Elevated levels of endogenous angiotensin can cause hypertensive nephrosclerosis as a result of the potent vasopressor action of the peptide. We have produced by gene targeting mice homozygous for a null mutation in the angiotensinogen gene (Atg-'-). Postnatally, Atg-'-animals show a modest delay in glomerular maturation. Although Atg-'-animals are hypotensive by 7 wk of age, they develop, by 3 wk of age, pronounced lesions in the renal cortex, similar to those of hypertensive nephrosclerosis. In addition, the papillae of homozygous mutant kidneys are reduced in size. These lesions are accompanied by local up-regulation of PDGF-B and TGF-fi1 mRNA in the cortex and down-regulation of PDGF-A mRNA in the papilla. The study demonstrates an important requirement for angiotensin in achieving and maintaining the normal morphology of the kidney. The mechanism through which angiotensin maintains the volume homeostasis in mammals includes promotion of the maturational growth of the papilla. (J. Clin. Invest. 1995.
Rodents are the unique species carrying duplicated angiotensin (Ang) type 1 (AT1) receptor genes, Agtr1a and Agtr1b. After separately generating Agtr1a and Agtr1b null mutant mice by gene targeting, we produced double mutant mice homozygous for both Agtr1a and Agtr1b null mutation (Agtr1a-/-; Agtr1b-/-) by mating the single gene mutants. Agtr1a-/-, Agtr1b-/- mice are characterized by normal in utero survival but decreased ex utero survival rate. After birth they are characterized by low body weight gain, marked hypotension, and abnormal kidney morphology including delayed maturity in glomerular growth, hypoplastic papilla, and renal arterial hypertrophy. These abnormal phenotypes are quantitatively similar to those found in mutant mice homozygous for the angiotensinogen gene (Agt-/-), indicating that major biological functions of endogenous Ang elucidated by the abnormal phenotypes of Agt-/- are mediated by the AT1 receptors. Infusion of Ang II, AT1 blockers, or an AT2 blocker was without effect on blood pressure in Agtr1a-/-; Agtr1b-/- mice, indicating that AT2 receptor does not exert acute depressor effects in these mice lacking AT1 receptors. Also, unlike Agt-/- mice, some Agtr1a-/-; Agtr1b-/- mice have a large ventricular septum defect, suggesting that another receptor such as AT2 is functionally activated in Agtr1a-/-, Agtr1b-/- mice.
We null mutated the mouse angiotensin type 1B (AT1B) receptor gene (Agtr1b) by gene targeting. To identify the specific cell types carrying high Agtr1b gene transcriptional activities, the AT1B coding exon was replaced with a reporter gene, lacZ. In 6- to 8-wk-old Agtr1b -/- mice, high AT1B transcriptional activity was observed in adrenal zona glomerulosa cells and the testis, including mature and immature spermatic cells, whereas low activity was detected homogeneously in anterior pituitary cells and choroidal plexus vessel walls. A similar pattern was observed in Agtr1b +/- mice with less intensity. Microscopically, the anterior pituitary, heart, adrenal, zona glomerulosa, kidney, and the testis of Agtr1b -/- mice were intact and were indistinguishable from those of Agtr1b +/+ mice. Systemic blood pressure was comparable in Agtr1b -/- and Agtr1b +/+ mice. Moreover, plasma aldosterone level was comparable between the two mouse groups. No compensatory enhancement of AT1A mRNA was found in the kidney and adrenal gland of Agtr1b -/- mice. The observed absence of the abnormal phenotypes in Agtr1b -/- mice, which have been described for homozygous angiotensinogen null mutant mice, indicates that 1) AT1A receptors can take over the role of AT1B receptors in Agtr1b -/- mice or 2) functionally significant non-AT1, non-AT2 receptor(s) may exist for the action of angiotensin.
Wild-type ( Agt ϩ / ϩ ) and homozygous angiotensinogen deletion mutant ( Agt Ϫ / Ϫ ) littermates were placed on normal (NS) or low Na diet (LS) for 2 weeks. Plasma aldosterone levels (P aldo ) were comparable during NS, and similarly elevated during LS in Agt ϩ / ϩ and Agt Ϫ / Ϫ . Moreover, in both, the elevation in P aldo was accompanied by marked increase in adrenal zona glomerulosa cells and adrenal P450aldo mRNA. Agt Ϫ / Ϫ mice were distinguished from Agt ϩ / ϩ mice by their higher plasma K level, by ف 1.5 and ف 3.8 mEq/liter during NS and LS, respectively. Within the Agt Ϫ / Ϫ group, P aldo was directly proportional to plasma K. The importance of K for the hyperaldosteronism during dietary Na restriction was verified by the observation that superimposition of K restriction led to hypotension in Agt ϩ / ϩ and uniform death in Agt Ϫ / Ϫ mice along with a reduction in P aldo by 75 and 90%, respectively. Thus, suppression of potassium, but not angiotensin, led to a marked attenuation of hyperaldosteronism during dietary Na restriction. Therefore, ( a ) a powerful angiotensin-independent mechanism exists for the hyperaldosteronism during LS; ( b ) high K is a central component of this mechanism; ( c ) contrary to current belief, the tonic effect of high K on aldosterone synthesis and release does not require an intact renin-angiotensin system; and ( d ) normally, intermediary feedback signals for hyperaldosteronism, i.e., both hypotension and high K, are effectively masked by aldosterone actions. ( J. Clin. Invest. 1997. 99:855-860.)
Chronic volume depletion by dietary salt restriction causes marked decrease in glomerular filtration rate (GFR) with little increase in urine osmolality in angiotensinogen gene null mutant (Agt-/-) mice. Moreover, urine osmolality is insensitive to both water and vasopressin challenge. In contrast, in normal wild-type (Agt+/+) mice, GFR remains remarkably constant and urine osmolality is adjusted promptly. Changes in volume status also cause striking divergence in renal structure between Agt-/- and Agt+/+ mice. Thus, in contrast to the remarkably stable glomerular size of Agt+/+ mice, glomeruli of Agt-/- mice are atrophied during a low salt and hypertrophied during a high salt diet. Moreover, the renal papilla, a structure unique to mammals and essential for urine diluting and concentrating mechanisms, is hypoplastic in Agt-/- mice. Thus, angiotensin is essential for the two fundamental homeostatic functions of the mammalian kidney, namely stable GFR and high urine diluting and concentrating capacity during alteration in extracellular fluid (ECF) volume. This is not only accompanied by angiotensin's tonic effects on renal vasomotor tone and tubule transporters, but also accomplished through its capacity to affect the structure of both the glomerulus and the papilla directly or indirectly.
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