Growth and DNA synthesis in embryonic chick heart cells, in vivo and in vitro

The Transitional Heart: From Early Embryonic and Fetal Development to Neonatal Life

Formation of the human heart involves complex biological signals, interactions, specification of myocardial progenitor cells, and heart tube looping. To facilitate survival in the hypoxemic intrauterine environment, the fetus possesses structural, physiological, and functional cardiovascular adaptations that are fundamentally different from the neonate. At birth, upon separation from the placental circulation, the neonatal cardiovascular system takes over responsibility of vital processes for survival. The transition from the fetal to neonatal circulation is considered to be a period of intricate physiological, anatomical, and biochemical changes in the cardiovascular system. With a successful cardiopulmonary transition to the extrauterine environment, the fetal shunts are functionally modified or eliminated, enabling independent life. Investigations using medical imaging tools such as ultrasound and magnetic resonance imaging have helped to define normal and abnormal patterns of cardiac remodeling both in utero and ex utero. This has not only allowed for a better understanding of how congenital cardiac malformations alter the hemodynamic transition to the extrauterine environment but also how other more common complications during pregnancy including intrauterine growth restriction, preeclampsia, and preterm delivery adversely affect offspring cardiac remodeling during this early transitional period. This review article describes key cardiac progenitors involved in embryonic heart development; the cellular, physiological, and anatomical changes during the transition from fetal to neonatal circulation; as well as the unique impact that different pregnancy complications have on cardiac remodeling.

Erythropoietin and retinoic acid, secreted from the epicardium, are required for cardiac myocyte proliferation

We have established a heart slice primary culture, which allows us to mechanically separate distinct cardiac cell populations and assay their relative mitogenic and trophic effects on cardiac myocyte proliferation and survival. Using this system, we have found that a signal(s) from the epicardium, but not the trabeculae and endocardium, is required in embryonic day 10 (E10) chick heart slices for continued cardiac myocyte proliferation and survival. An examination of potential epicardial growth or trophic factors has revealed that blockade of either retinoic acid (RA) or erythopoietin (epo) signaling from the epicardium inhibits cardiac myocyte proliferation and survival. The blockade of cardiac myocyte proliferation following administration of an RA antagonist can be rescued by exogenous epo. Conversely, the blockade of cardiac myocyte proliferation following administration of an anti-epo receptor antisera can be rescued by exogenous RA. Thus, our findings suggest that RA and epo signals work in parallel to support myocardial cell proliferation. In addition, we have found that these factors do not act directly on myocardial cells. Rather, they induce another soluble factor(s) in the epicardium that directly regulates proliferation of cardiac myocytes. We therefore postulate that the epicardium controls normal heart growth in ventricular segments of the embryonic chick heart by secreting a cardiac myocyte mitogen whose expression (or activity) is regulated by both RA and erythropoietin signaling.

Behavior of embryonic chick heart cells in culture. 1. Cellular responses to insulin-transferrin-selenium

Muscle cell-enriched primary cell cultures were prepared from 8-day embryonic chick heart ventricles (74% of these cells showed positive staining with anti-cardiac myosin antibody). To determine if ITS (a commercial mixture of insulin, transferrin, and selenium) affects these cardiac muscle cells, immunostaining and autoradiography were performed to determine the Muscle Cell Labeling Index (MLI). MLI represents the proportion of cardiac myosin-positive cells that specifically incorporated [3H]thymidine. The MLI for ITS-treated cells was 52%. Controls in Serum-free Nutrient Medium (SFNM) had a MLI of 27%. Combinations of growth signals also were tested. Whereas 5% Fetal Bovine Serum (FBS) was optimal for stimulation of [3H]thymidine incorporation, 10 and 20% FBS elicited an inhibitory effect. Addition of ITS enhanced the stimulatory effect of FBS and relieved some of the inhibitory effect. TGF-beta also was shown to have inhibitory effect on [3H]thymidine incorporation in these heart cells, but the inhibitory effect was not seen when it was added with ITS. Staining with anti-cardiac myosin antibody revealed that when the cells were cultured with ITS for 6 or 10 days, the percentages of muscle cells were 65 and 59%, whereas the percentages of muscle cells of controls in SFNM dropped to 44 and 31% respectively. Additional experiments showed that cell number increased in the presence of 5% FBS. In contrast, although ITS stimulated DNA synthesis, it did not immediately stimulate complete cell division. The percentage of muscle cells remained around 74% in the presence of 5% FBS, whereas it fell slightly (to 65%) in SFNM. This study showed that cardiac muscle cells from 8-day embryos in culture were responsive to ITS, FBS and TGF-beta and that ITS may be permissive for continued expression of differentiation of embryonic cardiac muscle cells.

