Delayed incorporation of H3-thymidine by primordial cells

Roots of Vicia faba were treated with H³-thymidine (1 c/ml) for 1 h and incorporation of H³-TdR into nuclei of primordia was studied. Large primordia (>1,500 cells) did not incorporate H³-TdR. Cells of small primordia did not incorporate the labeled precursor immediately but did so after a delay of several hours. The frequency of labeled nuclei became similar to that of lateral meristems only after a delay of 12–14 h. The gradual increase in labeling index also occurs in colchicine treated cells, which do not divide; this shows that the rise in labeling index is not due solely to the division of labeled cells. It has been estimated from H³-TdR and colchicine labeled cells that small primordia have a population of cells in which intermitotic time is about 12 h. The delay in incorporation appears to indicate that pools of H³-TdR can be maintained in small primordia for several hrs and that the precursor is not used until the cells synthesize thymidine kinase.This research has been supported by the U.S.A.E.C. [Grant AT (11-1) 1625-12].     

DNA biosynthesis in the muscular and connective tissue cells of the heart in experimental myocardial infarct

In 60 rabbits with experimental myocardial infarction induces by ligation of the anterior branch of the left coronary artery, DNA synthesis was studied by means of H3-thymidine in muscular and connective tissue cells depending on the period of myocardial infarction. The development of myocardial infarction in the cardiac muscle was stated to be accompanied by activation of DNA synthesis in the connective tissue cells not only in the necrotic zone but in the adjacent, as well as in distant areas of the myocardium and in stromal cells of the auriculum. Indices of H3-thymidine labeled nuclei were of high value during the acute period of myocardial infarction and gradually decreased with the time elapsed since the operation. During the period of the myocardical infarction organization high activity in DNA synthesis was revealed in connective tissue elements of the epicardium and the subepicardial zone of the heart. Myocardial cells of the cardiac auriculi incorporated H3-thymidine but extremely seldom-single labels per thousands of nuclei. In the auriculi with application of prolonged sessions of the labeled precussor introduction, DNA synthesising nuclei were revealed, sometimes with paired nuclei of cardiomyocytes.     

Morphological changes in rat skeletal muscle following reinnervation

Morphological changes appearing in the course of muscle regeneration after reinnervation of denervated M. soleus (slow) and M. tibialis anterior (fast) rat skeletal muscle were investigated. It was found that pathological changes typical for denervation atrophy (seen on the 10th day after crushing the sciatic nerve) and symptoms of regeneration (beginning about the 15th day) were much more pronounced in the soleus than in the tibialis muscle. Some stages of regeneration in the soleus muscle could be distinguished. The contractile material destructions were the first pathological changes that disappeared after the beginning of regeneration. In the second stage other denervation changes disappeared and intensive regeneration of muscle fibres was observed. In the next stage regeneration slowed down, and the reduction of the excess of muscle nuclei was visible. Four months after crushing the nerve, regeneration proceeded to completion with only some traces of the passed processes: in the soleus muscle, chains of sarcolemmal nuclei, satellite cells and newly formed muscle fibres were more often seen than in contralateral muscle; in the tibialis, collagen depots were present around the vessels and between muscle fascicles.     

Hmgb3 Is Regulated by MicroRNA-206 during Muscle Regeneration

Background

MicroRNAs (miRNAs) have been recently involved in most of human diseases as targets for potential strategies to rescue the pathological phenotype. Since the skeletal muscle is a spread-wide highly differentiated and organized tissue, rescue of severely compromised muscle still remains distant from nowadays. For this reason, we aimed to identify a subset of miRNAs major involved in muscle remodelling and regeneration by analysing the miRNA-profile of single fibres isolated from dystrophic muscle, which was here considered as a model of chronic damage.

