Journal of Histochemistry and Cytochemistry, Vol. 46, 963-970, August 1998, Copyright © 1998, The Histochemical Society, Inc.


ARTICLE

Translocation of 60S Ribosomal Subunit in Spreading Cardiac Myocytes

Terje H. Larsena and Thorvald Sætersdalb
a Experimental Cardiology Unit, Departments of Radiology, University of Bergen, Bergen, Norway
b Anatomy and Cell Biology, University of Bergen, Bergen, Norway

Correspondence to: Terje H. Larsen, Experimental Cardiology Unit, Dept. of Radiology, U. of Bergen, Årstadveien 19, N-5009 Bergen, Norway.


  Summary
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Cardiac myocytes in culture undergo considerable structural reorganization. The remodeling of the myofibrils and the nonmyofibrillar cytoskeleton that occurs in the spreading cardiac myocytes resembles the cellular features observed in the hypertrophying heart. In this study we examined the distribution of the large 60S ribosomal subunit in freshly isolated cardiac myocytes and during the course of attachment and spreading in culture. Initially, anti-60S immunolabeling was scattered widely throughout the sarcoplasm of the dissociated cardiac myocytes. After attachment to the substrate, the 60S ribosomal subunit attained wide sarcoplasmic localization before a sarcomere-related staining pattern appeared in the spreading cell. Double labeling experiments with {alpha}-actinin confirmed co-localization of the 60S ribosomal subunit with nascent and mature myofibrils. These findings demonstrate that translocation of the 60S ribosomal subunit coincides with the cytoskeletal reorganization taking place in these cells. Moreover, the close association between the myofibrils indicates a particular role for the ribosomes in maintenance and growth of the contractile apparatus. (J Histochem Cytochem 46:963–969, 1998)

Key Words: cardiac myocytes, ribosomes, 60S ribosomal subunit, immunofluorescence, microscopy, immunogold electron, microscopy, silver enhancement, myofibrillogenesis, hypertrophy


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Ribosomes ARE composed of a small 40S and a large 60S ribosomal subunit that form a complex. This ribosomal complex binds mRNA and tRNA and catalyzes peptide bond formation. Frequently the ribosomes occur in clusters, referred to as polyribosomes. Polyribosomes are present in various subcellular compartments as either membrane-bound, cytoskeletal-bound, or as free cytosolic polyribosomes. Whereas the membrane-bound polyribosomes are associated with synthesis of membrane proteins and secretory proteins, the majority of the mRNAs are translated on the other polyribosome fractions. Stimulation of protein synthesis may cause redistribution among the different populations of ribosomes (Vedeler et al. 1990 ), and it is proposed that this change reflects alterations in the pattern of proteins being synthesized (Hesketh et al. 1991 ). A close spatial relation has been detected for actin mRNA and immunoreactive actin proteins in defined areas of the cytoplasm (Singer et al. 1989 ). Similar subcellular compartments containing other cytoskeletal mRNAs and proteins have been detected as well (Lawrence and Singer 1986 ).

In striated muscle cells the myofibrillar components constitute the bulk proportion of proteins. In heart, the half-life of mixed muscle proteins is approximately 10 days (Lewis et al. 1984 ). Therefore, a considerable capacity to produce proteins is required. Studies on striated muscle cells in which in situ hybridization was applied have shown that myosin mRNA are localized in the subsarcolemmal and intermyofibrillar sarcoplasm (Dix and Eisenberg 1988 ; Eisenberg et al. 1991 ). Correspondingly, ribosomes demonstrated in striated muscle cells by conventional electron microscopy (Larson et al. 1969 ) or immunocytochemical techniques (Horne and Hesketh 1990 ; Larsen et al. 1994 ) are mainly accumulated between the myofibrils and in the subsarcolemmal areas. These results, taken together, suggest that translation of the mRNAs of myofibrillar proteins in striated muscle cells, at least the thick filaments, occurs close to the myofibrillar sites at which the proteins are to be inserted.

