Immunohistochemical demonstration of renin in the juxtaglomerular apparatus of three Bufo species

Summary The cellular localization of renin was examined in the kidneys of some amphibians of the genus Bufo by immunoperoxidase and immunofluorescence techniques with an antiserum to renin isolated from the submandibular gland of the mouse. Immunoreactivity could be demonstrated in the media cells of the afferent arterioles (juxtaglomerular cells) close to as well as at great distance from the glomeruli. Occasionally, media cells of larger arterial vessels were also stained. The immunohistochemical data seem to be in accordance with earlier results obtained with a modified silver impregnation technique (Movat's staining procedure) used for the visualization of juxtaglomerular cells in non-mammalian vertebrates. Mouse kidney tissue, studied for purposes of comparison, showed renin-immunoreactivity as described by earlier investigators, i.e., immunoreactive staining in the afferent arterioles near the glomeruli and in the proximal tubule cells.     

Studies on the juxtaglomerular apparatus

The juxtaglomerular apparatus of the rat was studied after freeze-fracturing with special respect to intercellular junctions. It was found that juxtaglomerular granulated cells of the vas afferens are interconnected by gap junctions to adjacent cells (granulated cells, possibly also smooth muscle cells). Gap junctions have also been found on the surface of lacis cells and mesangial cells. It is therefore concluded that these cells of the juxtaglomerular apparatus and the glomerulus--granulated cells (possibly also smooth muscle cells) of the vas afferens, lacis cells and mesangium cells--form a functional system reacting in a coordinated manner to physiological stimuli.     

Fluorescent Staining of Juxtaglomerular Cells in Frozen Sections

Enzymatic investigations of the juxtaglomerular apparatus often creates the need for visualisation of granulated juxtaglomerular cells (JGC) in preparations subjected to histochemical procedures. In our investigations, Pitcock and Hartroft's (1958) modification of Bowie's method and the Endes et al. (1969) combined trichrome staining proved to be inadequate when applied to fresh cryostat sections, or to formol- or glutaraldehyde-fixetl, gum sucrose-impregnated frozen sections. Friedberg and Reid's (1966) crystal violet procedure for waxembedded kidneys also failed to give uniformly reproducible results. In attempting to find a satisfactory technique for both enzyme and granule staining, we noted Janigan's (1965) and Haratla's (1969) observations on paraffin-embedded JGC, and tested the following fluorochromes: thioflavine T—Fluka, C. I. 49005; auramine O—Merck, C. I. 41000; acridine orange—E. Gurr, C. I. 46005; berberine sulfate—Fluka, C. I. 75160 on 10 μ sections of albino mouse kidneys prepared in 4 different ways as follows:     

A simple method of staining juxtaglomerular granules in the rat kidney for high resolution light microscopy

A simple method for the demonstration of juxtaglomerular granules in Epon embedded semithin (0.5-1 micrometer) sections has been developed as follows: sections are prepared as for routine electron microscopy except that before dehydration, the tissues are immersed in 0.5% uranyl acetate in Veronal acetate buffer (pH 5.0) overnight at room temperature. After sectioning on an ultramicrotome, the semithin sections are briefly stained with toluidine blue-pyronin Y. After staining, the section is rinsed in running tap water and then air dried. Under a light microscope with a 40 X or a 100 X objective, the juxtaglomerular granules appear as deep purple particles and are thus easily separated from the bluish cytoplasm of the juxtaglomerular cells. Cellular organelles in other cells of the kidney were also clearly stained and their fine structure distinguishable.     

A Simple Method of Staining Juxtaglomerular Granules in the Rat Kidney for High Resolution Light Microscopy

A simple method for the demonstration of juxtaglomerular granules in Epon embedded semithin (0.5-1 μm) sections has been developed as follows: sections are prepared as for routine electron microscopy except that before dehydration, the tissues are immersed in 0.5% uranyl acetate in Veronal acetate buffer (pH 5.0) overnight at room temperature. After sectioning on an ultramicro-tome, the semithin sections are briefly stained with toluidine blue-pyronin Y. After staining, the section is rinsed in running tap water and then air dried. Under a light microscope with a 40 × or a 100 × objective, the juxtaglomerular granules appear as deep purple particles and are thus easily separated from the bluish cytoplasm of the juxtaglomerular cells. Cellular organelles in other cells of the kidney were also clearly stained and their fine structure distinguishable.     