Clonal analysis of cardiac morphogenesis in the chicken embryo using a replication-defective retrovirus. III: Polyclonal origin of adjacent ventricular myocytes

Replication-incompetent variants of the avian spleen necrosis virus (SNV) encoding cytoplasmic or nuclear-directed beta-galactosidase (beta-gal) have been used to trace the clonal growth of myocytes during left ventricular free-wall formation. Tubular-stage hearts were infected with a mixed suspension of both retroviruses and, after hatching, the progeny of marked cells in the ventricular wall were examined by X-gal histochemistry. When a small number of virions was introduced individual blue patches contained myocytes with only one label type (cytoplasmic or nuclear). These results confirmed our previous conclusion that each cluster or patch represents a single clone (Mikawa et al., 1992, Dev. Dynamics, 193:11-23). Each of these clones formed a clone-shaped patch which often extended through the entire thickness of the ventricular myocardium, but typically each patch was heterogeneous, containing a mixture of labeled and unlabeled cells. We then asked whether the two populations of myocytes in each patch were clonally related or generated from more than one progenitor. When hearts were infected with high titer viral suspensions many patches were observed in which cytoplasmic-tagged myocytes were intermingled with nuclear-tagged myocytes. Thus, the cone-shaped myocyte patches in the ventricular wall are polyclones derived from separate progenitors in the precardiac mesoderm. This finding led us to examine the separation of clonally related ventricular myocytes in the developing hearts. Embryos were infected with retroviral suspensions at varying stages of development and the resulting colonies examined after hatching.(ABSTRACT TRUNCATED AT 250 WORDS)

Clonal analysis of cardiac morphogenesis in the chicken embryo using a replication-defective retrovirus: I. Formation of the ventricular myocardium

Cells of the precardiac mesoderm (stages 4-6) and dividing myocytes of early hearts (stages 10-15) were tagged with a replication-incompetent retrovirus (CXL) (Mikawa et al., 1991b) encoding bacterial beta-galactosidase (beta-gal). Two protocols were used to infect the cardiogenic cells. (1) Small blocks (approximately 50 micron 2) of anterolateral mesoderm were dissected from gastrula-stage embryos (stages 4-6) and incubated in liquid medium containing the retrovirus. After removal of CXL, the tissues were dispersed into single-cell suspensions and pressure injected into the precardiac areas of recipient embryos (stages 4-6). Such embryos were then incubated in vitro at 37 degrees C for 2 days (New, 1968), and those embryos with beating hearts were fixed for X-gal histochemistry and paraffin serial sectioning. (2) CXL was pressure injected in ovo (embryonic stages 4-15) into cardiogenic tissues and the eggs subsequently returned to an incubator. At selected stages of development embryos or whole hearts were fixed, stained with X-gal, and serially sectioned after paraffin embedding. The first method showed that (1) cells of the precardiac mesoderm could be infected with the retrovirus, (2) the transplanted cells would differentiate into beating myocytes, and (3) beta-gal expression was sufficiently high to be detected histochemically. With the second procedure we could show that (1) beta-gal-tagged cells formed colonies in the myocardium, (2) the labeled cells were exclusively myocytes, (3) the number of cells per colony increased with increasing age of embryonic development, (4) the size of colonies was larger in the left than the right ventricle, (5) many of the colonies were transmural, i.e., they extended from epicardial to endocardial layers of the myocardium and generally exhibited a cone or funnel-shape with the base of the cone nearest the epicardium, (6) the orientation of myocytes within each colony changed at different layers of the myocardium, and (7) the cones contained both beta-gal+ and beta-gal- myocytes. DNA labeling studies with [3H]thymidine indicated that cardiogenic cells divided every 16-18 hr during the first week of development and that the CXL-labeled cells divided indistinguishably from unlabeled myocytes. Based on these observations a model for the growth of the myocardium is presented.

