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Impaired Intracellular Ca2+ Dynamics in Live Cardiomyocytes Revealed by Rapid Line Scan Confocal Microscopy

Published online by Cambridge University Press:  12 May 2005

David M. Plank
Affiliation:
SDSU Heart Institute, Department of Biology, San Diego State University, San Diego, CA 92182, USA
Mark A. Sussman
Affiliation:
SDSU Heart Institute, Department of Biology, San Diego State University, San Diego, CA 92182, USA
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Abstract

Altered intracellular Ca2+ dynamics are characteristically observed in cardiomyocytes from failing hearts. Studies of Ca2+ handling in myocytes predominantly use Fluo-3 AM, a visible light excitable Ca2+ chelating fluorescent dye in conjunction with rapid line-scanning confocal microscopy. However, Fluo-3 AM does not allow for traditional ratiometric determination of intracellular Ca2+ concentration and has required the use of mathematic correction factors with values obtained from separate procedures to convert Fluo-3 AM fluorescence to appropriate Ca2+ concentrations. This study describes methodology to directly measure intracellular Ca2+ levels using inactivated, Fluo-3-AM-loaded cardiomyocytes equilibrated with Ca2+ concentration standards. Titration of Ca2+ concentration exhibits a linear relationship to increasing Fluo-3 AM fluorescence intensity. Images obtained from individual myocyte confocal scans were recorded, average pixel intensity values were calculated, and a plot is generated relating the average pixel intensity to known Ca2+ concentrations. These standard plots can be used to convert transient Ca2+ fluorescence obtained with experimental cells to Ca2+ concentrations by linear regression analysis. Standards are determined on the same microscope used for acquisition of unknown Ca2+ concentrations, simplifying data interpretation and assuring accuracy of conversion values. This procedure eliminates additional equipment, ratiometric imaging, and mathematic correction factors and should be useful to investigators requiring a straightforward method for measuring Ca2+ concentrations in live cells using Ca2+-chelating dyes exhibiting variable fluorescence intensity.

