Differentiation of Purkinje fibres and ordinary ventricular and atrial myocytes in the bovine heart: an immuno-and enzyme histochemical study

Summary The differentiation of Purkinje fibres and ordinary ventricular and atrial myocytes in bovine hearts was studied with specific antibodies against M-line proteins (MM-creatine kinase and myomesin) and with enzyme histochemistry (succinate dehydrogenase and mitochondrial glycerol-3-phosphate dehydrogenase). MM-creatine kinase was detected at an earlier stage in Purkinje fibres and atrial myocytes than in ordinary ventricular myocytes. The findings are in agreement with previous ultrastructural observations that an earlier appearance of a dense M-band occurs in Purkinje fibres than in ordinary ventricular myocytes. Myomesin was detected in all three cell types even at early foetal stages, in accordance with suggestions that it is an integral component of the myofibrillar structure. The activity of succinate dehydrogenase gradually increased in both ordinary ventricular and atrial myocytes, while the activity of mitochondrial glycerol-3-phosphate dehydrogenase was high at different stages of early foetal development in the two tissues, finally becoming low in the adult stage. The activity of succinate dehydrogenase and mitochondrial glycerol-3-phosphate dehydrogenase seemed to remain unchanged in the Purkinje fibres from early to late foetal stages. The present study shows that the Purkinje fibres are already different from ordinary ventricular myocytes at early foetal stages and that the two cell types differentiate in different ways. It is concluded that there are also developmental differences between ordinary ventricular and atrial myocytes.     

Composition and ultrastructure of elasmobranch granulocytes. I. Dogfishes (Squaliformes)

The blood granulocyte composition of 10 species of dogfish is given, together with ultrastructural observations made on Etmopterus baxteri Leydig organ and blood, and on spleens of Oxynotus bruniensis, Deania calcea, Scymnodon plunketi and blood of Centroscymnus crepidator . Neutrophilic granulocytes, which were common, had spherical granules that developed a dense core, which then lost contents to become lucent. Eosinophilic granulocytes had ovoid or elongated granules with a fibrillar content that became aligned longitudinally, and rarely formed an axial rod. Eosinophils had large spherical granules that were electron-dense but in early stages had a disorganised fibrillar content. These cells correspond to the neutrophils, heterophils and eosinophils, respectively, of other elasmobranchs.
Dogfish granulocytes are compared with those of other elasmobranchs, and their lack of similarity to those of higher vertebrates is noted.     

Scanning electron microscope observations of Amoeba proteus during phagocytosis.

Phagocytosing Amoeba proteus at different stages of forming foodcups have been observed by scanning electron microscopy. A nonphagocytosing ameba is characterized by dorsal and lateral ridges running longitudinally over the posterior half of the cell and its attachment to the substrate over small areas. When stimulated by prey organisms, the ameba loses polarity and ridges, and adheres to the substrate more firmly over a wider area of contact. Then it forms broad pseudopods to surround its prey and this results in the formation of foodcups. The surface of all ameba is covered with small projections, and membranous blebs are often seen on the surface of phagocytosing organisms.     

Distribution of elastic system fibers in the peripheral nerves of mammals

Various nerves of 6 representative species of mammals (including the human) were studied by the comparative association of the selective staining methods of light microscopy with the ultrastructural observation after tannic acid-glutaraldehyde fixation, which provided a reliable means of characterizing the different elastic system fibers. Although mature elastic fibers are not present in nerves, elastic-related fibers are frequently observed: oxytalan fibers are found mainly in the endoneurium, whereas elaunin fibers predominate in the epineurium. These fibers are longitudinally disposed, in a parallel orientation to the axons. The fact that these findings were consistently observed in the nerves of all species studied argues strongly in favor of the existence of a uniform structural pattern of distribution of elastic system fibers in nerves as a general phenomenon in mammals.     

