Actin-related intercellular adhesion junctions in the germinal compartment of the testis in the hagfish (Eptatretus stouti) and lamprey (Lampetra tridentatus)

The germinal epithelium of male vertebrates consists of Sertoli cells and spermatogenic cells. Intercellular junctions formed by Sertoli cells assume critical roles in the normal functions of this epithelium. While Sertoli cell junctions have been well characterized in mammals, similar junctions in nonmammalian vertebrates have received little attention. We examined the intercellular junctions found within the germinal epithelium of the hagfish (Eptatretus stouti) and lamprey (Lampetra tridentatus). Ultrastructurally, Sertoli cells were seen to form filament-associated junctions in both species. Adjacent Sertoli cells formed microfilament-related junctions near their apices. Filaments of these junctions were arranged in loose networks and were not associated with cisterns of endoplasmic reticulum. In fixed, frozen sections of hagfish testis, similar areas labeled with rhodamine phalloidin, indicating the filament type is actin. In the lamprey, desmosomes were observed immediately below the microfilament-related junctions. In appearance and location, the Sertoli cell junctions observed in these species resembled those of the typical junctional complex of other epithelial cell types. No junctions were observed between Sertoli cells and elongating spermatids. In the hagfish, but not the lamprey, an additional zone of microfilaments occurred near the base of Sertoli cells in areas of association with the basal lamina. Our observations are consistent with the proposal that the unique forms of intercellular attachment found in the testes of higher vertebrates evolved from a typical epithelial form of intercellular junction.     

Ultrastructure of Merkel corpuscles and so-called "transitional" cells in the white Leghorn chicken

In the chicken Merkel corpuscles are located in the dermis and consist of specialized Merkel cells, discoid nerve endings and lamellar cells. Merkel cells contain characteristic membrane-bound dense-core granules and bundles of microfilaments. Asymmetric junctions, synapse like, with thickened membranes and clusters of dense-core vesicles were observed between the Merkel cells and the nerve endings. The nerve ending is derived from myelinated nerves and sometimes contains clusters of clear vesicles. A laminar system formed by lamellar cells of the Schwann cell type encloses the Merkel cells and the nerve endings. So called "transitional" cells, showing some of the morphological features of both keratinocytes and Merkel cells, were observed in the basal layer of the epidermis. One was located partly in the epidermis and partly in the dermis. The structure of Merkel corpuscles is compared with that of Merkel cells in other tetrapods. The developmental significance of "transitional" cells and the origin of Merkel cells are discussed.     

Ultrastructural study of the myocardium of the sinus venosus and sinoatrial valve in the dogfish (Scyliorhinus canicula)

The myocardium of the sinus venosus of the dogfish ( Scyliorhinus canicula ) is located between a thick subepicardial collagen-rich layer and a subendocardial network of nerve fibres and ganglion cells. The sinoatrial valve consists of two transversal folds of the cardiac wall which are separated by connective tissue, except in their free margins.
The myocardium of the sinus venosus and the sinusal face of the sinoatrial valve is arranged in bundles which are surrounded by a 40 nm-thick basal lamina. The myocardial cells measure about 7-9 μm in diameter at the nuclear level. Nerve terminals are frequent in the centre of the bundles. Most of the sinusal myocardiocytes have a scarce amount of myofibrils which are randomly orientated. The sarcoplasmic reticulum is relatively well developed and consists of peripheral couplings, subsarcolemmal vesicles, circular and longitudinal tubules. The scarce intercalated discs show only fasciae adhaerentes . Gap junctions, desmosomes or specific granules are not observed in the sinusal myocardiocytes of the dogfish. In contrast, the atrial myocardiocytes are smaller, about 5-6 μm in diameter at the nuclear level. The cytoplasm is denser and the myofibrils are abundant and orientated in parallel directions. Specific granules are present. although scarce. Subsarcolemmal vesicles are less frequent, while the atrial intercalated discs are larger and more abundant than those of the sinus venosus. Neural elements are scarce in the atrium.
The differences observed between sinus venosus and atrium might be related to the morphological criteria to distinguish between the nodal tissue and the working myocardiocytes of higher vertebrates. On the other hand, we think that the connective tissue placed between sinus venom and atrium means that the contraction impulse generated in the sinus venosus must reach the atrium through the free margin of the valve. It might play a role in the sinoatrial valve function.     

