Anatomy and ultrastructure of the excretory system of a heart-bearing and a heart-less sacoglossan gastropod (Opisthobranchia, Sacoglossa)

The microanatomy and ultrastructure of the excretory system of the Sacoglossa have been investigated from two species by means of semithin serial sections, reconstructions and transmission electron microscopy. Whereas Bosellia mimetica shows a functional metanephridial system consisting of a heart with ventricle and auricle in a pericardium and a single kidney, Alderia modesta lacks heart and pericardium, possessing only several haemocoelic sinuses and a very long kidney. In B. mimetica podocytes as the site of ultrafiltration could be detected in the pericardial epithelium lining the auricular wall. The flat epithelium of the kidney with extensive basal infoldings and a dense microvillous border towards the luminal surface serves to modify the ultrafiltrate. In A. modesta podocytes are absent. Solitary rhogocytes (pore cells), the fine structure of which strongly resembles podocytes (meandering slits with diaphragms covered by extracellular matrix), occur in B. mimetica and A. modesta, representing additional loci of ultrafiltration. The presence of podocytes situated in the epicardial wall of the auricle is regarded as plesiomorphic for the Mollusca and confirmed for the Sacoglossa in this study, contradicting earlier assumptions of the loss of the primary site of ultrafiltration in the ancestors of the Opisthobranchia. In contrast to the likewise heart-less Rhodopidae with a pseudoprotonephridial ultrafiltration system, A. modesta shows no further modifications of the excretory system. Accepted: 7 May 2001     

Fine Structure of Heart,Pericardium and Glomerular Vessel in Cephalodiscus gracilis M'Intosh, 1882 (Pterobranchia,Hemichordata)

Heart, pericardium and glomerular vessel of Cephalodiscus gracilis have been studied with the electron microscope. The lumen of the heart is lined by a basal lamina and an associated epithelium, composed of myoepithelial cells with well developed thin and thick myofilaments. The heart is located in the pericardial cavity, which is deliminated by the pericardium. The latter is composed of two flat layers of myoepithelia with fused basal laminae. The outer layer of the pericardium is the protocoelomic lining, and the inner layer is the ‘parietal’ pericardial epithelium. The myoepithelium forming the heart wall can be considered to represent the ‘visceral’ pericardial epithelium. The spacious glomerular vessel is lined by a basal lamina, on which typical podocytes rest. These cells indicate that ultrafiltration takes place through the wall of the glomerular vessel. The lumen of the vessel contains fine granular material (presumably precipitated blood proteins), fibrils with a faint cross striation, suggesting that they represent collagen, and stellate cells, which in part line the vessel. Since ultrafiltration requires hydrostatic pressure, it is inferred that the blood flow is from the dorsal region then through the heart and into the glomerular vessel.     

Comparative Functional Morphology of the Bivalve Excretory System

Combining injection techniques with ultrastructural observations,and relating these findings to the more traditional physiologicaland morphological studies have shed new light onthe excretorymechanisms underlying the processes of ultrafiltration, secretionand reabsorption in some bivalve molluscs. These basic processesare further elucidated by comparing normal excretory tissueswith those in bivalves that have been subjected to stress bypollutants in either the natural environment or under laboratoryexperimentation. The process of ultrafiltration is size andcharge dependent and occurs at the filtration barrier at thebase of the podocytesin the pericardial gland. Primary urinemay be modified by secretion (primarily from the kidney cellsbut also from the podocytes), reabsorbtion in the kidney, andby the addition of hemocytes passing from blood spaces throughthe epithelium into the lumen of the kidney. Numerous concrements(granules, concretions and membranes) that result from lysosomalactivities inthe podocytes, kidney cells and hemocytes alongwith the fluid are excreted into the mantle cavity     

The Structure of Anuran Podocyte—Determined by Ecology?

Abstract The podocytes of ten frog species with different habitat preference were investigated by scanning electron microscopy. The visceral epithelium within these species shows considerable variation in the branching mode of the cellular processes, in the number of pedicels and in the form of cell bodies. The presence of various podocyte cell forms within anurans of one family (e.g. within Ranidae and Discoglossidae) indicates that podocytic structure is not manifested phylogenetically. The complexity of processes and pedicel numbers are high in glomeruli of terrestrial and semiterrestrial frogs but low in aquatic and semiaquatic animals. Consequently, podocyte structure is (a) correlated with environmental conditions and (b) plays an important role in osmoregulation. Furthermore, since podocytes are suggested to serve as stabilizers of glomerular vessels, the cells of the visceral epithelium provide the structural basis for regulation of glomerular filtration rate, e.g. for glomerular intermittency.     

