Wirkung von Aldosteron auf die Natrium-und Wasserresorption im proximalen Tubulus bei chronischer Kochsalzbelastung

Renal tubular function in the gravid rat

Pregnancy in the rat is accompanied by enhanced reabsorption of salt and water throughout most, if not all, of the gestational period. Many mechanisms have been suggested but definitive answers are still awaited. The major area of controversy centres around the detection of changes at term. There is general agreement that, at least in mid-gestation, the increase in reabsorption can be attributed to increases in the proximal tubules, the loop of Henle and the collecting duct. The contribution of the proximal tubule to the increased reabsorption at term is still uncertain. Enhanced salt and water reabsorption is demonstrated in distal nephron segments irrespective of the stage of gestation. Micropuncture and microperfusion experiments have identified increased reabsorption of water, sodium and chloride in the loop of Henle, but it appears that there is net addition of glucose, urea and potassium to the tubular fluid in this segment which, at least for potassium and glucose, offsets to some extent increased reabsorption by the proximal tubule. Altered renal handling of other solutes (uric acid, calcium and magnesium) also occurs throughout pregnancy but the mechanisms responsible and nephron sites involved remain to be investigated. Attempts to attribute altered reabsorption to direct renal effects of changes in maternal hormones are inconclusive. Prolactin mimics some of the pregnancy-associated increases in reabsorption following chronic administration to male and non-pregnant female rats. These effects might be due to a direct renal action of the hormone or even to the volume expansion following its dipsogenic action.

Renal tubular function in the gravid rat

Pregnancy in the rat is accompanied by enhanced reabsorption of salt and water throughout most, if not all, of the gestational period. Many mechanisms have been suggested but definitive answers are still awaited. The major area of controversy centres around the detection of changes at term. There is general agreement that, at least in mid-gestation, the increase in reabsorption can be attributed to increases in the proximal tubules, the loop of Henle and collecting duct. The contribution of the proximal tubule to the increased reabsorption at term is still uncertain. Enhanced salt and water reabsorption is demonstrated in distal nephron segments irrespective of the stage of gestation. Micropuncture and microperfusion experiments have identified increased reabsorption of water, sodium and chloride in the loop of Henle, but it appears that there is net addition of glucose, urea and potassium to the tubular fluid in this segment which, at least for potassium and glucose, offsets to some extent increased reabsorption by the proximal tubule. Altered renal handling of other solutes (uric acid, calcium and magnesium) also occurs throughout pregnancy but the mechanisms responsible and nephron sites involved remain to be investigated. Attempts to attribute altered reabsorption to direct renal effects of changes in maternal hormones are inconclusive. Prolactin mimics some of the pregnancy-associated increases in reabsorption following chronic administration to male and non-pregnant female rats. These effects might be due to a direct renal action of the hormone or even to the volume expansion following its dipsogenic action.

Oxidative response to aldosterone of pyridine nucleotide in rat kidney in situ

In an attempt to elucidate early biochemical events in the action of aldosterone on rat kidney in situ, the response of the pyridine nucleotide oxidation-reduction state of surface cells was directly and continuously recorded with an organ-fluorometer. Intravenous administration of aldosterone induced a rapid (maximum response in 10 min) and dose-related (2.5-25 microng/100 g rat) oxidative response that was specific to aldosterone and to the kidney. The oxidative response was 1) detectable with minute dise (approximately 0.2 microng/100 g rat) of hormone: 2) reproduced by other mineralocorticoids; 3) enhanced by a maneuver for expanding the extracellular fluid compartment or by adrenalectomy; and 4) prevented by spironolactone, progesterone, actinomycin D, and cycloheximide. All of these data argue that the redox response is related to the subsequent changes in aldosteronemediated ion transport. Experiments with an uncoupler and with redox substrates showed that mitochondrial NADH was the major nucleotide pool responding to hormone. The oxidation was not accompanied by changes in the adenylate energy charge level of the whole organ. These observations support the view that aldosterone acts on energy metabolism of tubular cells before developing apparent cation transport effects.