Characterization of dietary phosphorus-dependent duodenal calcium uptake in vitamin D-deficient chicks.

The effect of dietary phosphorus on intestinal calcium uptake was examined in duodenal cells isolated from vitamin D-deficient chicks. Cells from chicks on a high phosphorus diet accumulated calcium at a rate 38% higher than cells from animals on a normal phosphorus diet. Diet high in calcium did not affect calcium absorption in duodenal cells. The dietary phosphorus effect on calcium absorption was specific. Uptake of alpha-methyl glucose was not altered. Increase in calcium absorption by a high phosphorus diet was not due to a change in cellular energy metabolism nor to the content of phosphorus in cells. Kinetically, a high phosphorus diet increased the Vmax of calcium uptake; the affinity for calcium was unaffected. The effectiveness of dietary phosphorus to enhance the intestinal calcium uptake could also be demonstrated in brush border membrane vesicles. The increase in calcium uptake was not due to an alteration in membrane binding capacity nor to calcium efflux from vesicles. To test the hypothesis that a high phosphorus diet may affect membrane transport by altering phospholipid metabolism in duodenal cells, we examined the phospholipid content in isolated brush border membranes. The content of phosphatidylcholine, phosphatidylserine, phosphatidylinositol and phosphatidylethanolamine was not altered by the high phosphorus diet. These findings suggest that the vitamin D-independent and dietary phosphorus-dependent effect on intestinal calcium absorption was primarily due to a change in the calcium flux at the luminal side of the cells. However, the precise mechanism is still not clear.

Age-associated changes in ammoniagenesis in isolated rat renal tubule segments.

We investigated renal ammoniagenesis in isolated nephron segments from control and acidotic senescent and young adult rats. When young (6 mo) and senescent (24 mo) control groups were compared, there was no significant difference in glutamine-dependent ammonia production in any nephron tubule segments. However, ammonia production rates in glomeruli from old rats were significantly greater than the rate from young rats and were correlated with the serum creatinine and blood urea nitrogen (BUN) levels. After giving young and old rats an equivalent acid load (by gavage) of ammonia chloride solutions (6 mo, blood pH 7.34; 24 mo, blood pH 7.07), we measured a significant increase in ammoniagenesis on the S1 and S2 segments of proximal tubules and the distal convoluted tubules from old rats, and no increase in any segment from young rats. When we increased the acid load in young rats to an equivalent severity of acidosis (blood pH 7.07), we found significant increases in ammonia production in the S1, S2, S3, and distal convoluted tubule. With comparable blood pH values, ammoniagenesis in S1, S2, and S3 segments from young rats was about double the values measured in segments from senescent rats. The severity of the acidosis in the 24-mo-old rats was related to serum creatinine and BUN. Our findings show that ammoniagenesis in isolated segments from senescent rats is qualitatively similar to their younger counterparts but that this maximum capacity to generate ammonia is reduced. The change in nephron capacity to synthesize ammonia may be the result of age-associated physiological changes and/or the chronic renal failure exhibited in old rats.

Regulation of osteocalcin secretion by human primary bone cells and by the human osteosarcoma cell line MG-63.

