Cardiomyocyte survival and DNA repair in myocardium from C57Bl/6 and mdx mice after dynamical stress

Mdx mice cardiomyocytes are a perspective model to study survival of terminally differentiated cardiomyocytes and formation of cardiomyopathy under conditions of oxidative stress. It was previously observed that dynamical stress induced formation of low molecular DNA fragments. It is beyond question that DNA fragmentation develops because of formation of double strand DNA breaks (DNA DSB). To record appearance and disappearance of DNA DSB we used antibodies to phosphorylated histone H2Ax (histone gamma-H2Ax.). The presence of DNA DSB was estimated in 0.05% and 6.7% of cardiomyocytes in the myocardium form C57B1 and mdx mice without stress, respectively. The part of cardiomyocytes with DNA DSB increased in an hour after stress up to 1.0% and 41.7% in C57B1 and mdx mice, respectively. In 24 h after stress, the myocardium from mdx mice contained 5.2% of gamma-H2Ax-positive cardiomyocytes and no C57B1 myocardium was found with any amount of gamma-H2Ax-positive cells. The results presented show induction of DNA damage by dynamical stress and restoration of normal DNA structure in the cells of both strains in 24 h after stress. There was no mdx mice death after used dynamical stress. To estimate the real contribution of DNA repair to the survival of cardiomyocytes we have counted the cardiomyocyte loss. Morphometric analysis demonstrated that cell concentration in myocardium from mdx mice under normal conditions was less than that one in myocardium of C57B1/6. The cell loss varied between 20% for the base and 40% for the apex of mdx mice hearts. In 24 h after stress, the cell loss in the myocardium of mdx mice amounted to 2.5%. The difference between the number of cells with damaged DNA structure and the index of the real cell loss allows concluding that DNA repair makes a real contribution to the survival of mdx mice cardiomyocytes after dynamical stress.     

Double-strand breaks of DNA of C57BL and mdx mouse cardiomyocytes after dynamic stress

One of the approaches to analysis of survival of cardiomyocytes during oxidative stress can be the use of animals with genetic defects—mdx mice. In mdx mice, disturbance of dystrophine synthesis is known to be accompanied by development of oxydative stress in contractile cells that in turn produces cell death. Earlier we established that dynamic stress leads to the formation of low molecular DNA fragments in the mdx mouse myocardium. It is beyond any doubt that the DNA fragmentation develops via formation of double-strand DNA breaks (DB). To record the dynamics of the appearance and disappearance of DB in the mdx mouse cardiomyocytes after dynamic stress, we used an antibody to the phosphorylated form of the γ-H2Ax histone. In the absence of stress, DB in myocardial cell nuclei are revealed both in C57Bl and in mdx mice. The percentage of cardiomyocyte nuclei with DB in C57Bl and in mdx mice was 0.05 ± 0.07% and 6.7 ± 0.2%, respectively (Table 1). In the C57Bl mice 1 h after dynamic stress the fraction of labeled cardiomyocyte nuclei rose to 1.0 ± 0.02%, while in the mdx mice—to 41.7 ± 11.4% (Table 1). At 24 h after the dynamic stress 5.7 ± 0.2% cardiomyocyte nuclei remained labeled in the mdx mouse myocardium (Table 1), whereas in C57Bl mice no labeled cardiomyocyte nuclei were revealed. One hour after the dynamic stress, 0.3 ± 0.2% of cardiomyocyte nuclei of the C57Bl mice incorporated ³H-thymidine. In the mdx mice, 2.9 ± 0.5% of cardiomyocyte nuclei incorporated ³H-thymidine. At 24 h after the stress and ³H-thymidine administration the percentage of cardiomyocyte nuclei in the mdx mice fell to 0.4 ± 0.2%. In the C57Bl mice primarily labeled nuclei were not revealed. The ³H-thymidine incorporation is not associated with entrance of cardiomyocytes into the mitotic cycle; we consider it as a manifestation of reparative DNA synthesis. We conclude is that the disappearance of DB in DNA from the mdx mouse myocardium 24 h after the dynamic stress is associated both with DNA reparation and the loss of cardiomyocytes.     

