Detecting calcium in cardiac muscle: fluorescence to dye for.

Abstract

THE IMPORTANCE OF Ca 2 as a second messenger in general and as a mediator between electrical excitation and cellular contraction in the heart is well accepted. Accordingly, numerous Ca 2 -sensitive fluorescent dyes are available nowadays, rendering the choice of the appropriate dye for a particular application a challenge. It appears to be important to provide calibrated Ca 2 signals rather than fluorescence transients, especially when comparing data between studies. In case calibrated signals cannot be provided, then the time course of fluorescence transients should be interpreted with caution and such signals should be referred to as fluorescence transients rather than Ca 2 transients. Additionally, we discuss how major properties of the fluorescence dyes should be considered with a special emphasis on their Ca 2 dissociation properties. Furthermore, we highlight putative risks of tripping, especially in the context of multicellular recordings, and how to circumvent them. As an ubiquitous intracellular messenger, Ca 2 ions play an important role in almost all living cells (4). A particularly dynamic role has been assigned to Ca 2 in muscle cells because here they not only control gene expression and other slower signaling processes but serve as a direct transducer of the electrical excitation of the plasma membrane into the activation of the physiological response of the cell, the contraction, by activation of the contractile machinery (5). Almost 50 years ago, Jobsis and O’Connor (10) reported the measurements of intracellular Ca 2 transients in skeletal muscle using the Ca 2 -sensitive dye murexide, which changes its absorbance upon binding of Ca 2 ions. Later, these absorbance dyes were improved and an important member of this family, arsenazo III, was widely used to study intracellular Ca 2 in