The structure of the kidney of Japanese newts, Triturus (Cynops) pyrrhogaster

New Data on Nephron Microanatomy and Ultrastructure of Senegal Bichir (Polypterus senegalus)

Simple Summary

Transitional forms of animals between Pisces and Amphibia are interesting to study, as they are the first to begin the development of a new environment - terrestrial. Such a transitional form are amphibious fish. The study of the structure of the nephron, the main structure that performs an osmoregulatory function, makes it possible to build evolutionary series that describe the processes of transition from the aquatic environment to the terrestrial one. Bichirs is a monophyletic group that arose in the Devonian and formed a species complex only in the Neogene. They share features with lungfish and amphibians, which formed convergently in the early stages of evolution. Therefore Bichirs are of great interest as a transitional form of animals. This study presents new data on the nephron age of Polypterus senegalus. Two groups of features are described. The first group consists of ancestral traits that have been preserved in the modern population of P. senegalus and are associated with habitat conditions in the aquatic environment. The second group is a complex of characters associated with the adaptation of P. senegalus to air breathing and periodic ground migrations.

Abstract

This study presents new data on the microanatomy and ultrastructure of Polypterus senegalus nephrons. It was shown that the diameter and ultrastructure of renal corpuscles, a well-developed neck segment, and ultrastructure of two types of epithelial cells of the proximal tubule are ancestral signs of the modern population of P. senegalus associated with habitat conditions in the aquatic environment. The outer diameter of the tubules, the height of the epitheliocytes, the presence of two types of epithelial cells of the intermediate and distal tubules of the corresponding ultrastructure, and a large area of nephrogenic tissue are progressive features of the modern population of P. senegalus, associated with adaptation to air respiration and periodic terrestrial migrations, which were formed at the early stages of evolution of P. senegalus convergently with lungfish and amphibians.

Molecular determinants of protein reabsorption in the amphibian kidneys

Participation of molecular determinants of endocytosis in the processes of glomerular filtration and tubular reabsorption of albumin and lysozyme in the mesonephros of grass frogs (Rana temporaria L.), lake frogs (Rana ridibunda P.), and newts (Triturus vulgaris L.) is investigated. In all studied species, the constitutive expression of endocytic receptors in proximal tubule (PT) cells is established using immunofluorescence microscopy and immunoblotting. The certain stages of lysozyme and albumin endocytosis involving megalin/LRP2, cubilin, clathrin and protein Rab11 are detailed, and the central role of ligand-induced megalin/LRP2 activity in this process is shown. Increased ligand-induced expression for clathrin and Rab11was also found. In grass frogs, the different patterns of endocytic receptors and both absorbed proteins in the initial parts of proximal tubules suggest the proximo-distal specialization of absorptive processes along these tubule segments, similar to this in more complex mammalian nephrons. This data, as well as the revealed peculiarities of ligand-receptor interactions during intracellular trafficking of proteins prove that megalin is mainly involved in the absorption of lysozyme. At the same time, albumin absorption is mediated by both receptors, or cubilin contributes the most. The detection of endocytic receptor in glomerular structural elements in frogs and newts suggests the participation of filtration barrier components in endocytosis of filterable proteins. The results represent a new contribution to the study of the fundamental mechanisms of renal protein uptake in the amphibian mesonephros as a more primitive kidney compared to mammalian metanephros.

Amphibian Renal Disease

Amphibians are a remarkably diverse group of vertebrates with lifestyles ranging from fully aquatic to entirely terrestrial. Although some aspects of renal anatomy and physiology are similar among all amphibians, species differences in nitrogenous waste production and broad normal variation in plasma osmolality and composition make definitive antemortem diagnosis of renal disease challenging. Treatment is often empirical and aimed at addressing possible underlying infection, reducing abnormal fluid accumulation, and optimizing husbandry practices to support metabolic and fluid homeostasis. This article reviews amphibian renal anatomy and physiology, provides recommendations for diagnostic and therapeutic options, and discusses etiologies of renal disease.