Cardiomyocyte survival and DNA reparation in myocardium of C57Bl/6 and mdx mice after dynamical stress

The cardiomyocytes of mdx mice are the prospective model of research on the survival of terminally differentiated cardiomyocytes and the formation of cardiomyopathy in conditions of oxidative stress. Previously, it was observed that dynamical stress induces the formation of low-molecular fragments of DNA. It is beyond questioning that DNA fragmentation develops through the formation of double-strand breaks in DNA (DNA DSB). To record the appearance and disappearance of DSB DNA in the cardiomyocytes of mdx mice after dynamic stress, the antibodies were applied to the phosphorylated form of an H2Ax histon (γ-H2Ax). In the absence of stress, DSB DNA were detected in the nuclei of cells of the myocardium for C57Bl/6 mice (0.05%) and for mdx mice (6.7%), accordingly. For C57Bl mice, 1 h after stress, the share of marked cardiomyocyte nuclei increased up to 1% and, for mdx mice, up to 41.7%. 24 h after stress, in the myocardium of mdx mice, 5.2% of cardiomyocytes in the nuclei were stained, while, for C57BL/6 mice, marked cardiomyocytes in the nuclei were not determined. 24 h after stress, the cell loss of cardiomyocytes for mdx mice was 2.39–2.50%. For C57Bl mice, the general level of cell loss did not exceed a threshold of 0.38%. The obtained data allow us to suspect that, during the survival of cardiomyocytes in mdx mice, a mechanism of DNA reparation is involved.     

Ultrastructural and morphometrical analysis of apoptosis stages in cardiomyocytes of MDX mice

Our previous study of apoptosis in mdx mouse myocardium cells demonstrated the presence of middle-sized DNA fragments (60-65 kbp) in extracts of myocardium DNA, and irregular shape of membrane enveloped nuclei in cardiomyocytes. The DNA fragmentation (DNA laddering) was observed after biomechanical stress (5 min sweeming) only. Based on these results we concluded that the majority of cardiomyocytes were at the first stage of apoptosis. The purpose of this work was to provide some morphometrical quantitive characteristics of ultrastructural properties of the nuclei and mitochondria, and to determine morphological patterns of apoptosis in cardiomyocytes of mdx and C57B1 mice. To resolve the task, we made a morphometrical analysis of the electron microscope images of nuclei and mitochondria. First of all, we divided all nuclear images into three categories: normal, semi-pathological, and pathological forms according to the extent of nuclear membrane invaginations and that of condensed chromatin spreading. The most part of C57B1 cardiomyocyte nuclei belonged to the normal form (88.9 +/- 4.3%), while the smaller part (11.1 +/- 4.3%) was regarded as semi-pathological forms. Just a reverse was observed in mdx mice: the largest part of cardiomyocytes fell into category of semi-pathological (54.6 +/- 4.4%) and pathological (31.5 +/- 4.1%) forms while, the smallest part belonged to the normal form (13.8 +/- 3.0%). 24 h after biodynamic stress, the quantity of normal nuclei of C57B1 cardiomyocytes decreased to 61 +/- 5%, the number of semi-pathological nuclei increased to 39.0 +/- 4.4% (P < 0.05). The number of pathological nuclei of mdx, cardiomyocytes fell to 15.4 +/- 3.0% (P < 0.05). It means that mdx cardiomyocytes with pathological form of their nuclei disappear because of emerging the second, destructive stage of apoptosis. To estimate the degree of ultrastructural changes in the nuclei of all three forms of cardiomyocytes we counted the square/perimeter ratio in each nucleus (circle shape factor; CSF). The value of CSF for normal nuclei of all the forms of cardiomyocytes varied between 0.65 +/- 0.02 and 0.71 +/- 0.04. In semi-pathological and pathological nuclei a significant decrease in CSF to 0.56 +/- 0.02 and 0.56 +/- 0.03 was observed, respectively (P < 0.05). The biodynamical stress did not reduce the CSF value below this level. We also counted the ratio of the square to the product of a long and a short axes (ellipse shape factor; ESF). The ESF value for normal nuclei of all forms of cardiomyocytes varied between 0.97 +/- 0.01 and 0.99 +/- 0.01. In the case of mdx mice the biodynamical stress reduced ESF to 0.95 +/- 0.01 (P < 0.05) for pathological form of nuclei. The specific density of mitochondria in mdx cardiomyocytes (0.274 +/- 0.016) was less than that in C57B1 cardiomyocytes (0.329 +/- 0.018). At the destructive stage of apoptosis, the nuclei of cardiomyocytes were round in shape, the nuclear chromatin being hypercondensed, and mitochondria swollen. The cardiomyocyte morphology was in agreement with the definition of the final stage of apoptosis as secondary necrosis. Morphometrical results show that as many as 86-90% of nuclei of mdx cardiomyocytes have abnormal structure that confirms our conclusion that mdx cardiomyocytes were at the first stage of apoptosis. The final stage of apoptosis is rarely observed by biochemical or morphological methods. It suggests the presence of some inner mechanisms regulating the initiation of the final (destructive) stage of mdx cardiomyocyte apoptosis.     

