Sex-related differences in the handling of fluorescent ovalbumin by the proximal tubule of the rat kidney

Summary Sex-dependent protein handling in the rat renal tubular system was studied both qualitatively and quantitatively using the method of direct fluorescent protein tracing. The protein tracer, fluorescent ovalbumin, was synthesized by conjugating hen ovalbumin with fluorescein isothiocyanate (FITC), and the fluorescence characteristics of fluores-ceinthiocarbamyl (FTC)-ovalbumin conjugates with different degrees of labelling were studied. Heavily labelled tracer was intravenously injected into male and female rats, and both kidneys were perfused; the right kidney was then homogenized and used for quantitative fluorometric measurements, while the left kidney was perfusion fixed and prepared for fluorescence mciroscopy. The tubular reabsorption of fluorescent ovalbumin was studied 4 min and 10 min after the injection of different doses (1.4, 7.0 and 14.0 mg/kg body weight) of the tracer, and the tubular catabolism was investigated in animals killed 60 and 120 min after the injection. Fluorescence microscopy demonstrated that, in both sexes and regardless of the dose administered and the time after injection, specifically fluorescent protein or its degradation products was only present in the epithelial cells of the proximal tubule. With regard to sex-dependent differences in protein handling, fluorometry indicated that at 4 min (7.0 mg) and at 10 min (all doses) after injection, female animals had reabsorbed more fluorescent protein than males. With regard to the catabolic phase, both the fluorescence microscopy and the fluorometric results showed that the female rats had degraded the fluorescent tracer at a significantly higher rate than males. The results are discussed in connection with sex-dependent proteinuria in rats.In honour of Prof. P. van DuijnSupported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Tubular GFP uptake pattern in the rat and frog kidneys

The renal tubular uptake of green fluorescent protein (GFP) after its bolus intravenous injection was studied in both frogs and rats. GFP fluorescence in the proximal tubule (PT) was revealed by fluorescent and confocal microscopy. Granular GFP fluorescence was observed nearby in the apical membrane of PT cells featuring distribution over the cytoplasm. GFP was internalized into endosomes and lysosomes as determined by immunocytochemistry in frogs. The tubular uptake and accumulation of GFP were dose- and time-dependent in both rats and frogs. Intralymphatic sac injection of arginine vasotocin (AVT) decreased the uptake of GFP in hydrated frogs. A high negative correlation between the AVT dose and the uptake of GFP was revealed. The effect of AVT was inhibited by a V(1)-receptor antagonist. A noted decrease in the average number of fluorescent PT profiles per kidney section and their irregular distribution after AVT injections suggest that not all of the glomeruli or preglomerular vessels are equally responsive to AVT. GFP may serve as a good marker for tubular uptake and intracellular traffic in the amphibian kidney for use in in vivo studies.     

Reabsorption of fluorescein-isothiocyanate-labelled-ovalbumin in the kidney of normal and castrated male and female rats

The reabsorption of ovalbumin double labelled with fluorescein isothiocyanate (FITC) in the kidneys of normal and castrated male and female rats was investigated using fluorometry and fluorescence microscopy. The animals received an intravenous injection of either 2 or 7 mg fluorescein-thiocarbamyl (FTC)-ovalbumin per kilogram bodyweight (bw) and were killed 4 or 8 min post-injection. Animals injected with unlabelled ovalbumin (7.0 mg/kg bw) served as controls. Fluorescence microscopy revealed that FTC-ovalbumin was reabsorbed exclusively in the renal proximal tubule, the highest level of reabsorption being observed in its first part. Four and eight minutes after the injection, FTC-ovalbumin was only observed in apical reabsorption vacuoles, with lysosomes exhibiting no specific fluorescence. Fluorometric determinations for the renal homogenate supernatant showed that the renal reabsorption of FTC-ovalbumin was up to 24% higher in normal females than in normal males. Castration resulted in a significant increase in renal reabsorption in male rats (up to 38%; significant), whereas a minor decrease was observed in castrated females. The renal uptake differences in normal and castrated animals are discussed in the light of the sex-hormone-dependent catabolism of lysosomal proteins in the renal proximal tubule of rats.     