The ultrastructure of the sinu-atrial node of the bat

The sinu-atrial node (SAN) of the bat, Pipistrellus subflavus, is capable of generating a wide range of spontaneous activity varying from 20 bpm when hibernating to bursts of 800 bpm during active flight. Electrophysiological studies have shown an absence of arrhythmias even below 4 degrees C body temperature. In order to determine whether these physiological capabilities are based upon unique ultrastructural features of the bat SAN, the present study was conducted. We found that the structure of the SAN of the bat is typically mammalian. Diameters of all three cell types in the SAN (nodal, transitional, and atrial) are smaller than those observed in any other mammalian species. A morphometric analysis of cell junctions reveals that nodal-nodal and transitional-transitional cell contacts are primarily undifferentiated with few nexuses. Atrial-atrial cell contacts have a dominance of fasciae adherentes-type junctions with a small area left undifferentiated. Nexuses are much more prevalent in atrial-atrial cell contacts.     

Impermeability of hagfish cerebral capillaries to horseradish peroxidase

Summary Brain capillaries and their permeability to intravenously injected horseradish peroxidase, HRP, (MW: 40,000) were examined electron-microscopically in an attempt to find a structural explanation for the poorly developed blood-brain barrier in the hagfish, Myxine glutinosa. In particular, it was the aim of this study to examine the role of the numerous endothelial vesicles and tubules in the transport of this tracer between blood and brain. Many of the vesicles and tubules were found to be in continuity with the luminal or abluminal surfaces, but tubules generating channels through the endothelial cells were never observed. The cleft between adjacent endothelial cells was obliterated by punctate junctions. HRP, which was allowed to circulate for up to 35 min, was not found in the basal lamina or in the surrounding brain parenchyma. Few of the luminal vesicles and tubules were marked by the tracer. In the intercellular cleft HRP was stopped by the junctions. It is concluded that the hagfish like other vertebrates has a blood-brain barrier to HRP, and the numerous vesicles and tubules occurring in hagfish brain endothelium are not involved in the transendothelial transport of this macromolecule.     

Fine structural study of interstitial cells associated with the deep muscular plexus of the rat small intestine,with special reference to the intestinal pacemaker cells

Two types of interstitial cells have been demonstrated in close association in the deep muscular plexus of rat small intestine, by electron microscopy. Cells of the first type are characterized by a fibroblastic ultrastructure, i.e. a well-developed granular endoplasmic reticulum, Golgi apparatus and absence of the basal lamina. They form a few small gap junctions with the circular muscle cells and show close contact with axon terminals containing many synaptic vesicles. They may play a role in conducting electrical signals in the muscle tissue. Cells of the second type are characterized by many large gap junctions that interconnect with each other and with the circular muscle cells. Their cytoplasm is rich in cell organells, including mitochondria, granular endoplasmic reticulum and Golgi apparatus. They show some resemblance to the smooth muscle cells and have an incomplete basal lamina, caveolae and subsurface cisterns. However, they do not contain an organized contractile apparatus, although many intermediate filaments are present in their processes. They also show close contacts with axon terminals containing synaptic vesicles. These gap-junction-rich cells may be regular components of the intestinal tract and may be involved in the pacemaking activity of intestinal movement.     