Stress-induced DNA fragmentation in cardiomyocytes of MDX and C57Bl mice

The study deals with apoptosis of cardiomyocytes of adult mdx mice. Our previous investigation of the total DNA from mdx mice myocardium in 0.5% agarose and 5% PAAG revealed middle sized DNA fragments about 64 kb only. The DNA electrophoresis in 5% PAAG after alpha-32P-dATP incorporation into DNA, fragments mediated by terminal transferase, showed no presence of smaller DNA fragments. The low size DNA fragments (0.2, 0.4 and 11.0 kb) were observed only following stress (a 5 min swimming in water bath) by means of alpha-32P-dATP incorporation mediated by TdT reaction. DNA fragmentation lasted for 48 h after the stress. A study of the total DNA extracts of C57B1 mice also demonstrated middle and low molecular sized DNA fragmentation 2 h after the stress under the same condition of the experiment. But during the next 48 h the signs of DNA fragmentation of the total DNA disappeared. The authors conclude that the first stage of apoptosis is a permanent property of cardiomyocytes of mdx mice.     

Gene hACR-1 suppresses apoptosis of striated muscle fibres of m. quadriceps femoris after ballistic transfection of mdx mice

Human minidystrophin gene (pSG5dys plasmid) and hACR-1 gene (pRc-CMV-10.1 plasmid) were cotransfected by means of "gene-gun" to M. quadriceps femoris of mdx mice. Effects of transfection on dystrophin expression and survival of striated muscle fibres (SMF) were studied on the 21st day after shots. In the control mdx dystrophin-positive muscular fibers [D(+)] SMF and destroyed SMF made 2.1 +/- 0.1 and 2.1 +/- 0.3%, respectively. In mice transfected with pSG5dys plasmid (20 mkg of DNA per mouse), the shares of D(+) SMF and dead SMF raised, respectively, up to 5.6 +/- 1.4 and 4.5 +/- 0.9%. Transfection of mice with pRc-CMV-10.1 (DNA dose is 20 mkg per mouse) reduced the levels of apoptosis in SMF and D(+) SMF level to 1.6 +/- 0.6 and 1.1 +/- 0.4%, respectively. Cotransfection by pSG5dys and pRc-CMV-10.1 plasmids (10 and 10 mkg of each plasmids DNA per mouse) reduced the share of D(+) SMF to 1.1 +/- 0.5% and SMF destruction to 0.9 +/- 0.3%. pSG5dys transfection considerably reduced the share of SMF having peripherally located nuclei, thus indicating a decrease in SMF differentiation level after transfection. Cotransfection of ACR-1 gene and a dystrophin minigene did not suppress further cytodifferentiation of mdx muscle fibers. A conclusion is made that ballistic transfection by hACR-1 gene reduces the level of apoptosis in mdx mice SMF without changing the level of SMF differentiation. The cotransfection of mdx mice muscle by hACR-1 and human minidystrophin gene reduces SMF destruction and supports SMF differentiation, too.     