Methodology/Principal Findings

The miRNA-signature associated to regenerating (newly formed) and remodelling (resting) fibres was investigated in animal models of muscular dystrophies and acute damage, in order to distinguish which miRNAs are primary related to muscle regeneration. In this study we identify fourteen miRNAs associated to dystrophic fibres responsible for muscle regeneration and remodelling, and confirm over-expression of the previously identified regeneration-associated myomiR-206. In particular, a functional binding site for myomiR-206 was identified and validated in the 3′untranslated region (3′UTR) of an X-linked member of a family of sequence independent chromatin-binding proteins (Hmgb3) that is preferentially expressed in hematopoietic stem cells. During regeneration of single muscle fibres, Hmgb3 messenger RNA (mRNA) and protein expression was gradually reduced, concurrent with the up-regulation of miR-206.

Conclusion/Significance

Our results elucidate a negative feedback circuit in which myomiR-206 represses Hmgb3 expression to modulate the regeneration of single muscle fibres after acute and chronic muscle damage. These findings suggest that myomiR-206 may be a potential therapeutic target in muscle diseases.     

Muscle tissue regeneration of the lymph hearts in adult Rana temporaria frogs. A study by light and electron microscopy autoradiography methods

The regeneration response of adult frog lymph heart muscle tissue was studied from 2 to 3 weeks after mechanical injury. High resolution autoradiographic studies showed that regenerative necrotic zones have many actively proliferating mononuclear cells deprived of cytoplasmic myofilaments. Some of them have numerous free ribosomes, so they might be identified as myoblasts. On the 13th day after injury newly-formed myotubes with chains of myonuclei and pictures of active sarcomerogenesis were observed. On the other hand, the surviving muscle fibers of the perinecrotic zone were rich in myonuclei at their growing ends. In the vicinity of nuclei, accumulation of a mass of non-differentiated cytoplasm rich in free ribosomes and polysomes, rough endoplasmic reticulum, Golgi apparatus, and centrioles are seen. Tritiated thymidine pulse-labeling showed that only rare myonuclei of the perinecrotic zone muscle fibers were labeled, whereas numerous non-differentiated cells of granulation tissue and myosatellites incorporated thymidine. The number of labeled myonuclei markedly increased 96 hours after 3HTdr administration. These data evidence that the myoblastic mechanism is predominant in the regeneration of adult frog lymph heart muscle tissue. It is necessary to emphasize that during the lymph heart muscle tissue reparative myogenesis some of the perinecrotic myonuclei are able to synthesize DNA and to divide mitotically, which distinguishes this type of muscle from skeletal muscle tissue of vertebrates.     

Metabolic DNA in the hepatocyte nuclei in newborn rats.

The behaviour in time of labelled nuclear DNA in the hepatocytes of newborn rats was studied using autoradiographic and biochemical techniques in two groups of experiments. In the first group H-3-thymidine was injected to the mothers at the 16th day of pregnancy and the amount of labelled DNA was evaluated in the newborns after delivery. In the second group H-3-thymidine was injected to the newborns two hours after birth and the labelled DNA was studied at the same time intervals as the first group. The amount of labelled thymidine incorporated into the first group of animals remains constant for the first three days of life, thereafter a reduction in specific activity of DNA is observed concomitant with an increase of the percentage of labelled nuclei and a decrease of the number of grains per nucleus. These results show that mitotic divisions, which are absent during the first three days of life, take place between the third and sixth days of life. The decrease of the specific activity is therefore due to dilution and not to loss of labelled DNA. In the second group of experiments the DNA labelled with H-3-thymidine shows a decrease by about 30--40% per day during the first three days of life accompanied by a decrease in the number of grains per nucleus without changes in the percentage of labelled nuclei. These data show that DNA synthesized during the first day after birth is metabolically unstable, unlike that synthesized during foetal life.     

