Maternal treatment with teratogen causes congenital malformations in mouse embryos

Heterozygotes for the tail-short (Ts) mutant gene in the Balb/c strain have minor skeletal defects and a short, kinky tail. If heterozygote Ts/+ mothers are mated with normal-tail +/+ males and are treated with teratogenic doses of trypan blue on the eighth day of pregnancy, the mutant F1 heterozygotes develop exencephaly, folded neural tube and spina bifida significantly more often than non-mutants. This is indicative of gene-teratogen interaction, with the Ts gene increasing the embryo's susceptibility to trypan blue-induced neural tube defects.     

Resident and circulating mast cells in propulsative organs of frog <Emphasis Type="Italic">Rana temporaria</Emphasis>

A histochemical and ultrastructural examination of mast cells (MCs) in “blood” and lymph hearts of the adult frog Rana temporaria showed that they are represented by two populations, i.e., resident and circulating MCs. Resident cardiac MCs have an oval or elongated shape and are located in the atrial and ventricular myocardium, as well as in connective tissue of the epicardium. Circulating MCs were identified in heart lumen lacunas and in narrow clefts produced by ventricular trabecular myocardium, as well as in blood-filled atrial and ventricular central cavities. The small round shape circulating MCs resemble lymphocytes, but their cytoplasm is filled with granules that are ultrastucturally similar to granules of cardiac resident MCs. In the lymph heart, elongated resident MCs are located in the interstitial space between the cross-striated muscle fibers and smooth muscle cells of afferent and efferent heart valves. Round circulating MCs are occasionally visible in the cavity of the lymph heart. More commonly, circulating MCs are found in the lymphatic sinus cavity located adjacent to lymph hearts. In certain parts of the lymphatic sinus walls, MCs form clusters that are in tight contact with the mesothelial cells that line the lymphatic cavity. Our histochemical investigation revealed that both resident and circulating MCs of the propulsative organs are strongly alcian blue positive, but are weakly red after safranin staining and weakly metachromatic with toluidine blue. The presence of populations of circulating MCs in adult frogs suggests that there are differences in MC biology in lower and higher vertebrates.     

On the ultrastructure of specific heart granules in teleosts

The ultrastructure and chemical reactivity of teleostean specific ('atrial') heart granules (SHG) are described. In atrial cells of Glyptocephalus cynoglossus and Gadus morhua , large aggregations of SHG occur in areas of the sacroplasm rich in glycogen and poor in myofibrils. The SHG often appear to be in a process of lysis. A number of heart granules were also noted in atrial cells of Cichlasoma meeki, Pistella riddlei and Sebastes viviparus . although large aggregations were not seen. The mean diameters of SHG in G. cynoglossus and S. viviparus are 110 and 210 nm, respectively. SHG are regularly found in ventricular cells, although less frequently than in the atrium. Ultrahistochemical tests suggest that the teleostean SHG mainly contain proteins.     

Ultrastructure of atrial and ventricular myocytes of newborn rats: evidence for the existence of specific atrial granule-like organelles in the ventricle

The present study examined the ultrastructure of atrial and ventricular myocytes from the heart of newborn rats. It was found that, despite former reports stating that ventricular myocytes in adults do not contain cytoplasmic granules, specific atrial granule-like organelles are present in the ventricles of rats at birth. The presence of these granules together with the relatively underdeveloped contractile apparatus and extensive Golgi complex suggests that the ventricular, like the atrial, myocytes may have an endocrine function before or at birth. Further study is required to determine whether these ventricular cytoplasmic granules contain the same atrial natriuretic peptide species known to be present in the atrial specific granules.     

SPECIFIC GRANULES IN ATRIAL MUSCLE CELLS

Large populations (up to 600/cell) of spherical, electron-opaque granules ~0.3 to 0.4 µ in diameter are characteristically found in muscle fibers of mammalian atria. They are absent in muscle fibers of the ventricles. The granules are concentrated in the sarcoplasmic core and occur in lesser numbers in the sarcoplasmic layers between myofibrils and under the plasma membrane. Their intimate association with a central voluminous Golgi complex and the frequent occurrence of material reminiscent of the granular content within the cisternae of the Golgi complex suggest that the latter is involved in the formation of the atrial granules. Atrial granules are larger and more numerous in smaller species (rat, mouse), and generally smaller and less numerous in larger mammals (dog, cat, human); they are absent from the atrial fibers of very young fetuses (rat) but are present in those of newborn animals. A small population of bodies containing glycogen particles and remnants of the endoplasmic reticulum and mitochondria occurs in the sarcoplasmic cores of atrial as well as ventricular muscle fibers in the rat; they contain acid phosphatase and thus appear to be residual bodies of autolytic foci. Their frequency increases with the age of the animal. Typical lipofuscin pigment granules, which are known to contain acid phosphatase and are found in the sarcoplasmic cores in old animals (cat, dog and human), are presumed to arise by progressive aggregation and fusion of small residual bodies.     