Renal filtration and reabsorption of GFP in <Emphasis Type="Italic">Rana temporaria</Emphasis>: Effect of arginine-vasotocin

The renal tubular uptake of green fluorescent protein (GFP) in frog Rana temporaria was studied by laser confocal microscopy. The specific green fluorescence was revealed in cells of proximal tubules 30 min after intravenous GFP injection. The GFP fluorescence was located predominantly in the apical part of the cytoplasm in the form of intensively fluorescing vesicles. The GFP injections increased dose-dependently the GFP tubular uptake. This was confirmed by the quantitative assessment of intensity of the specific fluorescence, its relative vesicular density, and by correlation analysis. Preliminary administration of arginine-vasotocin into the dorsal lymphatic sack decreased significantly the GFP absorption. The effect of arginine-vasotocin was inhibited by pretreatment with an antagonist of vasopressin V_i-receptors. The results of this work together with literature data allow believing that a decrease in the GFP absorption in the frog kidney under effect of arginine-vasotocin is due to a fall of the AVT-dependent glomerular filtration rate and to a decrease in the input of protein into the lumen of tubules. The action of arginine-vasotocin seems to be mediated via the V_i-like receptors of preglomerular blood vessels.     

Reabsorption of fluorescein-isothiocyanate-labelled-ovalbumin in the kidney of normal and castrated male and female rats

Summary The reabsorption of ovalbumin double labelled with fluorescein isothiocyanate (FITC) in the kidneys of normal and castrated male and female rats was investigated using fluorometry and fluorescence microscopy. The animals received an intravenous injection of either 2 or 7 mg fluorescein-thiocarbamyl (FTC)-ovalbumin per kilogram bodyweight (bw) and were killed 4 or 8 min post-injection. Animals injected with unlabelled ovalbumin (7.0 mg/kg bw) served as controls. Fluorescence microscopy revealed that FTC-ovalbumin was reabsorbed exclusively in the renal proximal tubule, the highest level of reabsorption being observed in its first part. Four and eight minutes after the mjection, FTC-ovalbumin was only observed in apical reabsorption vacuoles, with lysosomes exhibiting no specific fluoreseence. Fluorometric determinations for the renal homogenate supernatant showed that the renal reabsorption of FTC-ovalbumin was up to 24% higher in normal females than in normal males. Castration resulted in a significant increase in renal reabsorption in male rats (up to 38%; significant), whereas a minor decrease was observed in castrated females. The renal uptake differences in normal and castrated animals are discussed in the light of the sex-hormone-dependent catabolism of lysosomal proteins in the renal proximal tubule of rats.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Tubular protein uptake pattern in the frog model (<Emphasis Type="Italic">Rana temporaria</Emphasis>): The effect of previous protein loading

The effect of increasing protein load on subsequent receptor-mediated protein uptake was studied in the kidney of the common frog Rana temporaria L. Results of in vivo experiments were analyzed in fixed kidney sections using fluorescent or confocal microscopy and immunohistochemistry. Lysozyme was used for daily tubular loading in short-term experiments. Reabsorption of yellow fluorescent protein (YFP) in the proximal tubule (PT) was tested 60 min after introduction into the dorsal lymphatic sac. YFP uptake decreased progressively with increasing duration of lysozyme preload from 2 to 4 days. Lysozyme loading and single protein injections did not change the morphological characteristics of frog glomeruli and PTs, as shown by light and electron microscopy and morphometric analysis. Cessation of loading led to a decrease in the amount of lysozyme accumulated in PT cells. Reduced YFP uptake gradually recovered after cessation of the 4-day load. Restoration of YFP reabsorption was accompanied by increasing expression of endocytic receptors, megalin and cubilin. Based on the data obtained, the frog model can be successfully used for studying both morphological and functional changes in the nephron caused by tubular or glomerular proteinuria and molecular mechanisms involved in the process of renal protein reabsorption.     