Intrarenal localization of renin binding substance in rats

Renin binding substance is a protein that reacts with renin (Mw:40,000) to form a high-molecular-weight renin (Mw:60,000). There is evidence that this substance is present in the renal cortex. However, the exact localization has not been determined. We now report that when glomeruli and tubular segments were isolated from the rat kidney cortex and were frozen and thawed to extract proteins, the high-molecular-weight renin was detected by high performance liquid chromatography, when renin was mixed with an extract of tubular segments, but was not detected with an extract of the glomeruli. Thus, the renin binding substance was demonstrated in the cortical tubular cells but not in the glomeruli. Thus, the renin binding substance was demonstrated in the cortical tubular cells but not in the glomeruli, and the renin binding substance probably does not contribute to the process of biosynthesis of renin in juxtaglomerular cells. Rather, this substance may play a role in tubular functions in the kidney.     

Immunofluorescent localization of Schistosoma mansoni circulating cathodic antigen in tissues of infected mice using monoclonal antibody

In the present study the kinetics of the uptake and deposition of the major circulating cathodic antigen (CCA) of Schistosoma mansoni in liver, spleen, and kidney of S. mansoni infected Swiss mice was investigated in relation to the duration of infection and infection dose (50, 100, 200 cercariae). The presence of antigen was studied with a direct immunofluorescence reaction on frozen sections of the mouse organs, using a fluorescein isothiocyanate (FITC)-labelled mouse IgM monoclonal antibody recognizing a repeating epitope of CCA. CCA was demonstrable from 2 weeks post infection (p.i.) onwards in Kupffer cells in the liver, from 3-4 weeks p.i. onwards in macrophages in the marginal zones in the spleen and from 8 weeks p.i. onwards in kidney glomeruli. The immunofluorescence reactions on CCA in kidney glomeruli, however, remained relatively weak.     

Stimulation of renin secretion from the intact kidney and from isolated glomeruli by the calcium ionophore A23187.

The ionophore A23187 evoked a dose-dependent release of renin from the isolated perfused cat kidney, which was inhibited by calcium deprivation and adrenergic blockade. The latter finding indicates that the effects of A23187 on the intact kidney are mediated mainly by catecholamine release from sympathetic nerve endings. Ionophore also elicited a concentration-dependent enhancement of renin secretion from a pure preparation of glomeruli isolated from cat kidney; this stimulation was still manifest when the glomeruli were superfused with a calcium-free solution. These findings indicate that A23187 evokes renin secretion from juxtaglomerular cells by mobilizing cellular calcium and support the view that an increase in intracellular calcium is intimately involved in the mechanism of renin secretion.     

Immunocytochemical and morphometric studies on the development of renin-immunoreactive cells in the rat kidney]

The development of renin-immunoreactive cells was immunocytochemically studied in Wistar-Imamichi rats. The renin-immunoreactivity was localized in the walls of the abdominal aorta, renal artery and arterioles in the kidney. The renin-immunoreactive cells converged with the progress of development from the renal artery via several arterioles to the afferent arteriole in the kidney. In the afferent arteriole, renin-immunoreactive cells appeared only in those of matured glomeruli. The matured glomerulus first appeared at 17 days of gestation followed by the initial appearance of renin-immunoreactive cells at 18 days. The juxtaglomerular index showing the relation between matured glomeruli and renin-immunoreactive cells increased rapidly until 20 days of gestation, shifted thereafter at a level similar to that at 20 days until 7 days after birth, and increased again until 20 days after birth. Although the area of the transverse section at the hilus of the kidney increased all through the period examined, the number of matured glomeruli increased rapidly from 17 days of gestation to 7 days after birth and maintained a fixed level thereafter. This led to the decrease in the number of matured glomeruli per unit area after 7 days after birth. The fine structure of renin-immunoreactive cells showed no difference according to their sites of localization.     