Modifications of the genital kidney proximal and distal tubules for sperm transport in Notophthalmus viridescens (Amphibia, Urodela, Salamandridae)

Male salamanders use nephrons from the genital kidney to transport sperm from the testicular lobules to the Wolffian duct. The microstructure of the epithelia of the genital kidney proximal tubule and distal tubule was studied over 1 year in a population of Notophthalmus viridescens from Crawford and Pike counties in central Missouri. Through ultrastructural analysis, we were able to support the hypothesis that the genital kidney nephrons are modified to aid in the transportation of sperm. A lack of folding of the basal plasma membrane, in both the genital kidney proximal and distal tubules when compared to the pelvic kidney proximal and distal tubules, reduces the surface area and thus likely decreases the efficiency of reabsorption in these nephron regions of the genital kidney. Ciliated epithelial cells are also present along the entire length of the genital kidney proximal tubule, but are lacking in the epithelium of the pelvic kidney proximal tubule. The exact function of these cilia remains unknown, but they may aid in mixing of seminal fluids or the transportation of immature sperm through the genital kidney nephrons. Ultrastructural analysis of proximal and distal tubules of the genital kidney revealed no seasonal variation in cellular activity and no mass production of seminal fluids throughout the reproductive cycle. Thus, we failed to support the hypothesis that the cellular activity of the epithelia lining the genital kidney nephrons is correlated to specific events in the reproductive cycle. The cytoplasmic contents and overall structure of the genital and pelvic kidney epithelial cells were similar to recent observations in Ambystoma maculatum, with the absence of abundant dense bodies apically in the epithelial cells lining the genital kidney distal tubule.

The testicular sperm ducts and genital kidney of male Ambystoma maculatum (Amphibia, Urodela, Ambystomatidae)

The ducts associated with sperm transport from the testicular lobules to the Wolffian ducts in Ambystoma maculatum were examined with transmission electron microscopy. Based on the ultrastructure and historical precedence, new terminology for this network of ducts is proposed that better represents primary hypotheses of homology. Furthermore, the terminology proposed better characterizes the distinct regions of the sperm transport ducts in salamanders based on anatomy and should, therefore, lead to more accurate comparisons in the future. While developing the above ontology, we also tested the hypothesis that nephrons from the genital kidney are modified from those of the pelvic kidney due to the fact that the former nephrons function in sperm transport. Our ultrastructural analysis of the genital kidney supports this hypothesis, as the basal plasma membrane of distinct functional regions of the nephron (proximal convoluted tubule, distal convoluted tubule, and collecting tubule) appear less folded (indicating decreased surface area and reduced reabsorption efficiency) and the proximal convoluted tubule possesses ciliated epithelial cells along its entire length. Furthermore, visible luminal filtrate is absent from the nephrons of the genital kidney throughout their entire length. Thus, it appears that the nephrons of the genital kidney have reduced reabsorptive capacity and ciliated cells of the proximal convoluted tubule may increase the movement of immature sperm through the sperm transport ducts or aid in the mixing of seminal fluids within the ducts.

Ultrastructure of the nephron in the soft-shelled turtle, Pelodiscus sinensis (Reptilia, Chelonia, Trionychidae)