Type
Research Article
Copyright
© 2005 Microscopy Society of America

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References

REFERENCES

Allen, D.G. & Blinks, J.R. (1978). Ca2+ transients in aequorin-injected frog cardiac muscle. Nature 273, 509513.Google Scholar
Bers, D.M., Patton, C.W., & Nuccitelli, R. (1994). A practical guide to the preparation of Ca2+ buffers. In Methods in Cell Biology, Nuccitelli R., (Ed.), pp. 428. San Diego, CA: Academic Press Inc.
Beuckelmann, D.J., Nabauer, M., & Erdmann, E. (1992). Intracellular Ca2+ handling in isolated ventricluar myocytes from patients with terminal heart failure. Circulation 85, 10461055.Google Scholar
Chandrashekhar, Y., Prahash, A.J., Sen, S., Gupta, S., & Anand, I.S. (1999). Cardiomyocytes from hearts with left ventricular dysfunction after ischmia-reperfusion do not manifest contractile abnormalities. J Am Coll Cardiol 34, 594602.Google Scholar
Grynkiewicz, G., Poenie, M., & Tsien, R.Y. (1985). A new generation of Ca2+ indicators with greatly improved fluorescence properties. J Biol Chem 260, 34403450.Google Scholar
Gwathmey, J.K., Copelas, L., MacKinnon, R., Schoen, F.J., Feldman, M.D., Grossman, W., & Morgan, J.P. (1987). Abnormal intracellular Ca2+ handling in myocardium from patients with end-stage heart failure. Circ Res 61, 7076.Google Scholar
Haddock, P.S., Coetzee, W.A., Cho, E., Porter, L., Katoh, H., Bers, D.M., Jafri, M.S., & Artman, M. (1999). Subcellular [Ca2+]i gradients during excitation-contraction coupling in newborn rabbit ventricular myocytes. Circ Res 815, 415427.Google Scholar
Harrison, S.M. & Bers, D.M. (1989). Correction of proton and Ca2+ association constants of EGTA for temperature and ionic strength. Am J Physiol 256, C12501256.Google Scholar
Holt, E., Tonnessen, T., Lunde, P.K., Semb, S.O., Wasserstrom, J.A., Sejersted, O.M., & Christensen, G. (1998). Mechanisms of cardiomyocytes dysfunction in heart failure following myocardial infarction in rats. J Mol Cell Cardiol 30, 15811593.Google Scholar
Ito, K., Yan, X., Feng, X., Manning, W.J., Dillman, W.H., & Lorell, B.H. (2001). Transgenic expression of sarcoplasmic reticulum Ca2+ ATPase modifies the transition from hypertrophy to early heart failure. Circ Res 89, 422429.Google Scholar
Kao, J.P., Harootunian, A.T., & Tsein, R.Y. (1989). Photochemically generated cytosolic Ca2+ pulses and their detection by fluo-3. J Biol Chem 264, 81798184.Google Scholar
Kubo, H., Margulies, K.B., Piacentino, V., Gaughan, J., & Houser, S.R. (2001). Patients with end-stage congestive heart failure treated with β-adrenergic receptor antagonists have improved ventricular myocyte calcium regulatory protein abundance. Circulation 104, 10121018.Google Scholar
Lindner, M., Brandt, M.C., Sauer, H., Heshceler, J., Bohle, T., & Beuckelmann, D.J. (2002). Calcium sparks in human ventricular cardiomyocytes from patients with terminal heart failure. Cell Calcium 31, 175182.Google Scholar
Lipp, P., Luscher, C., & Niggle, E. (1996). Photolysis of caged compounds characterized by ratiometric confocal microscopy: A new approach to homogeneously control and measure the Ca2+ concentration in cardiac myocytes. Cell Calcium 19, 255266.Google Scholar
Lipp, P. & Niggli, E. (1993). Ratiometric confocal Ca2+ measurements with visible wavelength indicators in isolated cardiac myocytes. Cell Calcium 14, 359372.Google Scholar
Minta, A., Kao, J.P.Y., & Tsien, R.Y. (1989). Fluorescent indicator for cytosolic Ca2+ based on rhodamine and fluorescein chromophores. J Biol Chem 264, 81718178.Google Scholar
Neary, P., Duncan, A.M., Cobbe, S.M., & Smith, G.L. (2002). Assessment of sarcoplasmic reticulum Ca2+ flux pathways in cardiomyocytes from rabbits with infarct-induced left ventricular dysfunction. Pflugers Arch 444, 360371.Google Scholar
Niggli, E. & Lederer, W.J. (1990). Real-time confocal microscopy and calcium measurements in heart muscle cells: Towards the development of a fluorescence microscope with high temporal and spatial resolution. Cell Calcium 11, 121130.Google Scholar
Plank, D.M., Yatani, A., Ritsu, A., Witt, S., Glascock, B., Lalli, M.J., Periasamy, M., Fiset, C., & Sussman, M.A. (2003). Calcium dynamics in the failing heart: Restoration by β-adrenergic blockade. Am J Physiol Heart Circ Physiol 285, H305H315.Google Scholar
Sussman, M.A., Welch, S., Cambon, N., Klevitsky, R., Hewett, T.E., Price, R., Witt, S.A., & Kimball, T.R. (1998). Myofibril degeneration caused by tropomodulin overexpression leads to dilated cardiomyopathy in juvenile mice. J Clin Invest 101, 5161.Google Scholar
Vahl, C.F., Bonz, A., Timek, T., & Hagl, S. (1994). Intracellular Ca2+ transient of working human myocardium of seven patients transplanted for congestive heart failure. Circ Res 74, 952958.Google Scholar
Williams, D.A. (1990). Quantitative intracellular Ca2+ imaging with laser-scanning confocal microscopy. Cell Calcium 11, 589597.Google Scholar
Williams, D.A. & Fay, F.S. (1990). Intracellular calibration of the fluorescent Ca2+ indicator Fura-2. Cell Calcium 11, 7583.Google Scholar
Wolska, B.M. & Solaro, J.R. (1996). Method for isolation of adult cardiac myocytes for studies of contraction and microfluorimetry. Am J Physiol 271, H1250H1255.Google Scholar
Yao, A., Dillman, W.H., & Barry, W.H. (1998a). Sarcoplasmic reticulum function in murine ventricular mycoyts overexpressing SR CaATPase. J Moll Cell Cardiol 30, 27112718.Google Scholar
Yao, A., Su, Y., Nonaka, A., Zubair, I., Lu, L., Philipson, K.D., Bridge, J., & Barry, W.H. (1998b). Effects of overexpression of the Na+-Ca2+ exchanger on [Ca2+]i transients in murine ventricular myocytes. Circ Res 82, 657665.Google Scholar