The renin-angiotensin system in rats made hypertensive by ligation of the kidney poles (38584).

The renin-angiotensin system was studied in experimental renal hypertension produced by ligation of the poles of the left kidney followed by contralateral nephrectomy. Plasma renin concentration of renin substrate was lower and that of angiotensin I converting enzyme was higher in hypertensive animals. The juxtaglomerular index decreased in the medial zone of the kidney, while heavily granulated areas appeared in the poles. Ligated kidneys of rats that remained normotensive showed juxtaglomerular indices intermediate between the control and the hypertensive rats. Differences in renal renin content between the groups correspond to those for the juxtaglomerular index, but were smaller. No differences between the experimental groups were observed in iso-renin content in the brain; however in all animals with ligated kidney poles, hypertensive or normotensive, there was a tendency for iso-renin in the adrenals, left ventricular myocardium, and especially aorta to be lower than in controls.     

Studies on the histochemistry of phosphatase enzymes in the juxtaglomerular complex

Summary The localisation of alkaline-, adenosine tri-, glucose-6- and acid phosphatase was studied in the juxtaglomerular complexes of rat, mouse and human kidneys. An alkaline-and adenosine triphosphatase active region was observed between the macula densa, Goormaghtigh cell group and in the interstitium of the latter. The adenosine triphosphatase activity extended into the lateral cell membranes of the macular cells and in properly incubated sections it did not appear among other distal tubular cells. The granular juxtaglomerular cells were ATP-ase negative. The cells of the human macula densa and the granular juxtaglomerular cells of the rat and mouse showed acid phosphatase activity. The glucose-6-phosphatase reaction, accomplished at acid and alkaline pH, was negative in the JG complex of all three species. The possible role of these enzymes in the function of the JG complex also has been discussed.     

The nerves of the juxtaglomerular apparatus of man and other mammals contain the potent peptide NPY

The juxtaglomerular apparatus, a neuroendocrine unit located in the vascular pole of the glomerulus and influencing blood pressure by the secretion of renin, is known to have a rich supply of monoaminergic nerve fibres. Neuropeptide Tyrosine (NPY), a newly discovered, potent, vasoconstrictor peptide of 36 amino acids, has been found by immunocytochemistry to be present in a dense plexus of fibres around the juxtaglomerular apparatus of man, monkey, mouse, hamster, rat and guinea pig. NPY-immunoreactivity was markedly depleted after chemical sympathectomy by 6-hydroxydopamine. The concentration of NPY within the whole mouse kidney was 29.6 +/- 6.8 pmol/g and fractionation of the extracts demonstrated that the NPY-like immunoreactivity co-eluted from the column in the same position as the porcine NPY standard. The role of this peptide in renal physiology and pathology now needs urgent investigation.     

Myoendothelial contacts in glomerular arterioles and in renal interlobular arteries of rat,mouse and Tupaia belangeri

Summary Cell contacts between elements of the tunica media and the intima in the afferent and efferent glomerular arteriole and in the interlobular artery were studied and evaluated semiquantitatively in thin sections of rat and mouse kidney.In the afferent arterioles, including their juxtaglomerular portion, contacts were seen between endothelial and smooth muscle cells, and between endothelial and granulated (renin producing) cells. The form of these musculoendothelial contacts varied from simple appositions of perikarya and cell processes to extensive club-shaped indentations of endothelial cells into media cells (common) or media cells into endothelial cells (rare). Most of these cell contacts seem to contain myoendothelial gap junctions. Fewer, mostly club-shaped myoendothelial contacts were found in the interlobular arteries of rats and mice than in their afferent arterioles. Simple membrane appositions predominated among the numerous myoendothelial contacts of efferent arterioles. Similar results (without quantitative analysis) were obtained in the kidney of Tupaia belangeri. The myoendothelial contacts may allow the detection and propagation of mechanical (autoregulatory) and humoral stimuli.These studies were supported by the German Research Foundation within the SFB 90 Cardiovasculäres System     

Atrial natriuretic peptide elevates cGMP contents in glomeruli and in distal tubules of rat kidney