On the shoulders of giants: the discovery of atrial natriuretic factor

Investigations culminating at the beginning of this century clearly established that the cardiac muscle cell (cardiocytes) is differentiated for excitation, conduction, and contraction. All of the physiology and pathophysiology of the heart was developed subsequently based on this concept. However, morphological investigations in the mid 1950s suggested a secretory function for mammalian atrial cardiocytes. These cells contain storage granules, the specific atrial granules, which resemble granules found in polypeptide hormone-producing cells. The development of techniques for the study of these granules using a combined biochemical-morphological approach during the 1970s defined their general chemical nature and their behaviour under different experimental conditions. Because the number of atrial granules change dramatically following upsets of water and electrolyte balance, atrial muscle extracts were tested for effects on kidney function. In 1981, it was reported that atrial extracts contain a natriuretic factor (ANF) capable of inducing massive diuresis, increases in hematocrit, and lowering of blood pressure. It was demonstrated soon thereafter that ANF is stored within specific atrial granules. More recent work has defined ANF as a polypeptide hormone that appears to modulate or antagonize the renin-angiotensin-aldosterone system. Current work attempts to define the physiological and pathophysiological role for ANF as well as possible therapeutic uses.     

Cardiac substances that influence blood-pressure. I. Identification of the agent that lowers blood-pressure in anaesthetized rats

Extracts of the atrium of the mammalian heart contain a natriuretic factor which may be associated with the atrium-specific granules. It has often been observed that the intravenous injection of a crude atrial extract into anaesthetized rats, causes a transient decrease in blood-pressure. In rabbits, this activity is present in stored aqueous extracts prepared from both atrial and ventricular tissue. The hypotensive activity, which can be readily separated from the natriuretic factor, is mainly due to the presence of adenosine and its derivatives, of which 5'-adenosine monophosphate is the major contributor. However, an extract from rabbit atrial muscle, carefully prepared under stringent conditions, caused a rapid and striking increase in blood-pressure, an activity that could not be detected in ventricular tissue.     

Tss (Tail-short Shionogi), a new short tail mutation found in the BALB/cMs strain, maps quite closely to the Tail-short (Ts) locus on mouse chromosome 11.

A spontaneous morphological mutation characterized by a short and kinky tail (Tail-short Shionogi: Tss) was observed in a BALB/cMs mouse breeding colony. The inheritance mode of the Tss mutation is semi-dominant, and homozygotes (Tss/Tss) are probably embryonic lethal. The viability of the Tss/+ heterozygotes appear to be influenced by the mating partner: 47.1% of the (BALB/cMs-Tss/+ x C57BL/6J)F1 embryos were the mutant phenotype, whereas there were no (BALB/cMs-Tss/+ x A/J)F1 embryos with the mutant phenotype. The Tss locus was mapped by linkage analysis between microsatellite markers D11Mit128 and D11Mit256 on mouse Chromosome 11. These results suggest that the Tss mutation is a new allele on the Tail-short (Ts) locus.     

Right and left ventricular wall deformation patterns in normal and left heart hypoplasia chick embryos

The vertebrate embryonic ventricle transforms from a smooth-walled single tube to trabeculated right ventricular (RV) and left ventricular (LV) chambers during cardiovascular morphogenesis. We hypothesized that ventricular contraction patterns change from globally isotropic to chamber-specific anisotropic patterns during normal morphogenesis and that these deformation patterns are influenced by experimentally altered mechanical load produced by chronic left atrial ligation (LAL). We measured epicardial RV and LV wall strains during normal development and left heart hypoplasia produced by LAL in Hamburger-Hamilton stage 21, 24, 27, and 31 chick embryos. Normal RV contracted isotropically until stage 24 and then contracted preferentially in the circumferential direction. Normal LV contracted isotropically at stage 21, preferentially in the longitudinal direction at stages 24 and 27, and then in the circumferential direction at stage 31. LAL altered both RV and LV strain patterns, accelerated the onset of preferential RV circumferential strain patterns, and abolished preferential LV longitudinal strain (P < 0.05 vs. normal). Mature patterns of anisotropic RV and LV deformation develop coincidentally with morphogenesis, and changes in these deformation patterns reflect altered cardiovascular function and/or morphogenesis.     

