The binding of [125I]-angiotensin to rat renal epithelial cell membranes

Androgens stimulate proximal tubule transport

BACKGROUND

Disrupting the enzyme cytochrome P4a14 in mice leads to hypertension, which is more severe in male than in female mice and appears to be due to androgen excess. Androgens are known to increase expression of angiotensinogen,but the effect of androgens on proximal tubule transport is unknown.

OBJECTIVE

These studies aimed to determine the effect of androgens on proximal tubule transport.

METHODS

Proximal tubules from knockout (KKO) and wild-ttype (WWT) (SSV/1129) mice were perfused in vitro. Volume resorption (JJ v ) was measured using 3 H-methoxy inulin as a volume marker. In separate experiments, male Sprague-Dawley rats were given dihydrotestosterone (DDHT) injections IP for 10 days. Proximal tubule transport was measured in this model using in vivo microperfusion. The renal expression of angiotensinogen was measured by Northern analysis, and brush border membrane protein abundance of the sodium-hhydrogen exchanger isoform 3 (NNHE3) was measured by Western blotting in the control and DHT-ttreated rats.

RESULTS

Mean (SSE) Jv was significantly elevated in proximal tubules from KO mice compared with WT mice (11.11 [0.006] vs 0.77 [0.112] nL/mm . mm, respectively; P<0.05). The mean proximal tubule Jv rate was significantly higher in DHT-ttreated rats than in control rats given vehicle injections (44.57 [0.331] vs 3.31 [0.223] nL/mm . min, respectively; P<0.01). Luminal perfusion with either enalaprilat or losartan decreased the proximal tubule J v rate in DHT-ttreated rats to a greater degree than in control rats. The DHT-treated rats had higher blood pressures and lower serum angiotensin II concentrations than did the control rats.

CONCLUSION

Results suggest that androgens may directly upregulate the proximal tubule reninangiotensin system, increase the expression of NHE3, and increase the Jv rate, thereby increasing extracel-lular volume and blood pressure and secondarily decreasing serum angiotensin II concentrations.

Androgens augment proximal tubule transport

The proximal tubule contains an autonomous renin-angiotensin system that regulates transport independently of circulating angiotensin II. Androgens are known to increase expression of angiotensinogen, but the effect of androgens on proximal tubule transport is unknown. In this in vivo microperfusion study, we examined the effect of androgens on proximal tubule transport. The volume reabsorptive rate in Sprague-Dawley rats given dihydrotestosterone (DHT) injections was significantly higher than in control rats given vehicle injections (4.57 +/- 0.31 vs. 3.31 +/- 0.23 nl x min(-1) x mm(-1), P < 0.01). Luminally perfusing with either enalaprilat (10(-4) M) to inhibit production of angiotensin II or losartan (10(-8) M) to block the angiotensin receptor decreased the proximal tubule volume reabsorptive rate in DHT-treated rats to a significantly greater degree than in control vehicle-injected rats. The renal expression of angiotensinogen was shown to be higher in the DHT-treated animals, using Northern blot analysis. The expression of angiotensin receptors, determined by specific binding of angiotensin II, was not different in the two groups of animals. Brush-border membrane protein abundance of the Na/H exchanger, a membrane transport protein under angiotensin II regulation, was also higher in DHT-treated rats vs. control rats. Rats that received DHT had higher blood pressures than the control rats but had no change in their glomerular filtration rate. In addition, serum angiotensin II levels were lower in DHT-treated vs. control rats. These results suggest that androgens may directly upregulate the proximal tubule renin-angiotensin system, increase the volume reabsorptive rate, and thereby increase extracellular volume and blood pressure and secondarily decrease serum angiotensin II levels.

Endogenous angiotensin II modulates rat proximal tubule transport with acute changes in extracellular volume

