The time for reflection: a luxury of the past.

We have examined the in vitro effect of glucocorticoid and nonglucocorticoid steroids on the transport of [3-(14)C]alpha aminoisobutyric acid (AIB) in lymphocytes from patients with chronic lymphocytic leukemia (CLL), and myeloblasts from patients with acute granulocytic leukemia (AGL). AIB uptake by CLL lymphocytes was markedly inhibited at 1.0 muM (52+/-2.1%) and slightly inhibited at 0.1 muM (17+/-3.0%) cortisol. A similar degree of inhibition developed at 50-fold lower concentrations of dexamethasone, indicating that the effect of these steroids on AIB accumulation parallels their glucocorticoid activity in vivo. In contrast, minimal or no inhibition was observed with steroids devoid of glucocorticoid activity (progesterone, testosterone, cortisone). 11-deoxycortisol, a nonglucocorticoid known to impede the binding of cortisol to cellular receptors in animal lymphocytes, failed to inhibit AIB uptake by CLL lymphocytes appreciably, but reduced the effect of cortisol to a statistically significant degree. Hence, cortisol-induced inhibition of AIB transport in CLL lymphocytes is related to its glucocorticoid activity and appears to require initial interaction with glucocorticoid-specific cellular receptors. In contrast, 1.0 muM cortisol enhanced the accumulation of AIB in AGL myeloblasts from each of five patients studied (mean = 19%, range 7-43%). Neither cortisone nor 11-deoxycortisol stimulated AIB uptake, and cortisol-mediated stimulation was not seen during simultaneous treatment with 11-deoxycortisol, suggesting that this effect of cortisol also represents a specific glucocorticoid effect. The divergent effects of cortisol on amino acid transport in CLL lymphocytes and AGL myeloblasts may explain, in part, the contrasting clinical effects of glucocorticoids administered to patients with these lymphoid and granulocytic hematopoietic malignancies.

Inhibition of transepithelial sodium transport in the frog skin by a low molecular weight fraction of uremic serum.

An inhibitor of transepithelial sodium transport was found in a low molecular weight fraction obtained from serum of patients with far advanced chronic renal disease. In 18 nondialyzed patients, the mean inhibition of short circuit current (SCC) was 24.9 +/-2.2% (SE). With a comparable fraction from 11 normal subjects. SCC decreased by only 5.3 +/-1.5%. There was significantly greater inhibition with the serum fractions of patients with end stage renal disease being maintained on chronic hemodialysis than in the normal control group; but the degree of inhibition in the dialyzed population was significantly less than that observed in the nondialyzed chronically uremic patients. The inhibition of SCC produced by the serum fractions of a group of seven patients with acute renal failure was not significantly different from the control group despite the presence of high grade uremia in the former. The inhibitory fraction has characteristics identical with the uremic serum fraction which previously has been shown to inhibit p-aminohippurate (PAH) uptake by rabbit kidney cortical slices. With gel filtration through Sephadex G-25, the active fraction appears after the major peaks of substances as small as urea and sodium; hence it may have been retarded on the column. But its ultrafiltration characteristics suggest that its molecular weight may be less than 1000. The inhibitory capability was not destroyed by boiling, freezing, or digestion with chymotrypsin or pronase. Neither methylguanidine nor guanidinosuccinic acid in concentrations well above those present in the serum of uremic patients inhibited sodium transport in the frog skin. The data suggest that there is an inhibitor of sodium transport in the serum of patients with chronic uremia. The role of this material in the regulation of sodium excretion in uremia as well as its possible role as a uremic toxin are subjects of both theoretical and practical interest.

On the influence of extracellular fluid volume expansion and of uremia on bicarbonate reabsorption in man.