The structure of the nephron in adult soft-shelled turtles (Pelodiscus sinensis) was studied by light microscopy, transmission and scanning electron microscopy. The kidney contained 5-6 renal lobes. Nephrons of P. sinensis are composed of a renal corpuscle (RC) and of a renal tubule that appears divided morphologically into five distinct segments: neck segment (NS) (This segment is only present in approximately 10% of the nephrons), proximal tubule (PT), intermediate segment (IS), distal tubule (DT), and collecting duct (CD). The RCs and most of the convoluted DTs lie in the central zone, while the PTs and the CDs lie in the peripheral zone of the renal lobe. The renal corpuscle is relatively large with especial processes in podocytes and a thick basement membrane. The podocyte processes covering a large capillary area can be observed by TEM, and the major podocyte processes formed a very specific pattern in SEM. The podocyte processes expand to form a flattened network over the whole capillary loops surface, and only may observe little filtration slits in glomerular area. The neck segment when presentis short and has a relatively narrow lumen, consisting of cuboidal or squamous cells. There is a well-developed endocytic-lysosomal apparatus in the apical cytoplasm of the PT. The proximal tubule and intermediate segment cells show some differences between male and female. It showed that proximal tubule cells of male soft-shelt turtle contain lateral intercellular spaces, into which extensions of the cell membrane protrude, and the basal cell membrane forms a conspicuous labyrinth. Whereas, the basal and lateral cell membranes of the female are smooth, and no later-basal intercellular spaces. The differences between male and female in the middle segment cells is similar to proximal tubule cells. Not previously reported in vertebrate kidneys. The IS is the narrowest nephron segment, formed by multiciliated as well as nonciliated cells. In DT cells, basolateral interdigitations and infoldings are particularly well-developed. The CD contains clear cells with numerous secretory granules and dark cells with dense mitochondria and an elaborate Golgi complex. This study was undertaken in order to disclose specific kidney features in P. sinensis that could be related to function. In addition, the ultrastructure of the nephrons in P. sinensis are discussed in relation to other turtles and vertebrates.

Beta-cytoplasmic actin localization in vertebrate glomerular podocytes

The unique cytoarchitecture of glomerular podocytes is conserved in vertebrate evolution. Actin filaments play a crucial role in the formation of the conserved cytoarchitecture, though several isoforms of cytoplasmic actin have been found in vertebrates. The present study examined the expression and subcellular distribution of the beta-cytoplasmic actin (beta-actin) isoform in the podocytes of six vertebrate species by means of immunohistochemical techniques to reveal whether the beta-actin isoform is involved in the formation of podocyte cytoarchitecture throughout vertebrates. beta-actin was predominantly localized at the foot processes in carp, turtle, quail, and rat podocytes in addition to actin filament condensations, which were found only in carp and rat podocytes. The actin filament condensations in rats were in direct contact with the basal plasma membrane, but those in carp were found at the cell body and separated from the basal plasma membrane. In contrast with the above four species, beta-actin was not detected in podocytes in two amphibians-newt and frog, although podocyte foot processes are actin-filament based cytoplasmic protrusions in these species as well as in other vertebrates. In conclusion, the beta-actin isoform is involved in the formation of the podocyte actin cytoskeleton in vertebrates except for amphibians. Several kinds of unconventional cytoplasmic actins other than beta- and gamma-cytoplasmic actins are known to be expressed in amphibians, making it highly likely that one of these isoforms, instead of beta-actin, constructs actin filaments in the foot processes of newt and frog podocytes.

Microanatomy and ultrastructure of the kidney of the African lungfishProtopterus dolloi

The Dipnoi (lungfishes) have developed true lungs, having the ability to take oxygen from both the gills and the lungs. During the tropical dry season, many lungfish estivate on land, breathing only air. The estivation period is accompanied by profound functional modifications, including the suppression of urine. Thus, the lungfish kidney must be designed to cope with these dramatic cyclic changes in renal function. We study here the microanatomy and the structure of the kidney of the African lungfish Protopterus dolloi, maintained under controlled freshwater conditions. Chemical microdissection, light microscopy, and scanning and transmission electron microscopy have been used. The nephrons of P. dolloi are composed of a renal corpuscle (RC) and of a renal tubule that appears divided into five morphologically distinct segments: neck segment (NS), proximal tubule (PT), intermediate segment (IS), distal tubule (DT), and collecting tubule (CT). Paired CTs abut into a collecting duct, the latter emptying into an archinephric duct. The RCs lie in the mid-zone of the kidney, between the PTs and the convoluted DTs. The spatial distribution of these elements allows recognition of a kidney zonation. The RCs group into clusters (3-4 RCs per cluster) that are supplied by a single arteriole surrounded by pericytes. Each cluster appears to represent a functional unit with a common hemodynamic regulatory mechanism. The major processes of the podocytes form flattened networks that appear to constitute an integrated system due to the presence of gap junctions. The existence of mesangial cells with large cell processes, and of mesangial cells with a dendritic appearance, suggests a complex functional role (contractile and phagocytic) for the mesangium. The NS and the IS are the narrowest nephron segments, formed only by multiciliated cells. The PT and the DT can be subdivided, based on the tubular morphology and on cell composition, into portions I and II: PTI is formed only by brush border (BB) cells, while PTII contains BB and multiciliated cells. The DTI is formed by segment-specific cells, while the DTII contains segment-specific and a small number of flask cells. The CT contains principal and flask cells in a 5:1 ratio. The flask cells adopt two different configurations (with a narrow canaliculus or with a large cavity). The main goal of this study was to disclose specific kidney features that could be related to function, phylogeny, and habitat. In addition, the present results constitute the basis for a study of the morphologic changes that should occur in the kidney of P. dolloi during estivation.

