chemistry.chemical_compound, RNA interference, Dendrimer, Cell Line, Tumor, Drug Discovery, siRNA, sticky siRNA, delivery, dendrimers and dendrons, free energy, steered molecular dynamics, genetics, Gene Silencing, Gene silencing, Humans, genetics, Gene Silencing, RNA, Small Interfering, steered molecular dynamic, dendrimers and dendron, RNA, Molecular biology, chemistry, Biophysics, Molecular Medicine, Female, Nanocarriers

Abstract

Small interfering RNA (siRNA) have attracted considerable attention, as compelling therapeutics providing safe and competent delivery systems are available. Dendrimers are emerging as appealing siRNA delivery vectors thanks to their unique, well-defined architecture and the resulting cooperativity and multivalency confined within a nanostructure. We have recently disclosed the structurally flexible fifth-generation TEA-core PAMAM dendrimer (G5) as an effective nanocarrier for delivery of sticky siRNA bearing long complementary sequence overhangs (dA)n/(dT)n (n = 5 or 7). Here, using combined experimental/computational approaches, we successfully clarified (i) the underlying mechanisms of interaction between the dendrimer nanovector G5 and siRNA molecules bearing either complementary or noncomplementary sequence overhangs of different length and chemistry and (ii) the impact of siRNA overhangs contributing toward the improved delivery potency. Using siRNA with complementary overhangs offer the best action in term of gene silencing through the formation of concatemers, that is, supramolecular structures resulting from synergistic and cooperative binding via (dA)n/(dT)n bridges (n = 5 or 7). On the other hand, although siRNA bearing long, noncomplementary overhangs (dA)n/(dA)n or (dT)n/(dT)n (n = 5 or 7) are endowed with considerably higher gene silencing potency than normal siRNA with (dT)2/(dT)2, they remain less effective than their sticky siRNA counterparts. The observed gene silencing potency depends on length, nature, and flexibility of the overhangs, which behave as a sort of clamps that hold and interact with the dendrimer nanovectors, thus impacting siRNA delivery performance and, ultimately, gene silencing. Our findings can be instrumental in designing siRNA entities with enhanced capability to achieve effective RNA interference for therapeutic applications.

Published

2013

6. Steered Molecular Dynamics Simulation in Rational Drug Design.

Author

Do PC, Lee EH, and Le L

Subjects

Animals, Drug Evaluation, Preclinical, Humans, Ligands, Protein Binding, Proteins chemistry, Computer-Aided Design, Drug Design, Molecular Dynamics Simulation, Proteins metabolism

Abstract

Conventional de novo drug design is time consuming, laborious, and resource intensive. In recent years, emerging in silico approaches have been proven to be critical to accelerate the process of bringing drugs to market. Molecular dynamics (MD) simulations of single molecule and molecular complexes have been commonly applied to achieve accurate binding modes and binding energies of drug-receptor interactions. A derivative of MD, namely, steered molecular dynamics (SMD), has been demonstrated as a promising tool for rational drug design. In this paper, we review various studies over the last 20 years using SMD simulations, thus paving the way to determine the relationship between protein structure and function. In addition, the paper highlights the use of SMD simulation for in silico drug design. We also aim to establish an understanding on the key interactions which play a crucial role in the stabilization of peptide-ligand interfaces, the binding and unbinding mechanism of the ligand-protein complex, the mechanism of ligand translocating via membrane, and the ranking of different ligands on receptors as therapeutic candidates.

Published

2018