The periesophageal celom of the articulate brachiopod Hemithyris psittacea (Rhynchonelliformea,Brachiopoda)

The celomic system of the articulate brachiopod Hemithyris psittacea is composed of the perivisceral cavity, the canal system of the lophophore, and the periesophageal celom. We study the microscopic anatomy and ultrastructure of the periesophageal celom using scanning and transmission electron microscopy. The periesophageal celom surrounds the esophagus, is isolated from the perivisceral cavity, and is divided by septa. The lining of the periesophageal celom includes two types of cells, epithelial cells and myoepithelial cells, both are monociliary. Some epithelial cells have long processes extending along the basal lamina, suggesting that these cells might function as podocytes. The myoepithelial cells have basal myofilaments and may be overlapped by the apical processes of the adjacent epithelial cells. The periesophageal celom forms protrusions that penetrate the extracellular matrix (ECM) of the body wall above the mouth and the ECM that surrounds the esophagus. The canals of the esophageal ECM form a complicated system. The celomic lining of the external circumferential canals consists of the epithelial cells and the podocyte‐like cells. The deepest canals lack a lumen; they are filled with the muscle cells surrounded by basal lamina. These branched canals might perform dual functions. First, they increase the surface area and might therefore facilitate ultrafiltration through the podocyte‐like cells. Second, the deepest canals form the thickened muscle wall of the esophagus and could be necessary for antiperistalsis of the gut. J. Morphol., 2011. © 2010 Wiley‐Liss, Inc.     

A study on the cytoplasmic granules of the pericardial gland cells of some bivalve molluscs

The pericardial glands of three bivalve molluscs are composed of convoluted epithelium that appears as pouches on the auricles of Mytilus and as tubules in the connective tissue at the anterior-lateral sides of the pericardial cavity of Mercenaria and Anodonta. The pericardial gland cells are attached to each other by many randomly placed desmosome-like cell junctions and gap junctions. Belt-desmosomes that are characteristic of epithelial cells were not observed. The basal membrane of these cells is invaginated producing complex interdigitating cytoplasmic processes and filtration slits. The pericardial gland cells stain for the presence of iron with Prussian blue stain. Electron-dense and electron-lucent granules of various diameters are present in the cytoplasm. Many electron-dense granules contain ferritin-like particles in which the presence of iron has been demonstrated by microanalysis. It is suggested that these particles are the iron storage protein ferritin since they contain iron, and are water soluble, heat stable, and morphologically similar to mammalian ferritin. Ferritin particles are probably both synthesized and broken down by the pericardial gland cells; thus the pericardial gland cells may be involved in iron homeostasis in these molluscs.     

Structure of the body cavity of the sea spider <Emphasis Type="Italic">Nymphon brevirostre</Emphasis> Hodge, 1863 (Arthropoda: Pycnogonida)

The microscopic anatomy and ultrastructure of the body cavity and adjacent organs in the sea spider Nymphon brevirostre Hodge, 1863 (Pycnogonida, Nymphonidae) were examined by transmission electron microscopy. The longitudinal septa subdividing the body cavity are described: (1) Dohrn’s horizontal septum, (2) lateral heart walls, and (3) paired ventral septa consisting of separate cellular bands. The body cavity is a hemocoel, it has no epithelial lining and is only bordered by a basal lamina. The epidermis, heart, and Dohrn’s septum are not separated from each other by basal laminae and may have a common origin. The cellular bands forming the longitudinal ventral septa are not covered with the basal lamina and presumably derive from cells belonging to the hemocoel. The roles of the morphological structures studied for the circulation of hemolymph are discussed. The gonad lies inside Dohrn’s septum, it is covered with its own basal lamina and surrounded by numerous lacunae of the hemocoel entering the septum. The gonad wall is formed with a single layer of epithelium. The same epithelial cells form the gonad stroma. The gonad cavity is not lined with the basal lamina; muscle cells are present in the gonad wall epithelium, thus rendering the lumen similar to a coelomic cavity. Freely circulating cells of two types are found in the hemocoel: small amebocytes containing electronic-dense granules that are similar to granulocytes of other arthropods, as well as hemocytes with large vacuoles of varying structure that are comparable with plasmatocytes; however some of these may be activated granulocytes.     

