Renal Organic Anion Secretion Research Articles

Human Renal Xenobiotic Transporter Expression is Altered in Progression of Non‐Alcoholic Fatty Liver Disease as revealed by Quantitative Targeted Proteomics

Alterations to hepatic function, including transporter expression, during progressive nonalcoholic fatty liver disease (NAFLD) and nonalcoholic steatohepatitis (NASH) are well documented. Recent evidence suggests that renal function, including glomerular filtration, is also perturbed during these diseases. To avoid adverse drug reactions, an accurate phenotype of renal xenobiotic transporters in NAFLD and NASH patients is critical. To evaluate this, formalin-fixed and paraffin-embedded kidney needle biopsies were acquired from patients (n=5-6/group) identified with paired diagnoses of NAFLD, NASH, or healthy liver. Protein was extracted and then digested with trypsin to generate unique surrogate peptides for 34 clinically relevant transporters; these surrogate peptides were then quantified against pure standards by LC-MS/MS. Trend analysis demonstrated transporter protein abundance decreases during disease progression from healthy to NASH of: BCRP (0.15 to 0.06 pmol/mg protein), OCT2 (157 to 17 pmol/mg protein), MRP3 (0.42 to 0.24 pmol/mg protein), ENT1 (28.5 to 10.8 pmol/mg protein), and CNT3 (0.19 to 0.09 pmol/mg protein). Only ASBT, a renal bile acid transporter, increased from 1.7 to 5.3 pmol/mg protein during disease progression. OAT4 expression decreased from healthy protein abundance of 1.72 to 0.78 in NAFLD and 0.47 pmol/mg protein in NASH patients. Interestingly, abundance of the alpha subunit of Na+/K+-ATPase decreased from 14.8 pmol/mg protein in healthy patients to 5.3 and 3.3 in NAFLD and NASH patients, respectively. These findings are the first to quantify alterations to renal xenobiotic transporters in patients with progressive stages of NAFLD. Notably, expression of transporters involved in renal secretion of organic anions (OAT4 and Na+/K+-ATPase) are considerably reduced, suggesting a novel mechanism by which these patients may be at greater risk of adverse drug reactions. As such, appropriate models recapitulating these changes are warranted to study their putative effects on the toxicokinetics of clinically relevant substrates.

Distribution of organic anion transporters NaDC3 and OAT1-3 along the human nephron.

The initial step in renal secretion of organic anions (OAs) is mediated by transporters in the basolateral membrane (BLM). Contributors to this process are primary active Na(+)-K(+)-ATPase (EC 3.6.3.9), secondary active Na(+)-dicarboxylate cotransporter 3 (NaDC3/SLC13A3), and tertiary active OA transporters (OATs) OAT1/SLC22A6, OAT2/SLC22A7, and OAT3/SLC22A8. In human kidneys, we analyzed the localization of these transporters by immunochemical methods in tissue cryosections and isolated membranes. The specificity of antibodies was validated with human embryonic kidney-293 cells stably transfected with functional OATs. Na(+)-K(+)-ATPase was immunolocalized to the BLM along the entire human nephron. NaDC3-related immunostaining was detected in the BLM of proximal tubules and in the BLM and/or luminal membrane of principal cells in connecting segments and collecting ducts. The thin and thick ascending limbs, macula densa, and distal tubules exhibited no reactivity with the anti-NaDC3 antibody. OAT1-OAT3-related immunostaining in human kidneys was detected only in the BLM of cortical proximal tubules; all three OATs were stained more intensely in S1/S2 segments compared with S3 segment in medullary rays, whereas the S3 segment in the outer stripe remained unstained. Expression of NaDC3, OAT1, OAT2, and OAT3 proteins exhibited considerable interindividual variability in both male and female kidneys, and sex differences in their expression could not be detected. Our experiments provide a side-by-side comparison of basolateral transporters cooperating in renal OA secretion in the human kidney.

Expression of basolateral organic anion and cation transporters in experimental cadmium nephrotoxicity in rat kidney.

