Characterization, Enrichment, and Computational Modeling of Cross-Linked Actin Networks in Transformed Trabecular Meshwork Cells
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Abstract
Purpose: Cross-linked actin networks (CLANs) are prevalent in the glaucomatous trabecular meshwork (TM). We previously developed the GTM3L cell line, which spontaneously forms fluorescently labeled CLANs, by transducing GTM3, a transformed glaucomatous TM cell line, with a lentivirus expressing the LifeAct-GFP fusion protein. Here, we determined if LifeAct-GFP viral copy numbers are associated with CLANs, developed approaches to increase CLAN incidence, and computationally studied the biomechanical properties of CLAN-containing GTM3L cells.
Methods: GTM3L cells were fluorescently sorted for viral copy number analysis to determine whether increased CLAN incidence was associated with copy number. CLAN incidence was increased by combining (1) differential adhesion sorting, (2) cell deswelling, and (3) cell stiffness selection. GTM3L cells were cultured on glass or soft hydrogels for stiffness measurement by atomic force microscopy. Computational models studied the biomechanical properties of CLANs.
Results: GTM3L cells had one LifeAct-GFP viral copy/cell on average, and viral copy number or LifeAct-GFP expression level did not associate with CLAN incidence rate. However, CLAN rate was increased from -0.28% to -50% by combining the three enrichment methods noted above. Further, GTM3L cells formed more CLANs on a stiff versus a soft substrate. Computational modeling predicted that CLANs contribute to higher cell stiffness, including increased resistance of the nucleus to tensile stress when CLANs are physically linked to the nucleus.
Conclusions: It is possible to greatly enhance CLAN incidence in GTM3L cells. CLANs are mechanosensitive structures that affect cell biomechanical properties. Further research is needed to determine the biomechanics, mechanobiology, and etiology of CLANs in the TM.