Involvement of actin and Na+-K+ ATPase in urine formation of the freshwater pulmonate Helisoma

The site and process of urine formation in the renopericardial system of Helisoma have been investigated. Osmotic pressure and protein content of hemolymph from the heart, pericardial fluid from the pericardial cavity, prourine from the kidney sac, and urine from the ureter have been determined. Osmotic pressure is equal in hemolymph, pericardial fluid, and prourine, but less in urine. Protein content is similar in hemolymph and pericardial fluid, but much less in prourine and urine. Hemoglobin molecules are present in hemolymph and pericardial fluid but not in prourine. It is suggested that in Helisoma the kidney sac is the site of prourine formation, and prourine is an ultrafiltrate of hemolymph. The kidney epithelial cells contain 6- to 7-nm microfilaments which react with heavy meromyosin producing unidirectional arrowheads. Numerous actin filaments are present in the vicinity of the lateral cell membranes and basal processes. It is possible that the actin filaments regulate the extracellular spaces for prourine passage. It is postulated that the actin-rich kidney epithelium may generate hydrostatic pressure for ultrafiltration. Na⁺-K⁺ ATPase is located on the luminal side of the kidney epithelium, which may regulate intracellular fluid level of the kidney epithelial cells, and thereby regulate their cell volume. Thus Na⁺-K⁺ ATPase may be involved in the regulation of extracellular spaces in kidney epithelial cells. The enzyme may participate in the production of hyposmotic urine.     

Ultrastructure of the renopericardial complex in Hypselodoris tricolor (Gastropoda, Nudibranchia)

The histology and ultrastructure of the renopericardial complex of Hypselodoris tricolor (Gastropoda, Nudibranchia, Doridoidea) have been investigated by means of semithin serial sections and transmission electron microscopy (TEM). The examinations revealed a functional metanephridial system comprising a monotocardian heart with ventricle and auricle in a spacious pericardium that is linked with the single, large kidney by a renopericardial duct with prominent ciliation towards its opening. Podocytes as the site of ultrafiltration were not only detected in the auricular epicardium, but also line the entire outer pericardial epithelium. The cuboidal, highly vacuolated excretory cells of the kidney epithelium with extensive basal infoldings and an apical microvillous border indicate secretory and reabsorptive activity. Solitary rhogocytes (pore cells) of the connective tissue and haemocoel represent additional loci of ultrafiltration with a fine structure identical to that of the podocytes (slits between cytoplasmic processes, bridged by fine diaphragms and covered by extracellular matrix). The presence of podocytes situated in the epicardial wall of the auricle is regarded as plesiomorphic for the Mollusca and is confirmed for the Nudibranchia. An additional, extensive and separate ultrafiltration site in the outer pericardial wall is not known from any other taxon of the Mollusca and strongly suggests a significantly increased ultrafiltration activity in H. tricolor.     

Ultrastructural evidence of the excretory function in the asteroid axial organ (Asteroidea,Echinodermata)

The ultrastructure of the axial organ of Asterias amurensis has been studied The organ is a network of canals of the axial coelom separated by haemocoelic spaces. The axial coelom is lined with two types of monociliary cells: podocytes and musculo-epithelial cells. Podocytes form numerous basal processes adjacent to the basal lamina on the coelomic side. Musculo-epithelial cells form processes running along the basal lamina. Some bundles of these processes wrapped in the basal lamina pass through haemocoelic spaces between neighboring coelomic canals. It is hypothesized that the axial organ serves for filtration of fluid from haemocoelic spaces into the axial coelom cavity, from which urine is excreted through the madreporite to the exterior.     