Immunological reactions in the early onthogenesis of Atlantic salmon and humpback salmon

The data on the inflammation and regeneration processes in the Atlantic salmon and humpback salmon at the early stages of onthogenesis during the action of the damaging agent are presented. Phagocyte phenomena related to the physiological displacement of the yolk into the organs and tissues of embryos are observed in tissues of the developing embryos. Inflammation processes are accompanied by accumulation of tissue liquid in the mesoderm derivatives and by increase of hydrophilia of cellular elements. Formation of inflammation processes accompanied by simultaneous slowing of regeneration processes rate is registered in pre-larvae and larvae. Regeneration becomes the final stage of an organism reaction to the damage. Inflammation reaction components in juvenile salmon of the current year and yearlings are already developed. Phagocytes of the epithelial origin are found at the early stages of inflammation. A typical leucocyte wall is formed at the later inflammation stages. Epithelium is growing into the wound canal and separates dead cells from the cluster of leucocytes. Trauma of the striped muscle fibres in one area does not lead to necrosis of the whole muscle segment in the yearlings.     

Long-term culture of muscle explants from Sparus aurata

Although there are mammalian myoblast cell lines, no fish myoblast cell line has been developed so far. The aim of this study was to develop a culture system of muscle explants for fish, as explants provide an approximation of the in vivo conditions for cell proliferation and differentiation, and enable a close comparison with events in muscle regenerating in vivo. Here we describe the main features of a long-term in vitro culture system for muscle explants from Sparus aurata fry. At the time of sampling, the original fibres were damaged and subsequently degenerated as shown by the loss of parvalbumin (PV) and presence of apoptotic nuclei. This mechanical damage provoked a myogenic response by activation of myogenic precursor cells. After a few days, new mononucleate cells aligned with the original fibres were seen in the explants, some with proliferating cell nuclear antigen (PCNA-) and Myf-5-positive nuclei, indicating proliferation and their myogenic fate. By 1 week, multinucleate cells with desmin immunoreactivity but PCNA- and Myf5-negative nuclei were present, equivalent to differentiated, postmitotic myotubes. Some of these myotubes were also immunoreactive for PV and insulin-like growth factors (IGFs). By 11 days, many of the myotubes were also immunoreactive for myostatin (MSTN). By 23 days, many of the myotubes had increased in diameter, were packed with myofibrils, and were strongly PV-positive and immunoreactive for MSTN, IGF-I and IGF-I receptor. This study shows that a proliferative process occurs in the explants despite the death of the original muscle fibres, and new muscle fibres expressing growth regulators are formed by regeneration from myogenic precursors present in the explants at the time of sampling.     

Acetylcholine receptor distribution on regenerating mammalian muscle fibers at sites of mature and developing nerve-muscle junctions

When rat soleus muscles fibers regenerated after notexin-induced damage, AChRs were present at high density on the surface of the new muscle fibers at the sites of the original NMJs, even if the intact motor axons were not present during regeneration. Some AChR molecules which were labelled with R-BgTx before notexin-induced damage persisted for some days at junctional sites after new muscle fibres had regenerated. During muscle fiber degeneration, components of the muscle fiber plasma membrane appeared to remain longer in the junctional region than elsewhere. When muscles on which new "ectopic" NMJs had been forming for at least 2 weeks were damaged, AChR clusters together with sites of high AChE activity were present 2 weeks later on the regenerated muscles in the region of new NMJ formation, even if the "foreign" nerve was not intact during the period of regeneration. If ectopic NMJs had been forming for only 4 days at the time of muscle and nerve damage, neither AChR clusters nor AChE activity were detected on the regenerated muscle fibers.     

The ultrastructure and function of human skeletomuscular tissue]

The electron microscopic study of the intact somatic muscle of man has established that skeletal muscular fibres have a well developed lysosome apparatus. This apparatus is localized near nuclei under the sarcolemma and is represented by 3 types of lysosomes: primary lysosomes, secondary lysosomes (phage lysosomes, digestive vacuoles) and residual bodies. These three morphological types of lysosomes reflect different stages of the functional activity of these organelles. The role of the lysosome apparatus in the process of intracellular digestion and self-renewal is shown. The presence of a peculiar "digestive center" of the muscle fibre has been established which is located in the perinuclear zone.     

