The novel transmembrane protein Tmem2 is essential for coordination of myocardial and endocardial morphogenesis

Coordination between adjacent tissues plays a crucial role during the morphogenesis of developing organs. In the embryonic heart, two tissues - the myocardium and the endocardium - are closely juxtaposed throughout their development. Myocardial and endocardial cells originate in neighboring regions of the lateral mesoderm, migrate medially in a synchronized fashion, collaborate to create concentric layers of the heart tube, and communicate during formation of the atrioventricular canal. Here, we identify a novel transmembrane protein, Tmem2, that has important functions during both myocardial and endocardial morphogenesis. We find that the zebrafish mutation frozen ventricle (frv) causes ectopic atrioventricular canal characteristics in the ventricular myocardium and endocardium, indicating a role of frv in the regional restriction of atrioventricular canal differentiation. Furthermore, in maternal-zygotic frv mutants, both myocardial and endocardial cells fail to move to the midline normally, indicating that frv facilitates cardiac fusion. Positional cloning reveals that the frv locus encodes Tmem2, a predicted type II single-pass transmembrane protein. Homologs of Tmem2 are present in all examined vertebrate genomes, but nothing is known about its molecular or cellular function in any context. By employing transgenes to drive tissue-specific expression of tmem2, we find that Tmem2 can function in the endocardium to repress atrioventricular differentiation within the ventricle. Additionally, Tmem2 can function in the myocardium to promote the medial movement of both myocardial and endocardial cells. Together, our data reveal that Tmem2 is an essential mediator of myocardium-endocardium coordination during cardiac morphogenesis.     

Morphologic study of ventricular trabeculation in the embryonic chick heart

This paper presents a morphologic study of ventricular trabeculation in chick embryo hearts between days 2 and 5 of incubation. Trabeculation appears to be the expression of three closely interrelated events: the formation of endocardial outgrowths that eventually invade the myocardium; the development of large intercellular spaces between the myocytes, and the decrease in thickness of the cardiac jelly. Endocardial cells present morphologic differences between trabeculated and nontrabeculated areas of the ventricular region. The elongation of the endocardial cells in the endocardial outgrowths and the presence of mitoses suggest that the endocardium grows out by means of an increase in cell number and by redistribution and elongation of the preexisting endocardial cells. The intercellular spaces of the myocardium appear filled with abundant extracellular material. It is suggested that the continuous synthesis of extracellular material by the myocytes may increase the hydrostatic pressure within the myocardium, inducing the formation and the enlargement of these intercellular spaces. The development and later rupture of endocardium-covered cords is described here. These cords are made up of a core of cardiac jelly material revested by endocardium. The cords may be engaged in the removal of substantial amounts of cardiac jelly during the formation of the trabeculae.     

Essential features of endocardial and myocardial morphology: SEM and TEM studies

The conducting pathway of the ferret's myocardium and endocardium was studied under the electron and scanning microscope. Comparisons between the two methods showed that the scanning microscope is well suited for those dimensional demonstration of biological material. Contrary to a relative absence of interspecific differences in endocardial morphology, there is a strong variation of this morphology related to the intracardiac localization of the endocardial cells. The following findings were obtained. S.e. microscopically, it was observed that the endocardium of the sino-atrial node region is not smooth, and that, more likely, it shows rough surfaced profiles. The electron microscopic study shows that the cells of the S-A node are elongated. The S-A node is located at the junction of the superior vena cava with the right atrial wall. It consists of nodal fibres which are embedded in a richinterstitial connective tissue (Figs 1-8). The Purkinje fibres originate from large bundles in the region of the right and left atrioventricular valve in the area where heart muscle fibres were originally described by Purkinje (Purkinje, 1845); these fibres, meanwhile, have become synonymous with cells of the generalized conducting system. The Purkinje fibres consist of a poorly developed contractile apparatus and contain unorganized, fine, filamentous material (Illustration 1). The SR is poorly developed, transverse tubules are absent. S.e. microscopically, one can visualize the trabecular system and the sinusoids. The trabeculae obtain muscle fibres rich in contractile material and transverse tubules. The trabeculae appear to be tendonous (chordae tendineae), especially when they freely traverse the ventricular cavity (Fig. 16). The interventricular septum (the muscle fibres from this region) takes its origin from large bundles in the region of the right and left atrioventricular valves. The endocardium of the interventricular septum is filled with large numbers of plasma-lemma folds (Figs 17, 18). The endocardium which covers the papillary muscle has a thickness of 0.5 micron. The endocardial cells lie on the myocardium so close and so thin that the surface relief and part of the atriation of the myocardium are visible (Figs 13-15).     