Sieve structure of slit diaphragms of podocytes and pore cells of gastropod molluscs

Summary The ultrastructure of the slit diaphragms between the pedicels of the podocytes of the prosobranch Viviparus viviparus and between the cytoplasmic tongues of the haemocyanin producing pore cells of the pulmonate Lymnaea stagnalis was investigated. In both cell types 2 diaphragms are present in the slits. They form a 3-dimensional sieve structure with holes of respectively 90 × 110 Å (podocyte) and 200 × 220 Å (pore cell). Injection experiments showed that the size of the holes of the pore cell sieve matches that of particles which can be ingested by this cell type. The substructure of the sieves of the molluscs is compared to that of the 2-dimensional sieve of the podocytes of the mouse and the rat.The authors thank Mrs. J.E. Vlugt-van Dalen for technical assistance and Mr. G.W.H. van der Berg for drawing the diagrams. Thanks are furthermore due to Miss B.E.C. Plesch for correcting the English text     

Ultrastructure of the metanephridial system in Aeolosoma bengalense (Annelida)

Summary The excretory system of Aeolosoma bengalense has been examined by light and electron microscopy. The system consists of seven serially arranged paris of metanephridia and six pairs of podocytes (referring to the first zoid of an animal chain). The podocytes surround blood spaces of the alimentary canal forming dorsoventrally running loops that emerge on both sides of it. The two elements of the system have a correlative position, each podocyte extending in close proximity to the funnel of a metanephridium. Only in the region of the first metanephridia are podocytes lacking. The nephrostome of the metanephridia consists of two cells, an inner one, the terminal duct cell, and an outer one enwrapping it, called the mantle cell. Nephrostomal cilia that extend into the coelomic space arise exclusively from the rim of the mantle cell whereas those of the terminal duct cell arranged on its luminal surface protrude into the canal forming a flame. The nephridial canal is ciliated throughout and is either intra- or extracellular. Its initial loops aggregate to form a compact organ, the nephridial body. The middle part of the duct constitutes a loop that ascends at each side of the alimentary canal where it is in intimate contact with its blood spaces. Ultrastructural features of the duct cells suggest a reabsorptive function in two regions, the nephridial body and the uppermost part of the loop. The terminal part of the duct passes through the nephridial body and opens ventrolaterally. Generally, the transverse vascular loops at the gut consist of one podocyte each. In the oesophageal region, where only one pair of podocytes is present, the loops connect the dorsal with the ventral longitudinal vessel. Three pairs of podocytes are present in the dilated region of the intestine emerging from its lateral wall and joining the median ventral vessel or blood spaces near by. In the hind gut, where two pairs of podocytes occur, the loops arise from the dorsolateral part and enter directly the ventral vessel. Cytological features of podocytes resemble those of other animals. The results are discussed on the basis of current theories on the function and the phylogenetic significance of excretory systems in the Annelida.Abbreviations bl basal lamina - bs blood space - bv blood vessel - cf ciliary flame - ci cilia - co connection of the vascular loop with the intestinal blood space - cu cuticle - db dense body - dc duct cell - di dictyosome - za zonula adhearens - dv dorsal vessel - ecb epicuticular body - ev endocytotic vesicle - ic intestinal cell - ici inner cilia - iv intestinal vessel - lm longitudinal muscle - mc mantle cell - mg midgut - mi mitochondrion - mv microvilli - nu nucleus - oci outer cilia - oe oesophagus - pc podocyte - pe pedicel - pel primary elongation of the podocyte - sm slit membrane - tc terminal duct cell - ve vesicle with heterogeneous contents - vv ventral vessel     

Permeability of the podocytes of Lumbricus terrestris (Annelida, Oligochaeta) to different markers

 The distribution of different injected markers between blood vessels and the coelomic cavity of Lumbricus terrestris was investigated by light and electron microscopy in order to show the direction of filtration and the permeability of the basement membrane of podocytes. The present results revealed that ultrafiltration takes place across the ventral vessel as well as through the peri-intestinal blood sinus of the typhlosolis. Furthermore, the filtration processes seem to be restricted to the front part of the body. Fluorescein isothiocyanate (FITC) [molecular weight (MW) 389.4 Da], Procion yellow (MW 873 Da), FITC-labelled dextrans (MW 39 kDa) and gold particles up to a diameter of 10–12 nm passed the podocytes. Evans blue (MW 960.8 Da) could not permeate through the podocytes. The injected gold particles were found inside the extracellular channels of the podocyte, between the microvilli-like processes of the podocyte and on the coelomic side of the peritoneal epithelium. The appearance of gold particles in the previously described structures indicated that filtration takes place from the lumen of the ventral vessel to the coelomic cavity. Accepted: 21 October 1996     

The fine structure of the kidney of Achatina achatina (L.)

