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Cofas Vargas L. F., Olivos-Ramirez G. E., Chwastyk M.♦, Moreira R.A.♦, Baker J. L.♦, Marrink S. J.♦, Poma Bernaola A.M., Nanomechanical footprint of SARS-CoV-2 variants in complex with a potent nanobody by molecular simulations,
NANOSCALE, ISSN: 2040-3364, DOI: 10.1039/D4NR02074J, pp.1-11, 2024Abstract: Rational design of novel antibody therapeutics against viral infections such as coronavirus relies on surface complementarity and high affinity for their effectiveness. Here, we explore an additional property of protein complexes, the intrinsic mechanical stability, in SARS-CoV-2 variants when complexed with a potent antibody. In this study, we utilized a recent implementation of the GōMartini 3 approach to investigate large conformational changes in protein complexes with a focus on the mechanostability of the receptor-binding domain (RBD) from WT, Alpha, Delta, and XBB.1.5 variants in complex with the H11-H4 nanobody. The analysis revealed moderate differences in mechanical stability among these variants. Also, we identified crucial residues in both the RBD and certain protein segments in the nanobody that contribute to this property. By performing pulling simulations and monitoring the presence of specific native and non-native contacts across the protein complex interface, we provided mechanistic insights into the dissociation process. Force-displacement profiles indicate a tensile force clamp mechanism associated with the type of protein complex. Our computational approach not only highlights the key mechanostable interactions that are necessary to maintain overall stability, but it also paves the way for the rational design of potent antibodies that are mechanostable and effective against emergent SARS-CoV-2 variants. Keywords: SARS-CoV-2, GōMartini 3, Nanomechanics, Protein complexes, protein engineering, MD, native contacts Affiliations:
Cofas Vargas L. F. | - | IPPT PAN | Olivos-Ramirez G. E. | - | IPPT PAN | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Moreira R.A. | - | other affiliation | Baker J. L. | - | The College of New Jersey (US) | Marrink S. J. | - | other affiliation | Poma Bernaola A.M. | - | IPPT PAN |
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Cofas Vargas L.F.♦, Azevedo Rodrigo M.♦, Poblete S.♦, Chwastyk M.♦, Poma Bernaola A.M.♦, The GōMartini Approach: Revisiting the Concept of Contact Maps and the Modelling of Protein Complexes,
ACTA PHYSICA POLONICA A, ISSN: 0587-4246, DOI: 10.12693/APhysPolA.145.S9, Vol.145, No.3, pp.S9-S20, 2024Abstract: We present a review of a series of contact maps for the determination of native interactions in proteins and nucleic acids based on a distance threshold. Such contact maps are mostly based on physical and chemical construction, and yet they are sensitive to some parameters (e.g., distances or atomic radii) and can neglect some key interactions. Furthermore, we also comment on a new class of contact maps that only requires geometric arguments. The contact map is a necessary ingredient to build a robust Gō-Martini model for proteins and their complexes in the Martini 3 force field. We present the extension of a popular structure-based Gō--like approach to the study of protein–sugar complexes, and the limitations of this approach are also discussed. The Gō-Martini approach was first introduced by Poma et al. (J. Chem. Theory Comput. 13, 1366 (2017)) in Martini 2 force field, and recently, it has gained the status of gold standard for protein simulation undergoing conformational changes in Martini 3 force field. We discuss several studies that have provided support for this approach in the context of the biophysical community. Keywords: Martini 3,Structure-based coarse-graining,SMFS,biomolecules,GoMartini Affiliations:
Cofas Vargas L.F. | - | other affiliation | Azevedo Rodrigo M. | - | other affiliation | Poblete S. | - | other affiliation | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Poma Bernaola A.M. | - | other affiliation |
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Moreira R., Chwastyk M.♦, Baker J.L.♦, Vargas Guzman H.A.♦, Poma A., Quantitative determination of mechanical stability in the novel coronavirus spike protein,
NANOSCALE, ISSN: 2040-3364, DOI: 10.1039/D0NR03969A, Vol.12, No.31, pp.16409-16413, 2020Abstract: We report on the novel observation about the gain in mechanical stability of the SARS-CoV-2 (CoV2) spike (S) protein in comparison with SARS-CoV from 2002 (CoV1). Our findings have several biological implications in the subfamily of coronaviruses, as they suggest that the receptor binding domain (RBD) (~200 amino acids) plays a fundamental role as a damping element of the massive viral particle's motion prior to cell-recognition, while also facilitating viral attachment, fusion and entry. The mechanical stability via pulling of the RBD is 250 pN and 200 pN for CoV2 and CoV1 respectively, and the additional stability observed for CoV2 (~50 pN) might play a role in the increasing spread of COVID-19. Affiliations:
Moreira R. | - | IPPT PAN | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Baker J.L. | - | The College of New Jersey (US) | Vargas Guzman H.A. | - | Max-Planck-Institute for Polymer Research (DE) | Poma A. | - | IPPT PAN |
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Poma Bernaola A.♦, Chwastyk M.♦, Cieplak M.♦, Elastic moduli of biological fibers in a coarse-grained model: crystalline cellulose and β-amyloids,
