Some of the material in is restricted to members of the community. By logging in, you may be able to gain additional access to certain collections or items. If you have questions about access or logging in, please use the form on the Contact Page.
Jaqaman, K., Galbraith, J. A., Davidson, M. W., & Galbraith, C. G. (2016). Changes in single-molecule integrin dynamics linked to local cellular behavior. Molecular Biology Of The Cell. Retrieved from http://purl.flvc.org/fsu/fd/FSU_pmch_27009207
Recent advances in light microscopy permit visualization of the behavior of individual molecules within dense macromolecular ensembles in live cells. It is now conceptually possible to relate the dynamic organization of molecular machinery to cellular function. However, inherent heterogeneities, as well as disparities between spatial and temporal scales, pose substantial challenges in deriving such a relationship. New approaches are required to link discrete single-molecule behavior with continuous cellular-level processes. Here we combined intercalated molecular and cellular imaging with a computational framework to detect reproducible transient changes in the behavior of individual molecules that are linked to cellular behaviors. Applying our approach to integrin transmembrane receptors revealed a spatial density gradient underlying characteristic molecular density increases and mobility decreases, indicating the subsequent onset of local protrusive activity. Integrin mutants further revealed that these density and mobility transients are separable and depend on different binding domains within the integrin cytoplasmic tail. Our approach provides a generalizable paradigm for dissecting dynamic spatiotemporal molecular behaviors linked to local cellular events.
Jaqaman, K., Galbraith, J. A., Davidson, M. W., & Galbraith, C. G. (2016). Changes in single-molecule integrin dynamics linked to local cellular behavior. Molecular Biology Of The Cell. Retrieved from http://purl.flvc.org/fsu/fd/FSU_pmch_27009207