Utrophin deficiency worsens cardiac contractile dysfunction present in dystrophin-deficient mdx mice

The loss of dystrophin in patients with Duchenne muscular dystrophy (DMD) causes devastating skeletal muscle degeneration and cardiomyopathy. Dystrophin-deficient (mdx) mice have a much milder phenotype, whereas double knockout (DKO) mice lacking both dystrophin and its homolog, utrophin, exhibit the clinical signs observed in DMD patients. We have previously shown that DKO and mdx mice have similar severities of histological features of cardiomyopathy, but no contractile functional measurements of DKO heart have ever been carried out. To investigate whether DKO mice display cardiac dysfunction at the tissue level, contractile response of the myocardium was tested in small, unbranched, ultrathin, right ventricular muscles. Under near physiological conditions, peak isometric active developed tension (F(dev), in mN/mm2) at a stimulation frequency of 4 Hz was depressed in DKO mice (15.3 +/- 3.7, n = 8) compared with mdx mice (24.2 +/- 5.4, n = 7), which in turn were depressed compared with wild-type (WT) control mice (33.2 +/- 4.5, n = 7). This reduced Fdev was also observed at frequencies within the murine physiological range; at 12 Hz, Fdev was (in mN/mm2) 11.4 +/- 1.8 in DKO, 14.5 +/- 4.2 in mdx, and 28.8 +/- 5.4 in WT mice. The depression of Fdev was observed over the entire frequency range of 4-14 Hz and was significant between DKO versus mdx mice, as well as between DKO or mdx mice versus WT mice. Under beta-adrenergic stimulation (1 micromol/l isoproterenol), Fdev in DKO preparations was only (in mN/mm2) 14.7 +/- 5.1 compared with 30.9 +/- 8.9 in mdx and 41.0 +/- 4.9 in WT mice. These data show that cardiac contractile dysfunction of mdx mice is generally worsened in mice also lacking utrophin.     

Image and DNA analysis of hypertrophic myocytes in hypertensive heart disease and hypertrophic cardiomyopathy

OBJECTIVE: To investigate differences in the pathophysiology of cardiac hypertrophy between patients with hypertensive heart disease (HHD) and hypertrophic cardiomyopathy (HCM). STUDY DESIGN: The study group consisted of 30 autopsied heart disease patients (10 HHD, 10 HCM and 10 noncardiac heart disease). DNA synthesis by hypertrophic cardiac myocytes was examined, and three-dimensional myocyte structure image was investigated. DNA synthesis and the cell cycle were investigated by flow cytometry using autopsy material. Three-dimensional myocyte structure image was visualized. RESULTS: The percentage of cells in G2M phase of the cell cycle was significantly decreased in the myocardium of autopsied hearts with HCM as compared with hearts with HHD (HCM:HHD = 1.2 +/- 1.1%: 7.7 +/- 2.6%, mean +/- SD). Hypertrophic myocytes of HCM characteristically possessed myocardial disarray and irregular side-to-side branch connections between myocytes. No myocyte disarray or irregular connections could be observed in HHD. CONCLUSION: These results suggest that the mechanism of cardiac hypertrophy differs between patients with HHD and HCM and also suggest dissimilar cell vitality and latent proliferative viability of hypertrophic myocytes in a hypertrophic process between HHD and HCM. That is, hypertrophic myocytes may be called "restricted" myocytes in a morphologic and biochemical sense.     

收缩活动促进新生大鼠培养心室肌细胞的^3H—亮氨酸...

To determine whether contraction could influence cell growth, the rate of protein synthesis (3H-leucine incorporation) and cell diameter and volume were measured in cultured neonatal rat cardiac myocytes beating spontaneously or arrested by high potassium. In medium supplemented with 10% calf serum, the 3H-leucine incorporation for 24 h in contracting myocytes (CMC) was significantly higher by 14.2% than that in quiescent myocytes (QMC), i.e. 1,229 +/- 29 cpm/10(5) cells vs. 1,076 +/- 60 cpm/10(5) cells (P < 0.01, n = 5 for each group). The cell diameter and cell volume in QMC group were respectively 15.14 +/- 0.42 microns and 1,842 +/- 123 microns3, while in the CMC group the corresponding figures reached to 16.82 +/- 0.64 microns3 and 2,495 +/- 210 microns3, increased by 11.1% and 35.5% respectively (P < 0.01, n = 6 for each group). With prolongation of culture time, the differences in these parameters between CMC and QMC became even more significant. In all these experiments, there was no significant difference in cell number between the two groups (P > 0.05). It is concluded that contraction per se can accelerate protein synthesis and cell growth in neonatal rat ventricular myocardium.     

