Urea transporters and renal function: lessons from knockout mice

PURPOSE OF REVIEW: Gene knockout mice have been created for the collecting duct urea transporters UT-A1 and UT-A3, the descending thin-limb urea transporter UT-A2 and the descending vasa recta isoform, UT-B. In this brief review, the new insights in our understanding of the role of urea in the urinary concentrating mechanism and kidney function resulting from studies in these mice are discussed. RECENT FINDINGS: The major findings in studies on urea transporter knockout mice are as follows: rapid transport of urea from the inner medulla collecting duct lumen via UT-A1 or UT-A3 is essential for urea accumulation in the inner medullary interstitium; inner medulla collecting duct urea transporters are essential in water conservation by preventing urea-induced osmotic diuresis; an absence of inner medulla collecting duct urea transport does not prevent the concentration of sodium chloride in the inner medulla interstitium; deletion of the vasa recta isoform UT-B has a much greater effect on urinary concentration than deleting the descending limb isoform UT-A2. SUMMARY: Multiple urea transport mechanisms within the kidney are essential for producing maximally concentrated urine.     

Urea and renal function in the 21st century: insights from knockout mice

Since the turn of the 21st century, gene knockout mice have been created for all major urea transporters that are expressed in the kidney: the collecting duct urea transporters UT-A1 and UT-A3, the descending thin limb isoform UT-A2, and the descending vasa recta isoform UT-B. This article discusses the new insights that the results from studies in these mice have produced in the understanding of the role of urea in the urinary concentrating mechanism and kidney function. Following is a summary of the major findings: (1) Urea accumulation in the inner medullary interstitium depends on rapid transport of urea from the inner medullary collecting duct (IMCD) lumen via UT-A1 and/or UT-A3; (2) as proposed by Robert Berliner and colleagues in the 1950s, the role of IMCD urea transporters in water conservation is to prevent a urea-induced osmotic diuresis; (3) the absence of IMCD urea transport does not prevent the concentration of NaCl in the inner medulla, contrary to what would be predicted from the passive countercurrent multiplier mechanism in the form proposed by Kokko and Rector and Stephenson; (4) deletion of UT-B (vasa recta isoform) has a much greater effect on urinary concentration than deletion of UT-A2 (descending limb isoform), suggesting that the recycling of urea between the vasa recta and the renal tubules quantitatively is less important than classic countercurrent exchange; and (5) urea reabsorption from the IMCD and the process of urea recycling are not important elements of the mechanism of protein-induced increases in GFR. In addition, the clinical relevance of these studies is discussed, and it is suggested that inhibitors that specifically target collecting duct urea transporters have the potential for clinical use as potassium-sparing diuretics that function by creation of urea-dependent osmotic diuresis.     

Mechanisms to concentrate the urine: an opinion

PURPOSE OF REVIEW: Our goal is to suggest how the renal concentrating mechanism is regulated in vivo. RECENT FINDINGS: The majority of descending thin limbs of the loop of Henle lack aquaporin-1 water channels, and loops of Henle in the inner medulla lack urea transporters. SUMMARY: Lack of water permeability in the descending thin limbs of the loop of Henle offers several advantages. First, since much less water is added to the outer medullary interstitial compartment, inhibitory control mechanisms on sodium and chloride reabsorption from the medullary thick ascending of loop of Henle initiated by water addition from the medullary collecting duct can be effective. Second, recycling of urea is efficient, as little urea will be washed out of the medulla. Third, delivery of a larger volume of filtrate to the medullary thick ascending limb of the loop of Henle permits both an appreciable reabsorption of sodium along with only a small fall in the luminal concentration of sodium in each of these liters. Hence there need be only a small lumen positive voltage in the medullary thick ascending limb of the loop of Henle. The absence of urea transporters in the loop of Henle in the inner medulla is required for a passive mechanism of sodium and chloride reabsorption in the inner medulla. Control of urea reabsorption from the medullary collecting duct is needed to prevent excessive oliguria in electrolyte-poor urine.     

Editorial review. Recent formulations of the urinary concentrating mechanism: a status report.