We present evidence that the regulation of osteocalcin secretion by PTH and PGE2 in normal human bone cells can be produced in the human osteoblast-like cell line MG-63. Both cell cultures showed time- and dose-dependent stimulation of osteocalcin secretion in response to 1,25(OH)2D3. Bovine parathyroid hormone (PTH) amino acid fragment 1-34 (40 nM) and prostaglandin E2 (PGE2, 5 nM) significantly inhibited 1,25(OH)2D3-induced osteocalcin secretion by these cells. The inhibition reached 20 and 36%, respectively. In contrast, PTH 3-34 had no effect on osteocalcin secretion. Both cell cultures produced cAMP in response to PTH. Dexamethasone (Dex) (100 nM) potentiated PTH-induced (40 nM) cAMP synthesis in subconfluent MG-63 cells (1.5-fold increase, P less than 0.05). This treatment with Dex resulted in a greater inhibition of 1,25(OH)2D3-induced osteocalcin secretion (-30%, P less than 0.005) by PTH in MG-63 cells as compared to cells exposed to PTH and 1,25(OH)2D3 alone. Pretreatment of subconfluent MG-63 cells with Dex (100 nM) for 48 h also increased 1,25(OH)2D3-induced osteocalcin secretion by 40% (P less than 0.025). In contrast, treatments of confluent MG-63 cells with Dex inhibited osteocalcin secretion regardless of the 1,25(OH)2D3 doses used. Forskolin (10(-7)-10(-5) M) and dibutyryl cAMP (10(-6)-(10(-3) M) both reproduced the effects observed with PTH and PGE2 in the two cell cultures. Forskolin's action was time-dependent: addition of forskolin (10(-6) M) 12 h after 1,25(OH)2D3 (50 nM) resulted in a progressively weaker inhibition of osteocalcin secretion. Increasing the extracellular calcium concentration of the incubation media resulted in a dose-dependent increase in osteocalcin secretion (P less than 0.01). These results indicate that PTH and PGE2 inhibit osteocalcin secretion by a mechanism involving cAMP production. In contrast, an increase in extracellular calcium stimulated osteocalcin release. Thus the human osteosarcoma cell line MG-63 is a useful osteoblast-like cell model to study the regulation of osteocalcin secretion. Furthermore, a factor (or factors) between hormone-receptor coupling and gene induction can regulate the expression of the osteocalcin gene or affect pre- or posttranslational mechanisms implicated in osteocalcin synthesis and secretion.

Purinergic regulation of cytosolic calcium and phosphoinositide metabolism in rat osteoblast-like osteosarcoma cells.

We have shown that ATP increases cytosolic Ca2+ in UMR-106 cells through P2-purinergic receptor stimulation (Calcif Tissue Int 45:251-254). This response was further characterized using cells loaded with indo-1/AM or prelabeled with [3H]inositol. ATP elicited a rapid transient increase in Ca2+ from 148 to 540 nM, followed by a biphasic decline (first rapid and then slower) to basal within 1 minute and then a late slow rise to 200 nM by 4 minutes. ADP also elicited a rapid transient increase, but this was followed by a second smaller transient and a later, slow increase above basal Ca2+. These transient increases in Ca2+ induced by ATP and ADP were dose dependent, detected at 10(-6)M ATP and 10(-7)M ADP, and saturated at 10(-4)M with both nucleotides. The maximum increase in Ca2+ was 20% greater with ATP than ADP. EGTA chelation of extracellular Ca2+ abolished the biphasicity of the ATP-induced Ca2+ transient, the second ADP-induced transient, and all late slower increases in Ca2+. Desmethoxyverapamil pretreatment attenuated the biphasicity of the ATP-induced transient and the second peak elicited by ADP. Elevated extracellular Ca2+ (5 mM) prevented the return to the basal level that normally follows the ATP-induced Ca2+ transient and amplified the sustained increase in Ca2+ but had little effect on the response to ADP. IP3 and IP4 increased rapidly after addition of ATP, with I(1,4,5)P3 increasing before I(1,3,4)P3. These data indicate that P2-purinergic stimulation of UMR-106 cells causes three consecutive responses in cytosolic Ca2+: (1) a transient increase due to IP3-mediated mobilization of intracellular Ca2+; (2) a transient increase due in part to influx, probably associated with a Ca2+ channel; and (3) a later sustained increase that requires extracellular calcium.

Alterations of duodenal vitamin D-dependent calcium-binding protein content and calcium uptake in brush border membrane vesicles in aged Wistar rats: role of 1,25-dihydroxyvitamin D3.

