Cardiomyocyte Remodeling and Sarcomere Addition after Uniaxial Static Strain In Vitro
Department of Physiology and Biophysics, University of Illinois at Chicago, Chicago, Illinois
Correspondence to: Brenda Russell, PhD, Department of Physiology and Biophysics (M/C 901), University of Illinois at Chicago, 835 S. Wolcott Avenue, Chicago, IL 60612-7342. E-mail: Russell{at}uic.edu
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Summary |
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Key Words: heart failure cell shape regulation length remodeling muscle adaptation eccentric hypertrophy myofibrillogenesis
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Introduction |
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As we strive to understand the functional mechanisms of mechanical transduction at the cellular level, our group has developed a three-dimensional (3D) culturing system of aligned, well-attached cardiomyocytes (Deutsch et al. 2000; Boateng et al. 2003
; Motlagh et al. 2003a
,b
). Culturing neonatal rat cardiomyocytes on a 3D surface provides an environment for uniform application of mechanical strain to all cells (Mansour et al. 2004
). Using this improved culture system of aligned cardiomyocytes, we have demonstrated a restoration of resting sarcomere from the strained length to the natural length after 4 hr of 10% uniaxial static strain. We suggested that the restoration of the sarcomere length was obtained by the addition of new sarcomeres into the preexisting myofibrils. However, our earlier study did not show where and how the new sarcomeres were added.
In the present study, we used the 3D culturing system for rat neonatal cardiomyocytes and applied a 10% static strain to the cells. The mechanical strain was maintained for 14 hr, and the cell morphology was examined with immunofluorescent microscopy during this time period. The use of series sampling over a 4-hr time interval allowed us to quantify the changes in cardiomyocyte structure and remodeling.
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Materials and Methods |
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Cell Culture
Animal experiments were performed according to Institutional Animal Care and Use Committee and NIH guidelines. Cardiomyocytes were isolated from neonatal Sprague-Dawley rats (Harlan; Indianapolis, IN) as previously described (Boateng et al. 2003). Briefly, hearts were removed from 1- to 2-day-old rats. Myocytes were isolated from ventricles and plated on fibronectin-coated silicone membranes (200,000 cells/cm2) and maintained in complete medium (DMEM and F-12 HAM without L-glutamine; Sigma), standard amino acid concentrations plus palmitic (2.56 mg/L) and linoleic (0.84 mg/L) fatty acids, penicillin G/streptomycin solution (10 µl/ml), and gentamicin (50 mg/L) with 5% fetal bovine serum for 48 hr before strain experiments.
Mechanical Strain
A strain was applied as previously described (Mansour et al. 2004). Briefly, by manually turning two adjustable screws at the free end of the strain device, a strain of
10% was applied to longitudinally aligned cardiomyocytes in all experiments. At various time points (14 hr) after the imposition of static strain, cells were washed in phosphate-buffered saline (PBS), fixed for 10 min in 4% paraformaldehyde (Fisher), and washed (70% ethanol). After gluing the silicone substrate to a glass slide (4 hr, 25C) with silicone glue (NuSil Med 1-4013; NuSil Silicone Technology, Carpinteria, CA), the textured membrane was cut free from the strain device for immunomicroscopy.
Immunohistochemistry
Monoclonal antibodies against -actinin (EA53; Abcam, Cambridge, MA) and N-cadherin (#32; BD Biosciences, San Jose, CA) were diluted to 1:200 and 1:500, respectively, in 0.01 M PBS containing 0.1% bovine serum albumin. Membranes were incubated with primary antibody for 60 min at 37C. Visualization of the primary antibody was performed with Alexa-conjugated goat anti-mouse secondary antibody (Molecular Probes; Eugene, OR). Control membranes were treated as above, except that the primary antibody was exchanged with non-immune serum. Filamentous actin was stained with rhodamine phalloidin (Molecular Probes) diluted in PBS (1:20). The membrane was incubated with rhodamine phalloidin for 30 min at room temperature and then rinsed three times (10 min) in PBS. Before applying a coverslip, Vectashield mounting medium (Vector Laboratories; Burlingame, CA) was applied to the surface of the silicone membrane to help preserve the stain. The mounting medium contained DAPI to stain nuclei. Myocytes were observed with a Nikon microscope (Microphot-FXA; Tokyo, Japan) equipped with a Spot RT camera (Diagnostic Instruments; Sterling Heights, MI). Digital images were processed using the Adobe Photoshop 7.0 software (Adobe Systems; Mountain View, CA).