An immunocytochemical study of the sinuatrial node and atrioventricular conducting system of the rat for atrial natriuretic peptide distribution

Summary Immunocytochemical studies of the adult rat heart show that specific heart granules and atrial natriuretic peptide immunoreactivity are absent from the majority of the myocytes of the specialized nodes, atrioventricular bundle and bundle branches. Immunoreactive granules are present in a small proportion of the transitional sinuatrial and atrioventricular nodal myocytes but, in these regions, they are smaller than their counterparts in the general atrial myocytes. A rarer type of cell profile, identical to general atrial myocytes but lacking immunoreactive granules, is also present at the periphery of the sinuatrial node. A very small proportion of myocytes in the ventricular myocardium, generally in the subendocardial layers subjacent to the terminal ramifications of the bundle branches, contain a few immunoreactive granules.     

Fetal arrhythmias: Diagnosis and management

This article reviews important features for improving the diagnosis and management of fetal arrhythmias. The normal fetal heart rate ranges between 110 and 160 beats per minute. A fetal heart rate is considered abnormal if the heart rate is beyond the normal ranges or the rhythm is irregular. The rate, duration, and origin of the rhythm and degree of irregularity usually determine the potential for hemodynamic consequences. Most of the fetal rhythm disturbances are the result of premature atrial contractions (PACs) and are of little clinical significance. Other arrhythmias include tachyarrhythmias (heart rate in excess of 160 beats/min) such as atrioventricular (AV) reentry tachycardia, atrial flutter, and ventricular tachycardia, and bradyarrhythmias (heart rate <110 beats/min) such as sinus node dysfunction, complete heart block (CHB) and long QT syndrome (which is associated with sinus bradycardia and pseudo-heart block).     

Quantitative studies on the ultrastructural differentiation and growth of mammalian cardiac muscle cells. The atria and ventricles of the cat

Ultrastructural differentiation of cardiac muscle cells in the bilateral atria and ventricles of the cat at 1, 16, 25 and 40 days and 6 months after birth was studied by morphometry on electron micrographs. At the newborn stage, no T-tubule was found in the ventricular muscle cells, but specific granules were already noted in the atrial myocytes. The cell diameter of the ventricular myocardium was greater than that of the atrium at this stage. The T-tubule was first recognized in the ventricular muscle cells at day 16, at which stage the area occupied by the mitochondria and glycogen in the atrial muscle cells was definitely found to differ from that in the ventricular muscle cells. Thereafter, the differences in the ultrastructure between the atria and ventricles became more remarkable, particularly in the cell diameter and in the mitochondrial area. The cat cardiac muscle cells are characterized by numerous lipid droplets within the cytoplasm in contrast to those of the rat and the guinea pig.     

Culture and characterization of fetal human atrial and ventricular cardiac muscle cells

Summary Atrial and ventricular cardiac muscle cells isolated from 14- to 18-wk old fetal human hearts were grown in culture and characterized. Once established in culture the flattened cells contracted spontaneously and possessed differentiated ultrastructural characteristics including organized sarcomeres, intercalated discs, and transverse tubules with couplings. Atrial granules were present in the cultured atrial cells. Some cultured ventricular myocytes also contained electron-dense granules associated with Golgi cisternae, which were similar in size and appearance to atrial granules. The cultured ventricular myocytes divided and expressed the genes for thymidine kinase, histone H4, myosin heavy chain, muscle-specific creatine kinase, atrial natriuretic factor, and insulin-like growth factor II. These results establish that differentiated fetal human heart muscle cells can be cultured in sufficient quantities for biochemical, molecular, and morphological analyses. This work was supported by a postdoctoral fellowship from the American Heart Association, Louisiana Affiliate (JBD) and the National Institutes of Health, Bethesda, MD (HL-35632) (WCC).     