Ultrastructural characteristics of elastogenesis in the major arteries of the canine hindlimb during leg lengthening

In mature dogs ultrastructural peculiarities of elastogenesis in femoral and anterior tibial arteries have been studied at various stages of the bone elongation after Ilizarov method. From the end of the 1st week of distraction, metabolic activation of intimal smooth muscle cells is revealed, from the 2d week--in the middle tunic, and on the 5th-6th week--fibroblasts of adventitia of the arteries investigated, directed to biosynthesis of intracellular predecessors of elastin and microfibrils of the elastic fibers. This results in activation of elastogenic processes, elastic structures in all three tunics of the arteries are observed to newly form and rearrange. The factor that stimulates and maintains elastogenesis is strain of extension, that occurs in the vessels during the experiment. Elastogenesis in the major arteries, when the extremity is elongated, has much in common with development of elastic components in the vascular wall in animals during the process of physiological growth.     

Scanning Electron Microscope Observations of Amoeba proteus During Phagocytosis*

SYNOPSIS. Phagocytosing Amoeba proteus at different stages of forming foodcups have been observed by scanning electron microscopy. A nonphagocytosing ameba is characterized by dorsal and lateral ridges running longitudinally over the posterior half of the cell and its attachment to the substrate over small areas. When stimulated by prey organisms, the ameba loses polarity and ridges, and adheres to the substrate more firmly over a wider area of contact. Then it forms broad pseudopods to surround its prey and this results in the formation of foodcups. The surface of all amebae is covered with small projections, and membranous blebs are often seen on the surface of phagocytosing organisms.     

Development and ultrastructure of the neuromuscular junction in bronchial smooth muscle tissue

At various stages of pre- and postnatal ontogenesis ultrastructure of contacts of smooth myocytes and nervous terminals in the white mice bronchial wall has been investigated. Nervous fibers grow into the forming tissue of the lung beginning from the 11th day of embryogenesis. By the end of the prenatal development the nervous fibers fasciculi with varicosites and having vesicles are localized at the distance of 100-300 nm from the developing myocytes. Formation of dense neuromuscular junctions with the distance of 35-60 nm between the axonal membranes and the myocyte is observed on the 10-15 day after birth. In mature animals combination of various types of neuromuscular connections is revealed; they ensure local and distant neurotrophic regulation. In the bronchial smooth musculature afferent connections are revealed, as well as connections of myocytic processes with the effectors. Terminals of the cholinergic type predominate, adrenergic effectors occur very seldom. There are terminals, in which combination of vesicles having various structure and diameter are observed.     

Myocardin is differentially required for the development of smooth muscle cells and cardiomyocytes

Myocardin is a serum response factor (SRF) coactivator exclusively expressed in cardiomyocytes and smooth muscle cells (SMCs). However, there is highly controversial evidence as to whether myocardin is essential for normal differentiation of these cell types, and there are no data showing whether cardiac or SMC subtypes exhibit differential myocardin requirements during development. Results of the present studies showed the virtual absence of myocardin(-/-) visceral SMCs or ventricular myocytes in chimeric myocardin knockout (KO) mice generated by injection of myocardin(-/-) embryonic stem cells (ESCs) into wild-type (WT; i.e., myocardin(+/+) ESC) blastocysts. In contrast, myocardin(-/-) ESCs readily formed vascular SMC, albeit at a reduced frequency compared with WT ESCs. In addition, myocardin(-/-) ESCs competed equally with WT ESCs in forming atrial myocytes. The ultrastructural features of myocardin(-/-) vascular SMCs and cardiomyocytes were unchanged from their WT counterparts as determined using a unique X-ray microprobe transmission electron microscopic method developed by our laboratory. Myocardin(-/-) ESC-derived SMCs also showed normal contractile properties in an in vitro embryoid body SMC differentiation model, other than impaired thromboxane A2 responsiveness. Together, these results provide novel evidence that myocardin is essential for development of visceral SMCs and ventricular myocytes but is dispensable for development of atrial myocytes and vascular SMCs in the setting of chimeric KO mice. In addition, results suggest that as yet undefined defects in development and/or maturation of ventricular cardiomyocytes may have contributed to early embryonic lethality observed in conventional myocardin KO mice and that observed deficiencies in development of vascular SMC may have been secondary to these defects.     