Proliferating cell nuclear antigen in developing and adult rat cardiac muscle cells

During early development, rat cardiac muscle cells actively proliferate. Shortly after birth, division of cardiac muscle cells ceases, whereas DNA synthesis continues for approximately 2 weeks at a progressively diminishing rate. Little DNA synthesis or cell division occurs in adult cardiocytes. Thus, developing cardiac muscle cells are an ideal system in which to examine the expression of cell cycle-regulated genes during development. We chose to examine proliferating cell nuclear antigen (PCNA), a gene expressed at the G1/S phase boundary of the cell cycle. Northern blots of RNA from cardiac muscle cells from 18-day-old rat fetuses and from day 0, 5, and 14 neonatal as well as adult rat hearts revealed that the PCNA mRNA was found in cardiac muscle cells from all ages. However, because it was possible that this was a result of fibroblast PCNA gene expression, we used reverse transcription followed by polymerase chain reaction to see if it was possible to detect the message for PCNA in cardiac muscle cells from all ages. Because of the great sensitivity of this technique, RNA was recovered from 25 isolated adult cardiac muscle cells. Polymerase chain reaction amplification products for PCNA produced from the RNA isolated from these cells conclusively demonstrated that mRNA for this gene, which normally is associated with proliferating cells, is expressed in adult cardiac muscle cells that no longer divide. Furthermore, Western blot analysis demonstrated that the PCNA protein was found only in embryonic and neonatal cells and not in adult rat cardiac muscle cells. Therefore, it might be inferred from these data that PCNA might be regulated at the posttranscriptional level in adult cardiac muscle cells.

Primary cell culture and morphological characterization of ventricular myocytes from the adult newt, Notophthalmus viridescens

Previous work has demonstrated that adult newt cardiac myocytes possess a proliferative ability in response to an experimentally induced injury, in vivo. This study describes an in vitro model in which the proliferative events of the adult cardiac myocyte may be studied. Ventricles were minced and then enzymatically dissociated in a Ca++- and MG++-free salt solution containing 0.5% trypsin and 625 U/ml of CLS II collagenase for 8 to 10 hours at 25 degrees C. Enzyme digests were preplated and then cultured on bovine corneal endothelial-derived basement membrane "carpets" in either serum-free or serum-supplemented modified Leibovitz's medium for up to 30 days. Light and transmission electron microscopic characterization demonstrated that a majority of the myocytes underwent an initial period of disorganization characterized by a "rounding up" of the cell and a loss of myofibrillar organization. Once the myocytes had attached to the culture substratum they began to spread out, underwent a reassembly of their contractile elements, resumed spontaneous contractions, and demonstrated ultrastructural evidence of protein synthesis. Mitosis was observed in several myocytes 8 to 15 days following isolation. In 15-day serum-supplemented and serum-free cultures, 6.5% +/- 0.9% and 8.1% +/- 1.4% of the myocytes were binucleated, respectively. These results demonstrate that adult newt ventricular myocytes can be successfully placed into primary culture and are capable of undergoing mitosis. This work may be considered as a foundation for future investigations which will focus on the mechanisms which control cardiac myocyte proliferation.

