Angiotensin's role in renal development.

All the components of the renin-angiotensin system (RAS) are highly expressed in the developing kidney in a unique spatial and temporal pattern that is associated with nephrogenesis, vascularization, and the proper architectural and functional development of this organ. Pharmacological inhibition of the RAS results in structural and functional developmental abnormalities of the kidneys in several animal species, including humans. Similarly, altered renal morphology and functional abnormalities have been described in mice with targeted inactivation of the angiotensinogen (Agt) and the angiotensin-converting enzyme (ACE) genes. In contrast, inactivation of angiotensin receptors have not resulted in renal morphological abnormalities, suggesting a redundancy at this level of the RAS cascade that prevents the development of renal pathology. More importantly, inactivation of the ACE or Ao genes results in a renal phenotype remarkably similar to that obtained with pharmacological inhibition of the RAS. Taken together, the available information suggests that angiotensin is necessary for normal kidney development and for the maintenance of the functional and structural integrity of the adult kidney.

Development of the kidney vasculature.

Renal vascularization and nephrogenesis occur simultaneously following a tightly regulated developmental program influenced by growth factors, extracellular matrix components and cell membrane receptors. Both processes of angiogenesis and vasculogenesis probably participate in the formation of renal vessels. The origin and fate of the various renal vascular cells and the molecular mechanisms that initiate and guide intrarenal vascularization are fundamental questions that remain to be answered.

Gradenigo syndrome as presenting sign of T-cell lymphoma.

Gradenigo syndrome is an uncommonly observed neurologic complex consisting of cranial nerve VI palsy associated with the loss of the sensory component of cranial nerve V. We report a patient whose presentation with Gradenigo syndrome led to the unexpected diagnosis of T-cell lymphoma and briefly discuss Gradenigo syndrome and intracranial lymphomas.

Bridging the gap between physiology and molecular biology: new approaches to perpetual questions.

Living organisms are the result of precise and complex associations of regulatory systems in which active biomolecules interact with one another and respond to the challenges of growth and development, alterations in the environment, and disease. Understanding of body homeostasis may be accomplished at various levels of scientific endeavor. Physiological research has brought about an enormous understanding of the fundamental principles that sustain life in health and disease. The field of molecular biology has provided new tools and strategies with which to examine physiological processes as viewed from the level of fundamental biomolecules. The integration of both fields as "molecular physiology" has provided the opportunity for another level of scientific understanding and the opening of new avenues of research. Renin is one such molecule that participates in the control of several diverse physiological responses including changes in blood pressure, fluid and electrolyte homeostasis, renal function, and perhaps some elements of growth and differentiation. Because of the authors' bias, this review article will use renin to introduce many of the techniques of molecular biology and illustrate the areas of ongoing and potential interdependent activities resulting in the emerging field of molecular physiology.

Developmental consequences of the renin-angiotensin system.

Molecular, cellular, and physiological studies indicate that the renin-angiotensin system (RAS) is highly expressed during early kidney development. We propose that a major function of the RAS during early embryonic development is the modulation of growth processes that lead the primitive kidney into a properly differentiated and architecturally organized organ suited for independent extrauterine life. As development progresses, the RAS acquires new and overlapping functions such as the endocrine and paracrine regulation of blood pressure and renal hemodynamics. Disease states in adult mammals often result in expression of RAS genes and phenotypic changes resembling the embryonic pattern, emphasizing the importance of undertaking developmental studies. Because of their importance in health and disease, the immediate challenge is to identify the mechanisms that regulate the unique development of the RAS and its role(s) in normal and abnormal growth processes.

Recent advances in renal development.

Anatomical development of the kidney is achieved by the reciprocal induction of the ureteric bud and the metanephric mesenchyma. This interaction triggers the process of nephrogenesis and culminates in the formation of the mature kidney. In vivo, nephrogenesis is coordinated with renal vascularization. In fact, vascular precursors, epithelial progenitors, and mesenchymal cells communicate with one another in a highly organized fashion. As a result of this complex interaction, a mature kidney, architecturally and functionally ready for extrauterine life, is produced. This review deals with the relevant molecules and mechanisms governing nephrovascular development.

Postnatal development and progression of renal dysplasia in cyclooxygenase-2 null mice.