The structure of the coeliac ganglion of a teleost fish Myoxocephalus scorpius

Summary In order to compare the structure of a teleost sympathetic ganglion with those of other vertebrates, light, fluorescence histochemical and electron microscopy were carried out on the coeliac ganglion of the scorpion fish, Myoxocephalus scorpius. In common with studies on other vertebrates, fluorescence histochemistry distinguished two cell types: a) principal neurones which exhibited low levels of specific catecholamine fluorescence and comprise the majority of neurones in the ganglia, and b) smaller intensely fluorescent cells, some of which had processes tens of micrometers long.With the electron microscope, the principal cells were seen to make axodendritic and axosomatic synapses with axons containing mainly 30 nm agranular vesicles at the synaptic site while in other vertebrates usually only one or other synaptic association is present.Both the somata and the processes of intensely fluorescent cells contain 300–600 nm diameter vesicles many of which have electron dense cores. These cells are also innervated by axons containing 30 nm agranular vesicles.     

An ultrastructural study of the polyp and strobila of Atorella japonica (Cnidaria,Coronatae) with respect to muscles and nerves

Atorella japonica were observed by TEM to examine the nerve plexus in the capitulum of the polyp and the cross-striated muscle cells of the strobila. The nerve plexus included a number of neuromuscular junctions and many interneural synapses. Neuromuscular junctions contained two types of synaptic vesicle: clear and small (ca 75 nm diam.), and dense cored and large (ca 120 nm diam.). The first type of vesicle always appeared near the presynaptic membrane and the second type was distributed behind the former. In interneural synapses, two types of vesicle which were similar to neuromuscular synaptic vesicles were recognized. They were distributed in a pattern similar to that of the neuromuscular synaptic vesicles, but these vesicles were found on both sides of the two synaptic membranes.     

Fine structure and permeability of capillaries in the stria vascularis and spiral ligament of the inner ear of the guinea pig

Summary The blood capillaries in the stria vascularis and the spiral ligament of guinea pigs were studied by electron microscopy with freeze-fracture and thin section methods, including tracer experiments with horseradish peroxidase (HRP) and microperoxidase (MP). The endothelial cells of the capillaries of both tissues are connected by tight junctions, and contain about the same number of micropinocytotic vesicles. In cases of intravascular administration before fixation, both of the tracers stained the perivascular space and almost all endothelial vesicles in the stria vascularis. On the other hand, the perivascular space and many vesicles in the spiral ligament were unstained. The endothelial tight junctions in the stria vascularis prevented the penetration of HRP, but sometimes allowed the penetration of MP. Those of the spiral ligament were impermeable to both tracers. In cases of tracer administration after fixation, leakage spots of HRP from capillaries were sparsely located all over the stria vascularis. Transendothelial channels and isolated fenestrae formed by micropinocytotic vesicles were detected. It is concluded that the capillaries of the stria vascularis are similar to the muscle capillaries and to the capillaries of the elasmobranch brain, whereas those in the spiral ligament are similar to the brain capillaries of higher vertebrates.     

Ultrastructure and cytochemistry of secretory cells in the skin of the leech,Dina lineata

The ultrastructure and histochemical features of the two types of secretory cells in leech skin are described. Pear-shaped cells secrete mucus containing carboxylated mucosubstances, while tubular cells produce a mucus containing a mixture of neutral, carboxylated, and sulfated mucosubstances. Pear-shaped secretory cells have two types of neuroglandular junctions, one containing dense-core serotonergic vesicles and the other small clear vesicles. Tubular secretory cells have large terminals, with many clear vesicles thought to be cholinergic. © 1993 Wiley-Liss, Inc.     

Cell junctions in amphioxus (Cephalochordata): a thin section and freeze-fracture study