The status of the purely passive mode of solute concentration as of 1979 appears to be similar to that of the original countercurrent hypothesis 10 years ago. The passive mode concept has advanced our understanding of the concentrating process by qualitatively incorporating the permeability characteristics of tubule segments and the lack of an active transport process in the thin loop of Henle into a mechanism which has attractive economy and explanatory value. But in the final analysis some assumptions are not borne out by experimental findings (for example, the high urea concentration of fluid in the rat and hamster end-descending limb; the likelihood of net transepithelial addition of sodium chloride to the Psammomys descending limb; the removal of sodium chloride from the hamster ascending limb against an apparent electrochemical gradient under certain circumstances; and the osmotic lag between vasa recta blood and interstitium in the rat). Furthermore, when the known permeability and transport characteristics of the renal tubule are incorporated into a mathematic model of the passive operating mode, numerical simulations fail to establish a progressively hyperosmotic inner medulla. This does not rule out the applicability of the more general model (Eq. 1), particularly if evidence for some form of active transport in the inner medulla, heretofore lacking, is forthcoming.     

Pericyte regulation of renal medullary blood flow

Pericytes are contractile smooth muscle-like cells that surround descending vasa recta (DVR) and provide their capability for vasomotion. The importance of the medullary pericyte derives from the role of DVR to distribute most or all of the blood flow from juxtamedullary cortex to the renal inner and outer medulla. Physiological processes that are likely to be influenced by pericyte constriction of DVR include the urinary concentrating mechanism and pressure natriuresis. Oxygen tensions in the medulla are low, so that subtle variation of pericyte vasomotion might play a role to abrogate hypoxia and prevent insult to the medullary thick ascending limb of Henle. Known vasoconstrictors of DVR include angiotensin II, endothelins, norepinephrine, acetylcholine, and adenosine. Vasodilators include prostaglandin E2, adenosine, acetylcholine, bradykinin, and nitric oxide.     

Historadioautographic localization, pharmacology and ontogeny of V(1a) vasopressin binding sites in the rat kidney.

The localization and pharmacological characteristics of vasopressin (VP) binding sites of the V(1a) subtype in developing and adult rat kidney were investigated by radioautography on kidney sections incubated in the presence of a radioiodinated selective V(1a) antagonist. Their localization after in vivo systemic infusion of the radioligand was also investigated. V(1a) binding sites first appear at embryonic day 16 on vascular elements. In the adult, they were localized in the cortex (vascular and tubular structures, juxtaglomerular apparatus), the outer medulla outer stripe (vasa recta) and inner stripe (thin descending limbs of short looped nephrons) and the inner medulla (collecting ducts). Data obtained in vitro were confirmed by in vivo binding at postnatal day 30 (PN30). Whatever their localizations, the V(1a) binding sites exhibited full V(1a) pharmacological profile in postnatal stages rats and in adult rats: a high affinity (nM range) for VP and for the V(1a) agonist, a lower affinity (microM range) for oxytocin and no affinity for the oxytocin agonist. The presence of V(1a) binding sites in these different structures raises the question of the putative roles of VP in modulating renal functions. A striking finding is the presence of V(1a) binding sites in the outer medullary thin descending limbs of short looped nephrons suggesting their colocalization with urea transporters.     

Aquaporin-1 is not expressed in descending thin limbs of short-loop nephrons

In mammalian kidneys, aquaporin-1 is responsible for water reabsorption along the proximal tubule and is also thought to be involved in the concentration of urine that occurs in the medulla. It has been suggested, however, that aquaporin-1 is not expressed in the last part of the descending thin limbs of short loop nephrons in rats and mice, and its expression in this region in humans has not been studied. We examined the expression of aquaporin-1 and the urea transporter UT-A2 in serial sections of mouse nephrons in the inner stripe of the outer medulla using immunohistochemistry. In contrast to previous observations, we demonstrate a complete absence of aquaporin-1 along the entire length of descending thin limbs of 90% of short loop nephrons. Conversely, as expected, we identified aquaporin-1 in proximal tubules, descending thin limbs of long loop nephrons, and medullary descending vasa recta. We also observed this abrupt transition from aquaporin-1-positive proximal tubules to aquaporin-1-negative descending thin limbs of short loop nephrons in sections of human and rat kidneys. UT-A2 was restricted to the last 28% to 44% of the descending thin limbs of all short loop nephrons. Because the majority of nephrons are of the short loop variety, our findings suggest that the mechanisms of water transport in the descending thin limbs of short loop nephrons should be reevaluated. Likewise, the roles of aquaporin-1 and UT-A2 in the countercurrent multiplier and water conversation may need to be readdressed.     

