Your search keyword '"Cantero‐Reviejo, Miguel"' showing total 2 results

1. Broad Adaptability of Coronavirus Adhesion Revealed from the Complementary Surface Affinity of Membrane and Spikes.

Author

García‐Arribas, Aritz B., Ibáñez‐Freire, Pablo, Carlero, Diego, Palacios‐Alonso, Pablo, Cantero‐Reviejo, Miguel, Ares, Pablo, López‐Polín, Guillermo, Yan, Han, Wang, Yan, Sarkar, Soumya, Chhowalla, Manish, Oksanen, Hanna M., Martín‐Benito, Jaime, de Pablo, Pedro J., and Delgado‐Buscalioni, Rafael

Subjects

ATOMIC force microscopy, CORONAVIRUSES, LANGMUIR isotherms, MEMBRANE proteins, COVID-19

Abstract

Coronavirus stands for a large family of viruses characterized by protruding spikes surrounding a lipidic membrane adorned with proteins. The present study explores the adhesion of transmissible gastroenteritis coronavirus (TGEV) particles on a variety of reference solid surfaces that emulate typical virus‐surface interactions. Atomic force microscopy informs about trapping effectivity and the shape of the virus envelope on each surface, revealing that the deformation of TGEV particles spans from 20% to 50% in diameter. Given this large deformation range, experimental Langmuir isotherms convey an unexpectedly moderate variation in the adsorption‐free energy, indicating a viral adhesion adaptability which goes beyond the membrane. The combination of an extended Helfrich theory and coarse‐grained simulations reveals that, in fact, the envelope and the spikes present complementary adsorption affinities. While strong membrane‐surface interaction lead to highly deformed TGEV particles, surfaces with strong spike attraction yield smaller deformations with similar or even larger adsorption‐free energies. [ABSTRACT FROM AUTHOR]

Published

2024

2. Surface characterization of alkane viral anchoring films prepared by titanate-assisted organosilanization

Author

Sanz Calderón, Aida, Cantero Reviejo, Miguel, Pérez, Uxia, Ortega González, Paula, San Martín, Carmen, de Pablo, Pedro J., Manso Silván, Miguel, Hernando Pérez, Mercedes, Universidad Autónoma de Madrid, Comunidad de Madrid, Ministerio de Ciencia e Innovación (España), Consejo Superior de Investigaciones Científicas (España), UAM. Departamento de Física Aplicada, UAM. Departamento de Física de la Materia Condensada, and UAM. Departamento de Física de Materiales

Subjects

Hydrophobic surfaces, Colloid and Surface Chemistry, Human adenovirus, Física, Surfaces and Interfaces, General Medicine, AFM, Reovirus, Physical and Theoretical Chemistry, Titanate-assisted organosilanization, Biotechnology

Abstract

8 pags., 5 figs., Studies of virus adsorption on surfaces with optimized properties have attracted a lot of interest, mainly due to the influence of the surface in the retention, orientation and stability of the viral capsids. Besides, viruses in whole or in parts can be used as cages or vectors in different areas, such as biomedicine and materials science. A key requirement for virus nanocage application is their physical properties, i.e. their mechanical response and the distribution of surface charge, which determine virus-substrate interactions and stability. In the present work we show two examples of viruses exhibiting strong surface interactions on homogeneous hydrophobic surfaces. The surfaces were prepared by titanate assisted organosilanization, a sol-gel spin coating process, followed by a mild annealing step. We show by surface and interface spectroscopies that the process allows trapping triethoxy-octylsilane (OCTS) molecules, exhibiting a hydrophobic alkane rich surface finishing. Furthermore, the surfaces remain flat and behave as more efficient sorptive surfaces for virus particles than mica or graphite (HOPG). Also, we determine by atomic force microscopy (AFM) the mechanical properties of two types of viruses (human adenovirus and reovirus) and compare the results obtained on the OCTS functionalized surfaces with those obtained on mica and HOPG. Finally, the TIPT+OCTS surfaces were validated as platforms for the morphological and mechanical characterization of virus particles by using adenovirus as initial model and using HOPG and mica as standard control surfaces. Then, the same characteristics were determined on reovirus using TIPT+OCTS and HOPG, as an original contribution to the catalogue of physical properties of viral particles., This work was supported by the grant Ayudas a Proyectos de I+D para Jóvenes Doctores de la Universidad Autónoma de Madrid 2021 (SI3/PJI/2021–00216) supported by Comunidad de Madrid and Universidad Autónoma de Madrid to M.H-P. Also, M.H-P acknowledges funding from the Spanish Ministry of Science and Innovation (TED2021–129937B-I00). Grant PID2019–104098GB-I00/AEI/10.13039/501100011033, co-funded by the Spanish State Research Agency and the European Regional Development Fund to C.S.M. The CNB-CSIC was further supported by a Spanish State Research Agency Severo Ochoa Excellence grant (SEV 2017–0712). C.S.M is a member of the CSIC funded consortium LifeHub (CSIC grant number: 202120E47). REACT-EU funding by Comunidad Autónoma de Madrid is also acknowledged. M.M.S acknowledges funding from MCIN/AEI /10.13039/501100011033 (PID2020–112770RB-C22). P.J.P acknowledges projects FIS2017–89549-R; and FIS2017–90701-REDT. P.J.P also acknowledges the Human Frontiers Science Program (HFSPO RGP0012/2018).

Published

2023