Comparative study of the space constant of electrotonic decay in the endocardium and epicardium of the rabbit right atrium

The distribution of the electronic potential in the endocardium and epicardium of the rabbit right atrium was studied. The distribution of the electronic potential was studied by the method of intracellular polarization of cardiac fibers via a suction electrode perfused from the inside with a KCl isotonic solution. The space constant of electronic decay along and across cardiac fibers in the endocardium and epicardium of rabbit right atrium was measured. It was shown that the space constant of electronic potential decay in rabbit the right atrium endocardium in the areas of ordered arrangement of trabecules both along (lambda x = 2117 +/- 653 microns) and across (lambda y = 394 +/- 212 microns) the fiber was higher (p < 0.001) than that in epicardium (lambda x and lambda y equal to 1361 +/- 486 microns and 212 +/- 63 microns, respectively). The values lambda x and lambda y do not significantly differ between separate areas of the epicardium. The degree of electrotonic anisotropy in all the structures investigated was almost the same, its value ranging from 2 to 17.     

Exocytosis of cortical granules from activated oocytes of the toad,Bufo arenarum

Summary Observation of the cortical region of oocytes of Bufo arenarum by transmission electron microscopy reveals modifications on their surface and in the contents of the cortical granules (CG) during activation. In non-activated oocytes only amorphous cortical granules (ACG) can be observed. Activated oocytes display ACG, intermediate cortical granules containing both amorphous and membranous material (ICG), and a third type containing only membranous material (MCG). During exocytosis, CG release their contents into the perivitelline space, where the amorphous and membranous materials are found. The three types of CG found during oocyte activation suggest transformation of ACG to MCG and indicate that the different components of the cortical granules, when released into the perivitelline space, might play different roles in prevention of polyspermy.Members of the Scientific Research Career of CONICET, R. Argentina.     

Incomplete fusion of the epithelial and endothelial basement membranes in interspecies hybrid glomeruli

Avascular, undifferentiated mouse kidneys transplanted onto quail chorioallantoic membrane differentiate and become vascularized by quail vessels. The glomeruli which form under these conditions consist of mouse podocytes and quail endothelial cells. Immunohistochemistry has shown that the glomerular basement membrane (GBM) has a dual origin, as integral basement membrane components are produced by both podocytes and endothelial cells. In electron microscopy this GBM is composed of two partially separated layers, an epithelial and an endothelial basal lamina which both have a lamina densa and a lamina rara. These two basal laminas are partially fused, but there are large areas where this fusion does not occur. In some places of incomplete fusion, fibrillar extracellular material is seen between and beneath the GBM. It is concluded that basement membrane components derived from the different species can interact partially, but the fusion is incomplete. The abnormal assembly of the epithelial and the endothelial basal laminas might be due to molecular differences between the components produced by the two cell lineages. In spite of the incomplete fusion, the system used serves as a good model-system to study basement membrane formation, since the cells organize in a histiotypic fashion and form true vascularized glomeruli.     

Cellular migration through the cardiac jelly matrix: A stereoanalysis by high-voltage electron microscopy

Formation and migration of cushion tissue in the developing chick heart was analyzed by scanning and high-voltage electron microscopic stereoanalysis. Two methods of fixation which enhance the preservation of water-soluble components of the extracellular matrix (cardiac jelly) were employed: 1% tannic acid in 3% glutaraldehyde (TAG) and 1% cetylpyridinium chloride (CPC) in 3% glutaraldehyde. Our results indicated that the preservation of the cell: matrix interaction exhibited by endocardial cells and migrating cushion tissue is dependent upon the method of fixation. In TAG-fixed embryos, filopodial extensions from the endocardium as well as filopodia of pioneering cells are most often associated with microfibrillar components of the matrix, whereas in CPC-fixed material these same cellular extensions are found in association with pleomorphic anastomosing strands rich in hyaluronate. Following these initial cell:matrix interactions by both the endocardium and pioneering cells, trailing cells invade the extracellular matrical region and clearly encounter in both types of fixation a different microenvironment in which to engage in cell:matrical associations. These observations support the hypothesis that filopodial probing by endocardial cells and pioneering cells results in macromolecular reorderings of the matrix and thus suggest an additional function for filopodia beyond translocation of the cells.     

