Characteristics of the compensatory renal growth of the remnant embryonic chick kidneys

Growth of the remnant embryonic kidney (the mesonephros), as expressed by wet weight, was more rapid in the chick embryos with experimentally induced unilateral renal agenesis compared to controls. The difference was significant between embryonic days 8-12, when the doubled weights of remnant kidneys were increased compared with the weights of paired control kidneys. The excessive growth of the mesonephros ceased on day 14, when the normal physiological regression of the embryonic kidney begins. In the definitive kidney, the metanephros, no significant differences in weights of the control vs. remnant metanephros were found on days 10-14. The characteristics of increased mesonephric growth were evaluated by determination of DNA/protein ratios in homogenates of the kidneys. Significant cellular hypertrophy was found in both the mesonephros and metanephros of the embryos with URA on day 10. Additionally, a non-significant cellular hyperplasia was also revealed in the remnant mesonephros on day 8. This gives evidence that the growth stimuli to the mesonephroi were probably strongest between days 8-10 and that they manifested in the remnant mesonephros only.     

Changes in the protein spectrum of the chick embryo mesonephros and metanephros in the course of development

The protein spectra of two fractions (the soluble and the membrane fraction) of chick embryo kidney homogenates were isolated by electrophoresis on polyacrylamide gels with the aim of detecting the kidney differentiation process at the molecular level and, at the same time, of evaluating similarities in the construction of the mesonephros and metanephros at this level. Corresponding stages of the above two types of kidney were chosen for studying changes in protein structure during differentiation--i.e. the outset of differentiation (the 6-day mesonephros, the 11-day metanephros) and the stage of full maturity (the 14-day mesonephros, the 20-day metanephros). A total of 36 proteins was distinguished. The analysis of the protein spectra showed that the number of proteins changes but slightly during differentiation; the protein composition of the two types of kidney during differentiation altered by 20-35% of the total number of proteins; the similarity of the protein composition of the corresponding stages of mesonephros and metanephros, expressed as the proportion of the number of identical proteins, was greater than the mutual similarity of different developmental stages of the same type of kidney. The percentage of different proteins at corresponding stages of the kidneys varied from 5% to 23% of the total number of proteins detected.     

Use of monoclonal antibodies to follow the phylogenic distribution of human renal antigens

Nine human differentiation antigens have been defined by monoclonal antibodies (M. Abs) developed from mice immunized with embryonic kidney cells (mesonephros or metanephros of 7 week-developmental ages). Their spatial and temporal distributions during human kidney organization were previously studied [3]. In this paper we have attempted to follow by immunofluorescence their phylogenic location, from fish to mammals. Six of them recognized the same structures as in humans: proximal convoluted tubules (PCT) (EG9.11, EG19.6, E116.1), glomerular basement membrane (GBM) (EG14.1) and extracellular matrix (EK8.1, EK17.1). However, staining was limited to certain mammals. EK17.1 has been characterized as an anti-fibronectin. These antibodies revealed the same histological structures in the human mesonephros and metanephros. The three other antibodies revealed epitopes appearing earlier in evolution and whose histological distribution varied according to species. These antibodies stained different structures in the mesonephros and metanephros. Thus, the staining particularities observed during human renal ontogenesis were found again in the phylogenetical study.     

Peroxisomes in permanent and provisional kidneys

Peroxisomes in three forms of vertebrate kidney (pronephros, mesonephros, and metanephros), as permanent or provisional kidney, are summarized concerning their ultrastructure and developmental changes. Because the peroxisome is known to be diverse in mammalian metanephros, and species difference is its distinctive feature among cell organelles, information should be obtained on each kidney of each species. The ultrastructural and biochemical features of peroxisomes have at least been partly delineated in the metanephros and mesonephros, but nothing is known about the pronephros. Ultrastructural studies of the metanephric peroxisomes are present in mammals, birds, and reptiles, but information on their development is restricted to mammals and birds. As for the mesonephric peroxisomes, both ultrastructural and developmental data have been accumulating on mammals and amphibians, and ultrastructural information is present on fishes, but not on birds and reptiles. At present, studies on peroxisomes of provisional kidney have been restricted to mammalian mesonephros. The common features of renal peroxisomes previously examined are that they are spherical cell organelles with a single limiting membrane in ultrastructure, and are positive for catalase. Information on the ultrastructure and enzymes is not sufficient at present for comparing the ontogenesis of renal peroxisomes with their phylogenesis. Part of this study appeared as an original paper (11), and was presented as a poster at the International Symposium/CREST Research Conference, Peroxisome: Biogenesis, Function and Disease.     