Satellite cells in movement disorders of various etiologies

The ultrastructural analysis of the muscle biopsy samples from patients with different neuro-muscular diseases revealed; both degeneration and regeneration of the muscle fibres. The number of satellite cells was increased due to their division and myonuclear segregation. Activated satellite cells were converted into myoblasts which probably could replace the injured fragments of the muscle fibres or form the myotubes. The process of muscle fibre regeneration is restricted not only by the damage of the muscle itself, but by the dystrophic process affecting satellite cells.     

Poor regenerative outcome after skeletal muscle necrosis induced by Bothrops asper venom: alterations in microvasculature and nerves

Background

Viperid snakebite envenoming is characterized by prominent local tissue damage, including muscle necrosis. A frequent outcome of such local pathology is deficient skeletal muscle regeneration, which causes muscle dysfunction, muscle loss and fibrosis, thus provoking permanent sequelae that greatly affect the quality of life of patients. The causes of such poor regenerative outcome of skeletal muscle after viperid snakebites are not fully understood.

Methodology/Principal Findings

A murine model of muscle necrosis and regeneration was adapted to study the effects of the venom and isolated toxins of Bothrops asper, the medically most important snake in Central America. Gastrocnemius muscle was injected with either B. asper venom, a myotoxic phospholipase A₂ (Mtx), a hemorrhagic metalloproteinase (SVMP), or saline solution. At various time intervals, during one month, tissue samples were collected and analyzed by histology, and by immunocytochemical and immunohistochemical techniques aimed at detecting muscle fibers, collagen, endothelial cells, myoblasts, myotubes, macrophages, TUNEL-positive nuclei, and axons. A successful regenerative response was observed in muscle injected with Mtx, which induces myonecrosis but does not affect the microvasculature. In contrast, poor regeneration, with fibrosis and atrophic fibers, occurred when muscle was injected with venom or SVMP, both of which provoke necrosis, microvascular damage leading to hemorrhage, and poor axonal regeneration.

Conclusions/Significance

The deficient skeletal muscle regeneration after injection of B. asper venom is likely to depend on the widespread damage to the microvasculature, which affects the removal of necrotic debris by phagocytes, and the provision of nutrients and oxygen required for regeneration. In addition, deficient axonal regeneration is likely to contribute to the poor regenerative outcome in this model.     

Intact testosterone receptor complex does not induce RNA synthesis of tfm-nuclei in multinucleated urethral muscle fibres of mosaic mice

Summary The X-linked testicular feminization mutation (Tfm) of the mouse leads to androgen insensitivity of target cells. Through the autosomal sex reversed (Sxr) factor we have converted female heterozygotes into males. Due to X-inactivation, mosaic animals arise which are composed of androgen sensitive wild-type and androgen insensitive Tfm cells. In the androgen dependent striated urethral muscle, Tfm and wild-type cells fuse and form multinucleated muscle fibres. In the muscle fibres the Tfm nuclei are exposed to the intact cytoplasmic testosterone receptor complex coded for by the wildtype nuclei. We ask the question whether under these conditions RNA synthesis can be stimulated in the Tfm nuclei. Castrated mosaic animals were injected with testosterone, and incorporation of ³H-uridine was studied by autoradiography. We found two classes of muscle cell nuclei, those with low grain counts corresponding to the Tfm controls and those with high grain counts corresponding to the stimulated male controls. The results indicate that the Tfm nuclei are not stimulated by the intact testosterone receptor complex.This study is dedicated to Prof. Dr. W. Graumann on occasion of his 65th birthday     