TELOCYTES IN ENDOCARDIUM: Electron Microscope Evidence

The term TELOCYTES was very recently introduced, for replacing the name Interstitial Cajal‐Like Cells (ICLC). In fact, telocytes are not really Cajal‐like cells, they being different from all other interstitial cells by the presence of telopodes, which are cell‐body prolongations, very thin (under the resolving power of light microscopy), extremely long (tens up to hundreds of micrometers), with a moniliform aspect (many dilations along), and having caveolae. The presence of telocytes in epicardium and myocardium was previously documented. We present here electron microscope images showing the existence of telocytes, with telopodes, at the level of mouse endocardium. Telocytes are located in the subendothelial layer of endocardium, and their telopodes are interposed in between the endocardial endothelium and the cardiomyocytes bundles. Some telopodes penetrate from the endocardium among the cardiomyocytes and surround them, eventually. Telopodes frequently establish close spatial relationships with myocardial blood capillaries and nerve endings. Because we may consider endocardium as a ‘blood–heart barrier’, or more exactly as a ‘blood–myocardium barrier’, telocytes might have an important role in such a barrier being the dominant cell population in subendothelial layer of endocardium.     

Distribution of endoglin in early human development reveals high levels on endocardial cushion tissue mesenchyme during valve formation

Endoglin is a component of the receptor complex for transforming growth factor (TGF)-β1 and TGF-β3. We analysed its expression by immunohistochemistry in human embryos at 4–8 weeks of gestation and in hearts ranging from 4–13 weeks old. We compared endoglin distribution with that of TGF-β receptors type I (TβR-I), type II (TβR-II) and betaglycan. Endoglin was found on endothelial cells in all tissues examined, consistent with its expression in adult blood vessels. TβR-I, TβR-II and betaglycan were observed on most cell types and had an overall similar pattern of distribution. Endoglin was detected on the endocardium as early as 4 weeks, but was absent from myocardium. It was present at high levels on the endocardial cushion tissue mesenchyme from 5–8 weeks’ gestation, during heart septation and valve formation, and subsequently decreased as the valves matured. Endoglin expression in heart extracts was confirmed by Western blot analysis. TβR-I, TβR-II and betaglycan were mostly found on cardiac myocytes, but were detectable at low levels on endocardium. They were expressed transiently on cushion mesenchyme, albeit at much lower levels than endoglin. All four components of the TGF-β receptor complex were detected by RT-PCR in embryonic heart. Thus transient up-regulation of the components of the TGF-β receptor complex, and particulartly of endoglin, is associated with heart septation and valve formation during early human development.     

Observations on the Fine Structure of the Turtle Atrium

The general fine structure of the atrial musculature of the turtle heart is described, including; the nature of the sarcolemma; the cross-banded structure of the myofibrils; the character of the sarcoplasm, and the form and disposition of its organelles. An abundant granular component of the sarcoplasm in this species is tentatively identified as a particulate form of glycogen. The myocardium is composed of individual cells joined end to end at primitive intercalated discs, and side to side at sites of cohesion that resemble the desmosomes of epithelia. Transitional forms are found between desmosomes and intercalated discs. Both consist of a thickened area of the cell membrane with an accumulation of dense material in the subjacent cytoplasm. This dense amorphous component is often continuous with the Z substance of the myofibrils and may be of the same composition. The observations reported reemphasize the basic similarity between desmosomes and terminal bars of epithelia and intercalated discs of cardiac muscle. Numerous unmyelinated nerves are found beneath the endocardium. Some of these occupy recesses in the surface of Schwann cells; others are naked axons. No specialized nerve endings are found. Axons passing near the sarcolemma contain synaptic vesicles, and it is believed that this degree of proximity is sufficient to constitute a functioning myoneural junction.     

Expression of extracellular matrix components fibronectin and laminin in the human fetal heart.

