Abstract
Raster image correlation spectroscopy (RICS) is a new and novel technique for measuring molecular dynamics and concentrations from fluorescence confocal images. The RICS technique extracts information about molecular dynamics and concentrations from images of living cells taken on commercial confocal systems. Here we develop guidelines for performing the RICS analysis on an analogue commercial laser scanning confocal microscope. Guidelines for typical instrument settings, image acquisition settings and analogue detector characterization are presented. Using appropriate instrument/acquisition parameters, diffusion coefficients and concentrations can be determined, even for highly dynamic dye molecules in solution. Standard curves presented herein demonstrate the ability to detect protein concentrations as low as approximately 2 nM. Additionally, cellular measurements give accurate values for the diffusion of paxillin-enhanced-green fluorescent protein (EGFP), an adhesion adaptor molecule, in the cytosol of the cell and also show slower paxillin dynamics near adhesions where paxillin interacts with immobile adhesion components. Methods are presented to account for bright immobile structures within the cell that dominate spatial correlation functions; allowing the extraction of fast protein dynamics within and near these structures. A running average algorithm is also presented to address slow cellular movement or movement of cellular features such as adhesions. Finally, methods to determine protein concentration in the presence of immobile structures within the cell are presented. A table is presented giving guidelines for instrument and imaging setting when performing RICS on the Olympus FV300 confocal and these guidelines are a starting point for performing the analysis on other commercial confocal systems.
Highlights
Recent advances in the speed and sensitivity of fluorescence confocal laser scanning microscopes (CLSMs) allow the acquisition and analysis of fluorescence images from live cells
If the Raster image correlation spectroscopy (RICS) analysis is performed in combination with temporal image correlation spectroscopy (t-ICS) (Wiseman et al, 2000) performed between images within an image time series on the seconds time scale the two methods provide dynamic information from microseconds to minutes or hours
This paper presents general guidelines for performing RICS measurements and illustrates their use on an Olympus Fluoview 300 (FV300) laser scanning confocal microscope
Summary
Recent advances in the speed and sensitivity of fluorescence confocal laser scanning microscopes (CLSMs) allow the acquisition and analysis of fluorescence images from live cells. Properties such as protein dynamics and aggregation states can be extracted following a careful analysis of these images. To capture and distinguish the subtle differences in the intensity fluctuations due to these cellular phenomena, the ideal correlation technique would have a spatial resolution limited only by light diffraction and would be sensitive to the very wide range of dynamics observed in living cells (Table 1). If the RICS analysis is performed in combination with temporal image correlation spectroscopy (t-ICS) (Wiseman et al, 2000) performed between images within an image time series on the seconds time scale (or longer) the two methods provide dynamic information from microseconds to minutes or hours
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