Previously we reported that uptake of Ca2+ in cells isolated from rat duodenum declined in senescence. In this paper we examined the possible mechanisms for this age-related defect. Duodenal vitamin D-dependent calcium-binding protein decreased steadily from 3-12 months (mo), followed by a minimal decline at 24 mo. On the contrary, Ca2+ uptake was not different in 3-, 6-, and 12-mo-old rats. A significant decline of Ca2+ uptake was observed at 24 mo. ATP contents in duodenal cells from 6- and 24-mo-old rats were not different. This suggests that the metabolic status of the duodenal cells was not the cause of the change in Ca2+ uptake. Ca2+ uptake activity was significantly lower in brush border membrane vesicles isolated from 24-mo-old rats than in those from 6-mo-old rats. The decrease in Ca2+ uptake activity in old rats was not due to a change in the Ca2(+)-binding capacity of the membranes. Kinetic analysis shows that the Vmax, the apparent maximum uptake capacity of membrane vesicles, decreased in senescent rats, whereas the Km, the apparent affinity to Ca2+, was unchanged. Since duodenal Ca2+ influx at the brush border was regulated by 1,25-dihydroxy-vitamin D3 [1,25-(OH)2D3], we tested the effect of 1,25-(OH)2D3 administration on the uptake activity in isolated membrane vesicles. After 1,25-(OH)2D3 treatment, Ca2+ uptake activity in brush border membranes prepared from senescent rats was only slightly lower than that in membranes from adult rats. We conclude that the decline in the influx of Ca2+ at the brush border membrane was the main cause of the decrease in duodenal Ca2+ uptake activity in aging. This defect was probably due to the low serum 1,25-(OH)2D3 concentration and not the result of impaired response to 1,25-(OH)2D3.

Osteocalcin secretion by the human osteosarcoma cell line MG-63.

The human osteosarcoma cell line MG-63 has been used to study the production of the bone-specific protein, osteocalcin. In the absence of any stimuli, MG-63 cells secreted very low levels of osteocalcin. The secretion of osteocalcin started after a lag time of 10-12 h upon 1,25-(OH)2D3 treatment. Osteocalcin secretion was measured at doses as low as 0.03 nM (fourfold increase, p less than 0.05), and this activity increased further with higher doses of 1,25-(OH)2D3 to reach a plateau at 50 nM. The secretion increased transiently from very low levels in sparse cell cultures to peak values in subconfluent cultures (+/- 40%), two- to threefold above values obtained for confluent cells. Values for confluent cells average 55.9 +/- 2.0 ng/ml protein per 48 h. A similar behavior is observed for 1,25-(OH)2D3 receptor concentration under similar experimental conditions. Bmax increased transiently from sparse to subconfluent cell cultures (40-60% confluent) and reached values 50% lower in confluent cells. However, the receptor affinity was not affected by cell density. MG-63 cells also possessed an alkaline phosphatase isoenzyme of the bone-liver-kidney type that was stimulated by 1,25-(OH)2D3 treatment (two- to threefold) and inhibited by parathyroid hormone (40 nM, -25%, p less than 0.025). PTH and PGE2 increased cAMP production in a dose-dependent manner, but the cells were irresponsive to salmon calcitonin. Basal and PTH-responsive cyclic AMP production were also modulated by cell density. Dexamethasone pretreatment (100 nM, 48 h) stimulated the PTH-dependent cAMP production but failed to influence the response to PGE2.(ABSTRACT TRUNCATED AT 250 WORDS)

Downregulation of parathyroid hormone receptors in renal membranes from aged rats.