Isolated cardiac myocytes from neonatal rats rapidly attain a spherical shape in suspension. In culture, these cells attach to the substrate and spread as they undergo considerable structural changes. Considerable reorganization of the normal cellular architecture, including myofibrillar disassembly and reassembly, is apparent within the first hours and days of incubation. It is generally believed that the premyofibril becomes a mature myofibril via a nascent stage by incorporation of certain muscle-specific proteins (Rhee et al. 1994 ). Moreover, immunolabeling of such proteins reveals a close spatial association with polyribosomes located adjacent to myofibrils (Komiyama et al. 1993 ). The sequence of events that takes place in the formation of myofibrils in cardiac myocytes in vitro is comparable to that seen in vivo (Borisov 1991 ).

In this study we examined the localization of the 60S ribosomal subunit in freshly isolated and cultured cardiac myocytes, using immunofluorescence staining techniques and immunogold electron microscopy. Redistribution of the 60S ribosomal subunit was demonstrated, along with the considerable structural reorganization of the cells during attachment and spreading.


  Materials and Methods
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Isolation and Culture of Cardiac Myocytes
Hearts from neonatal rats were washed in Ca++-free Joklik- modified minimal essential medium (MEM) (Gibco Life Technologies; Paisley, UK) with 26.7 mM NaHCO3, 1.20 mM MgSO4, and 1.00 mM DL-carnitine, pH 7.40, and gassed with 5% CO2 in air. After removal of the atria, the ventricular tissue was cut into small pieces and immersed in Ca++-free Joklik-modified MEM containing 0.1% (w/v) collagenase (Worthington Biochemicals; Freehold, NJ) and 0.08% (w/v) bovine serum albumin (BSA) (Sigma Chemical; St Louis, MO). The ventricular tissue was incubated for 60 min in a water bath shaker at 37C and continuously oxygenated. During incubation the enzyme solution was replaced with an identical fresh solution after 30 min. To increase the yield of dissociated myocytes, intact tissue was gently pipetted every 15 min. The cell suspension was filtered through a 200-µm-mesh nylon gauze, washed in Joklik-modified MEM with 1.50 mM Ca++, and the isolated cells collected by centrifugation. The isolated ventricular cells were transferred to a dish containing DMEM (Gibco), 10% fetal calf serum (Gibco), and antibiotics (penicillin 100 IU/ml medium and streptomycin 100 µg/ml medium) (Gibco). After 4 hr of preplating, a large proportion of the nonmyocytes were attached to the dish. The unattached ventricular cells were collected and seeded at a density of 1–3 x 105 cells/ml in tissue culture dishes (Falcon; Becton Dickinson, Oxford, UK) with or without coverglasses. The cultures were maintained in an atmosphere of 95% air and 5% CO2 at 37C.

Primary Antibodies
Polyclonal rabbit antibodies raised against 60S ribosomal subunits, prepared from rat liver as previously described (Horne and Hesketh 1990 ; Hesketh et al. 1991 ), were kindly provided by Dr. John E. Hesketh (the Rowett Research Institute, Aberdeen, Scotland). Monoclonal antibodies recognizing {alpha}-actinin were purchased from Amersham (Poole, UK).

Western Blotting
The protein samples were separated by SDS-PAGE electrophoresis on 10% gels. Protein fractions were then electrophoretically transferred onto a nitrocellulose sheet. Nonspecific binding sites were blocked with 5% BSA (w/v) in 0.1 M PBS containing 0.1% Tween 20 (v/v) before incubation with anti-60S antibodies (diluted 1:400 with 0.8% BSA in PBS/Tween) overnight at 4C. After washing in PBS/Tween, the sheet was incubated with peroxidase-conjugated anti-rabbit antibodies (Dakopatts; Copenhagen, Denmark). The antigen–antibody–peroxidase complex was visualized using the ECL chemiluminescence detection kit (Amersham). The specificity of the primary antibodies is shown in Figure 1.



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Figure 1. Western blot analyses of the specificity of the 60S antibodies. Protein fractions were transferred to a nitrocellulose sheet after SDS-PAGE and probed with the specific antibodies. Immunolabeling of purified 60S ribosomal subunit (Lane A) and whole-cell homogenates from cultured cardiac cells (Lane B) is demonstrated. A specific band (arrow) is identified in the cell homogenate (B), whereas in the purified protein extract (A) a degradation product is also recognized.