Ultrastructural organization of the septum pellucidum in dogs subjected to long-term partial intraspecific isolation

The dogs have been kept under conditions of a partial intraspecific isolation for a long time, beginning from early stages of the postnatal ontogenesis. The reactive changes in neurons, interneuronal contacts are shown to produce proliferation of neuroglial cells and a number of their ultrastructural reorganizations. Phagocytic cells--astrocytes and microgliocytes--activate. However, enhancement of trophic processes is noted, manifesting itself as hyperplasia of lamellar processes of astrocytes in the neuropil, as an increased number of neurons with subsurface cisterns, in their area an astrocyte process is constantly revealed.     

Cell formation by myxozoan species is not explained by dogma

Eukaryotes form new cells through the replication of nuclei followed by cytokinesis. A notable exception is reported from the class Myxosporea of the phylum Myxozoa. This assemblage of approximately 2310 species is regarded as either basal bilaterian or cnidarian, depending on the phylogenetic analysis employed. For myxosporeans, cells have long been regarded as forming within other cells by a process referred to as endogenous budding. This would involve a nucleus forming endoplasmic reticulum around it, which transforms into a new plasma membrane, thus enclosing and separating it from the surrounding cell. This remarkable process, unique within the Metazoa, is accepted as occurring within stages found in vertebrate hosts, but has only been inferred from those stages observed within invertebrate hosts. Therefore, I conducted an ultrastructural study to examine how internal cells are formed by a myxosporean parasitizing an annelid. In this case, actinospore parasite stages clearly internalized existing cells; a process with analogies to the acquisition of endosymbiotic algae by cnidarian species. A subsequent examination of the myxozoan literature did not support endogenous budding, indicating that this process, which has been a central tenet of myxozoan developmental biology for over a century, is dogma.     

Changes in three-dimensional structure of the internal elastic membrane of rat aorta after its mechanical injury and regeneration

By means of scanning electron microscopy of chemically extracted preparations the dynamics of changes in the three-dimensional structure of the internal elastic membrane (IEM) of the rat aorta has been investigated after its lesion by a vascular clip. The mechanical lesion results in rupture of the IEM along external borders of the instrument lips and in crushing of its central part. A niche is formed, along its periphery it is surrounded with a practically intact IEM. The aorta regeneration is accompanied with neoelastogenesis. In the center of the niche newly formed elastic structures appear later, but the IEM reparation develops more actively. During the neoelastogenesis some stages are distinguished: at first separate elastic fibers appear, which then anastomosed, uniting into fasciculi and laminae. It is supposed that the IEM-restoration at regeneration depends on synthetic activity of smooth myocytes and on the other hand, the changes in the IEM structure can regulate their migration and metabolism.     

Comparative ultrastructural analysis of the in vitro microspore embryoids and in vivo zygotic embryos of wheat as a basis for understanding of cytophysiological aspects of their development

Ultrastructures of in vitro microspore embryoids and in vivo zygotic embryos of spring wheat have been analyzed and compared. Along with the similarity of ultrastructural characteristics of embryoid and embryo cells at the corresponding developmental stages, some differences have been revealed. Unlike embryos, embryoid cells are characterized by lipid inclusions and numerous mitochondria with well-developed internal membranes. According to our hypothesis, lipids represent an alternative energy source required for active cell divisions in the forming embryoids. Unlike embryos, since the earliest developmental stages, embryoid cells accumulate a significant amount of starch and then utilize it during the organogenesis and germination. A conclusion has been made that embryoid cells create their own reserve of carbohydrates, which is then mobilized during their development. The concept of T.B. Batygina (1987, 1997, 2014) about the universal character of the plant morphogenesis in vivo, in situ, and in vitro has been confirmed. The prospects for the use of microspore embryoidogenesis in vitro as a model to study cytophysiological aspects of zygotic embryogenesis in vivo are discussed.     