The mechanism of the inhibition or blunting of parathyroid hormone (PTH)-stimulated Na(+)-Ca2+ exchange activity in renal cortical cells from aged rats was examined. The number of PTH binding sites in basolateral membranes prepared from adult (6 mo) and old (24 mo) rats was quantitated by the binding of the synthetic analogue 125I-labeled [Nle8,18, Tyr34]bPTH-(1-34) amide to the membrane. The maximum number of specific PTH binding sites, Bmax, was 92.7 +/- 9.3 and 36.7 +/- 6.1 fmol/mg protein, respectively, in membranes prepared from adult and old rats. The affinity of the receptor to PTH was unaffected with age. The level of PTH binding components (68 and 70 kDa) estimated by a ligand affinity blot technique using biotinylated bPTH-(1-34) as the ligand was similarly reduced in membranes isolated from senescent rats. To test the hypothesis that change in the number of PTH binding sites and level of PTH binding components represented an adaptive response to a high serum PTH level, rats were parathyroidectomized (PTX) and the changes were reexamined. Decreases in the number of PTH binding sites and PTH binding components were either partially or completely negated by the surgery. These findings suggest that the blunting of both the PTH-stimulated Na(+)-Ca2+ exchange and adenylate cyclase activities in the kidneys of aged rats was due, in part, to be loss of PTH receptors in basolateral membranes and that this defect could be partially reversed by removal of the parathyroid gland.

Effect of age on duodenal 1,25-dihydroxyvitamin D-3 receptors in Wistar rats.

We confirmed our previous observation that duodenal Ca2+ absorption and serum 1,25-dihydroxyvitamin D (1,25-(OH)2D) levels declined concurrently in old (24 months old) rats as compared to young (6 months old) rats. It is well known that 1,25-dihydroxyvitamin D-3 (1,25-(OH)2D3) expresses its action after binding to specific receptor molecules. In this paper, we compared certain properties of rat duodenal 1,25-(OH)2D3 receptors from old and young animals. Receptor preparations were incubated with [3H]1,25-(OH)2D3 to quantitate the number of unoccupied and total receptor sites and showed that total and unoccupied receptor sites decreased by 22 and 16%, respectively in old rats. Endogenously occupied sites were reduced by 43% in duodenum of the old rat and, consequently, the percentage of receptor occupancy also declined. Age did not affect the dissociation constant (KD) of 1,25-(OH)2D3 from the receptor; the sedimentation coefficient (3.3 S) of the tritiated 1,25-(OH)2D3-receptor complex in sucrose density centrifugation; or its affinity for DNA. The data are consistent with the hypothesis that the age-related decline in Ca2+ absorption in the intestine may be due, in part, to the decrement in the circulating level of 1,25-(OH)2D and a reduction of intestinal 1,25-(OH)2D3 receptor occupancy status.

Regulation of renal sodium calcium exchange by PTH: alteration with age.

Parathyroid hormone, when incubated with renal cells acting in vivo and in vitro, increased Na+/Ca2+ exchange activity. The effect of parathyroid hormone was specific for biologically active analogs and could be mimicked by cAMP and forskolin. Parathyroid hormone-sensitive Na+/Ca2+ exchange activity was markedly blunted in cells from senescent rats. Parathyroid hormone-stimulated adenylate cyclase was also decreased in aging. In contrast, forskolin-stimulated Na(+)-dependent Ca2+ efflux and adenylate cyclase did not change with senescence. Decrease of PTH binding sites was observed in cells from old rats. Further, cells from 24-month-old rats had decreased Gs and Gi proteins, as detected by ADP-ribosylation. Since serum iPTH level was elevated in the old rat and could contribute to the desensitization to PTH, we tested this hypothesis by comparing sham-operated and PTX animals. The decreases in PTH-sensitive Na+/Ca2+ exchange activity and adenylate cyclase activity in cells from 24-month-old rats could be completely negated by parathyroidectomy. Decrease in PTH binding sites and contents of Gs and Gi in cells from aged-rats was partially negated by the surgery. In conclusion, our results suggested that the age related blunting in responses of renal cells to PTH was due, at least in part, to the elevated serum iPTH level in old rats.

Stimulation by thyroid hormone of Na+-H+ exchange activity in cultured opossum kidney cells.