Morphology of the kidney in the West African caecilian,Geotrypetes seraphini(Amphibia, Gymnophiona, Caeciliidae)

This study deals with the morphology and ultrastructure of the mesonephros in adult caecilians of the species Geotrypetes seraphini. Based on serial sections in paraffin and araldite, nephrons are reconstructed and the cellular characteristics of different nephron segments described. The long and slender mesonephric kidneys of G. seraphini are broadest caudally and taper toward the front, where the organs are divided into smaller segmental divisions. Two nephron types can be distinguished on the basis of their connections to the coelom and their position within the nephric tissue: ventral nephrons connect to the coelom via a ciliated peritoneal funnel, whereas medial nephrons lack this connection. Both nephron types are composed of a filtration unit, the Malpighian corpuscle, and a renal tubule, which can be divided into six morphologically distinct segments: neck segment, proximal tubule, intermediate segment, early distal tubule, late distal tubule, and collecting tubule. Collecting tubules merge and form a branch system that opens into collecting ducts. Collecting ducts empty into the Wolffian duct. Proximal tubules of nephrons in the frontal divisions are morphologically different from the proximal tubules of more caudal kidney regions. Distal tubule subdivision is only clearly recognizable at the electron microscopic level. The length of each nephron segment is calculated from a ventral nephron with a total length of approximately 3.8 mm, and the course of the segments within the nephric tissue is reported. The number of nephrons was estimated at 1,700 units in each kidney. The segmentation and ultrastructure of the mesonephric nephrons in G. seraphini are discussed in relation to nephron descriptions from other caecilians and we further discuss the evolutionary origin of the amphibian nephron.

Histology of the kidney and urinary bladder of Siphonops annulatus (Amphibia-Gymnophiona)

The histology of the kidney and urinary bladder of Siphonops annulatus was studied by light microscopy in semithin sections of tissue embedded in hydrophilic resin. The kidney's nephron comprises the renal corpuscle, neck segment, proximal tubule, intermediate segment, distal tubule and collecting tubule. Nephrostomes are present. This structure, the neck segment, and intermediate tubules present long cilia, and probably play important roles in the propulsion of the peritoneal fluid and glomerular filtrate. The proximal tubule cells possess loosely packed microvilli and contain abundant polymorphic granules and vesicles that assume the aspect of lysosomes in different stages of intracellular digestion. The distal tubules are characterized by large, vertically disposed mitochondria assuming the aspect of ions transporting cells. The urinary bladder is lined with a transitional epithelium, whose aspect varies according to the quantity of urine.

A scanning electron microscope study of the neck segment of the rabbit nephron

The three-dimensional structure of the neck segment (NS) of the rabbit nephrons was studied by scanning electron microscopy (after fracture, micro-dissection, or after corrosion nephron casts), and by the air-cast method. The NS was observed at the glomerulotubular junction in 68.5% of all nephrons. In every case the NS appeared as a straight tube with its long axis oriented radially in relation to the glomerulus. Although the external diameter of the NS was smaller than that of the proximal tubule, its luminal diameter was greater. No valve-like structures were observed. Three cell types were observed in the NS: parietal-like, tubule-like, and intermediate. Parietal-like cells showed the same morphology as the parietal cells of the Bowman's capsule. Parietal-like cells constituted the only cell type in 25% of the NS. Tubule-like cells showed morphologic characteristics similar to proximal tubule cells; however, their microvilli were less numerous and exhibited an irregular pattern. Intermediate cells presented an intermediate morphology between tubule-like and parietal cells. In 75% of all NS, the three cellular types were present at the same time. The presence of tubule-like and intermediate cells is interpreted as the result of metaplasic transformation of the parietal cells. Our observations suggest that, in rabbits, the presence of the NS can be explained on the basis of phenotypical lability of the cells located at the glomerulo-tubular junction.