Wnt signaling and renal medulla formation

The renal medulla, the inner compartment of the metanephric kidney, plays vital roles in the regulation of body water, electrolyte homeostasis, and systemic blood pressure. It is composed of the loops-of-Henle, the medullary collecting ducts, the vasa recta, and the medullary interstitium. Its epithelial and endothelial components display ordered spatial organization. This organization serves as the structural basis for its function in urine concentration. The urine concentration ability of a renal medulla is also related to its length among species. In this review, the current understanding of the molecular and cellular mechanisms underlying renal medulla formation (elongation) is summarized, with a focus on the role of Wnt signaling in this developmental process. Renal medulla blunting and effacement is a common symptom of many renal and urological destructions. The knowledge in renal medulla formation should assist efforts in repair and regeneration of a damaged renal medulla, so to improve renal physiology in diseased situations.     

High resolution localization of angiotensin II receptors in rat renal medulla.

The cellular localization of angiotensin II (Ang II) receptors in the inner stripe of the outer medulla of the rat kidney was investigated by using high resolution light and electron microscopic autoradiography. Fresh tissue blocks from the inner stripe of the outer medulla were incubated with 125I-[Sar1, Ile8] Ang II and prepared for microscopic autoradiography. At the light microscopic level, 125I-[Sar1, Ile8] Ang II was found to penetrate into the tissue and to bind specifically to sites outlining renal tubules and vasa recta bundles. Electron microscopic autoradiography revealed that silver grains were detected over interstitial cells located between the tubules and components of the vasa recta bundles, but no silver grains were detected overlying the cells of the thin descending or thick ascending limbs of the loop of Henle, the collecting ducts, the vasa recta, or other blood vessels. These interstitial cells contained abundant endoplasmic reticulum, microfilaments, occasional lipid droplets and extensive cytoplasmic processes which closely related to the basement membranes of the vasa recta and loops of Henle. The cells therefore closely resemble type 1 interstitial cells. Since Ang II binding sites are absent in the inner medulla, the cells labelled by this technique must be a subset of type 1 interstitial cells, distinct from the typical lipid-laden interstitial cells most abundant in the inner medulla. These findings demonstrate that type 1 interstitial cells are the primary sites for a high density of Ang II receptors located in the inner stripe of the outer medulla.     

Role of aquaporin water channels in kidney function studied using transgenic mice

Several aquaporin (AQP) water transporting proteins are expressed in mammalian kidney: AQP1 in plasma membranes of proximal tubule, thin descending limb of Henle, and descending vasa recta; AQP2 in collecting duct luminal membrane; AQP3 and AQP4 in collecting duct basolateral membrane; AQP6 in intercalated cells; and AQP7 in the S3 segment of proximal tubule. To define the role of aquaporins in renal physiology, we have generated and characterized transgenic null mice deficient in AQP1, AQP3, and AQP4, individually and in combinations, as well as AQP2 mutant mice, in which the T126M mutation causing human nephrogenic diabetes insipidus was introduced. AQP1-deficient mice are polyuric and unable to concentrate their urine in response to water deprivation or vasopressin administration. AQP1 deletion greatly reduces osmotic water permeability in proximal tubule, thin descending limb of Henle, and descending vasa recta, resulting in defective proximal tubule fluid absorption and medullary countercurrent exchange. Mice lacking AQP3 have low basolateral membrane water permeability in cortical collecting duct and excrete large quantities of dilute urine. Mice lacking AQP4 have low water permeability in inner medullary collecting duct, but manifest only a mild defect in maximum urinary concentrating ability. These data, taken together with phenotype analyses of brain, lung, and gastrointestinal organs, support the paradigm that aquaporins facilitate rapid near-isosmolar transepithelial fluid absorption/secretion, as well as rapid vectorial water movement driven by osmotic gradients. The renal phenotype data in aquaporin knockout mice suggests the utility of aquaporin blockers as novel aquaretic-diuretic agents. Received: March 19, 2001 / Accepted: March 22, 2001     