Cultured opossum kidney (OK) cells were used to determine whether thyroid hormone has a direct stimulatory effect on Na(+)-H+ exchange activity in an intact cellular preparation. Na+ uptake or intracellular pH recovery was measured in confluent monolayer cells following acid loading with NH4Cl. Triiodo-L-thyronine (T3) had no effect on cell number or protein and DNA contents but stimulated amiloride-sensitive Na+ uptake in a dose- and time-dependent manner. Maximal stimulation of Na+ uptake was observed at 10(-7) M T3 and 10(-6) M L-thyroxine (T4) with half-maximal effects at 10(-9) M T3 and 3 x 10(-8) M T4. The T3 specific binding capacity of OK cells was 96 +/- 15 fmol/mg DNA with a KD of 1.1 +/- 0.2 x 10(-9) M T3. Neither T3 nor T4 had any effect on amiloride-insensitive Na+ uptake. In kinetic studies of Na+ uptake, T3 increased the Vmax from 123 +/- 22 to 157 +/- 24 nmol.mg-1.min-1 without changing the Michaelis-Menten kinetics (Km) for Na+ (21 +/- 1 in control and 22 +/- 4 mM in T3-treated cells). Studies of intracellular pH (pHi) showed that the resting pHi and the buffering capacity were unaffected by T3. However, after an acid load, OK cells treated with T3 exhibited a greater rate of Na(+)-dependent pH recovery than untreated control cells. These results indicate that thyroid hormone can stimulate Na(+)-H+ exchange activity directly in renal cell line without apparent changes in pHi, cellular hypertrophy, or hyperplasia.

Age- and sex-dependent stimulation of calcium uptake in duodenal cells by prolactin in vitamin D-deficient rats.

Administration of ovine-prolactin (O-PRL) stimulated Ca2+ uptake in isolated duodenal cells prepared from vitamin D-deficient rats. The time course of this effect was biphasic: uptake activity reached a peak in 2.5 hrs followed by a decrease at 5 hrs to original levels. This stimulatory effect of O-PRL was observed in vitamin D-deficient male, but not in female rats. This stimulatory effect was observed in 16- and 26-week old, but not 9 week old, animals. Increase in Ca2+ uptake in duodenal cells was not due to a decrease in intracellular Ca2+ efflux. We measured serum Ca concentration in vitamin D-deficient female rats and found that serum Ca increased in D-deficient female rats between 16 and 52 weeks whereas a minimal increase was observed in D-deficient male rats. Although prolactin was shown to stimulate duodenal Ca2+ uptake, it appears that the source of the increase in levels of serum Ca in D-deficient female rats was not derived from an increase in Ca2+ uptake by prolactin in duodenum. The increase in serum calcium with time may explain why female D-deficient rats survive longer then male.

Early effects of subtotal nephrectomy and food restriction on urinary calcium in the rat.

Urinary calcium excretion (UCa) is normal several weeks following subtotal nephrectomy (Nx) in the rat, despite factors such as magnified solute load per nephron which should promote hypercalciuria. To define the levels of UCa during the first few weeks after Nx and to determine if the development of compensatory mechanisms governing renal conservation of calcium are detectable, we measured UCa in Nx and sham Nx rats with matched food intake (10 g/day) from 10 days before through 20 days following Nx. In the sham Nx animals, UCa rose during the first 5 days following surgery from 27 +/- 8 to 66 +/- 5 microM/day and then plateaued for the remaining time. In Nx rats, UCa also rose during the first 5 postoperative days from 23 +/- 5 to 110 +/- 10 microM/day (Nx vs. sham Nx, p less than 0.05), but then fell over the next 3 days to levels observed simultaneously in sham Nx animals. The rise in UCa after Nx, but not after sham Nx, was associated with a doubling of urine flow rate and increased urinary titratable acid excretion. In parathyroidectomized rats, UCa also rose following Nx; however, maximum UCa was then sustained for at least 4 days. In an additional sham Nx group fed 20 g/day, no increase in UCa occurred following surgery. Thus, hypercalciuria is present following Nx in the rat, in part possibly attributable to increased acid excretion. The transient nature of calciuria reflects an adaptive phenomenon, most likely hyperparathyroidism. Diminished food intake following surgery independently contributes to hypercalciuria, regardless of the status of renal mass.