The development of the conduction system in the mouse embryo heart: III. The development of sinus muscle and sinoatrial node

The origin and development of the sinus musculature, and the sinoatrial node (SAN), were studied in mouse embryo heart from the 8th day postcoitum (dpc) to the neonate. In the medial wall of the right common cardinal vein (RCCV), the muscle cells clearly derive from the splanchnic epithelium, whereas in the dorsolateral wall of the sinus horns, the loose mesenchymal cells appear to transform into the early sinus muscle. The early sinus muscle is particularly voluminous around the right venous valve (RVV). The 9-dpc heart shows regular contractions, but a morphologically definable SAN is not seen until 11 dpc, located in the medioanterior wall of the RCCV. There is indication that the loose mesenchymal cells play a role in the development of the nodal fibers. The SAN and the atrioventricular conduction system (AVCS) develop simultaneously in the 11-to 12-dpc mouse embryo heart. In the medioanterior wall of the left common cardinal vein (LCCV), a transient node-like structure was found. This, however, integrates into the left atrial wall in the 13-dpc and older embryos. Growth and early differentiation of the sinus muscle proceed distally during embryonic life to the point where it is indistinguishable from the atrial musculature.     

Induction of myofibrillogenesis in cardiac lethal mutant axolotl hearts rescued by RNA derived from normal endoderm

A strain of axolotl, Ambystoma mexicanum, that carries the cardiac lethal or c gene presents an excellent model system in which to study inductive interactions during heart development. Embryos homozygous for gene c contain hearts that fail to beat and do not form sarcomeric myofibrils even though muscle proteins are present. Although they can survive for approximately three weeks, mutant embryos inevitably die due to lack of circulation. Embryonic axolotl hearts can be maintained easily in organ culture using only Holtfreter's solution as a culture medium. Mutant hearts can be induced to differentiate in vitro into functional cardiac muscle containing sarcomeric myofibrils by coculturing the mutant heart tube with anterior endoderm from a normal embryo. The induction of muscle differentiation can also be mediated through organ culture of mutant heart tubes in medium 'conditioned' by normal anterior endoderm. Ribonuclease was shown to abolish the ability of endoderm-conditioned medium to induce cardiac muscle differentiation. The addition of RNA extracted from normal early embryonic anterior endoderm to organ cultures of mutant hearts stimulated the differentiation of these tissues into contractile cardiac muscle containing well-organized sarcomeric myofibrils, while RNA extracted from early embryonic liver or neural tube did not induce either muscular contraction or myofibrillogenesis. Thus, RNA from anterior endoderm of normal embryos induces myofibrillogenesis and the development of contractile activity in mutant hearts, thereby correcting the genetic defect.     

Chicken atrial natriuretic peptide (chANP) and its secretion

Summary An immunohistochemical study using antiserum raised against synthetic chicken natriuretic polypeptide was used to investigate the distribution of this peptide in the chicken heart. Immunoreactive cells, both in the atrial and ventricular walls, were identified by electron microscopy, and electron-dense granules in the atrial and ventricular cardiocytes were revealed to be storage sites of the peptide. The electron-dense material, thought to be the peptide, was found in the sarcoplasmic reticulum, and it is suggested that a secretory pathway of the peptide through the latter to extracellular space, may be present, in addition to an exocytotic one.     

Correlation of myofibrillar ATPase activity and myosin heavy chain content in ventricular and atrial myocardium of fish heart

In the fish heart, ventricular and atrial muscles contain different isoforms of native myosin and myosin heavy chain (MyHC) but the significance of this diversity is still not known. We have analysed ventricular and atrial myocardium of six freshwater fish species (goldfish, roach, bream, rudd, perch and pike-perch) using histochemical staining for myofibrillar ATPase activity as well as non-denaturing and SDS gel electrophoreses for native myosin and MyHC content. In the range of fish species studied, the intensity of ATPase reaction was higher in the atrial myocardium than in the ventricular myocardium and the composition of native myosin isoforms differed between these two muscles. The MyHC content in the cardiac muscle showed some species-related differences. In the goldfish, both atrial and ventricular cardiac muscle contained electrophoretically similar MyHC. In the other fish species, however, the ventricular myocardium showed electrophoretically faster MyHC than that present in the atrial myocardium. These results indicate that there are consistent and characteristic species-related differences between the ventricular and atrial muscles at the level of ATPase staining and the type of MyHC expressed. The findings suggest that fish ventricular and atrial muscles may differ in their contractile properties.     

