Orthogonal cell polarity imaging by multiparametric fluorescence microscopy

The cellular microenvironment is a complex medium due to high concentrations of proteins and an intertwined framework of cellular organelles. In particular, cellular micro-polarity controls several biological processes, since it modulates hydrophobic/hydrophilic interactions and, hence, recognition, signalling and binding events. In this work, we have developed an unprecedented methodology to construct accurate environment polarity images using multiparametric fluorescence microscopy, via a multi-linear calibration of orthogonal parameters: the fluorescence lifetime and the spectral shift of a series of solvatochromic dyes. For this approach, we have synthesized and fully characterized N-substituted 2-methoxy-9-acridone dyes as suitable bioimaging polarity probes. However, to fully comprehend the complex links between microenvironment polarity and the dyes' properties, we have endeavoured a multidisciplinary approach, in which we have studied the photophysics of our fluorophores using spectroscopic tools and state-of-the-art computational chemistry. This profound knowledge permitted to use these dyes as intracellular polarity probes, quantitatively and robustly probing the microenvironment of different cellular compartments. Our new methodology may pave the way to further developments in accurate sensing of cellular microenvironment parameters.