Renal filtration and reabsorption of GFP in frog Rana temporaria: effect of arginine-vasotocin

The renal tubular uptake of green fluorescent protein (GFP) in frog Rana temporaria was studied by laser confocal microscopy. The specific green fluorescence was revealed in the proximal tubule cells 30 min after intravenous GFP injection. The GFP fluorescence was distributed predominantly in the apical part of the cytoplasm in the form of the intensively fluorescing vesicles. The GFP injections increased dose-dependently the GFP tubular uptake. This was confirmed by the quantitative assessment of intensity of the specific fluorescence, its relative vesicular density, and by correlation analysis. Preliminary administration of arginine vasotocin into the dorsal lymphatic sac decreased significantly the GFP absorption. The effect of arginine vasotocin was inhibited by pretreatment a vasopressin V1-receptor antagonist. These results suggest that a decrease in the GFP absorption is due to a fall of the AVT-dependent glomerular filtration rate and consequently a decrease in the filtered GFP amount. The effect of arginine vasotocin on the GFP absorption seems to be mediated via the V1-like receptors of preglomerular blood vessels.     

Albumin handling by renal tubular epithelial cells in a microfluidic bioreactor

Epithelial cells in the proximal tubule of the kidney reclaim and metabolize protein from the glomerular filtrate. Proteinuria, an overabundance of protein in the urine, affects tubular cell function and is a major factor in the progression of chronic kidney disease. By developing experimental systems to study tubular protein handling in a setting that simulates some of the environmental conditions of the kidney tubule in vivo, we can better understand how microenviromental conditions affect cellular protein handling to determine if these conditions are relevant in disease. To this end, we used two in vitro microfluidic models to evaluate albumin handling by renal proximal tubule cells. For the first system, cells were grown in a microfluidic channel and perfused with physiological levels of shear stress to evaluate the effect of mechanical stress on protein uptake. In the second system, a porous membrane was used to separate an apical and basolateral compartment to evaluate the fate of protein following cellular metabolism. Opossum kidney (OK) epithelial cells were exposed to fluorescently labeled albumin, and cellular uptake was determined by measuring the fluorescence of cell lysates. Confocal fluorescence microscopy was used to compare uptake in cells grown under flow and static conditions. Albumin processed by the cells was examined by size exclusion chromatography (SEC) and SDS-PAGE. Results showed that cellular uptake and/or degradation was significantly increased in cells exposed to flow compared to static conditions. This was confirmed by confocal microscopy. Size exclusion chromatography and SDS-PAGE showed that albumin was broken down into small molecular weight fragments and excreted by the cells. No trace of intact albumin was detectable by either SEC or SDS-PAGE. These results indicate that fluid shear stress is an important factor mediating cellular protein handling, and the microfluidic bioreactor provides a novel tool to investigate this process.     

Distribution of calcitonin gene-related peptide-containing fibers in the urinary bladder of the rat and their origin

Summary Using horseradish peroxidase (HRP) as a tracer, we have investigated if the so-called apical tubules (AT) in the kidney proximal tubule cells are directly involved in the endocytic process by carrying the tracer into the cells, or if they are derived from the intracellular membrane compartments. Rat kidney was fixed by vascular perfusion at different time intervals after intravenous injection of HRP and prepared for electron microscopy. An analysis revealed that 0.5 min after injection, invaginations of the plasma membrane and small apical endocytic vesicles, including coated vesicles, were labelled with reaction product, whereas almost all large apical endocytic vacuoles and the AT were negative. The endocytic vacuoles and about 18% of the AT were labelled 1 min after injection. The reaction product in the large endocytic vacuoles was usually seen along the luminal surface of the vacuoles. The AT with reaction product appeared as a branched network, and were frequently connected with the labelled endocytic vacuoles. Three min after injection, reaction product was detected in about 38% of the AT, and thereafter, the percentage increased to about 74% after 7 min. No reaction product was detected in the Golgi complex at any time after HRP-injection. These findings indicate that the AT are probably formed by budding off from the large endocytic vacuoles, rather than being directly involved in the endocytic process.     