The patterns of bicarbonate reabsorption during increasing plasma concentrations were studied in subjects with a range of glomerular filtration rates (GFR) from 170 to 2 ml/min. In a group of five subjects with GFR values above 30 ml/min, paired bicarbonate titration studies were performed first under conditions which minimized extracellular fluid (ECF) volume expansion, and second under conditions which were conducive to exaggerated expansion of ECF volume. In patients with GFR values below 30 ml/min, a single protocol was employed. Studies also were performed on two patients with far advanced renal disease who were nephrotic and exhibited a sodium-retaining state. When ECF volume expansion was minimized in the nonuremic subjects, values for bicarbonate reabsorption were well in excess of the usually accepted Tm level and over the range of plasma bicarbonate concentrations employed, no evidence of a Tm phenomenon was observed. A similar pattern emerged in the two nephrotic patients despite the presence of uremia. However, with both exaggerated expansion of ECF volume (GFR greater than 30) and in patients with advanced renal disease in the absence of exaggerated ECF volume expansion a tendency towards saturation kinetics for bicarbonate reabsorption was demonstrable. In comparing the minimized with the exaggerated expansion studies, evidence emerged for a decrease in both bicarbonate reabsorption per unit of GFR and the absolute rate of bicarbonate reabsorption. When ECF volume expansion was exaggerated in uremic patients after stable rates of bicarbonate reabsorption had been achieved, a decrease in reabsorption per unit of GFR and in absolute bicarbonate reabsorption occurred. The possible relationship of the factors controlling sodium excretion to the observed patterns of bicarbonate reabsorption is considered in the text.

Studies on the control of sodium excretion in experimental uremia.

A study of the mechanisms governing the high rate of sodium excretion per nephron characteristic of patients with chronic renal disease has been made in dogs. A "remnant kidney" was produced by 85% infarction of the left kidney while the right kidney was left intact. A bladder-splitting procedure allowed simultaneous measurement of glomerular filtration rate and the rate of sodium excretion by each kidney. The animals were fed a constant known amount of sodium chloride and 0.1 mg of 9 alpha-fluorohydrocortisone twice daily throughout the study. In a group of dogs fed 3 or 5 g of salt per day, sodium excretion by the remnant kidney averaged 6.5 muEq/min while the intact kidney was present and 53.7 muEq/min when the animals became uremic after the intact kidney was removed. The increased sodium excretion per nephron by the remnant organ often occurred within 18 hr after contralateral nephrectomy and persisted despite experimentally induced acute reductions in the glomerular filtration rate to below prenephrectomy levels. A second group of animals studied in the same manner but receiving 1 g of salt per day or less failed to develop a natriuresis after contralateral nephrectomy despite high grade uremia. Thus an increased impermeable solute load per nephron was not a regulatory factor in the production of the natriuresis. The increased rate of sodium excretion per nephron in uremia resembles that after saline loading in that it may occur without an increase in glomerular filtration rate or a reduction in mineralocorticoid stimulation. It follows that an additional factor or factors must be involved in the genesis of the natriuresis. In contrast to the natriuresis that is seen in normal animals subjected to saline loading, these uremic animals were found not to have a detectable increase in extracellular fluid volume or blood volume in the presence of high fractional sodium excretion rates. Sodium excretion in response to a small salt load by the remnant organ in uremia was 30% greater than the response of both kidneys in the preuremic state despite a markedly reduced total GFR. These data are consistent with the view that the volume control mechanism becomes more responsive in uremia.

The influence of saline loading on renal glucose reabsorption in the rat.

Glucose titration studies were performed in normal rats under control conditions and during expansion of the extracellular fluid volume. In association with expansion, the maximal rate of glucose transport (Tm(glucose)) decreased while glomerular filtration rate (GFR) typically increased; thus there was a consistent increase in the GFR/Tm(glucose) ratio. In previous studies, marked reduction of the nephron population was associated with an alteration in the kinetics of glucose transport and GFR/Tm(glucose) ratios were observed to increase. In both volume-expanded rats and in animals and human beings with uremia, the splay in the titration curve is increased. Finally in both volume-expanded animals and uremic animals fractional reabsorption of sodium is depressed. One interpretation of the present data is that the natriuretic "third factor" may influence a key rate-limiting step in glucose transport; and it is possible that this step is shared by or coupled to a rate-limiting step in sodium transport.