Effect of synthetic rat atrial natriuretic peptide (1-28) (ANP) on the cGMP content was studied using defined nephron segments of rat kidney. ANP elevates cGMP contents in glomeruli in a concentration and time-dependent manner. The increase of cGMP was observed in glomeruli, distal convoluted tubule (DCT) and cortical collecting tubule (CCT) (delta %; 279 +/- 35, 148 +/- 10 and 152 +/- 18, respectively), and no effect was observed in proximal convoluted (PCT) and straight tubule (PST). These results suggest that ANP may act directly on the tubular cells as well as glomeruli. In glomeruli, effects of ANP and carbamylcholine on cGMP contents were additive suggesting that these two agents may act on different receptors. Angiotensin II and norepinephrine failed to affect the ANP-induced cGMP production in the glomeruli.     

Increased susceptibility of decay-accelerating factor deficient mice to anti-glomerular basement membrane glomerulonephritis

To prevent complement-mediated autologous tissue damage, host cells express a number of membrane-bound complement inhibitors. Decay-accelerating factor (DAF, CD55) is a GPI-linked membrane complement regulator that is widely expressed in mammalian tissues including the kidney. DAF inhibits the C3 convertase of both the classical and alternative pathways. Although DAF deficiency contributes to the human hematological syndrome paroxysmal nocturnal hemoglobinuria, the relevance of DAF in autoimmune tissue damage such as immune glomerulonephritis remains to be determined. In this study, we have investigated the susceptibility of knockout mice that are deficient in GPI-anchored DAF to nephrotoxic serum nephritis. Injection of a subnephritogenic dose of rabbit anti-mouse glomerular basement membrane serum induced glomerular disease in DAF knockout mice but not in wild-type controls. When examined at 8 days after anti-glomerular basement membrane treatment, DAF knockout mice had a much higher percentage of diseased glomeruli than wild-type mice (68.8 +/- 25.0 vs 10.0 +/- 3.5%; p < 0.01). Morphologically, DAF knockout mice displayed increased glomerular volume (516 +/- 68 vs 325 +/- 18 x 10(3) microm(3) per glomerulus; p < 0.0001) and cellularity (47.1 +/- 8.9 vs 32.0 +/- 3.1 cells per glomerulus; p < 0.01). Although the blood urea nitrogen level showed no difference between the two groups, proteinuria was observed in the knockout mice but not in the wild-type mice (1.4 +/- 0.7 vs 0.02 +/- 0.01 mg/24 h albumin excretion). The morphological and functional abnormalities in the knockout mouse kidney were associated with evidence of increased complement activation in the glomeruli. These results support the conclusion that membrane C3 convertase inhibitors like DAF play a protective role in complement-mediated immune glomerular damage in vivo.     

Distribution of glomerular peripolar cells in different mammalian species

Summary Peripolar cells are granulated glomerular epithelial cells that form a cuff around the vascular pole of the glomerulus. Quantitation of these cells in 17 species of mammals (including man, several laboratory animals and a variety of other species) indicated that they were detectable by light microscopy in all but one of the mammals that were examined (the Australian hopping mouse). In adult mammals with detectable peripolar cells, the peripolar cell index (the percentage of randomly sectioned glomeruli that displayed peripolar cells in histological sections of kidney) ranged from 0.15 (for echidna) to 11.86 (for sheep). Newborn lambs and rats showed strikingly high values (23.30 and 10.76, respectively) compared with their adult counterparts. Using electron microscopy, peripolar cells were observed in all species that were examined, including the Australian hopping mouse. Morphologically, peripolar cells were similar in all species although their size and granule population varied. They showed a predominantly outer cortical glomerular distribution and a close anatomical relationship with the renin-containing myoepithelioid cells. These findings indicate that peripolar cells are present in a wide variety of species and support the view that such cells may play a significant role in the regulation of normal renal function.     

Localization of S-adenosylhomocysteine hydrolase in the rat kidney.