Effect of different proteins on reabsorption of yellow fluorescent protein in the kidney of the brown frog <Emphasis Type="Italic">Rana temporaria</Emphasis>

Protein reabsorption in the proximal tubules (PT) of the frog kidney was studied by immunohistochemistry, fluorescent and confocal microscopy. The yellow fluorescent protein (YFP) was introduced in combination with other proteins. Reabsorption of YFP co-injected with lysozyme or the green fluorescent protein (GFP) was indistinguishable from that of YFP injection alone. Preliminary lysozyme injection did not change YFP absorption in contrast to YFP uptake reduced after GFP pretreatment. Lysozyme loading for 4 days led to a significant reduction in YFP absorption. The results show that receptor-mediated endocytosis in the frog kidney depends on the molecular nature of absorbable ligands, conditions of their competitive absorption and lysosomal accumulation in PT epithelial cells.     

The fate of N-Dansyl-L-phenylalanine in the cerebrospinal fluid after intraventricular and intracisternal injection

Absorption, accumulation and release of N-Dansyl-L-phenylalanine (DPA) through the ependyma, plexus choriodei and brain parenchyma after intraventricular and intracisternal injection was examined at different postinjection intervals by fluorescence microscopy. The following results were obtained: 1. After intraventricular injection, DPA is rapidly absorbed from the ependyma and plexus choriodei in all ventricles and subsequently disappears from the various points of the ventricles at different times. DPA is no longer evident in the ependyma after 40 min and the plexus after 90 min. Aborption and storage occur primarily in the dopaminergic centers of the brain. This stage begins 5 min p.i. attains a maximum after 40 min and is maintained up to 180 min p.i. 2. If DPA is administered intracisternally, fluorescence is initially restricted to the ependyma and choroid plexus of the fourth ventricle and to the wall of the aquaeduct. Only at 5-10 min p.i. are rostral ventricular portions labelled. Passage of the amino acid out of the ventricle only occurs to a limited extent. 40 min after intracisternal injection, DPA is no longer demonstrable in the ependyma and plexus or brain parenchyma. 3. Intrathecally administered DPA appears in the periglomerular tubules of the kidney as well 2.5 min p.i. and is stored there for up to 40 min. The kidney medulla remains free of fluorescence. 4. DPA injected into the CSF is protein-bound.     

Receptor-Mediated Endocytosis of Lysozyme in Renal Proximal Tubules of the Frog Rana Temporaria

The mechanism of protein reabsorption in the kidney of lower vertebrates remains insufficiently investigated in spite of raising interest to the amphibian and fish kidneys as a useful model for physiological and pathophysiological examinations. In the present study, we examined the renal tubular uptake and the internalization rote of lysozyme after its intravenous injection in the wintering frog Rana temporaria using immunohisto- and immunocytochemistry and specific markers for some endocytic compartments. The distinct expression of megalin and cubilin in the proximal tubule cells of lysozyme-injected frogs was revealed whereas kidney tissue of control animals showed no positive immunoreactivity. Lysozyme was detected in the apical endocytic compartment of the tubular cells and colocalized with clathrin 10 min after injection. After 20 min, lysozyme was located in the subapical compartment negative to clathrin (endo-somes), and intracellular trafficking of lysozyme was coincided with the distribution of megalin and cubilin. However, internalized protein was retained in the endosomes and did not reach lysosomes within 30 min after treatment that may indicate the inhibition of intra-cellular trafficking in hibernating frogs. For the first time, we provided the evidence that lysozyme is filtered through the glomeruli and absorbed by receptor-mediated clathrin-dependent endocytosis in the frog proximal tubule cells. Thus, the protein uptake in the amphibian mesonephros is mediated by megalin and cubilin that confirms a critical role of endocytic receptors in the renal reabsorption of proteins in amphibians as in mammals.Key words: Endocytic receptor, frog, kidney, lysozyme, protein uptake, proximal tubule     

Renal clearance of absorbed intact GFP in the frog and rat intestine

Intestine absorption of intact green fluorescent protein (GFP) and its following accumulation in the renal proximal tubule cells after its intragastric administration have been established by confocal microscopy in the rat and frog. Reabsorbed GFP was revealed in the endosomes and lysosomes of the proximal tubule cells by the methods of GFP photooxidation and immunofluorescent microscopy. The GFP intestine absorption rate and GFP accumulation in the kidney were significantly higher in the frog than in the rat. No specific fluorescence was revealed in the liver and colon cells after the GFP intragastric administration. The data obtained indicate the ability of the small intestine in the frog and rat to absorb intact proteins and an important role of the kidney in exogenous protein metabolism.     