On the mechanism of the splay in the glucose titration curve in advanced experimental renal disease in the rat.

Glucose titration studies were performed in rats with unilateral chronic pyelonephritis before and after removal of the contralateral control kidneys. Identical studies were performed in animals with unilateral partial renal infarction in which the experimental kidneys had a marked reduction in nephron population but no anatomic deformation in the surviving nephrons. In the initial studies, both groups of animals were free of clinical and chemical abnormalities of uremia. In the follow-up studies uremic abnormalities were present. Minimal splay was observed in the titration curves in the initial studies; marked splay was present in the group data from the same kidneys in the subsequent studies. Thus a marked reduction in the nephron population was associated with the evolution of splay in both groups of animals. In association with the increase in splay, the mean values for maximal glucose transport increased; thus a defect in glucose transport can be excluded as the basis of the splay. Glomerular filtration rate increased proportionately more than the maximal transport of glucose; hence the ratios of glomerular filtration rate to maximal glucose transport increased consistently. The possibility of asymmetric hypertrophy of glomerular and tubular functions among the nephron population imposed by scar tissue or other anatomic deformities was considered, but the results in the animals with partially infarcted kidneys militate against this explanation. The splay also could reflect an asymmetric alteration in the distribution of glomerulotubular balance among the residual units initiated by functional adaptations. Finally, the splay could relate to an alteration in the kinetics of glucose transport without any change in the level of functional homogeneity. The possible nature of these has been considered in the text.

On the adaptation in sodium excretion in chronic uremia. The effects of "proportional reduction" of sodium intake.

Renal mass and glomerular filtration rate (GFR) were reduced from normal to approximately 15% of normal in two groups of dogs. One group received a constant salt intake (CSI) throughout the study. The second group was subjected to "proportional reduction" of sodium intake (PRS), a dietary regimen which involved the reduction of sodium intake in exact proportion to the decrement in GFR. In the CSI group, absolute sodium excretion rate (U(Na)V) remained essentially unchanged as GFR fell, while fractional sodium excretion (FE(Na)) increased progressively from a mean control value of 0.3% to a final value of 4.4%. In the PRS group, U(Na)V decreased with each reduction in GFR and salt intake, and FE(Na) remained constant throughout. In a second study, the fraction of serum that previously has been shown to possess natriuretic activity in studies of uremic patients was obtained from a group of uremic dogs on the CSI and from another group on the PRS regimen, and the effects of the fraction was measured on sodium excretion in rats. The serum fractions from the dogs on the CSI regimen produced a significant increase in both U(Na)V and FE(Na) in the assay rats. The same serum fraction from the dogs on the PRS regimen failed to produce a significant increase in either U(Na)V or FE(Na). The data are consistent with the view that (a) The increase in FE(Na) in chronically uremic dogs is dictated by the requirements for external sodium balance and may be prevented by prospective manipulation of salt intake: (b) a natriuretic factor, previously shown to exist in the serum of patients with chronic uremia, is also demonstrable in the serum of uremic dogs; and (c) with the present bioassay system, the factor is not detectable in the serum fraction of uremic dogs in which the requirements for an increased natriuresis per nephron have been obviated.

On the influence of the natriuretic factor from patients with chronic uremia on the bioelectric properties and sodium transport of the isolated mammalian collecting tubule.

