Integrin alpha(5) controls osteoblastic proliferation and differentiation responses to titanium substrates presenting different roughness characteristics in a roughness independent manner.

Integrin alpha(5)beta(1) regulates osteoblast proliferation and differentiation on smooth synthetic surfaces presenting different chemistries, but it is not known whether this integrin controls osteoblast behavior on surfaces that have micron-scale rough topographies. We cultured MG63 human osteoblast-like cells on titanium substrates with three different roughness characteristics: chemically polished (PT), grit blasted and acid etched with a complex topography consisting of 20-100 mum craters and 0.5-2 mum micropits (SLA), and plasma-sprayed Ti with irregular projections (TPS). Cells spread well on PT but displayed a smaller footprint on SLA or TPS. Nuclei were larger on PT as well. alpha(5)beta(1) binding and FAK phosphorylation were greater on the rougher surfaces (TPS > SLA > PT). Antibodies against the alpha(5)beta(1) binding site on fibronectin had no effect on cell number at 3 days, but [(3)H]-thymidine incorporation was increased, suggesting that binding to fibronectin was necessary for cell cycle regulation. Antibodies to the alpha(5) subunit reduced cell number at 3 days on PT and TPS and reduced DNA synthesis on all substrates in a surface microstructure-independent manner. At 7 days, cell numbers were reduced on PT, and DNA synthesis was reduced by 50% on all surfaces. At 7 days, anti-alpha(5) antibodies caused a partial reduction in alkaline phosphatase enzyme activity on all surfaces, but this effect was independent of surface microstructure. These results indicate that surface micron-scale topography modulates alpha(5)beta(1) integrin binding and FAK activation. Signaling via alpha(5)-dependent mechanisms is required for DNA synthesis and regulation of alkaline phosphatase, but this effect is independent of surface microstructure.