Immunofluorescent localization of desmin and vimentin in developing cardiac muscle of Syrian hamster

The distributions of desmin and vimentin were examined in frozen sections of cardiac muscle from embryonic, newborn, and adult Syrian hamster by using immunofluorescent methods. Frozen sections of newborn and adult skeletal muscle were used for comparison. Cardiac myocytes from day 9 in utero embryos already show a clear association of desmin with the sarcomeric myofibrils. In newborn hearts, desmin is localized in the myofibrillar Z-line areas as well as in the peripheral cytoplasm of the cell. Three days after birth, desmin is associated with the intercalated discs. Thus, in adult cardiac muscle, desmin is present in both Z-bands and intercalated discs. Skeletal muscle of newborn and adult hamster also contains desmin associated with the Z-lines of myofibrils. Vimentin is associated with the myofibrils of day 9 in utero cardiac muscle cells. The protein remains associated with the myofibrillar Z-lines in the newborns and adults. No detectable staining for vimentin was observed in newborn or adult hamster skeletal muscle. The existence of vimentin as well as desmin in differentiated cardiac muscle may be a consequence of the somewhat more epithelial-like nature of cardiac cells as compared to skeletal muscle syncitia.

DNA synthesis of adult mammalian cardiac muscle cells in long-term culture

Adult rat cardiac ventricular muscle cells were isolated and cultured in monolayer for 30-45 days. Most of the cardiac muscle cells undergo external and internal structural alterations, resembling embryonic/neonatal cardiac muscle cells in culture (Nag and Cheng, 1981; Nag et al., 1983). These cultured cells underwent DNA synthesis and mitosis as revealed by autoradiography studies that involved the exposure of the cells to [3H]-thymidine for 24 hr prior to the termination of the culture at selected intervals. During the first week of culture, cardiac muscle cells showed less than 5% labeled cells. The labeling index of myocytes attained a peak in the second week of culture, exhibiting approximately 23% labeled cells. The labeling indices of cardiac muscle cells declined over the period of 30 days of culture. During the end of the incubation period, approximately 4% of the myocytes were labeled. When the extent of the total cell population involved in DNA synthesis was examined by exposing the cells to [3H]-thymidine continuously for long periods of time, it was observed that approximately 26% of the cardiac muscle cells regained the capacity for DNA synthesis during 1-10 days of culture. From day 1 to day 14, approximately 29% of the total muscle cell population was labeled. When the cells were exposed to the radioactive isotope continuously for 30 days, approximately 31% of the cells incorporated radioactive isotope, showing their capacity for DNA synthesis. Approximately 90% of the cardiac muscle cells in long-term culture contained more than one nucleus. The nuclei were often observed in multiples of two. Labeled mitotic apparatus was observed in cardiac myocytes, indicating the replication of DNA, followed by karyokinesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of the growth of nonmuscle heart cells in culture

Primary cultures of neonatal rat hearts contain both striated muscle (myocytes) as well as nonmuscle heart cells (NMHC). Although myocytes do not divide in culture, NMHC do increase in number. The growth of NMHC is dependent on the concentration of serum in the media over a range of 1 to 10%. When compared to growth in 10%, cells in 1% serum have a prolonged doubling time and reach a maximum density that is 70% less. Thus, 1% serum which supports normal myocyte development is a useful culture media to also maintain muscle heart cell homogeneity by its failure to support optimum NMHC division.

Pathogenesis of ventricular hypertrophy

Growth of the vertebrate heart during embryonic and fetal life is characterized by hyperplasia of myocardial cells. Shortly after birth, myocardial cells lose the capability of dividing, and further growth of the heart is due to myocardial cell hypertrophy and nonmuscle cell hyperplasia. This process results in a 30- to 40-fold increase in volume of individual myocardial cells during normal postnatal growth and maturation. The transition from hyperplastic to hypertrophic growth is related to formation of binucleated myocardial cells as a result of karyokinesis without cytokinesis. The molecular mechanism of this transition is uncertain. The response of the heart to increased metabolic demands or an increased work load depends on the age of the animal at the time when the stress is imposed. Increased myocardial work loads in fetal or early neonatal life lead to cardiac enlargement by causing an increased rate of hyperplasia of myocardial cells or continuation of hyperplasia beyond the normal period of hyperplastic growth. In contrast, imposition of increased loads on the hearts of older animals results in cardiac hypertrophy due to enlargement of myocardial cells and hyperplasia of nonmuscular components. In addition to cellular enlargement, structural remodeling of the myocardial cells and of the chambers of the heart occurs during the development of hypertrophy. Important stimuli of cardiac hypertrophy include increased systolic force or tension generated by the myocardial fibers (pressure overload), increased end-diastolic wall stress (volume overload) and neurohumoral factors such as increased circulating catecholamines or discharge of cardiac sympathetic nerves, or both, activation of the renin-angiotensin system and increased levels of thyroxine and growth hormone.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in cytoplasmic and lysosomal enzyme activities in cultured rat heart cells: the relationship to cell differentiation and cell population in culture