Ultrastructural study of specialized conducting and working myocytes in the sinoatrial region of the human heart. I. Qualitative analysis

A qualitative ultrastructural analysis of specialized conducting and working myocytes in the sinoatrial region of the human heart was made using autopsied and biopsied material from 45 men and women. Autopsied material was prepared not later as than 3 hours after the death. Biopsied material was taken during the operation for surgical correction of disturbances of cardiac rhythm and conduction. Cell contacts of light and dark myocytes within the sinus node, and of working myocytes of the right atrium were evaluated. The ratio of light to dark myocytes in the sinus node were estimated from both dead people and patients. The principles of correct ultrastructural classification of conducting and working myocytes in human heart are discussed.     

Age-related structural and functional characteristics of cardiac myoendocrine cells of rats in a normal state and with hereditary hypertension

A qualitative and quantitative ultrastructural study of right atrial cardiomyocytes in WAG (normotensive control) and ISIAH (inherited stress-induced arterial hypertension) rats of different age (on day 18 of embryogenesis, on days 12 and 21 after birth, and at an age of 6 and 13 months) was performed. It was shown that, in embryos with an as yet incomplete atrial morphogenesis, secretory granules containing natriuretic peptides are actively formed, accumulated, and dissolved. In postnatal ontogeny, the secretory product is accumulated in atrial cells. In all ontogeny stages studied, the numerical density of secretory granules in the myoendocrine cells of hypertensive rats is greater and the qualitative composition of these granules is more diverse than in the control. It was established that, in atrial myocytes of ISIAH rats, the morphological signs of natriuretic peptide hypersecretion precede the development of genetically programmed high blood pressure. In adult hypertensive rats, hypertrophic and degenerative changes in myocytes are accompanied by excessive accumulation of secretory granules, some of which undergo intracellular degradation.     

The association of desmin with the developing myofibrils of cultured embryonic rat heart myocytes

The association of desmin, a 55,000-dalton intermediate-filament protein, with the developing cardiac myofibril was studied by immunocytochemical methods in primary cultured myocytes isolated from embyronic rat hearts at different ages. In the earliest contractile myocytes obtained from 10-day-old embryonic hearts, desmin exists as an extensive cytoskeletal network with little or no association with the myofibrils. As the heart develops the cytoskeletal desmin undergoes the myofibrils. Initially, the cytoskeletal desmin appears to outline the developing myofibril as short, discontinuous filaments. At intermediate stages of heart development, desmin filaments in 12- to 16-day-old embryonic myocytes continue to outline the forming myofibrils. Associated with these filaments are crossbridges and foci of desmin spaced at a frequency equal to that of the Z-line spacing. Desmin becomes progressively associated with the myofibril from the central region of the cell toward the cell margin. Desmin filaments at this stage begin to coalesce in the region of the intercalated disk. In the early neonatal heart, desmin of the Z lines becomes continuous across the sarcomere and appears to integrate the myofibrils into a unit. These observations suggest that desmin is not required in the early stages of mammalian heart development for the initial assembly of cardiac sarcomeres or the initiation of cardiac myofibrillar contractions. In later stages of mammalian heart development, desmin is found associated with the cardiac myofibrils in such a manner as to stably integrate these elements into the cytoplasm. Additionally, desmin, in the Z lines of the more mature myocytes appears to maintain the myofibrils in close registry to each other and to the intercalated disk.     

Ultrastructure of the pulmonary trunk wall during the prenatal period of ontogenesis

By means of transmissive electron microscopy stages of morphogenesis have been studied in the pulmonary trunk wall of 12 healthy human embryos and fetuses of 5-24-week-old. There is a close dependence in development of the smooth muscle component of the middle tunic, elastic and collagenous fibers of the pulmonary trunk wall. In the early prenatal morphogenesis of the pulmonary trunk fibrillogenesis develops intensively, overtakes the differentiation time of myocytes from mesenchymal cells, the collagenous fibers appearing earlier than the elastic ones. The structures, that ensure solidity of the vascular wall (collagenous fibers), appear in embryogenesis earlier that those, ensuring its elasticity (ability to reversible deformity).     