BACKGROUND: Genetic ablation of cyclooxygenase-2 (COX-2) resulted in cystic renal dysplasia and early death in adult mice. The ontologic development of the renal pathology and the biochemical and physiological abnormalities associated with the dysplasia are unknown. METHODS: Mice homozygous for a targeted deletion of COX-2 (-/-) were compared with wild-type littermates (+/+). Somatic and kidney growth and renal histology were studied at the day of birth and at a number of postnatal ages. Systolic blood pressure, urinalysis, urine osmolality, serum and urine chemistries, and inulin clearance were evaluated in adult animals. RESULTS: Beginning at postnatal day 10 (PN10), kidney growth was suppressed in -/- animals, while somatic growth and heart growth were unaffected. By PN10, -/- kidneys had thin nephrogenic cortexes and crowded, small, subcapsular glomeruli. The pathology increased with age with progressive outer cortical dysplasia, cystic subcapsular glomeruli, loss of proximal tubular mass, and tubular atrophy and cyst formation. Adult -/- kidneys had profound diffuse tubular cyst formation, outer cortical glomerular hypoplasia and periglomerular fibrosis, inner cortical nephron hypertrophy, and diffuse interstitial fibrosis. The glomerular filtration rate was reduced by more than 50% in -/- animals (6.82 +/- 0.65 mL/min/kg) compared with wild-type controls (14.7 +/- 1.01 mL/min/kg, P < 0. 001). Plasma blood urea nitrogen and creatinine were elevated in null animals compared with controls. Blood pressure, urinalysis, urine osmolality, and other plasma chemistries were unaffected by the deletion of COX-2. CONCLUSIONS: Deficiency of COX-2 results in progressive and specific renal architectural disruption and functional deterioration beginning in the final phases of nephrogenesis. Tissue-specific and time-dependent expression of COX-2 appears necessary for normal postnatal renal development and the maintenance of normal renal architecture and function.

Hypocomplementemic urticarial vasculitis: report of a pediatric case.

Hypocomplementemic urticarial vasculitis syndrome (HUVS) is well described in adults but is quite rare in children. We report a pediatric case of HUVS initially diagnosed as juvenile rheumatoid arthritis and then as Henoch-Schönlein purpura. Beginning at 3 years of age, our patient developed polyarthritis with hypocomplementemia. She subsequently experienced an intermittent purpuric rash beginning at age 4 years, and she continued to have episodic arthritis and rash for years. Hematuria and proteinuria were noted at 12 years of age; renal biopsy revealed membranoproliferative glomerulonephritis with membranous features. Serum complement evaluation revealed activation of the classical pathway, consistent with HUVS. Therapy with oral dapsone led to improvement in proteinuria. HUVS should be considered in the differential diagnosis of pediatric patients with glomerulonephritis, urticarial rash, arthritis/arthralgias, and obstructive pulmonary disease.

Novel expression and regulation of the renin-angiotensin system in metanephric organ culture.

To evaluate the presence and regulation of the renin-angiotensin system (RAS) in metanephric organ culture, embryonic day 14 (E14) rat metanephroi were cultured for 6 days. mRNAs for renin and both ANG II receptors (AT(1) and AT(2)) are expressed at E14, and all three genes continue to be expressed in culture. Renin mRNA is localized to developing tubules and ureteral branches in the cultured explants. At E14, renin immunostaining is found in isolated cells scattered within the mesenchyme. As differentiation progresses, renin localizes to the ureteric epithelium, developing tubules and glomeruli. E14 metanephroi contain ANG II, and peptide production persists in culture. Renin activity is present at E14 (6.13 +/- 0.61 pg ANG I. kidney(-1). h(-1)) and in cultured explants (28.84 +/- 1. 13 pg ANG I. kidney(-1). h(-1)). Renin activity in explants is increased by ANG II treatment (70.1 +/- 6.36 vs. 40.97 +/- 1.94 pg ANG I. kidney(-1). h(-1) in control). This increase is prevented by AT(1) blockade, whereas AT(2) antagonism has no effect. These studies document an operational local RAS and a previously undescribed positive-feedback mechanism for renin generation in avascular, cultured developing metanephroi. This novel expression pattern and regulatory mechanism highlight the unique ability of developing renal cells to express an active RAS.

Differential expression of angiotensin II receptors during early renal morphogenesis.

Angiotensin II (ANG II) and its receptors, AT1 and AT2, may modulate kidney development. To define the temporal and spatial distribution of AT1 and AT2 receptors and their mRNAs during nephrogenesis, fetal, newborn, and adult rat kidneys were studied using reverse transcription-polymerase chain reaction and radioligand binding autoradiography. AT1 expression was minimal at embryonic day 14 (E14), highly expressed at E20, and persisted into adulthood. Conversely, AT2 expression was easily detected from E14 through postnatal day 7 but was undetectable by postnatal day 28. At E14, 76% of the receptors were AT2, 24% were AT1, and both were found in the undifferentiated mesenchyme. By E17, AT1 comprised 40% of the receptors and localized to mature nephron segments, whereas AT2 remained within both condensed mesenchyme and differentiating epithelia. The dissociation constants for AT1 and AT2 were 0.45 +/- 0.09 nM and 0.73 +/- 0.15 nM, respectively, at E17, similar to adult values. By E20, AT1 and AT2 colocalized to the outer medullary stripe, deep nephrons, medullary rays, and blood vessels, while AT2 continued to predominate in the actively differentiating cortex. The presence of both subtypes of receptors capable of binding ANG II during early nephrogenesis and the time-dependent and structure-specific regulation of receptor localization confirm a regulated developmental program for receptor expression and suggest important roles for AT1 and AT2 in renal morphogenesis.