S-adenosylhomocysteine (SAH) hydrolase is a cytosolic enzyme present in the kidney. Enzyme activities of SAH hydrolase were measured in the kidney in isolated glomeruli and tubules. SAH hydrolase activity was 0.62 +/- 0.02 mU/mg in the kidney, 0.32 +/- 0.03 mU/mg in the glomeruli, and 0.50 +/- 0.02 mU/mg in isolated tubules. Using immunohistochemical methods, we describe the localization of the enzyme SAH hydrolase in rat kidney with a highly specific antibody raised in rabbits against purified SAH hydrolase from bovine kidney. This antibody crossreacts to almost the same extent with the SAH hydrolase from different species such as rat, pig, and human. Using light microscopy, SAH hydrolase was visualized by the biotin-streptavidin-alkaline phosphatase immunohistochemical procedure. SAH hydrolase immunostaining was observed in glomeruli and in the epithelium of the proximal and distal tubules. The collecting ducts of the cortex and medulla were homogeneously stained. By using double immunofluorescence staining and two-channel immunofluorescence confocal laser scanning microscopy, we differentiated the glomerular cells (endothelium, mesangium, podocytes) and found intensive staining of podocytes. Our results show that the enzyme SAH hydrolase is found ubiquitously in the rat kidney. The prominent staining of SAH hydrolase in the podocytes may reflect high rates of transmethylation. (J Histochem Cytochem 48:211-218, 2000)     

Atrial natriuretic factor (ANF) binding sites in frog kidney and adrenal.

Atrial natriuretic factor (ANF) binding sites were localized and quantified in kidney and adrenal of the frog Rana temporaria by quantitative in vitro autoradiography. [125I]-rat ANF(99-126) binding was present in kidney glomeruli and in the outer layer of interrenal tissue in the adrenal gland. ANF binding exhibited positive cooperativity with a half-maximal binding concentration (EC50) of 102 +/- 16 pM in glomeruli and 93 +/- 19 pM in interrenal tissue (n = 8). The corresponding maximal binding capacities (Bmax) were 1.33 +/- 0.16 and 1.21 +/- 0.36 fmol/mm2. [125I]-Rat ANF(99-126) binding was competitively displaced by unlabeled ANF analogues with an intact disulfide bridge showing a lower affinity than the iodinated ligand. The presence of ANF binding in glomeruli and steroidogenic interrenal cells suggests physiological functions of ANF for the osmomineral regulation in the frog by influencing glomerular filtration rate and adrenal steroid secretion.     

Cellular origin of fibronectin in interspecies hybrid kidneys

The cellular origin of fibronectin in the kidney was studied in three experimental models. Immunohistochemical techniques that use cross-reacting or species-specific antibodies against mouse or chicken fibronectin were employed. In the first model studied, initially avascular mouse kidneys cultured on avian chorioallantoic membranes differentiate into epithelial kidney tubules and become vascularized by chorioallantoic vessels. Subsequently, hybrid glomeruli composed of mouse podocytes and avian endothelial-mesangial cells form. In immunohistochemical studies, cross-reacting antibodies to fibronectin stained vascular walls, tubular basement membranes, interstitium, and glomeruli of mouse kidney grafts. The species-specific antibodies reacting only with mouse fibronectin stained interstitial areas and tubular basement membranes, but showed no reaction with hybrid glomeruli and avian vascular walls. In contrast, species-specific antibodies against chicken fibronectin stained both the interstitial areas and the vascular walls as well as the endothelial-mesangial areas of the hybrid glomeruli, but did not stain the mouse-derived epithelial structures of the kidneys. In the second model, embryonic kidneys cultured under avascular conditions in vitro develop glomerular tufts, which are devoid of endothelial cells. These explants showed fluorescence staining for fibronectin only in tubular basement membranes and in interstitium. The avascular, purely epithelial glomerular bodies remained unstained. Finally, in outgrowths of separated embryonic glomeruli, the cross-reacting fibronectin antibodies revealed two populations of cells: one devoid of fibronectin and another expressing fibronectin in strong fibrillar and granular patterns. These results favor the idea that the main endogenous cellular sources for fibronectin in the embryonic kidney are the interstitial and vascular cells. All experiments presented here suggest that fibronectin is not synthesized by glomerular epithelial cells in vivo.