Summary The kidney sac of Achatina achatina, the site of primary urine formation, seems to contain no direct structural analogue of the vertebrate glomerular podocytes. The nephrocytes which line the kidney sac and separate the blood from the primary urine are supported by a basal lamina which is permeable to ferritin but impermeable to colloidal gold particles (ca. 100 Å, and 80–240 Å respectively). The blood capillaries within the kidney sac are of two types, fenestrated and unfenestrated. The basal lamina which surrounds them is impermeable to haemocyanin. The nephrocytes are then, bathed apically by primary urine and basally by an ultrafiltrate of the blood. It is proposed that fluid enters the urinary space from the connective tissue by passing between the nephrocytes, perhaps through pores in the septate junctions. Other possible mechanisms of primary urine formation are discussed. The nephrocytes contain peroxisomes which may be involved in urate metabolism.The cells of the ureteral epithelium bear a lumenal microvillous border. Their lateral and basal plasma membranes are elaborately folded. These cytoplasmic folds enclose extracellular channels through which fluid is transported from the urine back into the blood.     

MORPHOLOGICAL BASIS OF EXCRETORY FUNCTION IN NAUSITORA FUSTICULA (JEFFREYS, 1860) (BIVALVIA: TEREDINIDAE)

The function of the excretory system of the teredinid bivalveNausitora fusticula is discussed on the basis of new informationon histology and ultrastructure. The wall of the auricles islined with podocytes that allow haemolymph ultrafiltration tothe pericardial cavity. These podocytes also show apical microvilliwith absorptive activity. The primary urine is drained fromthe pericardial cavity to the afferent ducts by a citiated bulb-likestructure. Theafferent and efferent ducts together form thekidney body. The afferent duct shows structures related to absorption,excretion and conduction of the urine. The efferent ducts, however,have structures concerned only with urine absorption and conduction. (Received 13 January 1997; accepted 15 July 1997)     

Ultrastructure of the coxal gland of the horseshoe crab Limulus polyphemus: Evidence for ultrafiltration and osmoregulation

Electron microscopic examination of the paired coxal glands of the horseshoe crab Limulus polyphemus, focusing on urinary and vascular channels, shows six morphologically distinct regions. Each of four nephridial lobes consists of two cortical layers surrounding a medulla. The outer and inner cortexes contain blood vessels separated by a basement membrane from the urinary space lined by podocytes. Podocyte foot processes are applied to the basement membrane, interdigitate with those from other podocytes, and have a filtration slit diaphragm between them. Cortical morphology demonstrates ultrafiltration of blood, a previously undescribed function of the gland, as well as possible endocytic reabsorption of materials by the podocytes. The medulla drains into the stolon connecting the four lobes. These two areas have urinary tubules of cuboidal epithelium featuring microvillous-like apical projections, cytoplasmic vesicles and vacuoles, elaborate lateral interdigitations with septate junctions, and basal invaginations containing numerous mitochondria. These tubules are closely surrounded by blood channels, lined by a basement membrane containing embedded support cells. The medulla and stolon morphology are suggestive of both ion transport and water movement, in keeping with the gland's role in osmoregulation. The stolon empties into the end sac in the base of the most posterior lobe. It is lined by tall epithelium exhibiting apical overlap, blunt projections into the lumen, apparent endocytic vesicles, and basal plasma membrane infoldings with mitochondria. The end sac drains into the conducting nephric duct, the proximal end of which is lined by a cuticle. J. Morphol. 234:233–252, 1997. © 1997 Wiley-Liss, Inc.     

Fine structure at the basal surface of intestinal epithelium in the midgut region of the balanidae,with special reference to “Neural-like” processes

Observations on fine structure at the basal end of the intestinal epithelium in the midgut region of Balanus balanoides and Balanus improvisus reveal complex interrelationships among several tissues. Numerous elongate cell processes extend towards the intestinal epithelium penetrating between layers of intestinal muscle through blood spaces and into the basal lamina underlying the epithelium. Two types of morphological relationships occur between cell processes and the basal end of the intestinal epithelial cell: 1. The cell process may penetrate the basal lamina and lie closely apposed to the epithelium. 2. The cell process may give rise to narrow, medially-directed, finger-like extensions (projections). The narrow projections penetrate the basal lamina and, in addition, terminate as dilated bulbs within inpocketings of the epithelium. In some respects the cell processes are suggestive of neural tissue.     

