Multiplexing molecular tension sensors reveals piconewton force gradient across talin-1.

Förster resonance energy transfer (FRET)-based tension sensor modules (TSMs) are available for investigating how distinct proteins bear mechanical forces in cells. Yet, forces in the single piconewton (pN) regime remain difficult to resolve, and tools for multiplexed tension sensing are lacking. Here, we report the generation and calibration of a genetically encoded, FRET-based biosensor called FL-TSM, which is characterized by a near-digital force response and increased sensitivity at 3-5 pN. In addition, we present a method allowing the simultaneous evaluation of coexpressed tension sensor constructs using two-color fluorescence lifetime microscopy. Finally, we introduce a procedure to calculate the fraction of mechanically engaged molecules within cells. Application of these techniques to new talin biosensors reveals an intramolecular tension gradient across talin-1 that is established upon integrin-mediated cell adhesion. The tension gradient is actomyosin- and vinculin-dependent and sensitive to the rigidity of the extracellular environment.

Investigating piconewton forces in cells by FRET-based molecular force microscopy.

The ability of cells to sense and respond to mechanical forces is crucial for a wide range of developmental and pathophysiological processes. The molecular mechanisms underlying cellular mechanotransduction, however, are largely unknown because suitable techniques to measure mechanical forces across individual molecules in cells have been missing. In this article, we highlight advances in the development of molecular force sensing techniques and discuss our recently expanded set of FRET-based tension sensors that allows the analysis of mechanical forces with piconewton sensitivity in cells. In addition, we provide a theoretical framework for the design of additional tension sensor modules with adjusted force sensitivity.

Tubulin detyrosination promotes monolayer formation and apical trafficking in epithelial cells.

The role of post-translational tubulin modifications in the development and maintenance of a polarized epithelium is not well understood. We studied the balance between detyrosinated (detyr-) and tyrosinated (tyr-) tubulin in the formation of MDCK cell monolayers. Increased quantities of detyrosinated microtubules were detected during assembly into confluent cell sheets. These tubules were composed of alternating stretches of detyr- and tyr-tubulin. Constant induction of tubulin tyrosination, which decreased the levels of detyr-tubulin by overexpression of tubulin tyrosine ligase (TTL), disrupted monolayer establishment. Detyr-tubulin-depleted cells assembled into isolated islands and developed a prematurely polarized architecture. Thus, tubulin detyrosination is required for the morphological differentiation from non-polarized cells into an epithelial monolayer. Moreover, membrane trafficking, in particular to the apical domain, was slowed down in TTL-overexpressing cells. This effect could be reversed by TTL knockdown, which suggests that detyr-tubulin-enriched microtubules serve as cytoskeletal tracks to guide membrane cargo in polarized MDCK cells.

The Piconewton Force Awakens: Quantifying Mechanics in Cells.

The development of calibrated Förster resonance energy transfer (FRET)-based tension sensors has allowed the first analyses of mechanical processes with piconewton (pN) sensitivity in cells. Here, we introduce the working principle of this emerging microscopy method and discuss how it has been utilized to obtain quantitative insights into the mechanisms of intracellular force transduction in cell-matrix adhesions, cell-cell junctions, and at the cell cortex. These examples demonstrate that genetically encoded tension sensors are powerful tools to unravel force transduction mechanisms, but also indicate current limitations. We propose that further technical improvements are needed to develop a truly molecular understanding of mechanobiological processes in cells and tissues.

Generation and analysis of biosensors to measure mechanical forces within cells.

The inability to measure mechanical forces within cells has been limiting our understanding of how mechanical information is processed on the molecular level. In this chapter, we describe a method that allows the analysis of force propagation across distinct proteins within living cells using Förster resonance energy transfer (FRET)-based biosensors.