Structure of the kidney in the crab-eating frog, Rana cancrivora

The structure of the nephron in the ranid frog, Rana cancrivora, was studied by light and electron microscopy. This frog is the only amphibian species to live in mangrove swamps of very high salinity. The nephron consists of the following parts: renal corpuscle, ciliated neck segment, proximal tubule, ciliated intermediate segment, distal tubule, connecting tubule, and collecting duct. The distal tubule is located in the ventromedial region of the kidney, and the other tubules are situated in the dorsolateral region. Renal corpuscles are found between the two regions. Some renal corpuscles have a wide Bowman's space because of the small glomerulus within them. The proximal tubules are composed of columnar cells with a dense luminal brush border of long microvilli and numerous apical vesicles and vacuoles. The initial part of the distal tubule consists of heavily interdigitated cells, characterized by a very regular palisade arrangement of mitochondria. In the terminal part of the distal tubule, shorter mitochondria of the infolding cells are situated irregularly around the nucleus. The connecting tubule consists of principal cells and canaliculus cells. The collecting duct consists of columnar or cuboidal cells; cytoplasmic organelles are relatively sparse. The canaliculus cells are intercalated between principal cells from the terminal distal tubule to the proximal part of the collecting duct. Our findings indicate that the kidney of R. cancrivora is structurally similar to kidneys of other amphibians. These findings are discussed with regard to probable correlations between ultrastructure and function in R. cancrivora.

Granulated peripolar epithelial cells in the renal corpuscle of marine elasmobranch fish

Granulated epithelial cells at the vascular pole of the renal corpuscle, peripolar cells, have been found in the kidneys of five species of elasmobranchs, the little skate (Raja erinacea), the smooth dogfish shark (Mustelus canis), the Atlantic sharpnose shark (Rhizoprionodon terraenovae), the scalloped hammerhead shark (Sphyrna lewini), and the cow-nosed ray (Rhinoptera bonasus). In a sixth elasmobranch, the spiny dogfish shark (Squalus acanthias), the peripolar cells could not be identified among numerous other granulated epithelial cells. The peripolar cells are located at the transition between the parietal epithelium of Bowman's capsule and the visceral epithelium (podocytes) of the glomerulus, thus forming a cuff-like arrangement surrounding the hilar vessels of the renal corpuscle. These cells may have granules and/or vacuoles. Electron microscopy shows that the granules are membrane-bounded, and contain either a homogeneous material or a paracrystalline structure with a repeating period of about 18 nm. The vacuoles are electron lucent or may contain remnants of a granule. These epithelial cells lie close to the granulated cells of the glomerular afferent arteriole. They correspond to the granular peripolar cells of the mammalian, avian and amphibian kidney. The present study is the first reported occurrence of peripolar cells in a marine organism or in either bony or cartilagenous fish.

Ultrastructure of the kidney of a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona). I. Renal corpuscle, neck segment, proximal tubule and intermediate segment