In the present study, we examined whether the effect of endogenously produced angiotensin II on proximal tubule transport in the male Sprague-Dawley rat is regulated by acute changes in extracellular volume. We measured the magnitude of endogenous angiotensin II-mediated stimulation of transport by sequentially perfusing proximal tubules in vivo, first with an ultrafiltrate-like solution, then by reperfusion of the same tubule with an ultrafiltrate-like solution containing 10(-8) M losartan (angiotensin II receptor antagonist). During volume contraction, 10(-8) M losartan decreased volume reabsorption from 4.20 +/- 0.50 to 1.70 +/- 0.30 nl . mm-1 . min-1 (P < 0.05), a decrease of 58.0 +/- 7.0%. In contrast, after acute volume expansion, 10(-8) M losartan decreased volume reabsorption from 1.84 +/- 0.20 to 1.31 +/- 0.20 nl . mm-1 . min-1 (P < 0.05), a decrease of 29.6 +/- 9.0%. In hydropenic rats, addition of exogenous luminal angiotensin II had no effect on transport. However, in volume-expanded rats, addition of 10(-8) M angiotensin II increased volume reabsorption from 2.10 +/- 0.34 to 4. 38 +/- 0.59 nl . mm-1 . min-1 (P < 0.005). These data are consistent with endogenously produced angiotensin II augmenting proximal tubule transport to a greater degree during volume contraction than after volume expansion.

The effect of angiotensin II upon electrogenic ion transport in rat intestinal epithelia

Epithelial sheets from rat jejunum and descending colon have been shown to respond to angiotensin II (AII) when studied under short-circuit conditions and bathed on both sides with Krebs-Henseleit solution. The octapeptide AII elicited increases in short-circuit current (SCC) in preparations of jejunum and decreases in SCC in the descending colon; both responses occurred when the peptide was applied to the basolateral surface, but not when applied to the apical solution. Responses in both tissues were highly specific, being inhibited by a range of AII antagonists with the following order of potency: [Sar1. Thr8]-AII greater than [Sar1. Leu8]-AII greater than [Sar1. Ile8]-AII greater than [Sar1. Ala8]-AII greater than [Des,Asp1. Ile8]-AII in rat jejunum. AII responses were not affected by alpha- or beta- adrenoceptor antagonists, atropine or tetrodotoxin. AII responses were totally inhibited by the chloride channel blocker, diphenylamine-2-carboxylate (DPC) while cotransport inhibitors e.g. piretanide and frusemide significantly reduced the size of AII responses in colon and jejunum. These patterns of activity suggest that in the jejunum the responses result from electrogenic chloride secretion. Although AII responses in colon were sensitive to DPC the transporting ions have not yet been identified. Both piroxicam and indomethacin inhibited the increase in SCC elicited by AII in the jejunum, and the reduction in SCC caused by AII in the colon. Taken together these results indicate that eicosanoids are involved in AII responses in both tissues. This is the first study to demonstrate a direct, electrogenic effect for AII on transporting epithelia from the gastrointestinal tract. The responses are most probably initiated by All interacting with previously identified specific All receptors within the epithelial membranes.

Angiotensin II binding sites in individual segments of the rat nephron

The sites of action of angiotensin II along the nephron are not well defined and both proximal and distal effects are suggested. Using a microassay that permits measurement of hormone binding in discrete tubule segments, we determined the binding sites of 125I-angiotensin II along the nephron of Sprague-Dawley rats. Specific binding in proximal convoluted tubule (PCT) (at 25 degrees C, pH 7.4) was linearly related to tubule length and saturable, with an apparent maximal binding capacity of approximately 300 amol X cm-1. Binding specificity was verified in competition experiments that revealed significant (P less than 0.001) and comparable competition for radioligand binding by angiotensin II and angiotensin precursor, metabolite, and analogues, whereas unrelated peptides of similar size (bradykinin, ACTH [1-10]) were without effect. The profile of specific angiotensin II binding along the nephron was: PCT, 216 +/- 13; pars recta, 86 +/- 14; medullary thick ascending limb of Henle's loop, 46 +/- 8; cortical thick ascending limb of Henle's loop, 77 +/- 8; distal convoluted tubule, 49 +/- 10; cortical collecting tubule, 15 +/- 1; medullary collecting tubule, 32 +/- 7 amol X cm-1. These results indicate the presence of specific angiotensin II binding sites in all tubule segments studied, but binding capacity was highest in the proximal convoluted tubule, in agreement with transport studies that localize the effects of the hormone in this segment.