Kidney development conserved over species: essential roles of Sall1

The kidney develops in three stages: pronephros, mesonephros, and metanephros. Molecular mechanisms underlying these three steps are similar, and we can thus examine genetic cascades occurring during development. The induction system for pronephros in vitro has been established in Xenopus. Using this system, we isolated Sall1 that is essential for the initial step in metanephros formation. The potential mechanisms involved and future directions regarding kidney development are discussed.     

Six1 and Six4 are essential for Gdnf expression in the metanephric mesenchyme and ureteric bud formation, while Six1 deficiency alone causes mesonephric-tubule defects

Interaction between the ureteric-bud epithelium and the metanephric mesenchyme is important for kidney development. Six1 and Six4 are the mammalian homologs of Drosophila sine oculis, and they are coexpressed in the nephrogenic mesenchyme. Six1-deficient mice show varying kidney defects, while Six4-deficient mice have no apparent abnormalities. Here, we report Six1/Six4-deficient mice that we generated in order to elucidate the functions of Six4 in Six1-deficient kidney development. The Six1/Six4-deficient mice exhibited more severe kidney phenotypes than the Six1-deficient mice; kidney and ureter agenesis was observed in all the neonates examined. The Six1/Six4-deficient metanephric mesenchyme cells were directed toward kidney lineage but failed to express Pax2, Pax8, or Gdnf, whereas the expression of these genes was partially reduced or unchanged in the case of Six1 deficiency. Thus, Six4 cooperates with Six1 in the metanephric mesenchyme to regulate the level of Gdnf expression; this could explain the absence of the ureteric bud in the Six1/Six4-deficient mice. In contrast, Six1 deficiency alone caused defects in mesonephric-tubule formation, and these defects were not exacerbated in the Six1/Six4-deficient mesonephros. These results highlight the fact that Six1 and Six4 have collaborative functions in the metanephros but not in the mesonephros.     

Involvement of FGF and BMP family proteins and VEGF in early human kidney development

The spatial and temporal pattern of the appearance of the fibroblast growth factor proteins (FGF-8 and FGF-10), the bone morphogenetic proteins (BMP-2/4 subfamily and BMP-7) and the vascular endothelial growth factor protein (VEGF) was investigated in the human mesonephros and metanephros of the 5-9 week-old conceptuses. In the mesonephros, both FGF's and BMP's were found in all structures and their expression slightly decreased in the early fetal period. VEGF positivity appeared in all mesonephric structures, and increased in the fetal period coincidently with formation of the mesonephric blood vessel network. In the metanephros, FGF-8 first appeared only in the metanephric mesenchyme, but from the 7th week on, its reactivity increased and spread to other metanephric structures. FGF-10 positive cells appeared in all metanephric structures already in the 5th week, and slightly intensified with progression of development. Cell survival and nephrogenesis in the permanent kidney might be associated with the appearance of both growth factors. Both BMP-2/4 and BMP-7 displayed a similar pattern of reactivity in all metanephric structures, and their reactivity intensified with advancing development. Alterations in their pattern of appearance might lead to the formation of small and dysplastic kidneys. Already in the earliest developmental stages, VEGF protein appeared in all metanephric structures. At later stages, VEGF showed more intense reaction in the collecting system than in the differentiating nephrons and interstitium. Due to VEGF involvement in vasculogenesis and angiogenesis, abnormal VEGF appearance might lead to impaired formation of the blood vessel network in the human permanent kidney.     

Frizzled-4 expression during chick kidney development

Wnts have been implicated in metanephric kidney development. To determine whether Frizzleds, the genes that encode Wnt receptors, are present at early stages of nephrogenesis, we examined the expression of several recently identified Frizzled genes in the chick by in situ hybridization. Here we report the cloning and characterization of chick Frizzled-4 (cFz-4), which we found to be expressed in the developing chick kidney. cFz-4 was first expressed in the pronephros caudal to the third somite at Hamburger and Hamilton stage 10. Its expression increased with maturation, becoming restricted to the newly induced glomeruli and tubules in the mesonephros and metanephros. Within the metanephros, cFz-4 and Wnt-4 expression patterns were similar, whereas Wnt-11 was expressed solely in the tips of the branching ureteric bud. cFz-4 expression was compared with that of known kidney markers. It preceded that of Lmx-1, but was similarly restricted to developing glomeruli and tubules. In contrast, Pax-2 expression and Lim 1/2 antibody labeling occurred in intermediate mesoderm caudal to the fifth somite in the early pronephros, and each persisted in both the tubules and nephric ducts throughout further development.     