Aquaporins in endothelia

Aquaporin-1 (AQP1) water channels are expressed widely in microvascular endothelia outside of the central nervous system, including renal vasa recta and tumor microvessels, as well as in non-vascular endothelia in pleura, peritoneum, cornea, and lymphatics. In kidney, AQP1-facilitated water transport in outer medullary descending vasa recta is likely an important component of the urinary concentrating mechanism. However, in most vascular endothelia outside of kidney, it remains uncertain whether AQP1 expression and high water permeability are physiologically important. AQP1 in non-vascular endothelia at the inner corneal surface is involved in the maintenance of corneal transparency. Recently, a new role of AQP1 in endothelial cell migration was discovered in analyzing the cause of defective tumor angiogenesis in AQP1-deficient mice. AQP1 facilitates endothelial cell migration by a mechanism that may involve facilitated water transport across cell protrusions (lamellipodia). AQP1 inhibitors may thus have aquaretic and antiangiogenic activity.     

Regulation of renal urea transporters

Urea is important for the conservation of body water due to its role in the production of concentrated urine in the renal inner medulla. Physiologic data demonstrate that urea is transported by facilitated and by active urea transporter proteins. The facilitated urea transporter (UT-A) in the terminal inner medullary collecting duct (IMCD) permits very high rates of transepithelial urea transport and results in the delivery of large amounts of urea into the deepest portions of the inner medulla where it is needed to maintain a high interstitial osmolality for concentrating the urine maximally. Four isoforms of the UT-A urea transporter family have been cloned to date. The facilitated urea transporter (UT-B) in erythrocytes permits these cells to lose urea rapidly as they traverse the ascending vasa recta, thereby preventing loss of urea from the medulla and decreasing urine-concentrating ability by decreasing the efficiency of countercurrent exchange, as occurs in Jk null individuals (who lack Kidd antigen). In addition to these facilitated urea transporters, three sodium-dependent, secondary active urea transport mechanisms have been characterized functionally in IMCD subsegments: (1) active urea reabsorption in the apical membrane of initial IMCD from low-protein fed or hypercalcemic rats; (2) active urea reabsorption in the basolateral membrane of initial IMCD from furosemide-treated rats; and (3) active urea secretion in the apical membrane of terminal IMCD from untreated rats. This review focuses on the physiologic, biophysical, and molecular evidence for facilitated and active urea transporters, and integrative studies of their acute and long-term regulation in rats with reduced urine-concentrating ability.     

Effect of cortical-medullary gradient for ammonia on urinary excretion of ammonia

Previous studies suggested that a portion of ammonia secreted into the proximal tubule may diffuse directly from Henle's loop into the medullary collecting duct. Since water is absorbed along the course of the descending portion of the loop, it was proposed that the concentration of ammonia increased in loop fluid, and that rapid diffusibility of the free base would facilitate the delivery of ammonia into medullary interstitium where a high level could be maintained by the countercurrent exchange process. In this schema it was proposed that there was an ammonia concentration gradient between medullary structures and cortex, and recovery of ammonia by the medullary collecting duct due to the low pH in tubule fluid at that site. The present study was designed to evaluate this hypothesis by estimating ammonia concentrations in medullary and cortical tissue, and by correlating medullary levels with secretion rate into the inner medullary collecting duct. In control animals the concentration of total ammonia (NH4+ + NH3+) in inner medullary vasa recta was 9.2 +/- 1.5 mumoles/ml, a level 100-fold higher than the cortical level of 0.10 +/- 0.01. During acute acidosis the medullary level rose to 22.5 +/- 2.7 mumoles/ml, but in acute acidosis during mannitol infusion the level fell to 8.0 +/- 1.2. The rate of ammonia secretion into inner medullary collecting duct fluid correlated directly with medullary vasa recta ammonia concentration. These data provide evidence for a steep ammonia concentration gradient between the medulla and cortex, and suggest that the diffusion gradient across collecting duct epithelium governs the rate of the addition of ammonia to collecting duct fluid.     