Postnatal rat heart cells in culture enriched with respect to muscle cells were obtained by either high density seeding or by the replating technique. [3H]Thymidine incorporation to DNA and the enzymatic pattern of cytoplasmic and lysosomal enzymes have been studied as a function of the culture's age, of seeding density, and replating. It was shown that replating maintains predominance of myocyte population for at least 2 wk in culture; heavy seeding density allows homogeneous myocyte population for the 1st wk in culture; and the enzyme profile of the culture may serve as an indicator for the type of cell population in culture and its state of differentiation.

Structural change of myofibrils during mitosis of newt embryonic myocardial cells in culture

Newt embryonic myocardial cells can undergo mitosis in culture. The successive changes in the striation pattern of sarcomeres of myofibrils during mitosis were studied by polarization microscopy without fixing or killing the cells. Birefringence of well-organized striation patterns, i.e., bright A-bands and dark I-bands, was clearly visible in interphase cells and did not show any detectable changes during incubation for 3 h or more. Electron microscopy showed the presence of well-organized myofibrils with Z-bands in these interphase cells. When myocardial cells entered the mitotic stage, the birefringence of striation pattern of their myofibrils gradually changed with the pattern in small parts of the myofibrils gradually becoming indistinct (called 'indistinct striation' in this paper). These indistinct regions increased in size during the mitotic stage. In addition, in some regions of the indistinct striation, the birefringence of sarcomeres gradually decreased and finally disappeared (called 'disappearance of sarcomeres' in this paper). No myocardial cells underwent mitosis without these disruptive changes of the myofibril striation patterns. In the post-mitotic stage, the well-organized striation of the myofibrils reappeared. Electron microscopy showed disorganized sarcomeres without Z-bands in the regions of indistinct striation, and no well-organized myofibrils in the regions where the sarcomeres had disappeared. Thus the well-organized myofibrils with Z-bands became transiently disorganized at least in some parts, during mitosis. They were then reorganized into daughter myocardial cells.

Analysis of population cytokinetics of chick myocardial cells in tissue culture

The growth of embryonic chick cardiac myocytes and fibroblasts in tissue culture was evaluated by the kinetics of nuclear labeling during continuous exposure to [3H]thymidine. The fraction of mitotically active cells, the mean intermitotic period and the population doubling times were determined in each cell type during 3 weeks in culture. After 24 hr in culture, 90% of the muscle cells were mitotically active with minimal population doubling times of 65 hr. By 17 days in culture only 5% of the myocytes continued to divide with population doubling times greater than 3000 hr. Primarily, the lengthening of doubling times was due to a withdrawal of cells from the mitotic cycle and much less to a lengthening of the intermitotic period. Growth of cardiac muscle cells from embryonic hearts from 4 to 10 days of development was also compared. Muscle cells from younger hearts displayed greater mitotic activity than those from older hearts at equivalent times in culture.