Cadmium (Cd)-intoxicated experimental animals exhibit impaired renal secretion of organic anions (OA) and cations (OC), indicating their transporters (Oats and Octs) in the proximal tubule (PT) basolateral membrane as possible targets of Cd. To correlate transport data from the literature with the expression of relevant transporters, we performed immunochemical and RT-PCR studies of renal Oats and Octs in the subchronic (treatment with CdCl2; 2 mg Cd/kg b.m./day, for 2 weeks) and acute (treatment with Cd-metallothionein (CdMT); 0.4 mg Cd/kg b.m., 6 or 12 h before killing) models of Cd nephrotoxicity. In the subchronic model, PT exhibited a minor loss of basolateral invaginations and overall unchanged expression of Na(+)/K(+)-ATPase and GAPDH proteins and mRNAs, while the expression of Oat and Oct proteins and their mRNAs was strongly downregulated. In the acute model, a time-related redistribution of basolateral transporters to the intracellular vesicular compartment was a major finding. However, 6 h following CdMT treatment, the total abundance of Oat and Oct proteins in the renal tissue remained unchanged, the expression of mRNAs decreased only for Oats, while a limited Oat1 and Na(+)/K(+)-ATPase immunoreactivity in the PT apical membrane indicated loss of cell polarity. As tested in rats treated with colchicine, the observed loss/redistribution of basolateral transporters in both models may be independent on microtubules. Therefore, the diminished renal secretion of OA and OC via PT in Cd nephrotoxicity may result from (a) limited loss of secretory surface (basolateral invaginations), (b) selective loss of Oats and Octs, and

Activation of Protein Kinase Cζ Increases OAT1 (SLC22A6)- and OAT3 (SLC22A8)-mediated Transport

Organic anion transporters (OATs) play a pivotal role in the clearance of small organic anions by the kidney, yet little is known about how their activity is regulated. A yeast two-hybrid assay was used to identify putative OAT3-associated proteins in the kidney. Atypical protein kinase Czeta (PKCzeta) was shown to bind to OAT3. Binding was confirmed in immunoprecipitation assays. The OAT3/PKCzeta interaction was investigated in rodent renal cortical slices from fasted animals. Insulin, an upstream activator of PKCzeta, increased both OAT3-mediated uptake of estrone sulfate (ES) and PKCzeta activity. Both effects were abolished by a PKCzeta-specific pseudosubstrate inhibitor. Increased ES transport was not observed in renal slices from OAT3-null mice. Transport of the shared OAT1/OAT3 substrate, rho-aminohippurate, behaved similarly, except that stimulation was reduced, not abolished, in the OAT3-null mice. This suggested that OAT1 activity was also modified by PKCzeta, subsequently confirmed using an OAT1-specific substrate, adefovir. Inhibition of PKCzeta also blocked the increase in ES uptake seen in response to epidermal growth factor and to activation of protein kinase A. Thus, PKCzeta acted downstream of the epidermal growth factor to protein kinase A signaling pathway. Activation of transport was accompanied by an increase in V(max) and was blocked by microtubule disruption, indicating that activation may result from trafficking of OAT3 into the plasma membrane. These data demonstrate that PKCzeta activation up-regulates OAT1 and OAT3 function, and that protein-protein interactions play a central role controlling these two important renal drug transporters.

Overlapping in vitro and in vivo specificities of the organic anion transporters OAT1 and OAT3 for loop and thiazide diuretics