Development of the urinary system of the marsupial native cat Dasyurus hallucatus.

The development of the mesonephros and metanephros was examined in the marsupial Northern native cat, Dasyurus hallucatus, from birth through to the end of lactation. The mesonephros was present at birth, reached a maximum volume 11 days after birth and had regressed completely by day 30. The metanephros was present on day 2; glomeruli were first seen on day 8, and nephrogenesis continued until day 89 post partum. The newborn native cat is at a very primitive stage of development compared to other marsupials. However, at weaning, like other marsupial species, the native cat has developed a fully morphological and functional urinary system.     

Comparative immunohistochemical analysis of the expression of cytokeratins, vimentin and alpha-smooth muscle actin in human foetal mesonephros and metanephros

The human mesonephros is currently regarded as a simplified version of the foetal metanephros, primarily due to the close morphological resemblance between these two structures. The aim of the present study was to define whether human mesonephric and foetal metanephric nephrons share immunophenotypical traits in their corresponding structures (glomeruli, proximal and distal tubules). For this purpose we first investigated immunohistochemically the overall expression and topographical distribution of cytokeratins 7, 8, 18, 19, and 20, vimentin and -smooth muscle actin in mature mesonephric nephrons and compared the results with those obtained in maturing-stage foetal metanephric nephrons. No expression of cytokeratins 7 and 20 was found. Cytokeratins 8, 18, and 19 and vimentin showed a restricted and basically coincident expression along the different components of both mesonephric and metanephric nephrons. These findings indicate that the intermediate filament protein profile of human mature mesonephric nephrons closely recapitulates that observed in developing metanephros and thereby strengthens the concept that human mesonephros, a transient ontogenic structure, is largely similar to the foetal metanephros.The sole difference between human mesonephros and foetal metanephros was the divergent expression of -smooth muscle actin. This protein exhibited an increasingly accentuated mesangial expression paralleling the morphological maturation of metanephric glomerulus, whereas it was absent from the mesonephric one. This would suggest that the mesangial cells in these two renal structures have a different function during the foetal life.     

Demonstration of human kidney differentiation antigens with monoclonal antibodies

Six human differentiation antigens (EE24.6, EG9.11, EG14.1, EI16.1, EK8.1, EK17.1) have been defined using monoclonal antibodies obtained from mice immunized with embryonic kidney cells. Their histologic distribution was determined on frozen sections of embryonic, fetal, and adult human kidneys by immunofluorescence assay. EE24.6, an ureteral bud marker, was detected only on the germ layer of mature kidney urothelium. EG9.11 and EG14.1 were detected on the S-shaped bodies and also on the adult proximal convoluted tubule for the former and the glomerular basement membrane for the latter. EI16.1, a marker of condensed mesenchyme, was detected only on epithelial cells of adult proximal convoluted tubule. EK8.1 was found in the mesangium, connective tissue, and with particularly dense labeling in the basement membranes. This labeling pattern was present throughout renal organogenesis. EK17.1 recognized both cell and plasma human fibronectins. Staining for all antibodies was nearly identical in mesonephros and metanephros. These results demonstate that some antigens follow their embryonic destiny. They indicate an antigenic similarity between the mesonephros and the metanephros and, therefore, a very early appearance of these antigens. During differentiation, these antigens concentrate on more defined structures, and staining became increased with an increased degree of differentiation.     

Essential function of Wnt-4 for tubulogenesis in the Xenopus pronephric kidney

In the vertebrate embryo, development of the excretory system is characterized by the successive formation of three distinct kidneys: the pronephros, mesonephros, and metanephros. While tubulogenesis in the metanephric kidney is critically dependent on the signaling molecule Wnt-4, it is unknown whether Wnt signaling is equally required for the formation of renal epithelia in the other embryonic kidney forms. We therefore investigated the expression of Wnt genes during the pronephric kidney development in Xenopus. Wnt4 was found to be associated with developing pronephric tubules, but was absent from the pronephric duct. Onset of pronephric Wnt-4 expression coincided with mesenchyme-to-epithelium transformation. To investigate Wnt-4 gene function, we performed gain- and loss-of-function experiments. Misexpression of Wnt4 in the intermediate and lateral mesoderm caused abnormal morphogenesis of the pronephric tubules, but was not sufficient to initiate ectopic tubule formation. We used a morpholino antisense oligonucleotide-based gene knockdown strategy to disrupt Wnt-4 gene function. Xenopus embryos injected with antisense Wnt-4 morpholinos developed normally, but marker gene and morphological analysis revealed a complete absence of pronephric tubules. Pronephric duct development was largely unaffected, indicating that ductogenesis may occur normally in the absence of pronephric tubules. Our results show that, as in the metanephric kidney, Wnt-4 is critically required for tubulogenesis in the pronephric kidney, indicating that a common, evolutionary conserved gene regulatory network may control tubulogenesis in different vertebrate excretory organs.     