Adult mammalian cardiac muscle cells in culture

Adult rat cardiac muscle cells were isolated from the ventricle by a retrograde perfusion technique through the aorta (Nag and Zak, 1979). These single, isolated cardiac muscle cells were cultured for 4 weeks. Throughout the culture period, a small number of muscle cells retained their cylindrical shape, while the rest exhibited alterations in shape and size assuming a flattened body of irregular shape with pseudopodia-like processes and thereby resembling embryonic/neonatal cardiac muscle cells in culture. Transmission electron microscopy revealed that the cylindrical muscle cells contained compactly arranged myofibrils and cellular organelles, similar to those of freshly isolated and in vivo cells. A few irregularly shaped cardiac muscle cells were similar to the cylindrical cells in their internal structural organization. Most of the irregular cells exhibited less myofibrillar content than that of the freshly dissociated and in vivo cells. Myofibrils in the irregular cells were widely spaced and myofilament of some of the myofibrils were loosely bunched. In addition, scattered patches of myofibrils and free myofilaments were observed in many of these cells. The internal structural organization of these irregularly shaped cardiac muscle cells closely resembled the embryonic and neonatal cardiac muscle cells in vitro and in vivo. Most of the muscle cells in culture continued to contract spontaneously, and electron microscope studies clearly indicated that they underwent dedifferentiation. Autoradiography studies demonstrated that the cylindrical and irregularly shaped cardiac muscle cells underwent DNA synthesis and cell division in culture.

The use of 5-bromodeoxyuridine and irradiation for the estimation of the myoblast and myocyte content of primary rat heart cell cultures

A method for killing dividing cells (Puck and Kao, '67) was adapted for the elimination of dividing heart muscle cells (myoblasts) in cultures. We have used this method to demonstrate their presence and to estimate their number as well as the number of nondividing heart muscle cells (myocytes) in the neo-natal rat heart. Cells were cultivated in BUdR (5-bromodeoxyuridine) 10(-4) M for 3 days and then irradiated with long UV light. The selective elimination of dividing cells led to a loss of myosin Ca2+-activated ATPase in the cultures. This indicates the presence of dividing cells which contain myosin. The percent of ATPase left after irradiation was 32% of the control in cultures derived from 1-day postnatal rats and 48% in cultures from 4-day postnatal rats. This reflects an in vivo shift of myoblasts to myocytes in the muscle cell population as the rat ages.

Histochemical demonstration of myosin Ca2+-ATPase accumulation in primary cultures of skeletal and heart muscle cells

A modified histochemical technique is described for the improved detection of myosin Ca2+-ATPase activity in single muscle cells in culture. The method was used to demonstrate the increase in myosin Ca2+-ATPase activity in differentiating chick skeletal muscle cells. Functional muscle cells were also positively identified in the heterogeneous cell population of primary hamster heart cell cultures. An age-dependent increase in the number of cells with high levels of myosin ATPase activity in mitotically arrested heart cell cultures was shown. Maturation of individual muscle cells could thus be evaluated.

Studies of adult amphibian heart cells in vitro: DNA synthesis and mitosis

The ventricle of the adult newt heart was excised and cut into several pieces of approximately 0.5-1.0 mm. These heart pieces were then cultured for 60 days at 25 degrees C in a modified Leibovitz medium (L-15). Approximately 37% of the explants were attached to the substrate and more than 33% of the attached explants and approximately 15% of the unattached explants established pulsation rates which ranged 3-67 beats/min. The explants were labeled with 1 muCi/ml of 3H-thymidine for 24 hr at 7, 15, 21, 30, 45 and 60 days of culture initiation, and processed for electron microscopic autoradiography. The examination of the autoradiograms revealed that as the culture continued, the cardiac muscle cells altered their morphology, resembling embryonic cardiac muscle cells. These altered muscle cells were termed dedifferentiated cardiac muscle cells. The number of these dedifferentiated cells increased over the period of culture, showing 10.3-94% dedifferentiated cells after 7-60 days of culture respectively. DNA synthesis and mitosis were observed in the dedifferentiated cardiac muscle cells, apart from the non-muscle cells. The quantitation of the autoradiograms revealed that the number of labeled nuclei in the cardiac muscle cells gradually increased over the period of culture, and a maximum number of labeled cardiac muscle cells (30%) was observed in the third week. The peak was followed by a decline in the eighth week which exhibited 1.5% labeled cardiac muscle cells. The trend of mitosis was similar to that of DNA synthesis. The maximum number of mitotic figures (9%) was observed in the third week of culture, which was followed by a decline and finally absent in the eight week. The cardiac non-muscle cells, mostly fibroblasts and endothelial cells, also showed incorporation of 3H-thymidine in their nuclei. The number of labeled non-muscle cells nuclei and the mitotic index were highest (61 and 15% respectively) in the first week of culture, but then they decreased gradually over the eight-week period in culture. This study provides evidence for the first time that the adult amphibian cardiac myocytes can undergo DNA synthesis and mitosis when explanted and cultured. The significance of this cell replication is discussed.