Thyroxine-induced cardiomegaly in rats of different age

In the present study the effect of thyroxine treatment on the development of cardiomegaly was compared in young (10-day-old) and adult (12-week-old) rats. L-thyroxine was administered subcutaneously in a dose of 1 mg per kg b.w. for 5 days. In young thyroxine-treated rats the heart weight increased by 79% in comparison with the control rats. The number of blood capillaries and muscle fibres per mm2 remained unchanged. The concentration of hydroxyproline was even lower than in control animals. The number of 3H-thymidine-labelled muscle cell nuclei was significantly higher both in the left and right ventricles of thyroxine treated rats. The density of capillaries and muscle fibres was significantly lower in adult rats than in the group of young animals. In adult thyroxine-treated animals the heart weight was higher by 36%, the number of capillaries and muscle fibres as well as the concentration of hydroxyproline was unchanged. Thyroxine induced significant increase in the number of DNA synthesizing nuclei of muscle cells in the left ventricle while the change in the right ventricular myocardium was not statistically significant. The present data indicate that a hyperplastic response of cardiac muscle cells to thyroxine occurs in both ventricles of young rats and also in the left ventricle of adult animals.     

Proliferation and differentiation of isolated cells and symplasts of the skeletal muscle tissue of chick embryos

By means of the radioautography, morphometry and alkaline dissociation methods musculus tibialis anterior has been studied in 30 chick embryos and chickens. The muscle fibers are variable in their diameter and length, number of nuclei 3H-thymidine-labelled including. The greatest variability of the structures is noted in 11-14-day-old embryos. Three classes of myotubes (MT) and symplasts are described. The primary MT are evidently the source of cellular elements, that form new cellular-symplastic structures (muscular-proliferative units) that develop, for some time, in a close connection with the primary MT. Between the extreme morphological variants of structure of the muscular elements, there is a transitional form. All the forms of the myosymplasts and MT reflect various stages of differentiation of the myogenic elements; this results in formation of the cellular-symplastic system--muscle fiber.     

Skeletal muscle regeneration in Xenopus tadpoles and zebrafish larvae

Background

Mammals are not able to restore lost appendages, while many amphibians are. One important question about epimorphic regeneration is related to the origin of the new tissues and whether they come from mature cells via dedifferentiation and/or from stem cells. Several studies in urodele amphibians (salamanders) indicate that, after limb or tail amputation, the multinucleated muscle fibres do dedifferentiate by fragmentation and proliferation, thereby contributing to the regenerate. In Xenopus laevis tadpoles, however, it was shown that muscle fibres do not contribute directly to the tail regenerate. We set out to study whether dedifferentiation was present during muscle regeneration of the tadpole limb and zebrafish larval tail, mainly by cell tracing and histological observations.

Results

Cell tracing and histological observations indicate that zebrafish tail muscle do not dedifferentiate during regeneration. Technical limitations did not allow us to trace tadpole limb cells, nevertheless we observed no signs of dedifferentiation histologically. However, ultrastructural and gene expression analysis of regenerating muscle in tadpole tail revealed an unexpected dedifferentiation phenotype. Further histological studies showed that dedifferentiating tail fibres did not enter the cell cycle and in vivo cell tracing revealed no evidences of muscle fibre fragmentation. In addition, our results indicate that this incomplete dedifferentiation was initiated by the retraction of muscle fibres.

Conclusions

Our results show that complete skeletal muscle dedifferentiation is less common than expected in lower vertebrates. In addition, the discovery of incomplete dedifferentiation in muscle fibres of the tadpole tail stresses the importance of coupling histological studies with in vivo cell tracing experiments to better understand the regenerative mechanisms.     

Is there "Metabolic" DNA in the Mouse Seminal Vesicle?

This study was designed to answer the question: Is H³-thymidine uptake by nuclei of the mouse seminal vesicle evidence for DNA synthesis and mitosis, or does it signify some "metabolic" function of DNA unrelated to chromosome duplication? Mice were given an intraperitoneal injection of H³-thymidine. Six hours later Feulgen squashes of the seminal vesicle epithelium were made and covered with autoradiographic stripping film. The silver grains above labeled nuclei were counted, and the Feulgen dye contents of these same nuclei were determined photometrically after removal of the grains from the emulsion. Unlabeled nuclei were also measured. The dye contents of non-radioactive nuclei form a unimodal distribution, indicating that polyploidy is absent from this tissue. The radioactive nuclei fall into two groups. In the first, the average dye content is the same as that of the cold nuclei (2C). In the second, the values range from 2C to 4C. In the 2C to 4C group the grain count is proportional to the dye content, showing that incorporation is correlated with synthesis. The radioactive 2C nuclei arose by mitosis during the course of the experiment. This is shown by the following facts: (1) They frequently occur in pairs. (2) They average smaller than unlabeled 2C nuclei. (3) Their average grain count is approximately half that of the 4C nuclei. (4) Labeled division figures are found. (5) A mitotic rate estimated from the number of labeled 2C nuclei accords reasonably well with one based on the number of observed mitoses. Since the incorporation of thymidine accompanies DNA synthesis and precedes mitosis, there is no reason to postulate a special "metabolic" DNA in this tissue.     