Ultrastructure of intercellular contacts of smooth myocytes of the respiratory tract

By means of electron microscopy at various stages of pre- and postnatal ontogenesis in rats and mice intercellular connections of smooth myocytes, included into the bronchial wall composition, have been investigated. Interaction of the smooth myocytes is ensured with numerous and various types of specialized connections. Certain modifications of the nexus structure are described, they, perhaps, depend on the level of conformational changes of connexons--protein molecules, included into its composition and responsible for intensity of transfer of ions and metabolites. Between the smooth myocytes a contact, that was not previously described, is revealed. It is presented with a complex, formed by vesicular structures, concentrated in the area of oriented in parallel electron opaque membrane area of the interacting cells. Owing to the presence of punctate contacts, not only at early stages of development, but also in the definitive tissue, it is possible to consider them as an independent type of specialized connections, and not as immature forms of gap junctions. There are not any essential differences in the structure and distribution of the contacts during the time of the investigation.     

Distribution pattern of connexin 43, a gap junctional protein, during the differentiation of mouse heart myocytes

In the cardiac muscle, the electrical coupling of myocytes by means of gap (or communicating) junctions, allows the action potentials to be propagated. Connexin 43 (CX 43) is the major constitutive protein of the gap junctions in the mammalian myocardium. In this organ, the abundance of CX 43 and of its messenger, as well as the spatial expression of this protein, are developmentally regulated. These findings are complemented by the results presented in this article, which deals with the distribution of CX 43 in the ventricular myocytes of mouse heart during differentiation, between the 11 days post coitum embryo stage and adulthood. By immunoelectron microscopy experiments on ultrathin sections of cardiac ventricular tissue of one-week-old mouse, we have provided confirmation that the anti-CX 43 antibodies used here specifically recognized the gap junctions. Double labeling immunofluorescence experiments have been undertaken to localize, within the same cells, either CX 43 and desmin, or CX 43 and Con A or WGA receptor sites. From the earliest stage investigated (11 days post coitum) onwards, expression of CX 43 is always associated with desmin-positive cells, that is, with the myocytes. Up to birth, there is in the ventricular wall a gradient of expression of CX 43 which is superimposable on a gradient of expression of desmin. Immunoreactivity to anti-CX 43 and anti-desmin antibodies is high in the sub-endocardial trabeculae and low (or even undetectable for CX 43, in the early stages) in the sub-epicardial cell layers. In the embryonic stages, the expression sites of CX 43 are visible in the form of small dots, whose abundance increases as development proceeds. During these stages, the immunoreactive sites are distributed in a relatively homogeneous pattern throughout the membrane of the myocytes. One week after birth, the CX 43 expression is restricted to the two ends of the myocytes (where the intercalated discs develop), and the adjacent lateral regions. This polarization of CX 43 is more pronounced at the two and three weeks post natal stages and in the fully differentiated ventricular myocytes (adult stage) CX 43 is only present in the intercalated discs.     

Cardiac Myocyte Diversity and a Fibroblast Network in the Junctional Region of the Zebrafish Heart Revealed by Transmission and Serial Block-Face Scanning Electron Microscopy

The zebrafish has emerged as an important model of heart development and regeneration. While the structural characteristics of the developing and adult zebrafish ventricle have been previously studied, little attention has been paid to the nature of the interface between the compact and spongy myocardium. Here we describe how these two distinct layers are structurally and functionally integrated. We demonstrate by transmission electron microscopy that this interface is complex and composed primarily of a junctional region occupied by collagen, as well as a population of fibroblasts that form a highly complex network. We also describe a continuum of uniquely flattened transitional cardiac myocytes that form a circumferential plate upon which the radially-oriented luminal trabeculae are anchored. In addition, we have uncovered within the transitional ring a subpopulation of markedly electron dense cardiac myocytes. At discrete intervals the transitional cardiac myocytes form contact bridges across the junctional space that are stabilized through localized desmosomes and fascia adherentes junctions with adjacent compact cardiac myocytes. Finally using serial block-face scanning electron microscopy, segmentation and volume reconstruction, we confirm the three-dimensional nature of the junctional region as well as the presence of the sheet-like fibroblast network. These ultrastructural studies demonstrate the previously unrecognized complexity with which the compact and spongy layers are structurally integrated, and provide a new basis for understanding development and regeneration in the zebrafish heart.