Data Collection and Image Analysis
All membranes were observed using a x60 objective lens. Ten digital images were taken in a systematic random sample from each membrane. Briefly, the image capturing started from the upper right corner of a membrane, then taking every other visual field in horizontal line scans across the membrane reversing direction when the last field containing cells growing in the grooved surface was reached. Prints were made and coded. All myocytes were carefully examined for any irregular staining by two different investigators who scored the morphological changes by anatomical features and the staining intensity of actin detected by rhodamine phalloidin to reveal the periodic sarcomeric pattern. Structural irregularities were classified into two types and counts recorded: 1. focal areas where the usual sarcomeric pattern was lacking or very weakly stained; 2. focal areas where the usual sarcomeric pattern was intensely stained. After decoding, the morphometric allocation was calculated for the irregular features of control and during the 4 hr after the static strain was applied, which permitted the time course to be determined.
The morphology at the ends of the myocytes after mechanical strain was revealed with antibodies against -actinin and N-cadherin. Strain induced pronounced changes for myocytes that terminated in a groove, as well as those abutting another cell at the intercalated disc. The free ends of myocytes were often relatively rounded with many parallel myofibrils having aligned sarcomeres. In other cases, myocytes ended in a relatively sharp point only one myofibril wide. The number of myocytes with rounded vs pointed ends from myocytes stained for
-actinin was counted from coded images as above.
Intercalated discs at myocyte-to-myocyte connections were evaluated by N-cadherin staining. These were either fairly straight or they exhibited many zigzags, sharp turns, and a high degree of convolution. The number of myocytes with relatively straight or zigzag features was counted using the double-blind coding as above.
Data Analysis
The number of samples at control, 1, 2, 3, and 4 hr was four. Morphometric counts were averaged for the two observers before computation of statistics. All values are mean ± SEM. Data were compared using one-way and two-way ANOVA or the Student's unpaired t-test. Differences among means were considered significant at p<0.05. Data were analyzed using GraphPad statistical software (GraphPad Software; San Diego, CA).
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Results |
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Quantification of the weakly or intensely stained disruptions in the sarcomeres showed the time course for their prevalence over the 4 hr after the static stretch was applied (Figure 2). The lightly stained sarcomeres with apparent gaps in the myofibrils were common at 1 hr after being strained, peaked at 2 hr, and then subsided. In contrast, the numbers of intensely stained sarcomeres were initially low, peaked at 3 hr, and then began to decline when compared with control values. In contrast, the focal areas of intensely stained myocytes was initially low, peaked at 3 hr, and then began to decline when compared with control values
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Further details of the myocyte terminations and myocyte-to-myocyte junctions were detected with an antibody against N-cadherin. In the unstretched myocytes, the contact between cells was a relatively straight, thin line (Figure 1I). After the mechanical strain, myocytes were coupled by thicker adherent junctions that had many zigzags, sharp turns, and a high degree of convolution (Figure 1J). These anatomic observations were statistically significant at 3 hr and 4 hr of mechanical strain when compared with unstretched myocytes (Figure 3).