Tissues from the epidermis, alimentary tract and notochord of the cephalochordate Branchiostoma lanceolatum have been examined in both thin sections and freeze-fracture replicas to ascertain the nature of the intercellular junctions that characterize their cell borders. The columnar epithelial cells from the branchial chamber (pharynx), as well as from the anterior and posterior intestine, all feature cilia and microvilli on their luminal surfaces. However, their lateral surfaces exhibit zonulae adhaerentes only. No gap junctions have been observed, nor any tight junctions (as are a feature of the gut of urochordates and higher vertebrates), nor unequivocal septate junctions (as are typical of the gut of invertebrates). The basal intercellular borders are likewise held together by zonulae adhaerentes while hemidesmosomes occur along the basal surface where the cells abut against the basal lamina. The lateral cell surfaces, where the adhesive junctions occur, at both luminal and basal borders, do not exhibit any specialized arrangement of intramembrane particles (IMPs), as visualized by freeze-fracture. The IMPs are scattered at random over the cell membranes, being particularly prevalent on the P-face. The only distinctive IMPs arrays are those found on the ciliary shafts in the form of ciliary necklaces and IMP clusters. With regard to these ciliary modifications, cephalochordates closely resemble the cells of the branchial tract of ascidians (urochordates). However, the absence of distinct junctions other than zonulae adhaerentes makes them exceptions to the situation generally encountered in both vertebrates and urochordates, as well as in the invertebrates. Infiltration with tracers such as lanthanum corroborates this finding; the lanthanum fills the extracellular spaces between the cells of the intestine since there are no junctions present to restrict its entry or to act even as a partial barrier. Junctions are likewise absent from the membranes of the notochord; the membranes of its lamellae and vesicles exhibit irregular clusters of IMPs which may be related to the association between the membranes and the notochordal filaments. Epidermis and glial cells from the nervous system possess extensive desmosomal-like associations or zonulae adhaerentes, but no other junctional type is obvious in thin sections, apart from very occasional cross-striations deemed by some previous investigators to represent 'poorly developed' septate junctions.     

Two types of neuromuscular junctions in the pharyngeal retractor muscle ofHelix lucorum

The pharyngeal retractor muscle of the snailHelix lucorum is innervated by a pair of nerves containing axons of two types, for which there are two corresponding types of myoneural junctions with the muscle cells. The junctions of type I correspond to the thick axons. The terminals of these axons, which contain numerous spherical transparent vesicles (41±5 nm) and fewer vesicles of the dense-core type (67±3 nm), make contact mainly with noncontracting sarcoplasmic projections of the muscle cells. Junctions of type II correspond to thin axons, containing many granules. The terminals of these axons make contact with contractile parts of the muscle cells and they contain a heterogeneous population of vesicles: small spherical clear vesicles (44±2 nm), granules with fine-grained contents (135±5 nm), and a few spherical dense-core vesicles. The distance between the muscle cells is usually great — over 50 nm, but in the region of the sarcoplasmic processes the surface membranes come together to form a gap which in some areas does not exceed 10 nm.N. K. Kol'tsov Institute of Developmental Biology, Academy of Sciences of the USSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 5, pp. 539–542, September–October, 1977.     

Observations on the ultrastructure of nerve cells in the brain of the planarian,Dugesia gonocephala

Summary The submicroscopic structure of the nerve cells in the planarian brain was studied. Close similarities with neurons of other invertebrates were noted. In the cytoplasm of the planarian nerve cells there are at least three types of vesicular inclusions: 1) Clear vesicles (200–800 Å in epon embedded tissue) similar in morphological appearance to classical synaptic vesicles. These have generally some content of extremely low density but occasionally a dense core. 2) Dense vesicles (400–1,200 Å in epon embedded tissue) containing highly osmiophilic granules. Between the limiting membrane of the vesicle and the granule there is always a clear rim of variable width. These vesicles closely resemble synaptic vesicles described in vertebrate adrenergic endings. 3) Neurosecretory vesicles (600–1,300 Å in Vestopal embedded tissue) similar to elementary granules observed in neurosecretory systems in vertebrates and invertebrates. All three vesicle types have the same mode of origin from the Golgi membranes. All are present in the nerve cell processes of the neuropil as well as in the perikarya. Any given perikaryon or axon contains only one of the three vesicle types. All of these vesicles are considered to be discharged into the axons from their site of origin within the perikaryon.     