Physical Chemistry Chemical Physics, ISSN: 1463-9076, DOI: 10.1039/C7CP05269C, Vol.19, pp.28195-28206, 2017Abstract: We study the mechanical response of cellulose and β-amyloid microfibrils to three types of deformation: tensile, indentational, and shear. The cellulose microfibrils correspond to the allomorphs Iα or Iβ whereas the β-amyloid microfibrils correspond to the polymorphs of either two- or three-fold symmetry. This response can be characterized by three elastic moduli, namely, YL, YT, and S. We use a structure-based coarse-grained model to analyze the deformations in a unified manner. We find that each of the moduli is almost the same for the two allomorphs of cellulose but YL is about 20 times larger than YT (140 GPa vs. 7 GPa), indicating the existence of significant anisotropy. For cellulose we note that the anisotropy results from the involvement of covalent bonds in stretching. For β-amyloid, the sense of anisotropy is opposite to that of cellulose. In the three-fold symmetry case, YL is about half of YT (3 vs. 7) whereas for two-fold symmetry the anisotropy is much larger (1.6 vs. 21 GPa). The S modulus is derived to be 1.2 GPa for three-fold symmetry and one half of it for the other symmetry and 3.0 GPa for cellulose. The values of the moduli reflect deformations in the hydrogen-bond network. Unlike in our theoretical approach, no experiment can measure all three elastic moduli with the same apparatus. However, our theoretical results are consistent with various measured values: typical YL for cellulose Iβ ranges from 133 to 155 GPa, YT from 2 to 25 GPa, and S from 1.8 to 3.8 GPa. For β-amyloid, the experimental values of S and YT are about 0.3 GPa and 3.3 GPa respectively, while the value of YL has not been reported. Keywords: Tensile, shear, indentation, Atomic Force Microscopy, amyloid, cellulose Affiliations:
Poma Bernaola A. | - | other affiliation | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Cieplak M. | - | Institute of Physics, Polish Academy of Sciences (PL) |
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Poma Bernaola A.♦, Chwastyk M.♦, Cieplak M.♦, Coarse-grained model of the native cellulose and the transformation pathways to the allomorph,
CELLULOSE, ISSN: 0969-0239, DOI: 10.1007/s10570-016-0903-4, Vol.23, pp.1573-1591, 2016Abstract: All-atom simulations are used to derive effective parameters for a coarse-grained description of the crystalline cellulose I Keywords: Cellulose, microfibril, allomorphs, structural transition, molecular dynamics, free energy Affiliations:
Poma Bernaola A. | - | other affiliation | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Cieplak M. | - | Institute of Physics, Polish Academy of Sciences (PL) |
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Poma Bernaola A.♦, Chwastyk M.♦, Cieplak M.♦, Polysaccharide–protein complexes in a Coarse-Grained Model,
JOURNAL OF PHYSICAL CHEMISTRY B, ISSN: 1520-6106, DOI: 10.1021/acs.jpcb.5b06141, Vol.119, pp.12028-12041, 2015Abstract: We construct two variants of coarse-grained models of three hexaoses: one based on the centers of mass of the monomers and the other associated with the C4 atoms. The latter is found to be better defined and more suitable for studying interactions with proteins described within α-C based models. We determine the corresponding effective stiffness constants through all-atom simulations and two statistical methods. One method is the Boltzmann inversion (BI) and the other, named energy-based (EB), involves direct monitoring of energies as a function of the variables that define the stiffness potentials. The two methods are generally consistent in their account of the stiffness. We find that the elastic constants differ between the hexaoses and are noticeably different from those determined for the crystalline cellulose Iβ. The nonbonded couplings through hydrogen bonds between different sugar molecules are modeled by the Lennard-Jones potentials and are found to be stronger than the hydrogen bonds in proteins. We observe that the EB method agrees with other theoretical and experimental determinations of the nonbonded parameters much better than BI. We then consider the hexaose-Man5B catalytic complexes and determine the contact energies between their the C4−α-C atoms. These interactions are found to be stronger than the proteinic hydrogen bonds: about four times as strong for cellohexaose and two times for mannohexaose. The fluctuational dynamics of the coarse-grained complexes are found to be compatible with previous all-atom studies by Bernardi et al. Keywords: Polysaccharide, protein, principal component analysis, coarse graining, molecular simulation Affiliations:
Poma Bernaola A. | - | other affiliation | Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Cieplak M. | - | Institute of Physics, Polish Academy of Sciences (PL) |
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Chwastyk M.♦, Poma Bernaola A.♦, Cieplak M.♦, Statistical radii associated with amino acids to determine the contact map: fixing the structure of a type I cohesin domain in the Clostridium thermocellum cellulosome,
PHYSICAL BIOLOGY, ISSN: 1478-3967, DOI: 10.1088/1478-3975/12/4/046002, Vol.12, No.046002, pp.1-11, 2015Abstract: We propose to improve and simplify protein refinement procedures through consideration of which pairs of amino acid residues should form native contacts. We first consider 11 330 proteins from the CATH database to determine statistical distributions of contacts associated with a given type of amino acid. The distributions are set across the distances between the α-C atoms that are in contact. Based on this data, we determine typical radii of effective spheres that can be placed on the α-C atoms in order to reconstruct the distribution of the contact lengths. This is done by checking for overlaps with enlarged van der Waals spheres associated with heavy atoms on other amino acids.The resulting contacts can be used to identify non-native contacts that may arise during the time evolution of structure-based models. Here, the radii are used to guide reconstruction of nine missing side chains in a type I cohesin domain with the Protein Data Bank code 1AOH. We first identify the likely missing contacts and then sculpt the corresponding side chains by standard refinement tools to achieve consistency with the expected contact map. One ambiguity in refinement is resolved by determining all-atom conformational energies. Keywords: Cohesin, Go-like model, protein prediction, proteins, AFM, stretching Affiliations:
Chwastyk M. | - | Institute of Physics, Polish Academy of Sciences (PL) | Poma Bernaola A. | - | other affiliation | Cieplak M. | - | Institute of Physics, Polish Academy of Sciences (PL) |
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