Immunofluorescence Microscopy
For immunofluorescence microscopy, cardiac cells grown on coverglasses were fixed with 3.7% formaldehyde in 0.1 M PBS after various periods of incubation. In addition, suspensions of freshly isolated cells were fixed and cytospun onto poly-L-lysine-coated coverglasses. Then the cells were permeabilized with 0.5% Triton X-100, treated with 0.2 M glycine, and preincubated with 5% normal swine serum (Dakopatts) and 0.8% BSA (w/v). Incubation with anti-60S antibodies [diluted 1:200 with 0.8% BSA (w/v) in 0.1 M PBS] was performed overnight at 4C. After being rinsed with BSA/PBS, the sections were incubated with TRITC-conjugated swine anti-rabbit antibodies (Dakopatts) at 20C for 1 hr. For double labeling experiments, the cells were further incubated with monoclonal anti-{alpha}-actinin antibodies (diluted 1:200) and then with FITC-conjugated anti-mouse antibodies (Boehringer Mannheim; Mannheim; Germany). Finally, the sections were rinsed in 0.1 M PBS and mounted in a fluorechrome anti-fading solution (H1000; Vector Laboratories, Burlingame, CA) before examination with a fluorescence microscope (Leitz Aristoplane; Leica, Wetzlar, Germany) or a confocal laser scanning microscope (MRC-600; Bio-Rad Microscience, Hertfordshire, UK). The specificity of the immunostaining was controlled by replacing the primary antibodies with normal rabbit serum or a BSA/PBS solution.

Pre-embedding Immunogold Electron Microscopy
Cultured cardiac cells were fixed in situ in the culture dish with 3.7% formaldehyde and 0.1% glutaraldehyde in Hanks' balanced salt solution (Sigma) for 1 hr at room temperature. The cells were permeabilized with 0.1% saponin for 10 min, and 0.01% saponin was used in the buffers during the incubation steps with antibodies. They were treated with glycine, preincubated with normal swine serum, and incubated with primary anti-60S antibodies using a similar protocol to that employed for immunofluorescence staining. The cells were then exposed to secondary antibodies conjugated to ultrasmall gold probes (Aurion; Wageningen, The Netherlands), postfixed with 2% glutaraldehyde, and exposed to a silver enhancement solution as previously described in detail (Larsen and Feller 1996 ). The cells were dehydrated in ascending concentrations of ethanol and embedded in Epon. Ultrathin sections were collected on copper grids and stained with uranyl acetate and lead citrate before being examined in the electron microscope.


  Results
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Materials and Methods
Results
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Confocal Laser Scanning Microscopy
After seeding, the cardiac cells became rapidly attached to the substrate and started to spread. Initially, the proportion of cardiac myocytes was 80–90%, whereas after 6 days in culture the proportion of noncardiac myocytes considerably increased. Prominent sarcoplasmic anti-60S immunostaining was revealed, and in some cardiac myocytes positive labeling was also observed in nucleoli (Figure 2).



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Figure 2. Confocal laser scanning microscopy of cardiac cells cultured for 1 day before fixation and immunostaining with anti-60S antibodies. In the noncardiac myocytes (NM) the staining is widely dispersed in the cytoplasm. In the cardiac myocytes, characterized by a centrally localized circular nucleus (occasionally they are binucleated), positive labeling is observed in the sarcoplasm. In some cells weak immunostaining of the nucleoli (arrow) occurred.

Double labeling of freshly isolated cardiac cells with anti-60S and anti-{alpha}-actinin antibodies showed that only a few cells retained a rod shape (Figure 3A), whereas the majority of cardiac myocytes were spherical (Figure 3B and Figure 3C). Concomitant with spherical transformation, the sarcomeric organization of myofibrils disappeared, as demonstrated by immunolabeling with anti-{alpha}-actinin antibodies. During this apparently rapid disassembly of the myofibrils, immunoreactive {alpha}-actinin was redistributed to the peripherial proportion of the sarcoplasm. Immunostaining with the anti-60S antibodies revealed specific labeling in the intermyofibrillar and subsarcolemmal areas in the rod-shaped cardiac myocytes. However, in the spherical cells the staining attained a wide distribution in the sarcoplasm without any detectable organization (Figure 3B and Figure 3C). After attachment to the substrate (4 and 8 hr), the sarcoplasmic 60S immunostaining attained a granular appearance (Figure 3D–F). At the sites of membrane attachment, {alpha}-actinin was accumulated, whereas little 60S immunoreactivity was evident in these areas as revealed by double immunolabeling.