Renal medullary circulation: hormonal control

It is now becoming apparent that the medullary circulation in the kidney can be regulated separately from overall renal blood flow. This characteristic of the medullary circulation plays an important role in the kidney's ability to excrete a dilute or concentrated urine in concert with changes in water and sodium transport in the distal nephron secondary to the action of vasopressin, prostaglandins, the renal nerves, and other hormones without significant other renal hemodynamic changes. There is strong evidence that renal autocoids such as angiotensin II and prostaglandins uniquely affect regional blood flow in the inner medulla because of the special structure and organization of the microvasculature in this region. There is also evidence that this regional blood flow is in part regulated by circulating hormones, such as vasopressin and atrial natriuretic peptide, which are released in response to changes in extracellular fluid volume or osmolality. In addition, data are emerging to suggest that the kallikrein-kinin system, acetylcholine, the renal nerves and adenosine participate in this regulation. In addition to the role of the medullary circulation in the urinary concentrating operation, there are data to suggest that the medullary circulation either directly (by changes in physical forces) or indirectly (by regulating medullary toxicity) may influence sodium excretion in a variety of conditions. In this regard, activation of the renin-angiotensin system locally reduces blood flow in the papilla which may be necessary before sodium retention is fully expressed in salt retaining states. Future research looking at the microvasculature of the medulla and papilla and those factors that control the contractility of these vessels are necessary before a clearer picture emerges. Nevertheless, from the data already available it seems reasonable to suggest that the medullary circulation may be as important to kidney function during physiological and pathophysiological states as is the cortical circulation.     

Suppression of potassium-recycling in the renal medulla by short-term potassium deprivation

Recently we proposed that potassium, like urea, normally undergoes medullary recycling from collecting tubule to the pars recta or descending limb of the juxtamedullary nephron and suggested that the extent of recycling is a function of the concentration of potassium in collecting tubule fluid. To test this hypothesis further, we fed young rats a potassium-free diet for 3 days and then prepared them for micropuncture of the left renal papilla. Compared to findings in normally fed animals, potassium deprivation caused a significant fall in plasma potassium and urinary excretion of potassium. There was a striking decrease in the fraction of filtered potassium remaining at the end of the justamedullary descending limb for 94 +/- 11% to 38 +/- 3% (P less than 0.001). The latter value is not significantly different from the fraction of filtered sodium remaining (36 +/- 4%) and suggests that net addition of potassium to the pars recta or descending limb was completely abolished. A correlation was observed between the fraction of filtered potassium remaining at the end of the descending limb and either urinary potassium excretion (P less than 0.001) or urinary potassium concentration(P less than 0.001) in the contralateral unexposed kidney. These results lend further support to the hypothesis of medullary recycling of potassium.     

Determinants of intrarenal oxygenation: factors in acute renal failure.