Localization of 3H-estradiol in the uterus of pregnant and non-pregnant armadillos

Summary The uptake and retention of radiolabeled estradiol by the uterus was examined in the armadillo. One pregnant and two non-pregnant armadillos were treated with 1.4 g/kg body weight of ³H-estradiol (E₂) by injection into the left ventricle, and one non-pregnant animal was injected with both the labeled hormone and 140 g/kg body weight of unlabeled E₂. One and a half hour after injection, the animals were sacrificed and the uteri were removed and processed for autoradiography. In the non-pregnant animals, nuclear localization was observed in the interstitial cells and glandular epithelium of the endometrium and the connective tissue cells and smooth muscle of the myometrium. Additionally, there was a gradation of uptake in the epithelial cells of the endometrium in that the glandular cells of the basal region were heavily labeled, while those cells in the sinusoidal, and luminal regions contained successively less label. The luminal cells were poorly labeled. In the pregnant female, the smooth muscle and glandular cells hypertrophied and their nuclei contained less label than was observed in the non-pregnant animals. The arteries of the myometrium were more easily distinguished in the pregnant animals and the nuclei of the endothelial cells and smooth muscle were more consistently labeled than those of the non-pregnant armadillos.     

Multinucleation during myogenesis of the myotome of Xenopus laevis: a qualitative study

Ultrastructural studies of myogenesis in the myotome of Xenopus laevis reveal that the myotubes developed by stage 33/34 have peripheral myofibrils but are still uninucleate with a single large nucleus. By stage 45, the cytoplasm of the muscle cells is filled with myofibrils and there are many small peripheral nuclei, resulting in multinucleate muscle fibres. With the electron microscope, we have examined myotomes from stages 33/34 to 59 of development and some stages were also investigated by autoradiography. There was no evidence from autoradiographic studies for DNA synthesis in muscle cells, and the increase in the number of myonuclei was accompanied by a decrease in their size. Satellite cells were not seen at the myotube stage but were first seen after the cells had become multinucleate, with many small nuclei close together forming rows. Constrictions were frequently observed in the large single nuclei. It is concluded that division of the myonuclei by amitosis is mainly responsible for the multinucleation that occurs during development of the myotome muscle in Xenopus laevis.     

The expression of vimentin in satellite cells of regenerating skeletal muscle in vivo

Summary The expression of the intermediate filament protein, vimentin, was studied in skeletal muscle during a cycle of degeneration and regeneration. Venom from the Australian tiger snake,Notechis scutatus scutatus, was used to initiate the breakdown of the soleus muscle of young, mature ratsin vivo. Cryosections and Western blots of muscle samples were labelled using antibodies to vimentin, and examined at fixed time points after venom injection. Vimentin was absent in control adult muscle fibres, but was identified in activated satellite cells 12 h after venom assault. The amount of this protein rose during the early stages of regeneration, reaching its peak at 2–3 days. At this time, the expression of muscle-specific intermediate filament protein, desmin, began. As the abundance of desmin increased with the maturation of the regenerating myofibres, the abundance of vimentin declined until it was no longer detectable in mature regenerated fibres. It is suggested that vimentin plays an important role during satellite cell activation in the early stages of regeneration, and that the expression of vimentin may act as a stimulus for the expression of desmin at later stages of regeneration.