Identification of selective, high affinity [125I]-angiotensin and [125I]-bradykinin binding sites in rat intestinal epithelia

Specific [125I]-angiotensin II (AII) and [125I]-bradykinin (Bk) binding sites have been identified within epithelial membranes from rat jejunum and descending colon. These high affinity intestinal sites exhibited KD values of 0.64 +/- 0.16 nM for [125I]-AII and 0.69 +/- 0.13 nM for [125I]-Bk, which were similar to those for [125I]-AII (0.85 nM) and [125I]-Bk binding sites (1.03 nM) previously identified in renal cortex epithelia. Specific [125I]-AII binding capacity was only 19.77 +/- 2.74 fmol mg-1 in small intestine and 11.31 +/- 2.66 fmol mg-1 in descending colon epithelia while a larger population, 332.0 +/- 72.9 fmol-mg-1 of specific [125I]-Bk sites were identified in epithelial membranes from small intestine. Significant hydrolysis of both free [125I]-AII and [125I]-Bk was observed while membrane bound peptides remained relatively resistant to degradation. Whilst no corrections have been made to the observed values of KD and Bmax quoted above, one may assume that the calculated reductions in the free hormone concentration will result in a decrease of the KD value for both peptides. Loss of membrane bound peptide, particularly of [125I]-AII, may indicate that the calculated Bmax value is an underestimation. Despite the rapid degradation of unbound [125I]-AII and [125I]-Bk during incubations the kinetics of specific peptide binding were reversible and highly selective. The order of potency for specific [125I]-AII binding was [Sar1, Leu8]-AII greater than or equal to [Sar1, Thr8]-AII greater than or equal to AII greater than [Sar1, Ile8]-AII greater than or equal to [Des, Asp1, Ile8] AII greater than AIII. Specific [125I]-Bk binding was also highly selective, the order of potency being Phe8-Bk greater than or equal to Tyr8-Bk greater than or equal to Lys-Bk much greater than Des, Arg1-Bk. AII exhibited an IC50 of greater than 1mM for specific [125I]-Bk binding and likewise Phe8-Bk for specific [125I]-AII binding.

Inactivation of [125I]-angiotensin II binding sites in rat renal cortex epithelial membranes by dithiothreitol

Preincubation of renal epithelial membranes with DTT produced a dose-dependent inhibition of specific [125I]-angiotensin binding, with an IC50 of 1 mM and total loss of binding at 5-10 mM DTT. Inactivation of specific [125I]-angiotensin II binding by DTT was temperature sensitive; the t1/2 at 22 degrees was 6 min compared with 30 min at 4 degrees. A rapid inactivation rate was dependent on the presence of NaCl. In the presence of 120 mM NaCl the t1/2 for inactivation by DTT was 6 min and 33 min in the absence of NaCl. Protection against DTT inactivation was obtained by preincubating membranes with unlabelled angiotensin II greater than angiotensin I greater than renin substrate while the dipeptide, Ileu-His was only effective in protecting the binding site at high concentrations (10 mM). Preincubations with DTT (1 mM) caused a 43% decrease in Bmax from 217.0 +/- 39.5 to 123.7 +/- 30.9 fmol bound/mg protein while the KD was not significantly affected.

Location of [125I]-angiotensin II receptors on rat kidney cortex epithelial cells

Angiotensin II (AII) stimulates active Na+ extrusion from Na+ loaded renal cortex slices. Specific high affinity [125I]-AII binding sites in partially purified basolateral and brush-border epithelial membranes exhibit a KD of 0.88 nM and Bmax of 321.13 fmol mg-1 protein. Separation and purification of brush-border membranes yielded high affinity [125I]-AII binding sites with KD of 1.02 nM and Bmax of 56.6 fmol mg-1 protein. Angiotensin II receptors of the same affinity are present on renal cortex brush-border and basolateral membranes but a greater proportion are located on the latter. These receptors may be involved in the direct control of Na+ and water transport by AII.

The effect of guanine nucleotides on [125I]-angiotensin binding in rat kidney cortex epithelial membranes

Specific [125I]-angiotensin binding to crude basolateral/brush border membranes of rat kidney cortex was influenced by guanine nucleotides. The order of potency of nucleotides in their ability to decrease specific binding, was Gpp(NH)p greater than GTP greater than or equal to ITP greater than GDP greater than ATP greater than GMP greater than IDP. The kinetic alterations induced by a maximally effective concentration of Gpp(NH)p were: (a) a reduced steady state level of binding and (b) a markedly slower rate of ligand dissociation. The presence of Gpp(NH)p was found to increase the affinity of [125I]-angiotensin binding sites in rat renal cortex membranes. This contrasts with the decreases in affinity of [125I]-angiotensin binding reported in adrenal and mesenteric artery membranes.