Caged Q-rhodamine dextran: a new photoactivated fluorescent tracer

An amine-reactive caged rhodamine was synthesized and conjugated to aminodextran. The resulting tracer was injected into a single cell zebrafish embryo, and a portion of the tracer was photolyzed in a single cell after development. The resulting fluorescent cell was imaged by fluorescence microscopy through a single round of cell division.     

Expression and analysis of green fluorescent proteins in human embryonic kidney cells by capillary electrophoresis

The green fluorescent protein (GFP) has attracted much interest as a reporter for gene expression. In this paper, application of capillary electrophoresis with laser-induced fluorescent (CE-LIF) for quantitation of green fluorescence protein in cellular extracts and single cells is investigated. The S65T mutant form of GFP protein was successfully expressed in human embryonic kidney (HEK293) cells, and its production was confirmed by fluorescence microscopy and CE-LIF. The mass limit of detection for the mutant S65T was 5.3 x 10(-20) mol, which was better than that for the wild-type GFP by a factor of six. Detection of a small amount of GFP is difficult by conventional techniques such as fluorescent microscopy due to interference from cell autofluorescence at low GFP concentrations. The HEK293 cells were transfected with the GFP plasmid that produced S65T-GFP. Transient production of S65T protein was detected 2 h after the transfection and reached a maximum after 48 h. The protein concentration began to decrease significantly after 96 h. Single cell analysis of HEK293 cells after transfection with GFP plasmid indicate a nonuniform production of S65T-GFP protein among cells.     

Endocytosis mediated by the mannose receptor in liver endothelial cells. An immunocytochemical study

Immunocytochemical labeling of ultrathin cryosections from rat liver showed that mannose-terminated glycoproteins are removed rapidly from the blood stream mainly by the sinusoidal endothelial cells. The mannose-terminated glycoprotein ovalbumin was injected intravenously into rats 1 min, 6 min, and 24 min before perfusion fixation of the liver. Several minor and at least three major subcellular compartments were shown to be involved in the endocytic process. One minute after injection, ovalbumin was found at the cell surface, in coated pits, in coated vesicles, in tubular structures, and bound to the membrane of large early endosomes of which some showed a cisternal structure. After 6 min, ovalbumin was found in the lumen of large electron-lucent late endosomes and after 24 min in electron-dense structures, presumably lysosomes. The early endosomes have an ultrastructure which, together with the labeling pattern, indicates that this compartment has the same function as the CURL identified in parenchymal liver cells. The results are in accordance with recent biochemical findings indicating that ovalbumin endocytosed by endothelial cells is found sequentially in three different subcellular fractions depending on the time between injection and cooling for fractionation (G. M. Kindberg, T. Berg: Intracellular transport of endocytosed mannose terminated glycoproteins in rat liver endothelial cells. In: E. Wisse, D. L. Knook, K. Decker (eds.): Cells of the Hepatic Sinusoid. Vol. 2. pp. 120-124. Kupffer Cell Foundation. Rijswijk The Netherlands 1989).     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : III. Tubular Gland Cell Cytodifferentiation

Administration of estrogen (E) to immature chicks triggers the cytodifferentiation of tubular gland cells in the magnum portion of the oviduct epithelium; these cells synthesize the major egg-white protein, ovalbumin. Electron microscopy and immunoprecipitation of ovalbumin from oviduct explants labeled with radioactive amino acids in tissue culture were used to follow and measure the degree of tubular gland cell cytodifferentiation. Ovalbumin is undetectable in the unstimulated chick oviduct and in oviducts of chicks treated with progesterone (P) for up to 5 days. Ovalbumin synthesis is first detected 24 hr after E administration, and by 5 days it accounts for 35% of the soluble protein being synthesized. Tubular gland cells begin to synthesize ovalbumin before gland formation which commences after 36 hr of E treatment. When E + P are administered together there is initially a synergistic effect on ovalbumin synthesis, however, after 2 days ovalbumin synthesis slows and by 5 days there is only 1/20th as much ovalbumin per magnum as in the E-treated controls. Whereas the magnum wet weight doubles about every 21 hr with E alone, growth stops after 3 days of E + P treatment. Histological and ultrastructural observations show that the partially differentiated tubular gland cells resulting from E + P treatment never invade the stroma and form definitive glands, as they would with E alone. Instead, these cells appear to transform into other cell types—some with cilia and some with unusual flocculent granules. We present a model of tubular gland cell cytodifferentiation and suggest that a distinct protodifferentiated stage exists. P appears to interfere with the normal transition from the protodifferentiated state to the mature tubular gland cell.     