Neurotransmitter regulation of cytosolic calcium in osteoblast-like bone cells.

The nervous system may play a role in regulation of bone metabolism. The effects of norepinephrine(NE), vasoactive intestinal peptide(VIP), and ATP on cytosolic Ca2+ were assessed in a rat osteoblast-like osteosarcoma cell line (UMR-106) responsive to PTH. All three transmitters transiently increased Ca2+, with ATP much greater than PTH greater than NE = VIP, and then caused sustained increases in Ca2+. The ATP-induced transient resulted from mobilization of intracellular Ca2+ store, while NE and VIP-induced transients also involved influx of Ca2+. Later sustained increases by all agonists were dependent upon extracellular Ca2+. Release of intracellular Ca2+ by ATP was associated with a marked increase in IP3 but without a significant change in cAMP. NE, VIP, and ATP, through regulation of Ca2+ metabolism, may be involved in various osteoporotic conditions.

Transient state kinetic evidence for an oligomer in the mechanism of Na+-H+ exchange.

Pre-steady-state kinetic measurements of 22Na+ uptake by the amiloride-sensitive Na+-H+ exchanger in renal brush border membrane vesicles (BBMV) were performed at 0 degrees C to characterize the intermediate reactions of the exchange cycle. At 1 mM Na+, the initial time course of Na+ uptake was resolved into three separate components: (i) a lag phase, (ii) an exponential or "burst" phase, and (iii) a constant velocity or steady-state phase. Pulse-chase experiments using partially loaded BBMV showed no evidence for 22Na+ back-flux, suggesting that the decline in the rate of Na+ uptake rate following the burst represents completion of the first turnover of the exchanger. Gramicidin completely abolished Na+ uptake, indicating that the burst phase results from the translocation of Na+ rather than from residual Na+ binding to external sites. Raising the [Na+] from 1 to 10 mM at constant pH (internal pH 5.7; external pH 7.7) produced a sigmoidal increase in the amplitude of the burst phase without affecting the lag duration or the apparent burst rate. In contrast, Na+ uptake in the steady state obeyed Michaelis-Menten kinetics. These results suggest that a minimum of two Na+ transport sites must be occupied to activate Na+ uptake in the pre-steady state. The transition to Michaelis-Menten kinetics in the steady state can be explained by a "flip-flop" or alternating site mechanism in which the functional transport unit is an oligomer and only one promoter per cycle is allowed to form a translocation complex with Na+ after the first turnover.

Effect of age on calcium uptake in isolated duodenum cells: role of 1,25-dihydroxyvitamin D3.

Uptake of Ca2+ in cells isolated from rat duodenum declined in the senescent rats. This age-related change was not due to an alteration in the rate of Ca2+ efflux or in the size of the cell. The decrease appeared specific, as alpha-methyl glucoside uptake was not altered. Cell population, as monitored by sucrase activity for villus cells, was not different between duodenal cells isolated from 6- and 24-month-old rats. Kinetic analysis shows the Vmax, the apparent maximum uptake capacity, decreased in the cells from senescent rats whereas the Km, the apparent affinity to Ca2+, was unchanged. Serum levels of 25-hydroxyvitamin D (25OHD) and 1,25-dihydroxyvitamin D [1,25-(OH)2D] were determined as a function of age; the levels of 25OHD were not significantly different in 3-, 6-, 12-, and 24-month-old rats. On the other hand, serum 1,25-(OH)2D decreased throughout the age range studied. Since duodenal Ca2+ uptake is closely regulated by 1,25-(OH)2D3, we tested the hypothesis that low serum 1,25-(OH)2D in the senescent rats may have contributed to the decline in duodenal Ca2+ uptake. In vivo administration of 1,25-(OH)2D3 to senescent rats significantly enhanced Ca2+ uptake activity in the isolated duodenal cells. After 1,25-(OH)2D3 treatment, Ca2+ uptake activity in cells isolated from senescent rats was only slightly less than that in cells from adult rats. We conclude that duodenal Ca2+ uptake declined in the senescent rats, and this age-related change was most likely due to the low serum level of 1,25-(OH)2D and not the result of a decrease in any duodenal response to 1,25-(OH)2D3.