Undifferentiated cells in the snail myocardium are capable of DNA synthesis and myodifferentiation

Cellular mechanisms of heart-muscle growth in the snail Achatina fulica have been studied using cytophotometry and electron microscopic autoradiography. Cytophotometric DNA measurements showed that the snail cardiomyocytes are mononucleated cells with diploid nuclei. Ultrastructural analysis of the snail myocardium revealed that, in addition to mature myocytes, it contains small roundish undifferentiated cells (UCs) and poorly differentiated muscle cells. EM autoradiography detected silver grains over the nuclei of UCs 2 h after injection of tritiated thymidine ([(3)H]Tdr), while the nuclei of both mature and poorly differentiated myocytes remained unlabeled. In EM autographs of the myocardial tissue fixed 14 days after [(3)H]Tdr administration, labeled myonuclei were evident, which may suggest some myodifferentiation of prelabeled UCs. Many labeled UCs persist for 14 days after a single [(3)H]Tdr injection, suggesting that not all UCs undergo myodifferentiation after passing through the cell cycle, and that those that do not can enter the next cycle. UCs in the snail myocardium presumably provide not only reserve but also stem cells for myocytes. Thus, the heart muscle of the adult snail consists of mononucleated diploid myocytes with blocked proliferative activity and a renewable population of precursor myogenic cells. The results obtained suggest that the growth of this muscle involves a myoblastic mechanism of myogenesis; this mechanism differs from that of vertebrate cardiac muscle growth, which is non-myoblastic-that is, based on proliferation or polyploidization of cardiomyocytes. Evolutionary aspects of cellular mechanisms of the heart-muscle growth are discussed.     

Influence of growth hormone and thyroxine on cell kinetics in the proximal tibial growth plate of Snell dwarf mice

In Snell dwarf mice, the influence of short-term treatment with human growth hormone (hGH) or thyroxine on the proliferative and sulphation activity of the proximal tibial growth plate was studied. By autoradiographic methods, the [3H]methylthymidine incorporation after a single injection was measured, after 2 hr incorporation time. The labelling index was calculated and the number of labelled mitoses was counted. In addition, the distribution of the labelled nuclei over the proliferating and degenerating zones was determined by continuous labelling for 25 and 73 hr. In untreated dwarf mice after [3H]-methylthymidine administration, the number of labelled nuclei in the growth plate is low. Labelling occurs, as expected, mainly in the cells of the proliferative zones. The number of labelled nuclei in control dwarf mice was similar after 25 and 73 hr continuous labelling. This suggests that many cells are in a resting G0 or prolonged G1 phase. Both hGH and T4 treatment induce a significant increase of the number of labelled nuclei per growth plate and of the number of mitoses. Since hormonal treatment induces a small number of mitoses after 2 hr incorporation of the label, the minimal G2 phase of the cell cycle is less than 2 hr. In addition, treatment with hGH and T4 stimulates chondrocytes in the zone of proliferative and hypertrophic cells to actively incorporate [35S]-sulphate.     

Lengthening-contractions in isolated myocardium impact force development and worsen cardiac contractile function in the mdx mouse model of muscular dystrophy

Lengthening-contractions exert eccentric stress on myofibers in normal myocardium. In congestive heart failure caused by a variety of diseases, the impact of lengthening-contractions of myocardium likely becomes more prevalent and severe. The present study introduces a method to investigate the role of stretching imposed by repetitive lengthening-contractions in myocardium under near-physiological conditions. By exerting various stretch-release ramps while the muscle is contracting, consecutive lengthening-contractions and their potential detrimental effect on cardiac function can be studied. We tested our model and hypothesis in age-matched (young and adult) mdx and wild-type mouse right ventricular trabeculae. These linear and ultrathin muscles possess all major cardiac cell types, and their contractile behavior very closely mimics that of the whole myocardium. In the first group of experiments, 10 lengthening-contractions at various magnitudes of stretch were performed in trabeculae from 10-wk-old mdx and wild-type mice. In the second group, 100 lengthening-contractions at various magnitudes were conducted in trabeculae from 10- and 20-wk-old mice. The peak isometric active developed tension (F(dev), in mN/mm(2)) and kinetic parameters time to peak tension (TTP, in ms) and time from peak tension to half-relaxation (RT50, in ms) were measured. Our results indicate lengthening-contractions significantly impact contractile behavior, and that dystrophin-deficient myocardium in mdx mice is significantly more susceptible to these damaging lengthening-contractions. The results indicate that lengthening-contractions in intact myocardium can be used in vitro to study this emerging contributor to cardiomyopathy.     