A gel filtration fraction of urine from patients with chronic renal disease (natriuretic factor) has been shown previously to cause natriuresis in rats and to inhibit sodium transport in the isolated toad bladder. The effect of this fraction on transtubular potential difference and sodium transport was examined on the isolated perfused cortical collecting tubule of the rabbit. A rapid inhibition of potential difference from -22.5 mV to -12 mV (P less than 0.001) was observed when the fraction was applied to the peritubular surface. This effect was accompanied by a decrease in net sodium flux from 6.29 to 3.21 pmol/cm per s (P less than 0.001). Unidirectional fluxes using isotopic sodium revealed that the inhibition of net sodium transport was due to a decrease in flux from the lumen to the peritubular surface, i.e., an inhibition of active sodium transport. There was no change in sodium flux in the reverse direction. These changes were all rapidly reversed by removal of the fraction from the peritubular surface. The addition of the fraction to the lumen had no effect on potential difference or net sodium flux. Control studies using the same fraction from the urine of normal subjects had no effect on any of the parameters studies. Where both a uremic and a normal fraction were sequentially applied to the peritubular surface of the same tubule, inhibition of potential difference was obtained only with the former. In the light of evidence implicating the collecting duct fraction from normal animals, the data are consistent with the view that the natriuretic factor may be biologically important in the regulation of sodium balance via it's regulatory role in active sodium transport in the collecting tubule.

A natriuretic factor in the serum of patients with chronic uremia.

Sera from chronically uremic and normal individuals were subjected to gel filtration with Sephadex G-25 and the same fraction of both was infused into rats with a decreased nephron population to determine the effects on sodium excretion. Sodium excretion rate and fractional sodium excretion increased slightly with the normal fractions; but the increase in both functional parameters produced by the uremic fractions was substantially and significantly greater. The natriuresis could not be explained by associated changes in glomerular filtration rate (GFR), para-aminohippurate (PAH) clearance, filtration fraction, hematocrit, or blood pressure. The possibility thus exists that the inhibitor affected some component part of the transepithelial sodium transport system. The elution characteristics of the fraction plus certain of its physicochemical properties suggest that the inhibitor of sodium reabsorption by the rat nephron may be identical with the inhibitor of PAH uptake by kidney slices and the inhibitor of transepithelial sodium transport by the frog skin and toad bladder previously found in the serum of chronically uremic patients.

The effects of the natriuretic factor from uremic urine on sodium transport, water and electrolyte content, and pyruvate oxidation by the isolated toad bladder.

The urine of patients with chronic uremia contains a gel filtration fraction that is natriuretic in the rat. The effects of this fraction on the isolated urinary bladder of the toad were examined in the present studies. When added to the serosal surface of the bladder, a significant and substantial fall in short-circuit current and potential difference was observed. The changes began after a lag period of at least 10 min and continued over a period of 60 min. The decrease in short-circuit current at the end of 1 h averaged 44%. The same fraction from the urine of normal subjects produced no significant change in either short-circuit current or potential difference. When the isolated epithelial cells from the toad bladder were incubated in the presence of the inhibitor, intracellular sodium content increased significantly. There was no change in intracellular water content; hence the intracellular concentration of sodium increased by a mean of 7 meq/liter. The changes in intracellular potassium content and concentration were not satistically significant. When the isolated epithelia were incubated with the uremic factor, there was also a significant decrease in pyruvate utilization in relation to cells from paired hemibladders incubated in the absence of the fraction. The fraction from normal subjects produced no change in either intracellular sodium content or pyruvate oxidation. The results suggest that the inhibitor acts from the serosal surface, inhibits sodium transport across the serosal barrier, and produces a decrease in substrate utilization in association with the change in transepithelial sodium transport.

Functional profile of the isolated uremic nephron. Impaired water permeability and adenylate cyclase responsiveness of the cortical collecting tubule to vasopressin.