Oxygen tension within the renal parenchyma is influenced by two factors: metabolic demand and oxygen supply. There are three regions within the kidney in which there is an anatomical basis for limited oxygen availability. The first is the inner stripe where oxygen diffusion between arterial and venous vasa recta reduces PO2. The other two are the outer stripe and medullary rays which are fed by O2-poor blood from venous vasa recta. The balance between oxygen demand and supply is most critical in the inner stripe where the PO2 is most influenced by transport activity. In contrast, altering transport activities in the outer stripe will not change the prevalence of hypoxic S3 injury but will alter its type (i.e., cell fragmentation related to high GFR and increased workload versus cell edema related to low GFR and minimal workload). The effect of transport activity on medullary ray PO2 has not been well defined. Using sensitive oxygen microelectrodes, cortical PO2 (52 +/- 2 mm Hg) in the rat was found to be higher than medullary PO2 (21 +/- 2 mm Hg, p less than 0.001). How are these observations reflected in current models of acute renal failure? The ischemia-reflow model affects proximal tubules with a predilection for S3 (located within the outer stripe of medulla) after short-term ischemia. With hyperfiltration (induced by glycine or renal hypertrophy) and the pursuant increase in transport related O2 demand, hypoxic mTAL inner stripe injury becomes prominent. Renal parenchymal hypertrophy exaggerates injury in the contrast nephropathy model, in which mTAL inner stripe injury is a predominant feature and medullary PO2 is very low.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of the collecting duct in urinary concentration

In summary, the three major segments of the collecting duct subserve three different functions in the urinary concentrating mechanism. The main function of the cortical collecting tubule is to raise the fractional solute contribution and absolute concentration of urea in fluid that it delivers to the outer medullary collecting duct. The function of the outer medullary collecting duct is to raise further the absolute intraluminal urea concentration. Finally, the inner medullary collecting duct has two major functions in urinary concentration: first, it adds net urea to the papillary interstitium, and second, it allows the generation of maximally concentrated urine due to osmotic water equilibration. Indeed, the urine osmolality can rise to levels higher than the papillary interstitial osmolality as a consequence of inequalities of the reflection coefficients of urea and sodium chloride.     

"Avian-type" renal medullary tubule organization causes immaturity of urine-concentrating ability in neonates

BACKGROUND: While neonatal kidneys are not powerful in concentrating urine, they already dilute urine as efficiently as adult kidneys. To elucidate the basis for this paradoxical immaturity in urine-concentrating ability, we investigated the function of Henle's loop and collecting ducts (IMCDs) in the inner medulla of neonatal rat kidneys. METHODS: Analyses of individual renal tubules in the inner medulla of neonatal and adult rat kidneys were performed by measuring mRNA expression of membrane transporters, transepithelial voltages, and isotopic water and ion fluxes. Immunofluorescent identification of the rCCC2 and rCLC-K1 using polyclonal antibodies was also performed in neonatal and adult kidney slices. RESULTS: On day 1, the transepithelial voltages (V(Ts)) in the thin ascending limbs (tALs) and IMCDs were 14.6 +/- 1.1 mV (N = 27) and -42.7 +/- 6.1 mV (N = 14), respectively. The V(Ts) in the thin descending limbs (tDLs) were zero on day 1. The V(Ts) in the tALs were strongly inhibited by luminal bumetanide or basolateral ouabain, suggesting the presence of a NaCl reabsorption mechanism similar to that in the thick ascending limb (TAL). The diffusional voltage (V(D)) of the tAL due to transepithelial NaCl gradient was almost insensitive to a chloride channel blocker 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB). The V(Ts) in the IMCDs were strongly inhibited by luminal amiloride. On day 1, both the tDL and tAL were impermeable to water, indicating the water impermeability of the entire loop. Diffusional water permeability (P(dw)) and urea permeabilities (P(urea)) in the IMCDs indicated virtual impermeability to water and urea on day 1. Stimulation by vasopressin (1 nmol/L) revealed that only P(dw) was sensitive to vasopressin by day 14. A partial isoosmolar replacement of luminal urea by NaCl evoked negligible water flux across the neonatal IMCDs, indicating the absence of urea-dependent volume flux in the neonatal IMCD. These transport characteristics in each neonatal tubule are similar to those in quail kidneys. Identification of mRNAs and immunofluorescent studies for specific transporters, including rAQP-1, rCCC2, rCLC-K1, rENaC beta subunit, rAQP-2, and rUT-A1, supported these findings. CONCLUSION: We hypothesize that the renal medullary tubule organization of neonatal rats shares a tremendous similarity with avian renal medulla. The qualitative changes in the organization of medullary tubules may be primarily responsible for the immature urine-concentrating ability in mammalian neonates.