Organization of a phyllobranchiate gill from the green shore crab Carcinus maenas (Crustacea,Decapoda)

Summary The phyllobranchiate gills of the green shore crab Carcinus maenas have been examined histologically and ultrastructurally. Each gill lamella is bounded by a chitinous cuticle. The apical surface of the branchial epithelium contacts this cuticle, and a basal lamina segregates the epithelium from an intralamellar hemocoel. In animals acclimated to normal sea water, five epithelial cell types can be identified in the lamellae of the posterior gills: chief cells, striated cells, pillar cells, nephrocytes, and glycocytes. Chief cells are the predominant cells in the branchial epithelium. They are squamous or low cuboidal and likely play a role in respiration. Striated cells, which are probably involved in ionoregulation, are also squamous or low cuboidal. Basal folds of the striated cells contain mitochondria and interdigitate with the bodies and processes of adjacent cells. Pillar cells span the hemocoel to link the proximal and distal sides of a lamella. Nephrocytes are large, spherical cells with voluminous vacuoles. They are rimmed by foot processes or pedicels and frequently associate with the pillar cells. Glycocytes are pleomorphic cells packed with glycogen granules and multigranular rosettes. The glycocytes often mingle with the nephrocytes. Inclusion of the nephrocytes and glycocytes as members of the branchial epithelium is justified by their participation in intercellular junctions and their position internal to the epithelial basal lamina.     

Biogenesis of podocalyxin--the major glomerular sialoglycoprotein--in the newborn rat kidney

The appearance and distribution of podocalyxin on the glomerular epithelium (podocytes) during glomerular development was determined in the newborn rat kidney using specific monoclonal and affinity-purified polyclonal antibodies. Kidneys from 2-day-old rats were perfusion-fixed and processed for immunofluorescence or immunoperoxidase localization or immunogold labeling on ultrathin frozen sections. Podocalyxin first appeared on the apical surfaces of the presumptive podocytes of the S-shaped body above the level of the junctional complexes that connect the cells at this stage. The latter consist of a shallow occluding zonule and a deeper adhering zonule. Early in the capillary loop stage, when the urinary spaces open and the junctional complexes migrate from the apex to the base of the cells, labeling for podocalyxin extended along the lateral plasmalemma above the migrating junctions. In the maturing glomerulus when the foot processes form and the occluding and adhering junctions give way to developing slit diaphragms, podocalyxin was found along all newly-opened surfaces above the occluding junctions or slit membranes. No labeling was found below the latter. Podocalyxin was also detected intracellularly throughout the entire exocytotic pathway--i.e., in the rough endoplasmic reticulum and perinuclear cisternae, in Golgi cisternae and associated vesicles, and in carrier vesicles presumably en route to the cell surface. It is concluded that 1) podocalyxin is synthesized at a high rate in the differentiating podocyte; 2) its distribution is restricted to the apical plus lateral plasmalemmal domain facing the urinary spaces above the migrating junctions; 3) its time of appearance and distribution during glomerular development are identical to that reported earlier for epithelial polyanion; and 4) its synthesis and insertion into the podocyte plasmalemma is closely coupled to the development of the foot processes and filtration slits.     

Structure of the cumulus oophorus at the time of fertilization

Summary The paired external glomus of the fully developed pronephros has been studied in early larvae (ammocoetes) of 2 lamprey species, Lampetra fluviatilis and Petromyzon marinus, several weeks after hatching and newly hatched, by use of light-, scanning (SEM) and transmission (TEM) electron microscopy. Three weeks after hatching the glomus is a complex of capillary loops supplied by a single arteriole branching from the aorta. The glomus consists of 3 cell types: podocytes, fenestrated endothelium, and mesangial cells. A basement membrane, which has a close contact to the podocytes, is the only continuous barrier between blood and the coelomic cavity. The glomus exhibits all fine-structural elements known to be essential for function in the glomeruli of other vertebrates. We therefore assume the pronephric glomus of lampreys to be functional in ultrafiltration, with the ultrafiltrate released into the coelomic cavity. In newly hatched larvae, the structure of the glomus is not fully developed. In this earlier stage several afferent arterioles supply each glomus. The endothelial cells in the glomar capillaries still lack regular epithelial organization and resemble mesenchymal cells. However, the presence of typical podocytes stretching over a continuous basement membrane suggests that the tissue is already capable of ultrafiltration.This paper is dedicated to the memory of Professor W. Bargmann, long-time editor of Cell and Tissue Research, the author of a splendid review on the structure of the vertebrate kidney and a master of German scientific writing