Studies of muscle proteins in embryonic myocardial cells of cardiac lethal mutant mexican axolotls (Ambystoma mexicanum) by use of heavy meromyosin binding and sodium dodecyl sulfate polyacrylamide gel electrophoresis

In the Mexican axolotl Ambystoma mexicanum recessive mutant gene c, by way of abnormal inductive processes from surrounding tissues, results in an absence of embryonic heart function. The lack of contractions in mutant heart cells apparently results from their inability to form normally organized myofibrils, even though a few actin-like (60-A) and myosin-like (150-A) filaments are present. Amorphous "proteinaceous" collections are often visible. In the present study, heavy meromyosin (HMM) treatment of mutant heart tissue greatly increases the number of thin filaments and decorates them in the usual fashion, confirming that they are actin. The amorphous collections disappear with the addition of HMM. In addition, an analysis of the constituent proteins of normal and mutant embryonic hearts and other tissues is made by sodium dodecyl sulfate (SDS) gel electrophoresis. These experiments are in full agreement with the morphological and HMM binding studies. The gels show distinct 42,000-dalton bands for both normal and mutant hearts, supporting the presence of normal actin. During early developmental stages (Harrison's stage 34) the cardiac tissues in normal and mutant siblings have indistinguishable banding patterns, but with increasing development several differences appear. Myosin heavy chain (200,000 daltons) increases substantially in normal hearts during development but very little in mutants. Even so the quantity of 200,000-dalton protein in mutant hearts is significantly more than in any of the nonmuscle tissues studied (i.e. gut, liver, brain). Unlike normal hearts, the mutant hearts lack a prominent 34,000-dalton band, indicating that if mutants contain muscle tropomyosin at all, it is present in drastically reduced amounts. Also, mutant hearts retain large amounts of yolk proteins at stages when the platelets have virtually disappeared from normal hearts. The morphologies and electrophoresis patterns of skeletal muscle from normal and mutant siblings are identical, confirming that gene c affects only heart muscle differentiation and not skeletal muscle. The results of the study suggest that the precardiac mesoderm in cardiac lethal mutant axolotl embryos initiates but then fails to complete its differentiation into functional muscle tissue. It appears that this single gene mutation, by way of abnormal inductive processes, affects the accumulation and organization of several different muscle proteins, including actin, myosin, and tropomyosin.     

The ultrastructure of the atrium in the adult newt Notophthalmus viridescens (Amphibia,Salamandridae)

The atrial wall of Notophthalmus viridescens is 25–75 μm thick and is trabeculated sparsely. Coronary vessels are absent. The endocardial endothelium is continuous and has 50–60 nm-wide fenestrae with diaphragms, rests on a discontinuous basal lamina and lacks occluding junctions. Cells found in the subendothelial connective tissue are xanthophores, melanophores, mast cells, fibroblasts, macrophages, and unmyelinated nerve fibers with Schwann cell investments. Epicardial mesothelial cells contain numerous 6–7 nm filaments and lamellar bodies which resemble myelin figures. Mesothelial cell junctions include maculae adhaerentes diminutae, desmosomes, and interdigitations. The epicardial connective tissue layer is more extensive than that of the endocardium, with xanthophores and melanophores rarely present and nerve fibers never observed. The myocardium consists of a mesh-work of myocytes 3–5 cell layers thick with little intervening connective tissue. Myocytes are 6–10 μm in diameter and have two or three peripheral myofibrillae. Typical A, I, H, Z, and M bands are present with a sarcomere length of 2.5 μm. T tubules are not observed. The sarcoplasmic reticulum has subsarcolemmal dilations. The nuclear pole region contains abundant mitochondria and atrial granules, extensive Golgi, and elements of smooth and rough-surfaced endoplasmic reticulum. Lateral intercellular junctions consisting of dense plaques, frequently continuous with Z-line material, are common. Oblique and transversely oriented junctions consisting of primarily of fascia adhaerentes, are present. It appears that amphibian atrial myocytes more closely resemble those of the amphibian ventricle than those of the mammalian atrium. Structural differences between amphibian atrial and ventricular myocytes seem to be quantitative rather than qualitative in nature.