DNA synthesis and mitosis in adult amphibian cardiac muscle cells in vitro

High-resolution autoradiography and fine structural analysis of adult newt heart tissue in long-term culture revealed that tritiated thymidine was concentrated in the nuclei of dedifferentiated myocardial cells. Mitotic chromosomes were observed in some of these cells. This demonstrates that adult amphibian myocardial cells in vitro are capable of DNA synthesis and mitosis.

Inhibition of cell-substratum attachment of cultured rat heart cells by protein synthesis inhibitors

Addition of cycloheximide to growth medium of neonatal rat heart cell cultures prevented cell-substratum attachment. Even concentrations of cycloheximide which inhibited only 50% of normal protein synthesis prevented some cells from attaching. Cells which required the longest time to attach were not dependent on protein synthesis. The kinetics of cell-substratum adhesion in the presence of various concentrations of cycloheximide supported the hypothesis that repair of damaged cell membranes was required prior to attachment. An alternate hypothesis that protein synthesis was required for substratum attachment either to synthesize new unique proteins or higher concentrations of existing proteins not damaged by enzymes was not supported by experimentally obtained data. If the second hypothesis were true, no cells would have attached when protein synthesis was completely inhibited (greater than 95%) and all cells should have been equally affected by protein synthesis inhibition; such was not the case. Inhibition of mRNA formation by actinomycin D also should have inhibited attachment completely and this was not observed. Since attachment was minimally affected by actinomycin D, protein synthesis on long-lived mRNA was apparently sufficient for cell-substratum adhesion.

Organ culture of adult amphibian heart: a fine structural analysis

Pieces of hearts from adult newts were cultured up to 2 months. Within 7 days of culture, approximately 37% of the cardiac explants were attached to the substrate and more than 33% of the attached explants and approximately 15% of the unattached explants established pulsation rates ranging from 3 to 67 beats/min. The control and cultured explants were processed at weekly intervals for electron microscopy. The diameter of the control cardiac muscle cells ranged approximately 3-5 micron. The cell surface was provided with microvilli. The intercellular spaces ranged approximately 150-500 A. The intercalated discs lacked the step-like courses observed in the mammalian cardiac muscle. Sarcoplasmic reticulum was scanty. Desmosomal-dense materials were frequently continuous with the Z-bands of both control and cultured cardiac muscle cells. The transverse tubular system and gap junction were absent in newt ventricles. The functional implications of these characterisitics are discussed. At the end of 1 week of culture, the surfaces of the explants were covered by one or more layers of non-muscle cells, and the core of the explants consisted mostly of cardiac muscle cells. In a few cardiac muscle cells the myofibrillar organization was disrupted, resulting in the distribution of scattered patches of myofibrils and free myofilaments in the sarcoplasm. A small number of intact muscle cells contained a considerable number of dense granules in the sarcoplasm. At 15 days in culture, a large number of muscle cells showed structural features reminiscent of embryonic cardiac muscle cells. These cells possessed patches of myofibrils, scattered myofilaments and scanty sarcoplasmic reticulum along with other cellular organelles and inclusions. Several of these altered cardiac muscle cells contained mitotic figures. The cardiac explants maintained the initial beating rate until the end of 2 months of culture, except for the 11% of the explants which stopped beating. By 3-4 weeks in culture, most of the cardiac muscle cells possessed the altered cell morphology mentioned above. The explants after 60 days in culture became more flattened than the earlier explants. The intact cardiac muscle cells were rare, and the cores of the explants were mostly occupied by the altered cardiac muscle cells. It is evident from our studies that the cardiac muscle cells have undergone dedifferentiation in long-term culture, and that this dedifferentiation process has yet had no effect in the maintenance of contractility of the explants. Furthermore, these dedifferentiated cardiac muscle cells are capable of DNA synthesis and mitosis.