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Figure 3. Double labeling experiments of 60S ribosomal subunit (TRITC, red fluorochrome) and {alpha}-actinin (FITC, green fluorochrome) in spreading cardiac myocytes. Overlapping of the two fluorochromes is recognized by a yellow color. After isolation, only a few rod-shaped cardiac myocytes are seen (A), whereas the majority of cells have attained a spherical shape (B,C). After seeding, the cells already attach after 4 hr (D), and they start to spread and form sarcoplasmic projections, lamellae (E,F 8 hr; G 12 hr; H,I 1 day; J,K 2 days; L 4 days; M–O 6 days). After attachment, most {alpha}-actinin immunolabeling is distributed in the peripheral portion of the sarcoplasm, and the 60S ribosomal subunit is localized widely in the sarcoplasm (asterisks) (C–F). During spreading the myofibrils (arrows) (G,H) are disassembled and nascent myofibrils emerge in the periphery of the sarcoplasm (arrowheads) (H–M). Considerable immunoreactivity of the 60S ribosomal subunits is seen, spatially associated with the sarcomeres (arrows) of the mature myofibrils (N,O). Occasionally a line of negative staining (arrowhead) was observed between the Z-lines (arrow) corresponding to the midportion of the A-band (N).

During further stages of culturing (12–24 hr), sarcoplasmic lamellae emerged concomitantly with the appearance of a centrally occurring sarcomeric-like {alpha}-actinin staining pattern (Figure 3G–I). Moreover, strands of {alpha}-actinin immunostaining, extending from the centrally occurring myofibrils towards the cell surface, were co-localized with labeling of the 60S ribosomal subunit (Figure 3H and Figure 3I). At later stages of spreading (2–6 days), the numbers of mature myofibrils increased, along with a redistribution of the 60S ribosomal subunit. In these cardiac myocytes, 60S labeling was present in the intermyofibrillar sarcoplasm (Figure 3J and Figure 3O). Moreover, in some instances an apparent sarcomere-associated immunostaining of the 60S ribosomal subunit occurred in cardiac myocytes containing mature myofibrils (Figure 3N).

Electron Microscopy
The sarcoplasm of the spreading cardiac myocytes contained an abundance of filamentous proteins and mitochondria (Figure 4A). Filaments attached to the substrate were arranged in bundles forming myofibril-like structures (Figure 4B). Silver-enhanced ultrasmall gold particles labeling the 60S ribosomal subunit were seen widely in the sarcoplasm. The specific labeling was frequently closely associated with filaments (Figure 4C) and developing myofibrils (Figure 4B and Figure 5).



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Figure 4. Pre-embedding immunogold electron microscopic detection of the 60S ribosomal subunit in spreading cardiac myocytes cultured for 3 days. The cells were fixed, incubated with specific antibodies, and labeled with ultrasmall gold probes followed by silver enhancement (arrows). Mitochondria (M) and myofibril-like structures (MF) are identified (A). Projecting from the membranous adhesion sites (arrowheads) are filamentous proteins arranged in bundles, forming attachment sites for the developing myofibrils (MF) (B). At high resolution the silver-enhanced gold probes are frequently seen in the proximity of filamentous proteins (C). Extracellular space is indicated by asterisks. ID, intercalated disc; S, substrate; SC, subsarcolemmal cytoskeleton.



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Figure 5. Immunolabeled cardiac myocytes incubated for 6 days. Silver-enhanced gold probes (arrows) are present in close spatial association with a developing myofibril (MF). Filaments are attached to the electron dense Z-line (Z).