Organic anion transporter (OAT) genes have been implicated in renal secretion of organic anions, but the individual in vivo contributions of OAT1 (first identified as NKT) and OAT3 remain unclear. Potential substrates include loop diuretics (e.g., furosemide) and thiazide diuretics (e.g., bendroflumethiazide), which reach their tubular sites of action mainly by proximal tubular secretion. Previous experiments in Oat1 knockout (-/-) mice revealed an almost complete loss of renal secretion of the prototypic organic anion p-aminohippurate (PAH) and a role of OAT1 in tubular secretion of furosemide (Eraly SA, Vallon V, Vaughn D, Gangoiti JA, Richter K, Nagle M, Monte JC, Rieg T, Truong DM, Long JM, Barshop BA, Kaler G, Nigam SK. J Biol Chem 281: 5072-5083, 2006). In this study we found that both furosemide and bendroflumethiazide inhibited mOat1- and mOat3-mediated uptake of a labeled tracer in Xenopus oocytes injected with cRNA, consistent with their being substrates for mouse OAT1 and OAT3. Experiments in Oat3(-/-) mice revealed intact renal secretion of PAH, but the dose-natriuresis curves for furosemide and bendroflumethiazide were shifted to the right and urinary furosemide excretion was impaired similar to the defect in Oat1(-/-) mice. Thus, whereas OAT1 (in contrast to OAT3) is the classic basolateral PAH transporter of the proximal tubule, both OAT1 and OAT3 contribute similarly to normal renal secretion of furosemide and bendroflumethiazide, and a lack of either one is not fully compensated by the other. Although microarray expression analysis in the kidneys of Oat1(-/-) and Oat3(-/-) mice revealed somewhat altered expression of a small number of transport-related genes, none were common to both knockout models. When searching for polymorphisms involved in human diuretic responsiveness, it may be necessary to consider both OAT1 and OAT3, among other genes.

Downregulation of organic anion transporters OAT1 and OAT3 correlates with impaired secretion ofpara-aminohippurate after ischemic acute renal failure in rats

Ischemic acute renal failure (iARF) was described to reduce renal extraction of the organic anion para-aminohippurate (PAH) in humans. The rate-limiting step of renal organic anion secretion is its basolateral uptake into proximal tubular cells. This process is mediated by the organic anion transporters OAT1 and OAT3, which both have a broad spectrum of substrates including a variety of pharmaceutics and toxins. Using a rat model of iARF, we investigated whether impairing the secretion of the organic anion PAH might be associated with downregulation of OAT1 or OAT3. Inulin and PAH clearance was determined starting from 6 up to 336 h after ischemia-reperfusion (I/R) injury. Net secretion of PAH was calculated and OAT1 as well as OAT3 expression was analyzed by RT-PCR and Western blotting. Inulin and PAH clearance along with PAH net secretion were initially diminished after I/R injury with a gradual recovery during follow-up. This initial impairment after iARF was accompanied by decreased mRNA and protein levels of OAT1 and OAT3 in clamped animals compared with sham-operated controls. In correlation to the improvement of kidney function, both mRNA and protein levels of OAT1 and OAT3 were upregulated during the follow-up. Thus decreased expression of OAT1 and OAT3 is sufficient to explain the decline of PAH secretion after iARF. As a result, this may have substantial impact on excretion kinetics and half-life of organic anions. As a consequence, the biological effects of a variety of organic anions may be affected after iARF.

Decreased Renal Organic Anion Secretion and Plasma Accumulation of Endogenous Organic Anions in OAT1 Knock-out Mice

The "classical" organic anion secretory pathway of the renal proximal tubule is critical for the renal excretion of the prototypic organic anion, para-aminohippurate, as well as of a large number of commonly prescribed drugs among other significant substrates. Organic anion transporter 1 (OAT1), originally identified as NKT (Lopez-Nieto, C. E., You, G., Bush, K. T., Barros, E. J. G., Beier, D. R., and Nigam, S. K. (1997) J. Biol. Chem. 272, 6471-6478), has physiological properties consistent with a role in this pathway. However, several other transporters (e.g. OAT2, OAT3, and MRP1) have also been proposed as important PAH transporters on the basis of in vitro studies; therefore, the relative contribution of OAT1 has remained unclear. We have now generated a colony of OAT1 knock-out mice, permitting elucidation of the role of OAT1 in the context of these other potentially functionally redundant transporters. We find that the knock-out mice manifest a profound loss of organic anion transport (e.g. para-aminohippurate) both ex vivo (in isolated renal slices) as well as in vivo (as indicated by loss of renal secretion). In the case of the organic anion, furosemide, loss of renal secretion in the knock-out results in impaired diuretic responsiveness to this drug. These results indicate a critical role for OAT1 in the functioning of the classical pathway. In addition, we have determined the levels of approximately 60 endogenous organic anions in the plasma and urine of wild-type and knock-out mice. This has led to identification of several compounds with significantly higher plasma concentrations and/or lower urinary concentrations in knock-out mice, suggesting the involvement of OAT1 in their renal secretion. We have also demonstrated in xenopus oocytes that some of these compounds interact with OAT1 in vitro. Thus, these latter compounds might represent physiological substrates of OAT1.