Participation of bone-marrow stem cells in the differentiation of mdx mice striated muscle

Two sets of experiments were carried out. The first one involved chimeric mice, obtained by intravenously injections of bone marrow derived cells taken from transgenic C57BL/6 mice, expressing GFP, to 5 Gy X-ray irradiated mdx or C57BL/6 mice. In 2 months M. quadriceps femoris of chimeric mice were destroyed by surgical clamp. Following the next 4-5 weeks, the same muscles were studied for the presence of GFP-positive striated muscle fibres. In the case of chimeric C57BL/6 mice GFP-positive striated muscle fibres were observed in 0.3 +/- 0.5 and in 0.2 +/- 0.3 % of destroyed muscle, and in lateral (control) muscle, consequently. In the case of chimeric mdx mice, positive results were observed in 1.7 +/- 0.4 and in 0.5 +/- 0.3 % of destroyed and control muscles, respectively. In the second set of experiments, the GFP-positive bone marrow cells were used for multiple intramuscular injections to M. quadriceps femoris of C57BL/6 or mdx mice in a dose of 2 x 10(5)-5 x 10(5) cells per mouse. Before injection, GFP-positive bone marrow cells were fractionated in a 63 % Percoll solution and then were exhausted from differentiated cells by magnetic manner using CD4, CD8, CD38, CD45R, CD119, Ly-6G, and F4/80 antibodies. After 2-3 weeks, as many as 0.15 +/- 0.40 and 0.1 +/- 0.2 % of GFP-positive muscle fibres were found in injected and control muscles of C57BL/6 mice, respectively. In the case of mdx mice, the frequency of GFP-positive striated muscle fibres was 2.0 +/- 0.8 and 1.2 +/- 0.6 % for injected and control muscles, respectively. A conclusion is made that bone marrow stem cells can take part in differentiation of mdx mouse muscles after their delivery by needle injections.     

Reinitiation of host DNA synthesis in senescent human diploid cells by infection with simian virus 40

Human diploid fibroblasts, TIG-1, cease to proliferate at about 60-62 population doubling level. In their senescent state used in this study, the percentage of nuclei labeled by [3H]thymidine for 48 h was around 1-2% in fresh medium containing 5-40% fetal bovine serum. The percentage of labelled nuclei increased up to 10-fold after infection with SV40. This increase reflects stimulation of cell DNA synthesis because: 1. The increase also occurred when ts A900 was used for infection at the non-permissive temperature, under these conditions viral DNA synthesis is inhibited; 2, the increase paralleled the stimulation of [3H]thymidine incorporation into DNA in a Hirt-precipitate fraction from SV40-infected cells. UV-irradiated SV40 had reduced ability to induce DNA synthesis. A viable deletion mutant of SV40, d1940, had almost the same activity to induce cell DNA synthesis as did wild-type SV40. Equilibrium density gradient centrifugation analysis of DNA labelled with 5-bromodeoxyuridine (BrdU) supported semiconservative replication rather than repair synthesis. We conclude that a considerable fraction of human diploid cells in a senescent population initiate host DNA replication by infection with SV40, although these cells cannot be stimulated with fetal bovine serum.     

Severe muscle dysfunction precedes collagen tissue proliferation in mdx mouse diaphragm.