The ultrastructure of the renal corpuscle, the neck segment, the proximal tubule and the intermediate segment of the kidney of a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona) was examined by means of transmission electron microscopy (TEM), scanning electron microscopy (SEM) and freeze-fracture technique. The glomerular filter apparatus consists of the podocyte epithelium, a distinct basement membrane, a subendothelial space and the capillary endothelium. Emanating from the podocyte cell body, several long primary processes encircle neighboring capillaries. The short slender foot processes originating from the primary processes interdigitate with those from other primary processes, thereby forming the meandering filtration slit. Thick bundles of microfilaments are found in the primary processes, but absent in the foot processes. The basement membrane consists of a lamina rara externa and a rather thin lamina densa (50 nm thickness). The wide subendothelial space contains abundant microfibrils, a few collagen fibrils and many thin processes of mesangial cells. The endothelium is flat and fenestrated (compared to mammals displaying relatively few fenestrations); some of the fenestrations are bridged by a diaphragm. The glomerular mesangium is made up of the mesangial cells and a prominent mesangial matrix containing microfibrils and collagen fibrils. The cells of the neck and intermediate segments display numerous cilia with their microtubules arranged in the typical 9 + 2 pattern. The basal bodies of the cilia are attached to thick filaments with a clear crossbanding pattern of 65 nm periodicity. The proximal tubule is composed of cells typical for this segment (PT cells) and light cells lacking a brush border (bald-headed cells). The PT cells measure 10-25 micron in height and 15-30 micron in width and do not interdigitate at their lateral borders with each other. Their basolateral cell membrane is amplified by many folds projecting into lateral intercellular spaces and into basal recesses. The brush border is scarce and composed of loosely arranged short microvilli.

Ultrastructure of the kidney of a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona). II. Distal tubule, connecting tubule, collecting duct and Wolffian duct

The ultrastructure of the distal nephron, the collecting duct and the Wolffian duct was studied in a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona) by transmission and scanning electron microscopy (TEM, SEM). The distal tubule (DT) is made up of one type of cell that has a well-developed membrane labyrinth established both by interdigitating processes and by interlocking ramifications. The processes contain large mitochondria, the ramifications do not. The tight junction is shallow and elongated by a meandering course. The connecting tubule (CNT) is composed of CNT cells proper and intercalated cells, both of which are cuboidal in shape. The CNT cells are characterized by many lateral interlocking folds. The intercalated cells have a dark cytoplasm densely filled with mitochondria. Their apical cell membrane is typically amplified by microplicae beneath which a layer of globular particles (studs) is found. The collecting duct (CD) is composed of principal cells and intercalated cells, again both cuboidal in shape. The CD epithelium is characterized by dilated intercellular spaces, which are often filled with lateral microfolds projecting from adjacent principal cells. The apical membrane is covered by a prominent glycocalyx. The intercalated cells in the CD are similar to those in the CNT. The Wolffian duct (WD) has a tall pseudostratified epithelium established by WD cells proper, intercalated cells and basal cells. The WD cells contain irregular-shaped dense granules located beneath the apical cell membrane. The intercalated cells of the WD have a dark cytoplasm with many mitochondria; their nuclei display a dense chromatin pattern.

The structural organization of the kidney of Typhlonectes compressicaudus (Amphibia, Gymnophiona)

The structural organization of the kidney of Typhlonectes compressicaudus (Amphibia, Gymnophiona) was studied by light microscopic (LM) examination of serial paraffin and semithin Epon sections. The kidney is slender and quite long and has a mesonephric segmental construction; the excretory duct (Wolffian duct), running along the lateral side of the kidney, segmentally receives the terminal trunks of the collecting duct system. The nephron has the following parts: renal corpuscle, neck segment, proximal tubule, intermediate segment, distal tubule and connecting tubule. The distal tubule is located in a ventromedial (central) zone of the kidney; all other tubular segments lie in a dorsolateral (peripheral) zone. The renal corpuscles are found at the border between these two zones. The renal corpuscle is very large; its urinary pole faces the peripheral zone. A small proportion of neck segments receive either a nephrostomal duct or a blind branch. The proximal tubule is a thick, highly convoluted tubule. The intermediate segment is ciliated and makes a few coils. The distal tubule is composed of three portions: a highly convoluted part in the central zone, subsequently an attachment site with the renal corpuscle and a short postattachment-part. The connecting tubule and the collecting duct have a heterogeneous epithelium consisting of light and dark cells. The collecting duct is distinguished by dilated intercellular spaces. The Wolffian duct has a pseudostratified epithelium. The present study correlates the course and segmentation of the renal tubule of Typhlonectes. The tubule has three major convolutions. The first occurs in the proximal tubule in the peripheral zone; the second is established by the distal tubule and occurs in the central zone; the third is formed by the connecting tubule and is found in the peripheral zone.