The renal-specific transporter mediates facilitative transport of organic anions at the brush border membrane of mouse renal tubules.

The renal secretion of organic anions across the proximal tubules is achieved by a coordination of uptake and efflux transporters. This study reports the expression, localization, and functional properties of mouse renal-specific transporter (RST). Mouse RST mRNA is predominantly expressed in the kidney and localized on the brush border membrane of mouse kidney proximal tubules. Mouse RST-expressing HEK293 cells exhibited saturable uptake of p-aminohippurate (Km approximately 234 microM), which was increased by an increase in K(+) concentration or in the presence of Ba(2+) and ouabain and decreased by diethylpyrocarbonate, a histidine modifier. An increase in K(+) concentration enhanced the uptake of benzylpenicillin, 2,4-dichlorophenoxyacetate, and dehydroepiandrosterone sulfate, suggesting polyspecific substrate specificity of mouse RST. Vectorial transport of 2,4-dichlorophenoxyacetate was observed in the basal-to-apical direction in rat organic anion transporter 3-expressing LLC-PK1 cells (rOat3-LLC); however, coexpression of mouse RST in rOat3-LLC caused a 1.3-fold increase in the basal-to-apical transport. In addition, the basal-to-apical transport of benzylpenicillin and urate was 3- and 2.5-fold greater than that in the opposite direction in the double-transfected cells, respectively, whereas their transepithelial transport in vector- or rOat3-LLC was symmetrical. Furthermore, the basal-to-apical transport of benzylpenicillin was saturable and reduced by increasing extracellular K(+) concentration and ouabain. These results suggest that mouse RST mediates the efflux of organic anions including urate and works as exit for organic anions in the proximal tubules. In addition to the kidney, mouse RST was detected in the brain capillaries and the choroid plexus, and it may also play a role in efflux transport of organic anions across the barriers of the central nervous system.

The molecular pharmacology of organic anion transporters: from DNA to FDA?

Renal organic anion secretion has been implicated in numerous clinically significant drug interactions and adverse reactions, indicating the importance of a detailed understanding of this pathway for the development of optimum therapeutics. With the cloning of multiple genes encoding organic anion transporters (OATs), the study of organic anion secretion has entered the molecular age. In this review, we focus on various aspects of the molecular biology and pharmacology of the OATs, including discussion of their structural biology, genomic organization in pairs, developmental regulation, toxicology, and pharmacogenetics. We propose functional, pathophysiological, and evolutionary hypotheses to help explain recent experimental and genomic data.

Novel aspects of renal organic anion transporters.

Organic anion transporters, transmembrane proteins present in the renal proximal tubule, are a critical component of the human drug excretion machinery. Recent advances have clarified the function of these transporters, with broad clinical implications for pharmacogenetics, drug interactions and adverse reactions. Here, we discuss these issues in the context of the basic biology of the transporters. Understanding of organic anion transporter function has proceeded on several fronts. The continued cataloging of organic anion transporter substrates has revealed that the transporters' activity likely underlies many common drug interactions and nephrotoxic adverse reactions. Meanwhile, immunohistochemical and physiological studies suggest their potential involvement in the apical as well as basolateral steps of renal organic anion secretion. In addition, studies of the genomic organization of these transporters reveal that they are found in pairs of similar and similarly expressed genes, suggesting that pair members are coordinately regulated. Finally, we hypothesize here that organic anion transporters might impact renal susceptibility to ischemia and toxic injury, because their uptake of substrates can result in the efflux of Krebs cycle intermediates, an important nutrient source for the proximal tubule. The study of these transporters will likely have a significant impact on renal pharmacology and pharmacogenetics. In this regard, the generation of organic anion transporter gene knockout mice could provide invaluable models for defects in renal drug-handling. Ultimately, detailed knowledge of organic anion transporter function will assist in the choice of optimum pharmacological therapies.