After extensive necrosis, progressive diaphragm muscle weakness in the mdx mouse is thought to reflect progressive replacement of contractile tissue by fibrosis. However, little has been documented on diaphragm muscle performance at the stage at which necrosis and fibrosis are limited. Diaphragm morphometric characteristics, muscle performance, and cross-bridge (CB) properties were investigated in 6-wk-old control (C) and mdx mice. Compared with C, maximum tetanic tension and shortening velocity were 37 and 32% lower, respectively, in mdx mice (each P < 0.05). The total number of active CB per millimeter squared (13.0 +/- 1.2 vs. 18.4 +/- 1.7 x 10(9)/mm(2), P < 0.05) and the CB elementary force (8.0 +/- 0.2 vs. 9.0 +/- 0.1 pN, P < 0.01) were lower in mdx than in C. The time cycle duration was lower in mdx than in C (127 +/- 18 vs. 267 +/- 61 ms, P < 0.05). Percentages of fiber necrosis represented 2.8 +/- 0.6% of the total muscle fibers, and collagen surface area occupied 3.6 +/- 0.7% in mdx diaphragm. Our results pointed to severe muscular dysfunction in mdx mouse diaphragm, despite limited necrotic and fibrotic lesions.     

Utilization of the label from bacterial [3H] DNA by isolated barley roots and embryos under different conditions

[³H] DNA fromEscherichia coli and [³H] thymidine were applied, in sterile conditions, on isolated barley embryos and on roots excised from these embryos, both cultivated in the liquid medium and on halves of barley seeds, through the endosperm bridge. In embryos and roots, the labelled compounds were applied in 1.5% sucrose + 0.2 SSC alone, or together with either unlabelled thymidine or DEAE-dextran. Similar labelling indices were found after [³H] thymidine and [³H] DNA treatment which shows that the activity of [³H] DNA is utilized during the S phase. After application of [³H] thymidine, only cell nuclei in S phase were labelled. After the application of [³H] DNA an extranuclear label, in addition to the labelling of nuclei in the S phase, was observed in some experimental variants. The density of label above labelled nuclei after [³H] DNA treatment sharply decreased when unlabelled thymidine or DEAE-dextran was added, while the density of label above nuclei labelled by [³H] thymidine decreased when unlabelled thymidine but not DEAE-dextran was added. The labelling of nuclei with the label from [³H] DNA is the result of degradation of exogenous DNA reutilization of low molecular weight products. Extranuclear labelling is most probably due to the polymerous or partly degraded DNA.     

Distinctive patterns of basic fibroblast growth factor (bFGF) distribution in degenerating and regenerating areas of dystrophic (mdx) striated muscles

Mdx mice uniquely recover from degenerative dystrophic lesions by an intense myoproliferative (regenerative) response. To investigate a potential role of endogenous basic fibroblast growth factor (bFGF) in injury-repair processes, we investigated its localization in several striated muscles of mdx and control mice using immunofluorescence labeling with specific antibodies. Basic FGF was localized consistently to the myofiber periphery and nuclei of intact myofibers, as well as in single, dystrophin-positive cells in close association with the myofibers (potential myosatellite cells). In mdx mice, actively degenerating skeletal or cardiac muscle fibers presented intense cytoplasmic anti-bFGF staining prior to mononuclear infiltration. Small regenerating fibers in mdx skeletal muscle exhibited greater bFGF accumulation than adjacent larger myofibers. Strong nuclear anti-bFGF immunolabeling was frequently observed in mdx cardiac myocytes at the borders of necrotic regions. In agreement with differences in intensity of immunolabeling, extracts from slow-twitch muscles contained higher levels of bFGF compared to those from fast-twitch muscles, in both control and mdx mice. In addition, bFGF levels were consistently higher in extracts from all mdx tissues compared to those derived from their control counterparts. Our data suggest that bFGF participates in the degenerative and regenerative responses of striated muscle to dystrophic injury and also indicate a potential involvement of this factor with the physiology of different striated muscles.     

