Litcius/Paper detail

Complex effects of Mg-biomaterials on the osteoblast cell machinery: A proteomic study

Andreia Cerqueira, Iñaki García‐Arnáez, Francisco Romero‐Gavilán, Mikel Azkargorta, Félix Elortza, José Javier Martín de Llanos, Carmen Cardá, M. Gurruchaga, Isabel Goñi, J. Suay

2022Biomaterials Advances23 citationsDOIOpen Access PDF

Abstract

The cell-biomaterial interface is highly complex; thousands of molecules and many processes participate in its formation. Growing demand for improved biomaterials has highlighted the need to understand the structure and functions of this interface. Proteomic methods offer a viable alternative to the traditional in vitro techniques for analyzing such systems. Magnesium is a promoter of cell adhesion and osteogenesis. Here, we used the LC-MS/MS to compare the protein expression profiles of human osteoblasts (HOb) exposed to sol-gel coatings without (MT) and with Mg (MT1.5Mg) for 1, 3, and 7 days. PANTHER, DAVID, and IPA databases were employed for protein identification and data analysis. Confocal microscopy and gene expression analysis were used for further characterization. Exposure to MT1.5Mg increased the HOb cell area and the expression of SP7, RUNX2, IBP3, COL3A1, MXRA8, and FBN1 genes. Proteomic analysis showed that MT1.5Mg affected the early osteoblast maturation (PI3/AKT, mTOR, ERK/MAPK), insulin metabolism, cell adhesion (integrin, FAK, actin cytoskeleton regulation) and oxidative stress pathways. Thus, the effects of Mg on cell adhesion and osteogenesis are rather complex, affecting several pathways rather than single processes. Our analysis also confirms the potential of proteomics in biomaterial characterization, showing a good correlation with in vitro results.

Topics & Concepts

ProteomicsCell biologyRUNX2BiomaterialCell adhesionActin cytoskeletonChemistryIntegrinPI3K/AKT/mTOR pathwayProtein kinase BOsteoblastAdhesionCytoskeletonCellSignal transductionBiologyIn vitroBiochemistryGeneOrganic chemistryMagnesium Alloys: Properties and ApplicationsBone Tissue Engineering MaterialsMXene and MAX Phase Materials