Resistance of the chronically diseased kidney to vasopressin has been proposed as a possible explanation for the urinary concentrating defect of uremia. The present studies examined the water permeability and adenylate cyclase responsiveness of isolated cortical collecting tubules (CCT) from remnant kidneys of uremic rabbits to vasopressin. In the absence of vasopressin the CCTs of both normal and uremic rabbits were impermeable to water. At the same osmotic gradient, addition of a supramaximal concentration of vasopressin to the peritubular bathing medium led to a significantly lower net water flux per unit length (and per unit luminal surface area) in uremic CCTs than in normal CCTs. Transepithelial osmotic water permeability coefficient, P(f), was 0.0232 +/-0.0043 cm/s in normal CCTs and 0.0059+/-0.001 cm/s in uremic CCTs (P < 0.001). The impaired vasopressin responsiveness of the uremic CCTs was observed whether normal or uremic serum was present in the bath. Basal adenylate cyclase activity per microgram protein was comparable in normal and uremic CCTs. Stimulation by NaF led to equivalent levels of activity in both, whereas vasopressin-stimulated activity was 50% lower in the uremic than in the normal CCTs (P < 0.025). The cyclic AMP analogue, 8-bromo cyclic AMP, produced an increase in the P(f) of normal CCTs closely comparable to that observed with vasopressin. In contrast, the P(f) of uremic CCTs was only minimally increased by this analogue and was not further stimulated by theophylline. These studies demonstrate an impaired responsiveness of the uremic CCT to vasopressin. This functional defect appears to be a result, at least in part, of a blunted responsiveness of adenylate cyclase to vasopressin. The data further suggest that an additional defect in the cellular response to vasopressin may exist, involving a step (or steps) subsequent to the formation of cyclic AMP.A unifying concept of the urinary concentrating defect of uremia is proposed which incorporates a number of hitherto unexplained observations on the concentrating and diluting functions of the diseased kidney.

Functional profile of the isolated uremic nephron. Role of compensatory hypertrophy in the control of fluid reabsorption by the proximal straight tubule.

An in vitro approach to the study of single nephron function in uremia has been employed in evaluating the control of fluid reabsorption by the renal superficial proximal straight tubule (PST). Isolated segments of PSTs from the remnant kidneys of uremic rabbits (stage III) were perfused in vitro and their rate of fluid reabsorption compared with normal PSTs and with PSTs derived from the remnant kidneys of nonuremic rabbits (stage II). All segments were exposed to a peritubular bathing medium of both normal and uremic rabbit serum thereby permitting a differentiation to be made between adaptations in function which are intrinsic to the tubular epithelium and those which are dependent upon a uremic milieu.Compared with normal and stage II PSTs, there was significant hypertrophy of the stage III tubules as evidenced by an increase in length and internal diameter, and a twofold increase in the dry weight per unit length. Fluid reabsorption per unit length of tubule was 70% greater in stage III than in normal and stage II PSTs, and was closely correlated with the increase in dry weight. Substitutions between normal and uremic rabbit serum in the peritubular bathing medium did not affect fluid reabsorption significantly in any of the three groups of PSTs. Perfusion of the tubules with an ultrafiltrate of normal vs. uremic serum likewise failed to influence the rate of net fluid reabsorption. It has previously been observed that net fluid secretion may occur in nonperfused or stop-flow perfused normal rabbit PSTs exposed to human uremic serum. Additional studies were thus performed on normal and stage III PSTs to evaluate whether net secretion occurs in the presence of rabbit uremic serum. No evidence for net secretion was found. These studies demonstrate that fluid reabsorption is greatly increased in the superficial PST of the uremic remnant kidney and that this functional adaptation is closely correlated with compensatory hypertrophy of the segment. Humoral factors in the peritubular environment do not appear to be important mediators of the enhanced fluid reabsorption.

On the influence of extracellular fluid volume expansion on bicarbonate reabsorption in the rat.