Stoichiometry of organic anion/dicarboxylate exchange in membrane vesicles from rat renal cortex and hOAT1-expressing cells.

Although membrane vesicle studies have established the driving forces that mediate renal organic anion secretion and the organic anion transporter Oat1 has now been cloned in several species, its stoichiometry has remained uncertain. In this study, we used electrophysiology, kinetic measurements, and static head experiments to determine the coupling ratio for Oat1-mediated organic anion/dicarboxylate exchange. Initial experiments demonstrated that uptake of PAH by voltage-clamped Xenopus laevis oocytes expressing rOat1 led to net entry of positive charge, suggesting that coupling was one-to-one. This conclusion was confirmed by kinetic analysis of PAH and glutarate fluxes in native basolateral membrane vesicles from the rat renal cortex, which showed a Hill coefficient of 1. Similarly, static head experiments on the rat vesicles also showed a 1:1 coupling ratio. To confirm these conclusions in a system expressing a single cloned transporter, Madin-Darby canine kidney cells were stably transfected with the human exchanger hOAT1. The hOAT1-expressing cell line showed extensive PAH transport, which was very similar in all respects to transport expressed by hOAT1 in Xenopus oocytes. Its Km for PAH was 8 microM and glutarate effectively trans-stimulated PAH transport. When stoichiometry was assessed using plasma membranes isolated from the hOAT1-expressing cells, both kinetic and static head data indicated that hOAT1 also demonstrated a 1:1 coupling between organic anion and dicarboxylate.

Human Organic Anion Transporter 3 (hOAT3) can Operate as an Exchanger and Mediate Secretory Urate Flux

Background/Aims: Renal secretion of organic anions is critically dependent on their basolateral uptake against the electrochemical gradient. Due to their localization, two transporters are likely involved, namely OAT1 and OAT3. While OAT1 as an exchanger clearly operates in the secretory direction, OAT3 in its previously supposed mode as a uniporter should move anionic substrates from cell to blood. It would thus dissipate gradients established by OAT1 of common OAT1/OAT3 substrates. In the present study we therefore reinvestigated the driving forces of human OAT3. Methods: The human OAT3 obtained from the Resource Center/Primary Database was made functional by site-directed mutagenesis. Using the Xenopus laevis oocyte expression system, hOAT3-mediated transport of estrone sulfate (ES) and dicarboxylates was assayed for cis-inhibition and/or trans-stimulation in both the uptake and efflux direction. Results: hOAT3-mediated efflux of glutarate (GA), can be significantly trans-stimulated by a variety of ions with high cis-inhibitory potency, including GA (282%), α-ketoglutarate (476%), p-aminohippurate (179%), and, most notably, urate (167%). Urate cis-inhibited ES uptake with an IC₅₀ close to normal serum urate concentrations. Conclusion: These data indicate that OAT3 does not represent a uniporter but operates as an organic ion%dicarboxylate exchanger similar to OAT1, and may mediate renal urate secretion.

Influence of Sex Differences on the Renal Secretion of Organic Anions

Influence of Sex Differences on the Renal Secretion of Organic Anions

Renal organic anion secretion: evidence for dopaminergic and adrenergic regulation.