Pleiotypic response of rat heart cells in culture to serum stimulation

The pleiotypic effects of medium replacement were studied in rat heart cell cultures. After each medium change alpha-aminoisobutyric acid and glucose transport are increased, RNA and protein syntheses are activated. DNA synthesis did not begin before 12 hours and was followed by a wave of mitoses. This sequence of events suggests that the stimulated cells were in early G 1 phase. DNA synthesis, following the shift to a fresh medium, is linearly related to the amount of serum used as is protein synthesis. However when serum concentrations higher than 20 percent were used no increased protein synthesis could be observed suggesting the existence of another limiting factor, which was probably the isoleucine content of the medium. The serum stimulating factor is heat stable, dialysable and was found in both human and fetal calf sera.

Spontaneous contractions of dispersed vascular muscle in cell culture

Dispersed vascular muscle cells from chick omphalomesenteric vessels maintained in primary cell culture contracted spontaneously. Six methods which produced contracting isolated muscle cells are described and compared. The combination of dispersion method and culture conditions to produce contracting muscle cells was more critical for vascular than for heart muscle. These findings of continuing pacemaker function demonstrate that functional integrity of isolated vascular muscle cells is possible to maintain. Further indication of the full functional state of the isolated vascular muscle cells was demonstrated by the sensitivity to norepinephrine at a physiological concentration (0.1 muM). Spontaneous contraction frequencies were similar to the range found in situ, and spontanious or norepinephrine-induced contractions had time courses corresponding to intact vessel contractions. This is the first report that isolated vascular muscle cells in primary cell culture retain functional characteristics found in situ and are suitable for pharmacological characterization of individual muscle cells.

Selective control of fibroblast proliferation and its effect on cardiac muscle differentiation in vitro

The stability of the differentiated state of cardiac myocytes in vitro was examined under culture conditions which selectively stimulated or inhibited proliferation of fibroblasts. Regulation of fibroblast proliferation in cultures of myocardial cells from 8-day embryonic chicks was achieved by adjustment of the glutamine (Gln) concentration in the culture medium (Ham's F-12 medium containing 2 x amino acids and 5% fetal calf serum). Myocardial cells, when plated at 80 cells/mm2 in Gln- medium, maintained a stable density of approximately 40% of the plating density for more than 30 days. When Gln was added to the medium (292 micrograms/ml) fibroblast proliferation was stimulated, and by 5-6 days after this addition cell densities had increased to confluency. The selective action of glutamine on fibroblast proliferation was determined by labeling cultures with tritiated thymidine ([3H]TdR) and scoring its incorporation into myocytes and fibroblasts by radioautography. After 2 weeks in Gln- medium, the mitotic index was 0.3% and the [3H]TdR-labeling index (1.5-hr pulse) was 6.4%. In addition, the proportion of myocytes in the population was constant at 64.2% for at least 30 days in vitro, and contractile activity was observed for up to 6 months. After 5 days of Gln replacement, the cells exhibited a labeling index of 25%, the proportion of myocytes decreased to less than 10% and contractile activity was rarely observed. Although the [3H]TdR-labeling index of fibroblasts and myocytes was nearly identical in Gln- medium, the addition of Gln produced a fivefold stimulation in the fibroblast labeling index, but did not affect myocyte proliferation or DNA synthesis. A unique phenomenon of myocyte congregation was observed only in Gln- medium which resulted in the formation of myocyte colonies from which fibroblasts were largely absent. It is suggested that this process with the resultant establishment of a functional electrical syncytium plays a significant role in the development and stabilization of myocyte differentiation in vitro.

DNA synthesis and mitosis in well-differentiated mammalian cardiocytes

Incorporation of [(3)H]thymidine into nuclei of heart cells of 2-day-old rats indicates that neonatal cardiac cells containing well-aligned myofibrils synthesize DNA. In these highly differentiated cells, neither the presence of contractile proteins nor their organization into myofibrils inhibits either DNA synthesis or mitosis.