Ba2+-sensitive potassium permeability of the apical membrane in newt kidney proximal tubule

The apical membrane K+ permeability of the newt proximal tubular cells was examined in the doubly perfused isolated kidney by measuring the apical membrane potential change (Va change) during alteration of luminal K+ concentration and resultant voltage deflections caused by current pulse injection into the lumen. Va change/decade for K+ was 50 mV at K+ concentration higher than 25 mM, and the resistance of the apical membrane decreased by 58% of control when luminal K+ concentration was increased from 2.5 to 25 mM. Ba2+ (1 mM in the lumen) reduced Va change/decade to 24 mV and increased the apical membrane resistance by 70%. These data support the view that Ba2+-sensitive K+ conductance exists in the apical membrane of the newt proximal tubule. Furthermore, intracellular K+ activity measured by K+-selective electrode was 82.4 +/- 3.6 meq/liter, which was higher than that predicted from the Nernst equation for K+ across both cell membranes. Thus, it is concluded that cell K+ passively diffuses, at least in part, through the K+ conductive pathway of the apical membrane.

The elasmobranch kidney. I. Gross anatomy and general distribution of the nephrons

The morphology of the little skate (Raja erinacea) and spiny dogfish shark (Squalus acanthias) nephron has been investigated in sexually mature females by 1) gross observations of the kidney surfaces, 2) vascular injections, 3) scanning electron microscopy, 4) light microscopy. In the little skate, each nephron is highly complex and begins at the urinary pole of the renal corpuscle, which is located between a thin, dorsal bundle zone and a thicker, ventral sinus zone. The nephron loops back and forth, repeatedly entering and exiting each zone. In the bundle zone, segments from each nephron form a bundle of 5 tubules (tubular bundle) which are arranged in a countercurrent loop fashion. A peritubular sheath composed of closely packed, squamous cells wraps the 5 nephron segments of the tubular bundle together and separates each bundle from the next. In the sinus zone the tubules from many nephrons mix freely with each other in large blood sinuses. In the spiny dogfish, the nephron displays a complex pattern similar to that of the skate. Renal corpuscles are adjacent to a bundle zone composed of tubular bundles, each wrapped by a peritubular sheath in a cell-rich connective tissue matrix. However, the bundle zone is not limited to the dorsal region of the shark kidney but extends ventrally along deep interlobular septa. The sinus zone of the shark is like that of the skate except that it is not limited to the ventral regions of the kidney.

The structure of the kidney from the freshwater teleost Carassius auratus

The structure of the kidney of the crucian carp (Carassius auratus; a freshwater teleost, Cypriniformes) was studied by means of reconstruction from serial paraffin and semithin sections. In C. auratus, the Wolffian duct traverses the entire kidney. At various levels collecting ducts of different length and thickness join the Wolffian duct at right angles. Each collecting duct accepts a large number of connecting tubules, which are established by the joining of many nephrons. A regular pattern concerning the distribution of nephrons and the fusion of renal tubules is not apparent. Four segments have been distinguished in renal tubules; 1) proximal tubule, 2) distal tubule, 3) connecting tubule and 4) collecting duct. A neck and an intermediate segment are absent. The proximal tubule is established by proximal tubule cells which bear a brush border and have a conspicuous apical cytoplasmic rim containing few cell organelles, ciliated cells, mucous cells and dark cells. In the first part of the proximal tubule the brush border and the apical cytoplasmic rim of proximal tubule cells are well developed. Ciliated cells are interposed between proximal tubule cells, decreasing in number toward the end of this part. In the second part ciliated cells are absent and dark cells are numerous. In the third part the brush border and the apical cytoplasmic rim of proximal tubule cells are scarcely developed. Ciliated cells reappear and increase in number toward the distal tubule. The distal and connecting tubule are similar in epithelial structure. Connecting tubules are joined distal tubules and thus they belong to two or more nephrons.(ABSTRACT TRUNCATED AT 250 WORDS)