To examine possible regulatory control of renal proximal tubule organic anion secretion, winter flounder (Pleuronectes americanus) proximal tubule primary cultures were mounted in Ussing chambers. Unidirectional fluxes of [2,4-(14)C]dichlorophenoxyacetic acid were determined under short-circuited conditions. Phorbol 12-myristate 13-acetate (1 microM) caused a significant (P < 0.01) inhibition of net 2,4-dichlorophenoxyacetic acid secretion. Preincubation with staurosporine (1 microM) blocked the phorbol 12-myristate 13-acetate-induced decrease in secretion. Neither forskolin (10 microM) nor W-7 (20 microM) had any effect on net transport. Elevation of intracellular calcium activity with either A-23187 or thapsigargin produced a slight, transient decrease in transport. Addition of dopamine (1 microM) to the peritubular side, but not the luminal side, caused a significant (P < 0.01) decrease in net secretion. Both the alpha-adrenergic agonist oxymetazoline (10 microM) and depletion of intracellular Na+ transiently, but significantly (P < 0.05), increased net transport. The data indicate that renal organic anion excretion may be regulated through dopaminergic inhibition and alpha-adrenergic stimulation of net transepithelial secretion.

The influence of moderate hypoalbuminaemia on the renal metabolism and dynamics of furosemide in the rabbit.

1. The present study aimed to investigate the influence of hypoalbuminaemia on the pharmacokinetics and pharmacodynamics of furosemide. Hypoalbuminaemia was produced by repeated plasmapheresis, to attain plasma albumin concentrations of 21.6 +/- 0.9 g l-1, compared with 33.0 +/- 0.6 g l-1 in controls (P < 0.001). The per cent of bound furosemide in hypoalbuminaemic rabbits (90.8 +/- 0.7%) was lower than that in control rabbits (97.4 +/- 0.5%, P < 0.001). The kinetics of intravenous furosemide (2.5 mg kg-1) were studied in control (n = 6) and hypoalbuminaemic rabbits (n = 6). 2. To assess the effect of hypoalbuminaemia on extrarenal clearance of furosemide, functional anephria was induced by ligating the renal pedicles of 12 rabbits, which were segregated in two groups, with and without hypoalbuminaemia. 3. In the control group, total, urinary and metabolic clearances of furosemide were 11.8 +/- 1.0, 5.0 +/- 0.4 and 6.8 +/- 0.6 ml min-1 kg-1, respectively. Compared with control rabbits, in hypoalbuminaemic rabbits, total clearance of furosemide increased by 40% (P < 0.001), result of the enhancement of furosemide metabolic clearance (C1m) from 5 to 10 ml min-1 kg-1 (P < 0.01). In hypoalbuminaemic rabbits, urinary excretion of furosemide was reduced by 26% (2451 +/- 115 vs 1818 +/- 134 micrograms h-1, P < 0.01). In anephric rabbits, furosemide total clearance was 1.77 +/- 0.12 ml min-1 kg-1, value not affected by hypoalbuminaemia, confirming that the increase in C1m induced by hypoalbuminaemia occurs in the kidneys. 4. Compared with controls, in hypoalbuminaemic rabbits, the rate of urinary excretion (142 +/- 9 vs 74 +/- 8 ml h-1, P < 0.001) and the rate of excretion of sodium (18.6 +/- 0.9 vs 9.9 +/- 0.9 mmol h-1, P < 0.001) were very much reduced. However, the dose-response curves were not different. 5. In conclusion, hypoalbuminaemia is associated with an increase in renal metabolic clearance of furosemide, possibly because of the increase in furosemide unbound concentration, and a decrease in the diuretic/natriuretic effect of furosemide, secondary to a reduction in furosemide tubular secretion. Thus, albumin facilitates the renal secretion of organic anions but not their metabolism.

