Novel features of the rabbit transverse tubular system revealed by quantitative analysis of three-dimensional reconstructions from confocal images.

With scanning confocal microscopy we obtained three-dimensional (3D) reconstructions of the transverse tubular system (t-system) of rabbit ventricular cells. We accomplished this by labeling the t-system with dextran linked to fluorescein or, alternatively, wheat-germ agglutinin conjugated to an Alexa fluor dye. Image processing and visualization techniques allowed us to reconstruct the t-system in three dimensions. In a myocyte lying flat on a coverslip, t-tubules typically progressed from its upper and lower surfaces. 3D reconstructions of the t-tubules also suggested that some of them progressed from the sides of the cell. The analysis of single t-tubules revealed novel morphological features. The average diameter of single t-tubules from six cells was estimated to 448 +/- 172 nm (mean +/- SD, number of t-tubules 348, number of cross sections 5323). From reconstructions we were able to identify constrictions occurring every 1.87 +/- 1.09 microm along the principal axis of the tubule. The cross-sectional area of these constrictions was reduced to an average of 57.7 +/- 27.5% (number of constrictions 170) of the adjacent local maximal areas. Principal component analysis revealed flattening of t-tubular cross sections, confirming findings that we obtained from electron micrographs. Dextran- and wheat-germ agglutinin-associated signals were correlated in the t-system and are therefore equally good markers. The 3D structure of the t-system in rabbit ventricular myocytes seems to be less complex than that found in rat. Moreover, we found that t-tubules in rabbit have approximately twice the diameter of those in rat. We speculate that the constrictions (or regions between them) are sites of dyadic clefts and therefore can provide geometric markers for colocalizing dyadic proteins. In consideration of the resolution of the imaging system, we suggest that our methods permit us to obtain spatially resolved 3D reconstructions of the t-system in rabbit cells. We also propose that our methods allow us to characterize pathological defects of the t-system, e.g., its remodeling as a result of heart failure.

[1]  N. Severs,et al.  Distinct patterns of dystrophin organization in myocyte sarcolemma and transverse tubules of normal and diseased human myocardium. , 2000, Circulation.

[2]  Frank B. Sachse,et al.  A Framework for Analyzing Confocal Images of Transversal Tubules in Cardiomyocytes , 2007, FIMH.

[3]  W. Lederer,et al.  Propagation of excitation-contraction coupling into ventricular myocytes , 1994, Pflügers Archiv.

[4]  N. Severs,et al.  The cardiac muscle cell. , 2000, BioEssays : news and reviews in molecular, cellular and developmental biology.

[5]  Tom Davis,et al.  Opengl programming guide: the official guide to learning opengl , 1993 .

[6]  R. Kieval,et al.  Immunofluorescence localization of the Na-Ca exchanger in heart cells. , 1992, The American journal of physiology.

[7]  V. Bhavanandan,et al.  The interaction of wheat germ agglutinin with sialoglycoproteins. The role of sialic acid. , 1979, The Journal of biological chemistry.

[8]  D. Fawcett,et al.  THE ULTRASTRUCTURE OF THE CAT MYOCARDIUM , 1969, The Journal of cell biology.

[9]  G J Brakenhoff,et al.  Dynamics of three-dimensional replication patterns during the S-phase, analysed by double labelling of DNA and confocal microscopy. , 1992, Journal of cell science.

[10]  C. Orchard,et al.  Resurgence of cardiac t-tubule research. , 2007, Physiology.

[11]  Eric A Sobie,et al.  Orphaned ryanodine receptors in the failing heart. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[12]  Petter Laake,et al.  T‐tubule disorganization and reduced synchrony of Ca2+ release in murine cardiomyocytes following myocardial infarction , 2006, The Journal of physiology.

[13]  F. Protasi,et al.  Shape, size, and distribution of Ca(2+) release units and couplons in skeletal and cardiac muscles. , 1999, Biophysical journal.

[14]  A. Garfinkel,et al.  1 – Immunologicalization and Structural Configuration of Membrane and Cytoskeletal Proteins Involved in Excitation-Contraction Coupling of Cardiac Muscle , 1997 .

[15]  A. Yao,et al.  The restriction of diffusion of cations at the external surface of cardiac myocytes varies between species. , 1997, Cell calcium.

[16]  D. Shotton,et al.  Rapid freezing, freeze fracture, and deep etching , 1995 .

[17]  E. Benson,et al.  ON THE STRUCTURAL CONTINUITIES OF THE TRANSVERSE TUBULAR SYSTEM OF RABBIT AND HUMAN MYOCARDIAL CELLS , 1963, The Journal of cell biology.

[18]  R. Molday,et al.  Distribution of the Na(+)-Ca2+ exchange protein in mammalian cardiac myocytes: an immunofluorescence and immunocolloidal gold-labeling study , 1992, The Journal of cell biology.

[19]  J. Foell,et al.  Reduction in density of transverse tubules and L-type Ca(2+) channels in canine tachycardia-induced heart failure. , 2001, Cardiovascular research.

[20]  Josie Wernecke,et al.  The inventor mentor - programming object-oriented 3D graphics with Open Inventor, release 2 , 1993 .

[21]  J. Heuser Preparing biological samples for stereomicroscopy by the quick-freeze, deep-etch, rotary-replication technique. , 1981, Methods in cell biology.

[22]  J. Hell,et al.  Localization of cardiac L-type Ca(2+) channels to a caveolar macromolecular signaling complex is required for beta(2)-adrenergic regulation. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[23]  E. Page,et al.  Quantitative electron microscopic description of heart muscle cells. Application to normal, hypertrophied and thyroxin-stimulated hearts. , 1973, The American journal of cardiology.

[24]  F. Cordelières,et al.  A guided tour into subcellular colocalization analysis in light microscopy , 2006, Journal of microscopy.

[25]  E. Lindner [Submicroscopic morphology of the cardiac muscle]. , 1957, Zeitschrift fur Zellforschung und mikroskopische Anatomie.

[26]  W. Lederer,et al.  Calcium sparks: elementary events underlying excitation-contraction coupling in heart muscle. , 1993, Science.

[27]  M. Dennis,et al.  Synaptic vesicle exocytosis captured by quick freezing and correlated with quantal transmitter release , 1979, The Journal of cell biology.

[28]  W. Giles,et al.  Location of the initiation site of calcium transients and sparks in rabbit heart Purkinje cells , 2001, The Journal of physiology.

[29]  Michael D. Stern,et al.  Local Control Model of Excitation–Contraction Coupling in Skeletal Muscle , 1997, The Journal of general physiology.

[30]  C. Soeller,et al.  Examination of the transverse tubular system in living cardiac rat myocytes by 2-photon microscopy and digital image-processing techniques. , 1999, Circulation research.