  Discussion
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

The dramatic rearrangement of the cell architecture that occurs after isolation and attachment of the cardiac myocytes to the substrate is associated with major changes in the cytoskeleton (Guo et al. 1986 ). The initial redistribution of the 60S ribosomal subunit, as demonstrated in the present work, may therefore be connected with alteration of the cytoskeletal network, e.g., intermediate filaments, which coincide with the disassembly of the myofibrils. In cultures of chick cardiac myocytes it has been shown that the myofibrils disassemble through stages of transitory single sarcomeres, the cardiac polygons, that disappear after 5 days of incubation (Lin et al. 1989 ). During spreading of cardiac myocytes, premyofibrils are formed at the cell periphery (Lu et al. 1992 ). The fully mature myofibrils, however, are localized in the perinuclear areas, whereas the nascent myofibrils are positioned between the premyofibrils and the mature myofibrils (Rhee et al. 1994 ). During the initial stages of myofibrillogenesis, {alpha}-actinin containing dense bodies forms irregular Z-lines to which the thin actin filaments are anchored. Subsequently, muscle myosin II thick filaments as well as other sarcomeric proteins are incorporated into the preformed I-Z-I structures during maturation of the myofibrils (Schultheiss et al. 1990 ; Komiyama et al. 1993 ; Rhee et al. 1994 ). A similar sequence of filament incorporation occurs in the developing heart and in the adult hypertrophying heart (Satersdal et al. 1976 ; Myklebust et al. 1978 ). In the present study, the 60S ribosomal subunit was accumulated in the perinuclear sarcoplasm during the early stages of spreading. However, after 2–3 days of culture a spatial relation between the 60S ribosomal subunit and the nascent and mature myofibrils emerged. Taking these findings together, it is indicated that the 60S ribosomal subunit has a particular role in the maintenance and growth of mature myofibrils rather than being involved in the initial formation of nascent myofirils.

A close relation of 60S ribosomal subunit staining along the myofibrils was demonstrated in cells co-labeled with anti-{alpha}-actinin antibodies. The 60S ribosomal subunit appeared to be accumulated towards the Z-lines, which is consistent with the ribosome distribution observed in adult skeletal muscle by conventional electron microscopy (Larson et al. 1969 ). The synthesis of thick filaments has been shown to be connected with the presence of ribosomes (Myklebust et al. 1978 ). These findings are in accordance with that observed in cardiac myocytes in vivo in which the 60S immunostaining occurs as cross-striated bands in close spatial relation to the myofibrils (Larsen et al. 1994 ). Hence, the ribosome association to the filamentous proteins and the morphological features of cell differentiation confirm significant similarities between the developing and hypertrophying cardiac myocytes in vivo and the differentiation of isolated cardiac myocytes during culture. A large proportion of the existing pool of ribosomes are normally associated with steady-state synthesis of proteins (Luyken et al. 1996 ). Consequently, cardiac growth requires an increased synthesis of ribosomal proteins. Ribosome formation is regulated at the level of transcription of ribosomal RNA genes. Accelerated ribosomal RNA synthesis is accompanied by an increase of the ribosomal DNA transcription factor UBF, which is important for both initiation and maintenance of activated DNA transcription (Hannan et al. 1995 , Hannan et al. 1996 ). Therefore, the presence of the 60S ribosomal subunit in the nucleoli of the spreading cardiac myocytes probably reflects an increased synthesis of ribosomal proteins, which are then assembled into ribosome complexes in the nucleoli before being transported back to the sarcoplasm. Similar nucleolar staining has been identified in 3T3 fibroblasts (Hesketh et al. 1991 ). However, preceding the increase in cell size a sequence of cell responses occurs. After induction of immediate-early genes, e.g., c-fos, the transcription of genes encoding for structural proteins and for fetal isoforms of certain proteins is increased (Lompre et al. 1991 ). In regionally infarcted hearts, transient c-fos activation is seen at 1–48 hr in cardiac myocytes undergoing cellular growth (manuscript in preparation). These cardiac myocytes, localized adjacent to the infarcted areas, express high levels of immunoreactive atrial natriuretic factor after 2–3 days (Larsen and Satersdal 1993 ), and the size of the cells increases significantly (Cox et al. 1991 ). Moreover, a significantly increased content of 60S ribosomal subunits is seen in these cardiac cells after myocardial infarction (Larsen et al. 1994 ). Similar signaling pathways and regulation of gene transcription have been found in hypertrophying cardiac myocytes in culture as well (Sadoshima et al. 1992 ; Yazaki et al. 1993 ). In summary, the neonatal rat model is a useful system in which to study redifferentiation and myofibrillogenesis in cardiac myocytes. The present data suggest a significant role for the ribosomes during the remodeling and growth of the developing myofibrils.


  Acknowledgments

Supported by grants from the Norwegian Research Council and the Bergen Heart Foundation.

The skillful technical assistance of Edel Karin Frotjold and Kjellfrid Haukanes is gratefully acknowledged.

Received for publication September 3, 1997; accepted March 11, 1998.


  Literature Cited
Top
Summary
Introduction
Materials and Methods
Results
Discussion
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