Renal secretion of organic anions and cations

The renal proximal tubule actively transports charged, potentially toxic xenobiotics from blood to lumen. Basolateral uptake of organic anions is indirectly coupled to the sodium gradient through Na-dicarboxylate cotransport and dicarboxylate-organic anion exchange. Upon entry, a significant fraction of intracellular organic anion is sequestered within vesicles. Disruption of the cellular microtubular network can lead to both diminished vesicular movement and reduced transepithelial secretion. Luminal efflux of organic anions is energetically downhill, but carrier mediated. Both anion exchange and potential driven transport are present, but neither completely accounts for transport from cell to lumen. For organic cations, basolateral entry is downhill via potential driven facilitated diffusion. Intracellular sequestration of organic cations in vesicles is substantial, but its role in secretion is uncertain. Multiple carriers are available to drive organic cations uphill into the tubular lumen. The classical system indirectly taps the energy of the luminal Na gradient to drive organic cation efflux via Na(+)-H+ and proton-organic cation exchange. In addition, the multidrug resistance ATPase can pump organic cations into the tubular lumen. Thus, although much detailed information has been added over the last 50 years, it is not yet possible to provide a detailed, quantitative understanding of these important excretory systems.

Mechanisms mediating renal secretion of organic anions and cations

Mechanisms mediating renal secretion of organic anions and cations

Sulfate homeostasis. IV. Probenecid-induced alterations of inorganic sulfate in rats.

Homeostasis of inorganic sulfate is maintained by the capacity-limited renal reabsorption of sulfate in the proximal tubule. The purpose of the present investigation was to determine if probenecid, the classical inhibitor of renal organic anion secretion, may affect sulfate renal clearance. Two groups of rats were administered in a randomized crossover design, an i.v. bolus dose (20.6 or 92.4 mg/kg) and 4-hr infusion (0.28 or 0.59 mg/min/kg) of probenecid or vehicle, and blood and urine samples were collected. At a steady-state serum concentration of 0.45 mM, probenecid had no significant effect on the serum concentrations or renal clearance of inorganic sulfate, whereas at a serum concentration of 1.4 mM, probenecid treatment caused a significant decrease in serum sulfate concentrations (0.57 +/- 0.11 vs 0.96 +/- 0.19 mM in controls, mean +/- SD, n = 6, P less than 0.001) due to an increase in the renal clearance of sulfate (3.88 +/- 1.18 vs 2.13 +/- 0.84 ml/min/kg in controls, P less than 0.01). The fraction of the filtered sulfate that was reabsorbed was significantly decreased (0.38 +/- 0.23, vs 0.74 +/- 0.09 in controls, P less than 0.01). Therefore, probenecid treatment results in the inhibition of the renal reabsorption of inorganic sulfate in rats in vivo.

Inhibitory action of urate on rho-aminohippurate secretion by the isolated rat kidney.

We utilized an isolated perfusion rat kidney preparation to assess the influence of uric acid on <i>p</i>-amino-hippurate (PAH) secretion. In the absence of urate, PAHsecretion averaged 183 µg/min (0.94 µmol/min) at a perfusate PAHconcentration of 3.2 mg/dl (0.16 mmol/l), and was not influenced by increasing the perfusate PAHto 45 mg/dl (2.3 mmol/l). After addition of urate to the perfusate, PAHsecretion was 73% less at a perfusate PAHof 2.4 mg/dl (0.12 mmol/l), and changed very little following a 20-fold increase in perfusate PAH. The results raise the possibility that urate may depress renal organic anion secretion in vivo.

Effects of penicillin pretreatment on renal tubular para-aminohippurate transport in the immature rat

The effect of pretreatment with penicillin on para-aminohippurate (PAH) transport by the kidney of the immature rat was evaluated in vivo. After 3 days of penicillin administration, renal clearances of inulin (CIN), PAH (CPAH), and the renal tubular transport maximum (Tm) for PAH were measured in rats as young as 17 days of age. The CPAH in 19- to 21-day-old rats pretreated with procaine penicillin was 54% greater than that of their littermate controls. Similarly, CPAH of rats that received sodium penicillin was 31% greater than control. CIN was not increased after penicillin pretreatment. Pretreatment of rats older than 24 days did not change CIN or CPAH. The Tm for PAH of 17-day-old rats pretreated with sodium penicillin was 51% greater than that of control rats. It was concluded that pretreatment with penicillin enhances the renal secretion of organic anions by the immature rat.