Consequences of cardiac myocyte-specific ablation of KATP channels in transgenic mice expressing dominant negative Kir6 subunits

Cardiac ATP-sensitive K+ (K(ATP)) channels are formed by Kir6.2 and SUR2A subunits. We produced transgenic mice that express dominant negative Kir6.x pore-forming subunits (Kir6.1-AAA or Kir6.2-AAA) in cardiac myocytes by driving their expression with the alpha-myosin heavy chain promoter. Weight gain and development after birth of these mice were similar to nontransgenic mice, but an increased mortality was noted after the age of 4-5 mo. Transgenic mice lacked cardiac K(ATP) channel activity as assessed with patch clamp techniques. Consistent with a decreased current density observed at positive voltages, the action potential duration was increased in these mice. Some myocytes developed EADs after isoproterenol treatment. Hemodynamic measurements revealed no significant effects on ventricular function (apart from a slightly elevated heart rate), whereas in vivo electrophysiological recordings revealed a prolonged ventricular effective refractory period in transgenic mice. The transgenic mice tolerated stress less well as evident from treadmill stress tests. The proarrhythmogenic features and lack of adaptation to a stress response in transgenic mice suggest that these features are intrinsic to the myocardium and that K(ATP) channels in the myocardium have an important role in protecting the heart from lethal arrhythmias and adaptation to stress situations.     

A rapid and strong apoptotic process is triggered by hyperosmotic stress in cultured rat cardiac myocytes

In all cell types, the maintenance of normal cell volume is an essential homeostatic function. Relatively little is known about the induction of apoptosis by hyperosmotic stress and its molecular mechanism in terminally differentiated cardiac myocytes. We compared the apoptotic response of cultured neonatal rat cardiomyoctes to hyperosmotic stress by sorbitol (SOR) with those induced by doxorubicin (Doxo) or angiotensin II (Ang II). We also examined the apoptotic-signaling pathway stimulated by the hyperosmotic stress. Apoptosis was assessed by the observation of: (1) cell viability, (2) DNA fragmentation detected by the TUNEL method and by agarose gel electrophoresis, and (3) poly(ADP-ribose)polymerase (PARP) degradation, and Bcl-XS and Bcl-XL levels by Western blot analysis. Exposure of cardiomyocytes to 0.3 M SOR for 24 h resulted in decreased cell viability and increased generation of oligosomal DNA fragments (2.5-fold of controls). At this time, 83 +/- 5% of SOR-treated myocytes were TUNEL-positive (vs 23.7 +/- 6.8% in controls; P<0.01). PARP levels also decreased by approximately 42% when cardiac myocytes were exposed to SOR. Hyperosmotic stress induced a more rapid and stronger apoptotic response in cardiomyocytes than Doxo or Ang II. In addition, SOR increased 3.2-fold Bcl-XS proapoptotic protein without changes in Bcl-XL antiapoptotic protein levels and in the p53-transactivating activity. Taken together, these results strongly suggest that hyperosmotic stress triggers cardiac myocyte apoptosis in a p53-independent manner, being earlier and stronger than apoptosis induced by Doxo and Ang II.     

Regeneration and DNA synthesis in cultures of rat heart ventricles after damage to the cellular layer

By means of the 3H-thymidine radioautography method replicative activity of myocytes and other cells in a dense layer of cellular culture of the traumatized ventricular myocardium has been studied in newborn (2-3-day-old) rats after lesion of the myocardium. Proliferation of the non-muscular cells is sharply suppressed after the cellular layer formation: their labelling index (LI) is 5.7 +/- 2.2% on the 8th day. Simultaneously, LI of unicellular myocytes is 25 +/- 6%, and that of binuclear ones, specific for the myocardium of mature animals is 6.4 +/- 2.9%. That demonstrates autonomy of DNA synthesis in myocytes from its suppression in the surrounding non-muscular cells. For 1-2 days after trauma intensive migration of fibroblasts into the wound is observed; they are often oriented perpendicularly to the edges of the cellular layer. There is an activation of DNA synthesis in the non-muscular cells in the wound area (in 20 h after the lesion LI is 73.4 +/- 1.7%) and in the layer edge directed to the wound LI is 23.9 +/- 0.0%, while in the depth of the zone situating close to the wound their LI is 7.8 +/- 2.4%. The replicative activity of mononuclear cardiomyocytes in the zone mentioned increases very weakly (LI 32 +/- 5%), and LI of binuclear ones is practically unchanged (6.1 +/- 2.3%). Karyo-kinetic activity is estimated by amount of binuclear cardiomyocytes and in the zone near the wound, in comparison to that in an intact layer, it does not change (35 +/- 3% and 34.4 +/- 2.5%).(ABSTRACT TRUNCATED AT 250 WORDS)