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Discussion |
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A morphometric analysis of the changes in the sarcomeric patterns permits interpretation of a time course for the remodeling events. Initially, 13 hr after the application of a sudden strain, the most common changes were the weakly stained gaps along myocytes, whereas in the later period (3 hr and 4 hr) more myocytes showed regions that stained intensely for F-actin. We hypothesize that the mechanical strain disrupts the periodic structure in the myofibril, first leaving the weakly stained gaps. We note that, in some of the gaps, some thin, wispy longitudinal strands survive and appear to connect the adjacent sarcomeres. We suggest that these thin longitudinal F-actin strands might form a platform for the initiation for repair of the disruption. As the repair progresses, more F-actin filaments might be accumulated, forming the intensely stained regions observed 34 hr after straining. Interestingly, within the intensely stained areas, there were some regions where some extra sarcomeres were observed, suggesting that the repair is not simply a reassembly of the original periodic structure but a remodeling process with the addition of new sarcomeres into the preexisting myofibrils.
Cyclic stresses and strains occur in normal physiology, and when these stresses and strains are maintained at new levels, the myocyte responds by growth or atrophy. Cells elongate in response to increased diastolic strain by adding sarcomeres in series, and they thicken in response to continued stress by adding filaments in parallel (Russell et al. 2000). They do this while still keeping the resting sarcomere length close to its optimal value at the peak of the lengthtension curve. One could argue that cells in dilated cardiomyopathy have adapted well to a never-ending volume overload by an obligatory lengthening coupled to mechano-sensing of strain. In contrast, myocytes in concentric myopathy that is short and thick has adapted to overstress (Gerdes et al. 1992
). Thus, these shapes eventually become maladapted because long, thin myocytes provide little total force for ejection of the blood whereas short, thick ones intrude on chamber volume itself. We suggest that sarcomerogenesis in the neonatal myocyte induced by mechanical strain in culture might form the basis for increased lengthening of individual cardiomyocytes in dilated cardiomyopathy.
It is possible that costameres and Z-discs in myofiber play a key role for addition of new filaments to existing myofibrils in hypertrophying myocytes. Recent studies in human skeletal muscle confirm that new sarcomeres are added along the entire length of the fiber (Yu and Thornell 2002, Yu et al. 2003
,2004
). Essentially, a Y-shaped scaffold of desmin is inserted at the costamere permitting new shorter sarcomeres to be spliced into the Z-disk. Quick stretches deform the middle of a muscle to a greater extent because it is less stiff and less well protected than at the ends. Thus, skeletal muscle is weakest in the middle, so new sarcomeres are most likely added centrally as a response to increased stretch (Yu and Thornell 2002
, Yu et al. 2003
,2004
). Cardiac connective tissue is equally strong throughout the length of the cell. Passive resistance is much higher than in skeletal muscle due to titin internally and collagen externally. Despite the differences between skeletal muscle and cardiac tissue, the present study demonstrated that new sarcomeres could also be added at the costameres and central regions (Z-disc) of myofiber in culture but differential resistance in vivo might result in altered morphological insertion sites.
In the present study, the myocytes in the mechanically strained cultures usually had very elongated ends and were only one myofibril wide. Close inspection also revealed that the sarcomeric transverse striations in the myocyte ends were not complete but had regular punctate spots of -actinin, which might correspond to developing Z-discs.
The intercalated discs in unstretched myocytes follow a straight course between cells, whereas after the mechanical strain more zigzags or convoluted patterns were observed especially at the 3 hr and 4 hr sampling times. We suggest that the zigzag pattern of the intercalated discs might correlate with new sarcomere appearance and yield progressive lengthening at the ends of the cell. The intercalated disc has been suggested to be one of the key structures in heart failure because of its integral function in mechanical force transmission as well as intercellular communication in the heart (Perriard et al. 2003).
In conclusion, our study investigated the remodeling of rat neonatal myocytes after static strain of aligned cells in vitro. Our major finding is the addition of new sarcomeres throughout the entire length of the myofibril and major changes in the irregularity of the intercalated disc at the end of the myocytes.
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Acknowledgments |
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Footnotes |
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Literature Cited |
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