Bicarbonate reabsorption is classically regarded as a rate-limited process characterized by saturation kinetics. The tubular maximum (Tm), however, varies with glomerular filtration rate. Thus bicarbonate reabsorption, in common with sodium reabsorption, is characterized by glomerulo-tubular balance. The examination of bicarbonate reabsorption is accomplished using the bicarbonate titration technique; however, this method in its traditional form leads to marked expansion of extracellular fluid (ECF) volume. The possibility exists, therefore, that glomerulo-tubular balance for bicarbonate is altered by the volume expansion and thus that the classic pattern of reabsorption may actually reflect inhibited bicarbonate reabsorptive capacity. The present studies were performed in rats to examine this possibility. Bicarbonate titration studies were performed in two groups of animals: (a) those in which ECF volume expansion was minimized; and (b) those in which ECF volume expansion was exaggerated. In the first group, no Tm for bicarbonate was observed either in the majority of individual rats studied or in a group plot for all rats studied despite the fact that plasma bicarbonate concentrations were increased to values in excess of 60 mEq/liter. In the second group, a clear Tm was demonstrated both in individual animals and in group data and there was a lowered threshold for the excretion of bicarbonate. The data thus lend support to the view that the "normal" Tm for bicarbonate may actually represent an inhibited level of bicarbonate reabsorption induced by ECF volume expansion.

Glucose titration studies in patients with chronic progressive renal disease.

Glucose titration studies were performed on 17 patients with either chronic pyelonephritis or chronic glomerulonephritis. Glomerular filtration rates for the group ranged from 4.3 to 58.1 ml per minute. In none of the patients in whom the glomerular filtration rate was over 15 ml per minute was there appreciable splay, and the mean titration curve for these patients resembled that obtained by Smith and associates in normal man (1). In half of this group of eight patients, GFR ranged from 16.6 to 22.7 ml per minute; in the other half values ranged from 42.3 to 58.1 ml per minute. Yet, the mean titration curves were identical for the two groups. In addition, no difference was observed in the titration curves for patients with pyelonephritis and those with glomerulonephritis. In patients with GFR values below 15 ml per minute, increased splay was observed, and below a GFR of 10 ml per minute, the splay was very marked. Both the absence of exaggerated splay in patients with reduction of glomerular filtration rate by as much as 85%, and the emergence of exaggerated splay in patients with more marked reduction of GFR, require explanation. Theoretical considerations are presented in the text.

Studies on the characteristics of the control system governing sodium excretion in uremic man.

Sodium excretion was studied in a group of patients with chronic renal disease, (a) on constant salt intakes of varying amounts with and without mineralocorticoid hormone administration and, (b) after acute extracellular fluid volume expansion. The lower the steady-state glomerular filtration rate (GFR), the greater was the fraction of filtered sodium excreted on both a 3.5 and 7.0 g salt diet; and the lower the GFR, the greater was the change in fractional excretion in the transition from the 3.5 to the 7.0 g salt diet. This regulatory capacity did not appear to be influenced by mineralocorticoid hormone administration. After acute expansion of extracellular fluid (ECF) volume, the increment in sodium excretion exceeded the concomitant increment in filtered sodium in six of nine studies and in the remaining three studies, the increment in excretion averaged 59% of the Delta filtered load (i.e., only 41% of the increase in filtered sodium was reabsorbed). During saline loading, the decrease in fractional reabsorption of sodium tended to vary inversely with the steady-state GFR, although all patients received approximately the same loading volume. When an edema-forming stimulus was applied during saline infusion, the natriuretic response was aborted and the lag time was relatively short. When GFR and the filtered load of sodium were increased without volume expansion, the Delta sodium excretion averaged only 19% of the Delta filtered load; moreover, changes in fractional sodium reabsorption were considerably smaller than those observed during saline loading. The data implicate the presence of a factor other than GFR and mineralocorticoid changes in the modulation of sodium excretion in uremic man.

Control of phosphate excretion in uremic man.