环境毒素对未成熟肾脏的影响

肾脏是人体主要的排泄器官,它的发育经过原肾、中肾、后肾3个阶段。外界环境中的化学物质、生物及物理因素的毒性作用可损害未成熟肾脏的发育,并严重影响胚胎和儿童的正常发育和身体健康。本文就影响肾脏血流动力学的药物、有机阴离子和有机阳离子、真菌毒素、环境污染物等具体毒素对未成熟肾脏的影响及其临床表现的研究进展作一综述。     

Developmental modifications of sheep kidney antigens

We have used monoclonal antibodies to study the changes in the expression of four kidney antigens during organogenesis in the sheep. Two of these antibodies, EE24.6 and EJ30.1, label intensely only the adult kidney, whereas the other two, EK17.1 and EJ15.1, bind to the extracellular matrix of the embryonic kidney. For EJ15.1, the staining of the extracellular matrix decreases temporarily during the second half of intrauterine life, a period during which a light staining appears in the mesangium. For the other, EK17.1, the extracellular matrix staining in the stroma gradually decreases as the embryo grows, while staining of the mesangium and the arterial intima becomes evident. With EK17.1, fibronectin is identified in the extracellular matrix of the embryonic kidney and intracellularly in the mesangial cells after these cells have colonized the glomerulus. The mesonephros staining seems to be the same as that of the metanephros.In the adult, extraglomerular vascular endothelial cells bind EK17.1, whereas intraglomerular endothelial cells do not express fibronectin, which suggests a functional difference between endothelial cells in these two localizations.     

Autoradiographic demonstration of specific binding sites for E. coli enterotoxin in various epithelia of the North American opossum

Summary In the North American opossum, heat-stable specific binding sites for E. coli enterotoxin are observed (i) in epithelial cells lining the small intestine, colon, gall bladder, cystic duct, common bile duct and trachea, and (ii) in epithelial cells forming the duodenal (Brunner's) glands, liver, kidneys (metanephros, mesonephros) and testis, as demonstrated by autoradiography. Enterotoxin-specific binding sites in the intestinal tract are only found in intestinal epithelial cells with the highest concentration in the microvillus border. Enterotoxin-specific binding sites also occur in epithelial cells comprising the secretory tubules and ducts of the duodenal glands. In the kidneys (metanephros and mesonephros), enterotoxin-specific binding sites are confirmed primarily to the proximal tubules, whereas in the testis they are localized in seminiferous tubules. In the liver, enterotoxin-specific binding sites are confined primarily to hepatocytes. E. coli enterotoxin caused a 7-fold increase of cGMP in the liver and a 30-fold increase in the duodenal glands. The liver responded in about half of the animals studied, whereas the duodenal glands gave a consistent response in each case. Likewise, the duodenal glands consistently showed strong labelling for ¹²⁵I-enterotoxin, whereas receptor labelling of hepatocytes was inconsistent in nearly half the incubations and corresponds to the observed cGMP measurements.Supported by a Weldon Springs Grant, University of Missouri and by funds from the Medical Research Service, Department of Veteran's Affairs     

Expression of aquaporin-1 (AQP1) in the adult and developing sheep kidney

The distributions of aquaporin-1 mRNA and protein were studied by hybridization histochemistry with a homologous riboprobe and immunohistochemistry, in the adult sheep kidney. Heaviest labelling occurred in the thin descending limb (DTL) of the loop of Henle in the inner stripe of the outer medulla, with apparent decreasing expression in the inner medulla, outer stripe of the outer medulla and cortex, but no quantitation was performed. Only proximal tubules (PT) (convoluted and straight) and DTL labelled. The glomerulus showed no labelling, consistent with the pattern in the rat but different to that in the human. During ontogeny, no labelling occurred in the mesonephros at 27 or 41 days of gestation (term = 145–150 days) but other structures did label at 27 days (heart, lung bud, blood vessels surrounding developing spinal cord). Labelling first occurred faintly in the metanephros at 41 days of gestation and increased throughout gestation consistent with morphological development of nephrons.