Desensitization to parathyroid hormone in renal cells from aged rats is associated with alterations in G-protein activity.

Parathyroid hormone (PTH)-stimulated Na+/Ca2+ exchange activity, but not forskolin-sensitive Na+-dependent Ca2+ efflux, was blunted in renal cortical cells from aged rats. PTH-sensitive adenylate cyclase activity in renal membranes from senescent rats also declined, but forskolin-stimulated activity did not change. In addition, cholera toxin- and pertussis toxin-stimulated Na+-dependent Ca2+ efflux and cAMP formation were blunted in cells from aged animals. Further, cells from aged rats had decreased Gs-alpha and Gi-alpha proteins, as detected by ADP-ribosylation. These findings would be consistent with the proposal of an age-associated heterologous desensitization that involved the G-proteins. Serum concentrations of iPTH were increased in the old rat, suggesting that the desensitization to PTH in the aging rat represented an adaptive response to prolonged stimulation by the hormone. This hypothesis was supported by the findings that the attenuated PTH-sensitive Na+/Ca2+ exchange activity, cAMP formation, and adenylate cyclase activity in cells from old rats could be reversed by parathyroidectomy. The decreased label in cholera toxin-catalyzed ADP-ribosylated Gs-alpha and pertussis toxin catalyzed ADP-ribosylated Gi-alpha found in cells from aged rats was also largely negated by the surgery. In conclusion, the results suggest that the age-related blunting in the responses of renal cells to PTH was associated with a deficit in G-protein function and that this alteration could be reversed by removal of the parathyroid gland.

Renal adaptation to metabolic acidosis in senescent rats.

In this study, we compared results obtained in senescent rats with young rats given an equivalent acid load. We examined the renal changes by giving equivalent acid loads for 48 h to both 6- and 24-mo-old rats. The basal excretion of ammonium was the same in both groups, whereas titratable acids, phosphate, and Ca2+ excretions were increased in the senescent animal. After administration of the acid load, ammonium, phosphate, Ca2+, and titratable acid excretions increased in both age groups, but there were greater absolute increases in ammonium and titratable acid excretions in the young rats. The total acid excreted by the 24-mo rats was reduced 50 (day 1) and 25% (day 2) compared with the young rats, which was reflected by the more severe acidosis in those animals. The portion of total acid excreted as titratable acids in senescent animals was also increased during acidosis when compared with the young animals. In isolated proximal tubule brush-border membrane vesicles, acidosis increased Na+-H+ exchange and decreased Na+-dependent phosphate transport in both age groups. We also found that the basal activity of the Na+-H+ exchanger was not changed with age but the Na+-dependent phosphate transporter was less in the 24-mo rat. The results suggest that physiological regulation of these renal processes remains intact in the aged rat but the responses may be reduced or delayed in the senescent animal.

Stimulation by thyroid hormone of phosphate transport in primary cultured renal cells.

The regulation by thyroid hormone of phosphate transport in primary cultured chick renal cells was examined. The more physiologically active L-analogs of triiodothyronine and thyroxine, but not the D-analogs of the hormones, stimulated the Na+-dependent phosphate uptake system. Na+-independent phosphate uptake and Na+-dependent uptakes of alpha-methylglucoside and L-proline were unaffected. The increase in Na+-dependent phosphate uptake was concentration dependent, exhibited an induction period, and was blocked by inhibitors of RNA and protein synthesis. The stimulation of phosphate uptake by triiodothyronine was due to an increased Vmax rather than to an altered affinity for phosphate. These findings demonstrate that thyroid hormone acts directly on renal cells to modulate phosphate transport and suggest that the renal cell system may serve as a model to examine the mechanism by which thyroid hormone controls gene expression and regulates plasma membrane transport function.