Abstract
When a protein unfolds in the cell, its diffusion coefficient is affected by its increased hydrodynamic radius and by interactions of exposed hydrophobic residues with the cytoplasmic matrix, including chaperones. We characterize protein diffusion by photobleaching whole cells at a single point, and imaging the concentration change of fluorescent-labeled protein throughout the cell as a function of time. As a folded reference protein we use green fluorescent protein. The resulting region-dependent anomalous diffusion is well characterized by 2-D or 3-D diffusion equations coupled to a clustering algorithm that accounts for position-dependent diffusion. Then we study diffusion of a destabilized mutant of the enzyme phosphoglycerate kinase (PGK) and of its stable control inside the cell. Unlike the green fluorescent protein control's diffusion coefficient, PGK's diffusion coefficient is a non-monotonic function of temperature, signaling ‘sticking’ of the protein in the cytosol as it begins to unfold. The temperature-dependent increase and subsequent decrease of the PGK diffusion coefficient in the cytosol is greater than a simple size-scaling model suggests. Chaperone binding of the unfolding protein inside the cell is one plausible candidate for even slower diffusion of PGK, and we test the plausibility of this hypothesis experimentally, although we do not rule out other candidates.
Highlights
Macromolecular crowding in the cell modulates protein structure and stability, as well as protein diffusion and transport [1,2]
We study variants of the enzyme phosphoglycerate kinase (PGK) because their thermal stability and kinetics have been thoroughly studied in vitro, in crowders, and in live cells by the FREI technique [18,19]
from cell-to-cell (FLIP) and point-to-point (FRAP) has been applied widely to measure diffusion coefficients of fluorescentlylabeled biomolecules in cells. It measures only one point of interest at a time. Such a localized result serves as a useful comparison with global Fluorescence loss in photobleaching (FLIP) measurements, where the entire cell is imaged during fluorescence depletion
Summary
Macromolecular crowding in the cell modulates protein structure and stability, as well as protein diffusion and transport [1,2]. The crowded environment of the cell limits protein diffusion and gives rise to anomalous diffusion on long time scales [3,4], as well as position-dependent diffusion [5,6]. (FRAP) [5,7,8] and by fluorescence correlation spectroscopy (FCS) [4,9,10]. Both methods focus on local diffusion, providing little information about the global cellular environment. Fluorescence loss in photobleaching (FLIP), while it gives up precise details about short distance behavior, has the potential to provide a larger scale view of diffusion [11]
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