Vascular endothelial growth factor induces nephrogenesis and vasculogenesis.

The expression of vascular endothelial growth factor (VEGF) and its receptors Flt-1 and Flk-1 in the rat kidney was examined during ontogeny using Northern blot analysis and immunocytochemistry. In prevascular embryonic kidneys (embryonic day 14 [E14]), immunoreactive Flt-1 and Flk-1 were observed in isolated angioblasts, whereas VEGF was not detected. Angioblasts aligned forming cords before morphologically differentiating into endothelial cells. In late fetal kidneys (E19), immunoreactive VEGF was detected in glomerular epithelial and tubular cells, whereas Flt-1 and Flk-1 were expressed in contiguous endothelial cells. To determine whether VEGF induces endothelial cell differentiation and vascular development in the kidney, the effect of recombinant human VEGF (5 ng/ml) was examined on rat metanephric organ culture, a model known to recapitulate nephrogenesis in the absence of vessels. After 6 d in culture in serum-free, defined media, metanephric kidney growth and morphology were assessed. DNA content was higher in VEGF-treated explants (1.9 +/- 0.17 microg/kidney, n = 9) than in paired control explants (1.4 +/- 0.10 microg/kidney, n = 9) (P < 0.05). VEGF induced proliferation of tubular epithelial cells, as indicated by an increased number of tubules and tubular proliferating cell nuclear antigen-containing cells. VEGF induced upregulation of Flk-1 and Flt-1 expression, as assessed by Western blot analysis. Developing endothelial cells were identified and localized using immunocytochemistry and electron microscopy. Flt-1, Flk-1, and angiotensin-converting enzyme-containing cells were detected in VEGF-treated explants, whereas control explants were negative. These studies confirmed previous reports indicating that the expression of VEGF and its receptors is temporally and spatially associated with kidney vascularization and identified angioblasts expressing Flt-1 and Flk-1 in prevascular embryonic kidneys. The data indicate that VEGF expression is downregulated in standard culture conditions and that VEGF stimulates growth of embryonic kidney explants by expanding both endothelium and epithelium, resulting in vasculogenesis and enhanced tubulogenesis. These data suggest that VEGF plays a critical role in renal development by promoting endothelial cell differentiation, capillary formation, and proliferation of tubular epithelia.

Neonatal ureteral obstruction stimulates recruitment of renin-secreting renal cortical cells.

Unilateral ureteral obstruction (UUO) in the neonate increases ipsilateral renal renin gene expression, an effect which is mediated by renal nerves. To determine whether neonatal UUO alters the number of renal cortical cells secreting renin and whether this change is modulated by renal nerve activity, newborn Sprague-Dawley rats were subjected to left UUO, right uninephrectomy, or sham operation and studied four weeks thereafter. To evaluate the importance of renal nerves in this response, an additional group of animals underwent chemical sympathectomy with guanethidine. Ureteral obstruction was associated with marked reduction in renal mass in the obstructed kidney and contralateral compensatory hypertrophy, changes which were not altered by sympathectomy. Renin messenger RNA and renal renin content were elevated in the obstructed kidney. The number of cells secreting renin, measured by the reverse hemolytic plaque assay, was markedly increased in the obstructed kidney (45 +/- 18 plaques/slide vs. 11 +/- 1 plaques/slide in sham animals), but not in the opposite kidney or following uninephrectomy. This effect was not significantly altered by sympathectomy. There was no change in the amount of renin secreted per cell or in the secretory response to Ca++. These results show that UUO results in recruitment of cells not previously secreting renin by a mechanism independent of renal nerve activity. This recruitment occurs without alteration of the quantity of renin secreted per cell or in the normal regulatory effect of Ca++ on renin secretion. An increase in the number of renin-secreting cells may contribute to the activation of the renin-angiotensin system, and thus to the vasoconstriction observed following ureteral obstruction.

Oxygen regulates vascular endothelial growth factor-mediated vasculogenesis and tubulogenesis.