The present studies were performed in an effort to examine the characteristics of the control system governing phosphate excretion in uremic man. In a group of patients with glomerular filtration rates (GFR) ranging from normal to 2 ml/min, it was found that the lower the GFR the lower the fraction of filtered phosphate reabsorbed (TRP). On a fixed phosphate intake, phosphate excretion rate was the same in patients with GFRs ranging from 60 to 3 ml/min. When plasma phosphate concentrations were diminished to subnormal levels in hyperphosphatemic, hypocalcemic uremic patients, TRP values increased but did not return to normal. TRP failed to rise substantially when GFR, as well as plasma phosphate concentrations, were diminished. In patients with unilateral renal disease, TRP values were equal bilaterally, and values were substantially higher in the diseased kidneys than in patients with bilateral involvement. When plasma calcium concentrations were raised to normal for 2-3 wk in uremic patients in whom plasma phosphate concentrations had previously been lowered to subnormal levels, TRP values rose to an average value of 86%. Values remained in the normal range when phosphate concentrations were allowed to increase while normocalcemia was maintained. The data are interpreted to indicate that in advancing renal disease, the changing patterns of phosphate excretion are mediated by a control system in which parathyroid hormone serves as a major effector element. An increase in GFR per nephron, hyperphosphatemia, and intrinsic inability of the surviving nephrons to transport phosphate do not appear to be of primary importance in the progressive reduction in TRP.

The presence of a natriuretic factor in urine of patients with chronic uremia. The absence of the factor in nephrotic uremic patients.

A gel filtration fraction of serum from chronically uremic patients has been shown previously to produce natriuresis in the rat. In the present studies, the same fraction from urine of uremic patients and normal subjects was studied for its natriuretic activity. Urine samples were obtained from 17 chronically uremic patients (mean glomerular filtration rate [GFR], 8.7 ml/min; mean fractional sodium excretion [FE(Na)], 5.7%), and 14 normal subjects. The fraction from the uremic patients produced a significant increase in absolute sodium excretion (U(Na)V) and FE(Na); the fraction from normal subjects had no statistically significant effect on either U(Na)V or FE(Na); and the difference between the response to the uremic vs. normal fractions was highly significant for both parameters of sodium excretion. When a more concentrated urine fraction from uremic patients was administered, a striking natriuresis was observed with values for FE(Na) rising to levels as high as 12%. Studies also were performed on eight patients with far advanced chronic renal insufficiency and the nephrotic syndrome. The serum fraction was studied in each of these patients and the urine fraction in three. For the group, U(Na)V in the assay rats decreased by 0.87 mueq/min and FE(Na) decreased by 1.35% after infusion of the serum fraction. These results differ significantly from those of patients with chronic uremia without the nephrotic syndrome. The data are consistent with the view that the increased activity of the natriuretic factor in the serum of chronically uremic patients is not due to failure of excretion; rather it relates either to an increased rate of production and/or a decreased rate of degradation. The data also show that the inhibitor is detectable when FE(Na) is increased, but not when uremia is associated with a sodium-retaining state.

An inhibitor of sodium transport in the urine of dogs with normal renal function.

The urine and serum of chronically uremic patients and dogs contain an inhibitor of sodium transport that reduces short-circuit current (SCC) in the toad bladder and produces natriuresis in the rat. The present studies represent an effort to determine whether the same inhibitor is detectable in urine of normal dogs maintained on a dosium intake varying from 3 to 258 meq/day. Observations were made with and without fludrocortisone. The same Sephadex G-25 gel filtration fraction previously shown to contain the "uremic" inhibitor was tested in both the isolated toad bladder and rat bioassay systems. The fraction from dogs maintained on 258 meq qodium plus 0.2 mg fludrocortisone/day consistently inhibited SCC in the toad bladder and induced a natriuresis in the rat (P less than 0.001). The fraction from dogs on the same sodium intake without fludrocortisone was also natriuretic (P less than 0.01) but did not inhibit SCC significantly. In contrast, the fraction from dogs fed 3 meq sodium with fludrocortisone or 91 meq sodium without fludrocortisone had no significant effect in either assay system. Thus, an inhibitor of sodium transport has been found in the urine of nonuremic dogs. Both the degree of natriuresis in the rat and the degree of inhibition of SCC in the toad bladder correlated with the state of sodium balance which ensued in the dog.

A study of the intrarenal recycling of urea in the rat with chronic experimental pyelonephritis.