Three-dimensional architecture of the tubular endocytic apparatus and paramembranous networks of the endoplasmic reticulum in the rat visceral yolk-sac endoderm

The three-dimensional architecture of the tubular endocytic apparatus and the endoplasmic reticulum in the rat yolk-sac endoderm was investigated after loading with horseradish peroxidase-conjugated concanavalin A by intrauterine administration. After 30 min, small vesicles (50–150 nm in diameter), small tubules (80–100 nm in diameter) and large vacuoles (0.2–1.0 m in diameter) in the apical cytoplasm were labeled with the tracer, but lysosomes (1.0–3.5 m in diameter) in the supranuclear cytoplasm were not labeled until 60 min after loading. Stereo-viewing of the labeled small tubules in thick sections revealed that they were not isolated structures but formed three-dimensional anastomosing networks, which were also confirmed by scanning electron microscopy after maceration with diluted osmium tetroxide. Their earlier labeling with the endocytic tracer, localization in the apical cytoplasm and three-dimensional network formation indicated that the labeled small tubules represented tubular endosomes (tubular endocytic apparatus). These well-developed membranous networks provided by the tubular endosomes are suggested to facilitate the receptor-mediated endocytosis and transcytosis of the maternal immunoglobulin in the rat yolk-sac endoderm. Scanning electron microscopy further revealed lace-like networks of the smooth endoplasmic reticulum near the lateral plasma membrane. Their possible involvement in transport of small molecules or electrolytes is discussed.     

Role of apical tubules in endocytosis in nonciliated cells of the ductuli efferentes of the rat: a kinetic analysis

The apical region of nonciliated cells of the ductuli efferentes of the rat contains tubular coated pits (TCP) connected to the apical plasma membrane, apical tubules (AT) which occasionally show a partial coat, and endosomes which are often continuous with one or more apical tubules. To investigate the formation and fate of TCP and AT, a quantitative analysis was performed on the labeling indices of these structures at various time intervals (0.5-120 min) after a single injection of a tracer, cationic ferritin (CF), into the lumen of the rete testis. The labeling indices of both TCP and AT exhibited similar cyclical patterns, first reaching a peak at 25 min, then dropping to a minimum at 35 min, then rising to a second peak at 60 min. Since TCP were well labeled at 30 sec while AT were not, the tracer must rapidly enter TCP and thence AT. However, since tracer was virtually absent from the lumen by 30 min, it was not possible to reconcile the second peak of labeling index of TCP and AT by this mechanism. In another experiment, rats were injected once as before, injected again at 30 min, and then sacrificed at 30 min following the second injection. The results from this experiment showed that the labeling index of TCP and AT did not drop but was similar to that of the 60-min peak after a single injection. The interpretation is that there was recycling of tracer, which had already migrated from TCP to AT to endosomes, back to the apical plasma membrane via apical tubules. Moreover, when rats were injected once, injected again at 30 min, and sacrificed 3 min following the second injection, the labeling index for TCP and AT was significantly higher (P less than .05) than at the 30-min time interval after a single injection, indicating that recycled apical tubules were functionally capable of binding further CF. Morphological observations on images of transition between TCP and AT and the fact that AT were often found connected to endosomes suggest that TCP detach from the cell surface to give rise to AT, which in turn fuse to form endosomes. The kinetic analysis demonstrates in quantitative terms that a portion of the AT, which fuses to form endosomes, recycles back to the apical plasma membrane and contributes to the formation of new TCP.