To determine whether low oxygen is a stimulus for endothelial cell differentiation and vascular development in the kidney, we examined the effect of low oxygen on rat metanephric organ culture, a model known to recapitulate nephrogenesis in the absence of vessels. After 6 days in culture in standard (20% O2) or low oxygen (1-3% O2) conditions, metanephric kidney growth and morphology were assessed by DNA measurement, and light and electron microscopy. DNA content was higher in 3% O2-treated explants (2.5 +/- 0.17 microgram/kidney, n = 9) than in 20% O2 explants (1.5 +/- 0.09 microgram/kidney, n = 9), P < 0.05. Low oxygen induced proliferation of tubular epithelial cells, resulting in enhanced number of tubules of similar size. Endothelial cells forming capillaries were localized in 3% O2 explants by light and electron microscopy and by immunocytochemistry using endothelial cell markers. Flt-1, Flk-1, and ACE-containing cells were detected in 3% O2-treated explants, whereas 20% O2 explants were virtually negative. VEGF mRNA levels were 10-fold higher in 3% O2-treated explants than in 20% O2-treated explants. Addition of anti-VEGF antibodies to 3% O2-treated explants prevented low oxygen-induced growth and endothelial cell differentiation and proliferation. Our data indicate that low oxygen stimulates growth by cell proliferation and induces tubulogenesis, endothelial cell differentiation, and vasculogenesis in metanephric kidneys in culture. Upregulation of VEGF expression by low oxygen and prevention of low oxygen-induced tubulogenesis and vasculogenesis by anti-VEGF antibodies indicate that these changes were mediated by VEGF. These data suggest that low oxygen is the stimulus to initiate renal vascularization.

Regulation of angiotensin II AT1 and AT2 receptors in neonatal ureteral obstruction.

Chronic unilateral ureteral obstruction (UUO) in early development activates the intrarenal renin-angiotensin system and leads to profound renal vasoconstriction, renal growth arrest, and interstitial fibrosis. To investigate the response of the AT1 and AT2 subtypes of the angiotensin II (ANG II) receptors to UUO, Sprague-Dawley rats underwent UUO or control sham operation in the first 48 h of life and were studied 1-28 days later. Renal mRNA for renin, AT1 and AT2 receptor, and receptor binding and distribution were determined. In contrast to controls, renin mRNA increased from 14 to 28 days in the obstructed kidney. After ipsilateral UUO, AT1 mRNA was suppressed at 1 day, but had increased compared with controls at 28 days. AT2 receptor mRNA fell rapidly in all kidneys from 1 to 3 days of age, after which it remained undetectable. Compared with the intact opposite kidney, AT2 mRNA was suppressed in the obstructed kidney 1 day after UUO. Compared with controls, AT1 and AT2 receptor binding was decreased by ipsilateral UUO at 1 day, whereas AT1 binding was increased at 28 days. Renal ANG II content was increased in the obstructed compared with the intact opposite kidney 28 days after UUO. In view of the increase in renal renin and angiotensin II production resulting from UUO, increased renal AT1 mRNA and receptor binding are likely to contribute to the vasoconstriction and interstitial fibrosis of the neonatal kidney after prolonged UUO.

Zis: a developmentally regulated gene expressed in juxtaglomerular cells.

Renal juxtaglomerular (JG) cells are specialized myoepithelioid cells located in the afferent arteriole at the entrance to the glomerulus. Their main function and distinctive feature is the synthesis and release of renin, the key hormone-enzyme of the renin-angiotensin system that regulates arterial blood pressure. Despite their relevance to health and disease, not much is known about factors that confer and/or maintain JG cell identity. To identify genes uniquely expressed in JG cells, we used a cell culture model and RNA differential display. JG cells cultured for 2 days express renin and renin mRNA, but after 10 days in culture they no longer contain or release renin and renin mRNA is reduced 700-fold. We report one cDNA differentially expressed in the 2-day JG cell culture that detects a 2.6-kb mRNA expressed at higher levels in newborn than adult kidney. Screening a 2-day culture JG cell cDNA library yielded clones representing differentially spliced transcripts. These cDNAs encode one unique protein (Zis) containing zinc fingers and domains characteristic of splicing factors and RNA binding proteins. Northern blot analysis confirmed Zis mRNA expression in differentiated JG cells, and identified an additional unique 1.5-kb transcript. The Zis transcripts are developmentally regulated in kidney and a number of other organs. The features of the Zis protein and its organ distribution suggest a possible role in regulation of transcription and/or splicing, both important steps for controlling developmentally expressed genes.

The maturing kidney: development and susceptibility.

Kidney morphogenesis is accomplished by the coordinated interaction of molecular signals that culminate in the production of an organ that is architecturally and functionally ready for extrauterine, free life. In humans, nephrogenesis is completed before birth. However the kidney continues to mature both from a functional and anatomical point of view. Throughout its development, the kidney is susceptible to a variety of injurious agents. This brief review considers the basic mechanisms of kidney organogenesis and functional maturation. To illustrate some concepts, the renal alterations caused by interference with a normal regulatory system, the renin-angiotensin system is discussed.