Organization and function of septate junctions

In most cell types, distinct forms of intercellular junctions have been visualized at the ultrastructural level. Among these, the septate junctions are thought to seal the neighboring cells and thus to function as the paracellular barriers. The most extensively studied form of septate junctions, referred to as the pleated septate junctions, is ultrastructurally distinct with an electron-dense ladder-like arrangement of transverse septa present in invertebrates as well as vertebrates. In invertebrates, such as the fruit fly Drosophila melanogaster, septate junctions are present in all ectodermally derived epithelia, imaginal discs, and the nervous system. In vertebrates, septate junctions are present in the myelinated nerves at the paranodal interface between the myelin loops and the axonal membrane. In this review, we present an evolutionary perspective of septate junctions, especially their initial identification across phyla, and discuss many common features of their morphology, molecular organization, and functional similarities in invertebrates and vertebrates.     

The ultrastructural differentiation of synaptic sites in the inner plexiform layer of a teleostean retina.

The differentiation of axon terminals in the retina inner plexiform layer was studied by electron microscopy, with special reference to synaptic junctions, number and size of synaptic vesicles, dense core vesicles, biogenic amines and ATPase. Five types of synaptic junctions were found, including a ribbon type. They appear on different days of embryonic life and show different patterns of increase. The ultrastructural differentiation of the most frequent type is described in detail. The numbers of synaptic vesicles indicate the existence of three types of axon terminals which appear on different days. These and other data lead to the following model: The contacts between amacrine cells are the first to appear, followed by amacrine--bipolar cell contacts and amacrine--ganglion cell contacts. The latter are the most frequent ones and increase immediately after having appeared, while amacrine--bipolar cell contacts increase only some days later, which is also the case for bipolar--amacrine cell contacts. Biogenic amines and cytochemically detectable ATPase appear along with the formation of synaptic sites.     

Relationship of saccular ultrastructure to otolith growth in the teleost Oreochromis niloticus

The sacculus of Oreochromis niloticus is anatomically separated from the utriculus and semicircular canals. The saccular wall is composed of the sensory epithelium, transitional epithelia, and squamous epithelium. Cellular granules are abundant in the sensory and transitional epithelia but scarce in the squamous epithelium. Over the dorsal side of the dorsal transitional epithelium there exists an oval patch of cells with distinctive microvilli. New finding is a shallow groove which extends from the anterior end of the sensory epithelium approximately halfway down along the ventral perimacular transitional epithelium. Small vesicles, which appear “empty” under transmission electron microscopy (TEM), are aggregated in the posterior region of the groove. These small vesicles are also present in both the sensory and transitional epithelia. A second kind of vesicle is comparatively large and appears filled with stainable contents. These vesicles are restricted to the sensory region. Both kinds of vesicles appear to be involved in apical secretion and possibly provide the otolithic membrane with fibers. The otolithic membrane is composed of a gelatinuous layer and subcupular meshwork. The meshwork appears to contribute to the formation of the otolith. The small empty vesicles appear to originate in sensory and transitional epithelial cells and may form the subcupular meshwork. The larger filled vesicles are derived predominantly from sensory cells in the sensory epithelium and appear to contribute to the gelatinuous layer of otoliths. © 1992 Wiley-Liss, Inc.     

INNERVATION OF THE FIBRILLAR FLIGHT MUSCLE OF AN INSECT: TENEBRIO MOLITOR (COLEOPTERA)

The structure of peripheral nerves, and the organization of the myoneural junctions in flight muscle fibers of a beetle is described. The uniaxonal presynaptic nerve branches display the "tunicated" structure reported in the case of other insect nerves and the relationship between the axon and the lemnoblast folds is discussed. The synapsing nerve terminal shows many similarities with that of central and peripheral junctions of other insects and of vertebrates (e.g., the intra-axonal synaptic vesicles) but certain important differences have been noted between this region in Tenebrio flight muscle and in other insect muscles. Firstly, the axon discards the lemnoblast before the junction is established and the axon effects a circumferential synapse with the plasma membrane of the fiber, which alone shows the increased thickness often observed in both pre- and postsynaptic elements. Secondly, in addition to the synaptic vesicles within the axon are present, in the immediately adjacent sarcoplasm, great numbers of larger postsynaptic vesicles which, it is tentatively suggested, may represent the sites of storage of the enzymatic destroyer of the activating substance similarly quantized within the intra-axonal vesicles. The spatial relationship between the peripherally located junctions and the portion of the fiber plasma membrane internalized as circumtracheolar sheaths is considered, and the possible significance of this with respect to impulse conduction is discussed briefly.     