It has been well documented that the extracellular matrix components fibronectin and laminin promote or regulate morphogenesis of the myocardial cells in mammalian heart. However, their chronological change of expression (or localization) in the human heart remains elusive. In this study, fibronectin and laminin in the left ventricle of forty-two human fetuses aged from 8 to 26 weeks gestation and left ventricular tissues obtained from a 2-week old infant and two adults were investigated by Western blot analyses and indirect immunofluorescence technique with monoclonal antibodies. In the fetal heart, fibronectins were present along the endocardium, epicardium, and linings of larger blood vessels. In 14-16 weeks gestation, fibronectin immunofluorescence became stronger but not evenly dispersed in the interstitium. After 24 weeks gestation, they were strongly positive only in the relatively larger blood vessels, as well as those in the infant and adult cardiac tissues. Laminins were strongly positive along the endocardium and basement membrane of the myocardial cells and fibroblasts during fetal life. After birth, laminins formed fine fibrillar network along the basement membrane in association with the transverse tubules of myocardial cell; these morphological characteristics remained in the adult cardiac tissues. These results indicate that fibronectin expression is relatively constant during fetal life but decreases after birth; in contrast, laminin expression is not age-dependent and constant throughout the life.     

A light and electron microscopic study of he heart of a crayfish, Procambarus clarkii (Giraud). II. Fine structure

The adventitia of the crayfish heart is composed of cells that are separated from each other by an intercellular space about 280 Å wide. Desmosomes are present on apposing surfaces of adjacent cells. A basal lamina underlies the adventitia and consists of a dense, amorphous substance that contains numerous fine filaments. The myocardial cells are striated and an external lamina 0.1 μ thick is present on the surface of the plasma membrane. The nuclei and most of the cytoplasm, glycogen and mitochondria are located at the cell periphery. The myofibrils are composed of thick and thin filaments and confined to the core of the cell. A T system and a well-developed SR are present. Elements of these organelles form dyads at levels that correspond to the H bands, and triads at levels that correspond to the Z bands of the peripheral myofibrils. The relationship of the T tubules to the myofibrils is discussed. Locus cells exhibit a unique pattern of intracellular myofibrillar branching. They branch from a region which has a structure similar to the Z band material. The myofibrils radiate outwardly in various directions and form numerous cellular branches which form intercalated discs with adjacent myocardial cells. These discs are more complex than those observed in poikilothermic vertebrates but are simpler than those in mammals. An endocardium is lacking in the crayfish heart but interstitial cells are present in close association with the myocardial cells and neural elements. Terminal nerve processes deeply embedded in the myocardial cells are described.     

Cellular aspects of elastogenesis in the elastic tendon of the chicken wing

Morphological, immunocytochemical and ultrastructural methods were used to investigate the role of cells during elastogenesis in the elastic tendon of the chicken wing. Intimate contact of the cell processes with elastic fibers was observed in adult birds. During development there was a sequential appearance of microfibril bundles that became progressively impregnated with amorphous elastin, which eventually predominated in fully developed elastic fibers. The growing elastic fibers were usually enveloped by recesses of the cell surface. The tendon cells were polarized in their association with fibrous components of the extracellular matrix. This arrangement suggests that these cells secrete and organize elastic and collagen fibers to different extracellular compartments. These results show that cells are intimately involved in producing components of different extracellular matrix fibers, in controlling their assembly, and in defining their borders and associations during development.     

Inhibitory effect of intracellular lipid load on macroautophagy

Degradation of intracellular components via macroautophagy is a complex multi-step process that starts with the sequestration of cytosolic cargo in a de novo formed double-membrane vesicle or autophagosome. This compartment acquires the hydrolases required for cargo digestion by fusion with lysosomes. In contrast to the detailed molecular dissection of the components that participate in the induction, regulation and execution of the early steps in macroautophagy, through the engulfment of cargo in autophagosomes, the mechanisms involved in the lysosomal clearance of autophagosomes have been poorly characterized in mammals. One of the major limitations in this respect has been the fact that autophagosome-lysosome fusion in intact cells involves several independent steps, namely binding of the molecular motors associated to the surface of the vesicles with the cytoskeletal network, directional vesicular trafficking and fusion between the two vesicular compartments. Furthermore, both lysosomes and autophagosomes are very dynamic organelles that can fuse with different vesicular structures involved in macroautophagy, but also along the endocytic and phagocytic pathways. To resolve these limitations and directly analyze the fusion step between autophagosomes and different compartments of the endocytic-lysosomal pathway, we have recently developed an in vitro fusion assay with autophagosomes, lysosomes and endosomes isolated from cells or tissues. Fluorescent labeling of these compartments allows for the tracking of fusion events by fluorescence microscopy or by fluorescence activated cell sorting (FACS). Labeling of either membrane proteins on the surface of the organelles or dye-loading of the vesicles permits the monitoring of hemi-membrane fusion and complete vesicular fusion (cargo mixing).     

