COUNTERBALANCE IN FUNCTIONAL ADAPTATION TO URETERAL OBSTRUCTION DURING DEVELOPMENT

被引：12

作者：

CHEVALIER, RL

机构：

[1] Department of Pediatrics, The University of Virginia School of Medicine, Health Sciences Center, Charlottesville, 22908, VA

来源：

PEDIATRIC NEPHROLOGY | 1990年 / 4卷 / 04期

关键词：

Angiotensin; Development; Gene expression; Renal hemodynamics; Renal nerves; Renin; Unilateral ureteral obstruction;

D O I：

10.1007/BF00862533

中图分类号：

R72 [儿科学];

学科分类号：

100202 ;

摘要：

Renal counterbalance, as described by Hinman in 1923, is the phenomenon of increased function of the intact kidney in proportion to the loss of function resulting from unilateral ureteral obstruction (UUO). In the neonatal guinea pig, chronic partial UUO results in severe vasoconstriction and growth arrest of the ipsilateral kidney. Angiotensin II appears to contribute significantly to the vasoconstriction, and the renin-angiotensin system is also involved in the hemodynamic response of the intact opposite kidney to UUO and to relief of UUO. Immunolocalization of renin following complete UUO in the neonatal rat revealed extension of renin-containing cells along the length of the afferent arteriole in both the obstructed and the intact opposite kidney. The proportion of juxtaglomerular apparatuses with detectable renin and renin messenger ribonucleic acid (mRNA) (identified by in situ hybridization), as well as renal renin content (a measure of active renin), were increased in the obstructed kidney compared with the intact opposite kidney. Chemical sympathectomy by chronic guanethidine administration reduced the total renin mRNA in the obstructed kidney (determined by Northern blot analysis) and prevented the increased renin immunostaining in both kidneys. Thus, renal counterbalance in the developing kidney subjected to UUO is mediated or modulated by the renal nerves and involves marked alterations in gene expression and cellular processing of renin. © 1990 IPNA.

引用

页码：442 / 444

页数：3

共 16 条

[1]

Hinman F., Renal counterbalance: an experimental and clinical study with reference to the significance of disuse atrophy, J Urol, 9, pp. 289-314, (1923)

[2]

Hayslett J.P., Effect of age on compensatory renal growth, Kidney Int, 23, pp. 599-602, (1983)

[3]

Taki M., Goldsmith D.I., Spitzer A., Impact of age on effects of ureteral obstruction on renal function, Kidney Int, 24, pp. 602-609, (1983)

[4]

Chevalier R.L., Glomerular number and perfusion during normal and compensatory renal growth in the guinea pig, Pediatr Res, 16, pp. 436-440, (1982)

[5]

Chevalier R.L., Functional adaptation to reduced renal mass in early development, Am J Physiol, 242, pp. F190-F196, (1982)

[6]

Chevalier R.L., Reduced renal mass in early postnatal development: glomerular dynamics in the guinea pig, Biol Neonate, 44, pp. 158-165, (1983)

[7]

Chevalier R.L., Kaiser D.L., Chronic partial ureteral obstruction in the neonatal guinea pig. I. Influence of uninephrectomy on growth and hemodynamics, Pediatr Res, 18, pp. 1266-1271, (1984)

[8]

Chevalier R.L., Gomez R.A., Jones C.A., Developmental determinants of recovery after relief of partial ureteral obstruction, Kidney Int, 33, pp. 775-781, (1988)

[9]

Chevalier R.L., Sturgill, Jones C.E., Morphologic correlates of renal growth arrest in neonatal partial ureteral obstruction, Pediatr Res, 21, pp. 338-346, (1987)

[10]

Chevalier R.L., Peach M.J., Hemodynamic effects of enalapril on neonatal chronic partial ureteral obstruction, Kidney Int, 28, pp. 891-898, (1985)

← 1 2 →