Structural basis for some permeability properties of the air--blood barrier.

The structural basis for the permeability of the alveolar-capillary membrane to water-soluble solutes rests in part on the structure and function of its intercellular junctions and the pinocytotic vesicles within its cells. Intercellular junctions between endothelial cells of the pulmonary capillary bed differ both in permeability to enzyme tracers and in their structure. As determined by freeze fracture, the junctions in the arteriolar, capillary, and venular portion of the capillary network vary in complexity, and in the number of rows of particles constituting the junction. Because there are few particles associated with the junctions in the venular end of the capillary bed, these are considered to be the most permeable of the three types of vascular junctions. Epithelial junctions, in contrast, are impermeable to all enzyme tracers studied, and they are composed of a continuous, complex network of junctional fibrils. While intercellular junctions form seals of varying 'tightness,' pinocytotic vesicles provide a means for the transport of water-soluble macromolecules across the alveolar-capillary membrane.     

Atrial natriuretic factor in the vena cava and sinus node

We investigated the localization of atrial natriuretic factor (ANF) mRNA and of immunoreactive ANF in the vena cava and sinus node of rat and, for comparative purposes, in atria and ventricles. In situ hybridization with an ANF cRNA probe revealed that the supradiaphragmatic portion of the inferior vena cava contains almost as much mRNA as the atria, whereas the levels were less in the superior vena cava and higher than in ventricles in the sinus node. Immunoreactive ANF (high Mr form) was found to be 22 times less abundant in the supradiaphragmatic vena cava and 148 times less abundant in the superior vena cava than in atrial cardiocytes. The wall of the supradiaphragmatic portion of the vena cava and the valve (eustachian valve) that separates the atrial cavity from that of the vein are made up of atrial-like cardiocytes containing secretory granules. The subendothelial area of the superior vena cava also contains atrial-like cardiocytes with secretory granules, whereas the outer portion of the vein is made up of "transitional cells" without or with only a few secretory granules. Secretory granules in the vena cava and nodal cells, as well as transitional cells, contain immunoreactive ANF. With immunocryoultramicrotomy, virtually all cells, whether atrial-like, transitional, or nodal, and even those without secretory granules, were found to contain immunoreactive ANF in their Golgi complex and in secretory vesicles in the vena cava and in the sinus node.     

Fine-structural study of the pineal body of the monkey (Macaca fuscata) with special reference to synaptic formations

Summary Various types of synaptic formations on pinealocytes and pineal neurons were found in the pineal body of Macaca fuscata. Axo-somatic synapses of the Gray type-II category were detected on the pinealocyte cell body. Gap junctions and ribbon synapses were observed between adjacent pinealocytes. About 70 nerve-cell bodies were detected in one half of the whole pineal body bisected midsagittally. They were localized exclusively deep in the central part. When examined electron-microscopically, they were found to receive ribbon-synapse-like contacts from pinealocytic processes. They also received synaptic contacts of the Gray type-I category on their dendrites, and those of the Gray type-II category on their cell bodies from nerve terminals of unknown origin. All these synapse-forming axon terminals contained small clear vesicles. Thus, the pineal neurons of the monkey, at least in part, are suggested to be derived from the pineal ganglion cells in the lower vertebrates and not from the postganglionic parasympathetic neurons. The functional significance of these observations is discussed in relation to the innervation of the pineal body of the monkey.