Elastica-positive material in the atrial endocardium. Light and electron microscopic identification

The elastic layer of the endocardium is studied in various laboratory animals (mouse, rat, rabbit, cat, and dog) and in man. Coarse elastica-positive fibers form a tightly woven layer in the endocardium of the left atrium; the elastic layer consists of loosely arranged delicate fibers in the endocardium of the right atrium. Electron microscopy shows the elastic material to consist of homogeneous elastin (E) and of elastic fiber microfibrils (EFM). Elastic material in the endocardium of the left atrium is mainly formed of E with few EFM present. By contrast, the portion of EFM predominated that of E in elastic fibers from the right atrium, where some elastica-positive fibers even appear as pure bundles of microfibrils. This was also observed in human material obtained from aged individuals (8th decennium). It is concluded that EFM are not only progenitors of E but represent an independent fibrous component of the connective tissue.     

N-cadherin localization in early heart development and polar expression of Na+,K(+)-ATPase, and integrin during pericardial coelom formation and epithelialization of the differentiating myocardium.

N-cadherin, a Ca(2+)-dependent cell adhesion molecule, has been localized previously to the mesoderm during chick gastrulation and to adherens junctions in beating avian hearts. However, a systematic study of the dynamic nature of N-cadherin localization in the critical early stages of heart development is lacking. The presented work defines the changes in the spatial and temporal expression of N-cadherin during early stages of chick heart development, principally between Hamburger and Hamilton stages 5-8, 18-29 hr of development. During gastrulation N-cadherin appears evenly distributed in the heart forming region. As development proceeds to form the pericardial coelom (stages 6, 7, and 8, i.e., between 22 and 26 hr of development) N-cadherin localization becomes restricted to the more central areas of the mesoderm. The localization also shows a periodicity that correlates closely with the distance between foci of cavities that eventually coalesce to form the coelom. This distribution suggests that N-cadherin may have a function in the sorting out of somatic and splanchnic mesoderm cells to form the coelom. This separation of the mesoderm in the embryo for the first time physically delineates the precardiac mesoderm population. Concomitant with cell sorting during coelom formation, the precardiac cells change shape and show a distinct polarity as conveyed by (1) the apical expression of N-cadherin on precardiac cell surfaces lining the pericardial coelom, (2) the primarily lateral expression of Na+,K(+)-ATPase, and (3) an enrichment of integrin (beta 1 subunit) on basal cell surfaces. The somatic mesoderm cells apparently down-regulate N-cadherin expression. N-cadherin is also absent from the precardiac cells close to the endoderm. The latter cells eventually form the endocardium, i.e., the endothelial lining of the heart. By contrast, in the tubular, beating heart N-cadherin is found throughout the myocardium. In summary, immunolocalization patterns of N-cadherin during early cardiogenesis suggest that this cell adhesion molecule has a major role in the dynamics of pericardial coelom formation. Subsequently, its continued expression during cell differentiation of the cardiomyocyte to form the myocardium, but not endocardium, suggests N-cadherin is an essential morphoregulatory molecule in heart organogenesis.     

Control of cell migration in atrioventricular pads during chick early heart development: Analysis of cushion tissue migration in vitro

The formation of the valvular and septal primordia of the embryonic heart depends upon the migration of endocardial cushion tissue mesenchyme (CT) to populate the cardiac jelly (CJ) in specific heart regions (e.g., atrioventricular (AV) pads). It has been proposed that the migration of CT may be directed by macromolecules of the CJ. In this study, [³H]thymidine-labeled endocardial (EC) and CT cells were transplanted onto intact pre- and postmigratory AV pads in vitro to test whether the compositional or structural changes known to occur in the cardiac jelly during development influence the migration of cushion tissue cells. After transplantation of labeled donor cells, host AV pads were fixed, embedded, and sectioned, and autoradiography was performed to determine the distribution of labeled donor cells within the host CJ. The experiments indicate that transplanted mural EC cells remain primarily at the AV pad surface, while grafted CT cells of all developmental ages rapidly invade both developmentally young and older AV pads. Furthermore, CT cells readily migrate in a direction opposite to that of cells in vivo when transplanted to inverted AV pads from which the myocardium has been removed. It is concluded that the CJ matrix, which is clearly a suitable framework for CT cell migration, provides no direct cues to determining the polarity or extent of migration.