The concentrating ability of the kidney was studied by clearance and micropuncture techniques and tissue slice analyses in normal rats with two intact kidneys (intact controls), normal rats with a solitary kidney (uninephrectomized controls), and uremic rats with a single pyelonephritic kidney. Urinary osmolality after water deprivation for 24 h and administration of antidiuretic hormone was 2,501+/-217 and 2,874+/-392 mosmol/kg H2O in intact and uninephrectomized control rats, respectively, and 929+/-130 mosmol/kg H2O in pyelonephritic rats (P less than 0.001 compared to each control group). Fractional water reabsorption and concentrating ability were significantly decreased in the pyelonephritic group, and, to achieve an equivalent fractional excretion of urea, a greater fractional excretion of water was required in the pyelonephritic rats than in the control rats. Whole animal glomerular filtration rate was 1.57+/-0.19 ml/min and 1.39+/-0.18 ml/min in intact and in uninephrectomized controls, respectively, and 0.30+/-0.07 ml/min in pyelonephritic rats (P less than 0.001 compared to each control group). Single nephron glomerular filtration rate was 35.6+/-3.8 nl/min in intact control rats and was significantly increased (P less than 0.05) in both uninephrectomized (88.0+/-10.8 nl/min) and pyelonephritic rats (71.5+/-14.4 nl/min). In all groups fractional water delivery and fractional sodium delivery were closely comparable at the end of the proximal convoluted tubule and at the beginning of the distal convoluted tubule. In contrast, fractional urea delivery out of the proximal tubule was greater in the intact control group (73+/-8%) than in either the uninephrectomized (52+/-2%) or the pyelonephritic group (53+/-3%) (P less than 0.005). Fractional urea delivery at the early part of the distal tubule increased significantly to 137+/-11% and 93+/-6% of the filtered load in intact control and uninephrectomized control rats, respectively (P less than 0.001 compared to the late proximal values of each group), but failed to increase significantly in pyelonephritic rats (65+/-13%), indicating interruption of the normal recycling of urea in the latter group. Analysis of tissue slices demonstrated a rising corticopapillary gradient for total tissue water solute concentration as well as for tissue water urea concentration in both groups of control rats. In contrast, the pyelonephritic animals exhibited no similar gradients from cortex to papilla. These data indicate that the pyelonephritic kidney fails to recycle urea and accumulate interstitial solute. The latter must inevitably lead to a concentrating defect.

On the adaptation in potassium excretion associated with nephron reduction in the dog.

An effort to examine certain aspects of the adaptation in potassium excretion associated with nephron reduction was made in dogs with unilateral remnant kidneys. A constant intake of potassium was maintained by tube feeding and studies were performed before and after removal of the intact control kidney. The removal of the intact kidney created the need for the remaining nephrons of the remnant kidney to increase their rate of potassium excretion markedly. Sodium intake was held constant either at a normal or a low level. Mineralocorticoid hormone activity was maintained either at a high level by the administration of 0.2 mg 9-alpha-fluorohydrocortisone daily or at a low level by performing bilateral adrenalectomy and administering a minimal maintenance dose of deoxycorticosterone acetate (DOCA) and cortisol. Potassium excretion per nephron increased strikingly within 18 hr of contralateral nephrectomy and by 7 days, excretion rates were 600% of control values for the remnant kidney. More potassium was excreted in the first 5 hr after administration of a test dose of potassium by the remnant kidney alone in the postnephrectomy state than by both the remnant and intact kidneys in the prenephrectomy state. 24 hr excretion of potassium by the remnant kidney postnephrectomy averaged 92% of the administered load of potassium. The adaptation in potassium excretion was independent of the concurrent rate of sodium excretion and of mineralocorticoid hormone activity and persisted during constriction of the renal artery, a stimulus which presumably decreased distal delivery of sodium. The adaptation and the continued modulation of potassium excretion could not be explained adequately by an increase in impermeant anion excretion per nephron. Finally, known changes in hydrogen ion excretion per nephron associated with nephron reduction are in a direction opposite to those which would explain the acquired kaliuresis per nephron.