Abstract
The regulated process of protein import into the nucleus of a eukaryotic cell is mediated by specific nuclear localization signals (NLSs) that are recognized by protein-import receptors. In this study, we present fluorescence-based methods to quantitatively address the physicochemical details of NLS recognition by the receptor protein importin alpha (Impalpha) in living cells. First, by combining fluorescence recovery after photobleaching measurements and protein-concentration calibration, we quantitatively define nuclear import saturability and afford an affinity value for NLS-Impalpha binding. Second, by fluorescence lifetime imaging microscopy, we directly monitor the occurrence of NLS-Impalpha interaction and measure its effective dissociation constant (K(D)) in the actual cellular environment. Our kinetic and thermodynamic analyses independently indicate that the subsaturation of Impalpha with the expressed NLS cargo regulates nuclear import rates in living cells, in contrast to what can be predicted on the basis of available in vitro data. Finally, our experiments also provide evidence for the regulation of nuclear import mediated by the intrasteric importin beta-binding domain of Impalpha and yield the first estimate of its autoinhibition energy in living cells.
Highlights
A much studied mechanism for active translocation across the nuclear envelope is based on the presence of a “classical” nuclear localization sequence (NLS)
We present fluorescence-based methods to quantitatively address the physicochemical details of NLS recognition by the receptor protein importin ␣ (Imp␣) in living cells
Data show Imp␣ accumulation on the nuclear envelope that can be linked to its binding to nuclear pore complexes (NPCs) components, such as nucleoporins and importin  [23]
Summary
Cell Culture, and Transfections—Cloning of the EGFP, EBFP-EGFP (GFP2), NLS-EGFP, and NLS-EBFP-EGFP (NLS-GFP2) constructs used in this study was described in detail in a previous report [20]. Fluorescence counts were converted into absolute concentration values taking into account the difference in brightness (molar absorption times fluorescence quantum yield) between EGFP (or mCherry) and F-Gly. Fluorescence Recovery after Photobleaching: Experimental Details and Data Analysis—Each FRAP experiment started with a four-time line-averaged image (pre-bleach) of the cell followed by a single-point bleach (nonscanning) near the center of the nucleus with laser pulse at full power to photobleach most of the nuclear fluorescence. Timecorrelated single photon counting-detection was used to generate a lifetime map by fitting the fluorescence decay curve in each pixel of the image. Fluorescence decay curves of biological samples containing only unbound (EGFP-Imp␣) or only bound Imp␣ (NLS-mCherry]1⁄7EGFP-Imp␣) were fitted within a monoexponential decay model; the result of the fitting procedure is a single fluorescence lifetime, characteristic of the Imp␣ form (F and B, respectively). Where F and B were set to their previously determined values, and the amplitude coefficients XB and XF are the fitting parameters
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