I. INTRODUCTION

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K⁺ is the most abundant cation in the intracellular fluid and is required for many normal functions of the cell. The average daily dietary intake of K⁺ is ~75-100 meq. Each day 90-95% of dietary K⁺ is normally excreted into urine, and the 5-10% is excreted into stools (95, 96, 383). The internal K⁺ distribution needs to be tightly regulated, because movement of a range of a mere 1-2% of K⁺ from the intracellular to the extracellular fluid compartment can result in a potentially fatal increase in plasma K⁺ concentration.

Much of our knowledge of K⁺ handling by the mammalian kidney has been based on clearance and in vivo micropuncture studies of the rat kidney, which are necessarily confined to superficial nephrons (78, 96, 173, 185, 383) (Fig. 1). K⁺ is freely filtered across the glomerulus. The bulk of the filtered K⁺ is reabsorbed in the proximal tubule and the loop of Henle, such that the only 10% is delivered to the distal tubule. In the micropuncture literature, the distal tubule is the nephron segment extending from the macula densa region to the first confluence with another distal tubule. This part of the renal tubule is composed of three ultrastructurally and functionally distinct segments (139, 302): the distal convoluted tubule, the connecting tubule, and the initial collecting tubule. The final urine may contain as little as 5% or as much as 200% of the filtered K⁺ load, indicating that the distal nephron, mainly the collecting duct, is capable of either K⁺ secretion or reabsorption. Under normal circumstances, K⁺ is secreted into the lumen, mainly in the distal tubule and the cortical collecting duct, whereas under K⁺ depletion, K⁺ is absorbed from the lumen in the outer medullary collecting duct. Therefore, varying the rate of K⁺ secretion or reabsorption along the collecting duct determines the final urinary concentration and amount of K⁺. On the other hand, K⁺ secreted into the distal tubule and the cortical collecting duct is partly reabsorbed in the region of the inner stripe of the outer medulla. K⁺ is also absorbed from the thick ascending limb of Henle's loop. The resulting high medullary interstitial concentrations of K⁺ provide a gradient favoring passive secretion of K⁺ into the proximal straight tubule and the descending thin limb of Henle's loop (K⁺ recycling).

View larger version (41K): [in this window] [in a new window]   Fig. 1. K+ transport along the nephron segments (78). Percentage data refer to estimates of the fraction of the filtered K+ load remaining at the sites shown. Arrows show direction of net K+ transport (reabsorption or secretion). Asterisk shows major sites of K+ secretion. PCT, proximal convoluted tubule; PST, proximal straight tubule; DTL, descending thin limb; ATL, ascending thin limb; MTAL, medullary thick ascending limb of Henle's loop; CTAL, cortical thick ascending limb of Henle's loop; DCT, distal convoluted tubule; CNT, connecting tubule; ICT, initial collecting tubule; CCD, cortical collecting duct; OMCD, outer medullary collecting duct; IMCD, inner medullary collecting duct.

Our understanding of the ion transport properties of the mammalian collecting duct, including K⁺, relied greatly on the development of the in vitro microperfusion technique of the isolated renal tubule originally described by Burg et al. (37), because the cortical and outer medullary collecting ducts are inaccessible to micropuncture. However, this technique had some limitations because of the presence of different cell types that may vary in their functions. Some of these limitations have been overcome with an application of microelectrode techniques to the isolated perfused collecting duct segments (61, 129, 133, 148-151, 212-224, 235, 238, 239, 267-270, 275, 280, 281, 305, 325, 326). Also, the recent development of the patch clamp and advances in molecular biological techniques provided us further detailed K⁺ transport properties of the collecting ducts. Information obtained using the above techniques is reviewed, with emphasis on the cellular and membrane mechanisms. I also consider how K⁺ transport in the collecting duct is regulated in response to a number of physiological stimuli.

	II. CELLULAR MECHANISMS OF POTASSIUM TRANSPORT IN THE COLLECTING DUCT

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The collecting ducts are formed in the renal cortex by the connection of several nephrons. They descend within the medullary rays of the cortex, penetrate the outer medulla, and in the inner medulla they successively fuse together. Based on their location within the kidney, the collecting duct can be subdivided into the cortical collecting duct (CCD), the outer medullary collecting duct (OMCD), and inner medullary collecting duct (IMCD) (138, 182, 331) (see Fig. 1). Furthermore, the OMCD can be subdivided into an outer and inner stripe portion (138, 182, 331). The CCD and OMCD are unbranched along their entire length, whereas the IMCD is a highly branched structure (138, 182).

Studies of the transport properties of various portions of the collecting duct have demonstrated considerable axial heterogeneity. Table 1 summarizes the transepithelial and cellular electrical properties of the various collecting duct segments from rabbit kidneys. In particular, the CCD is a site for K⁺ secretion and Na⁺ reabsorption. The secretory capacity for K⁺ diminishes sharply with the transition to the outer medulla. The transepithelial voltage (V_T) is oriented lumen-negative in the cortex and outer stripe but becomes lumen-positive within the inner stripe. A progressive decline in the magnitude of the basolateral membrane voltage (V_B) along the collecting ducts is also observed. Heterogeneity in the conductive properties of these segments is further apparent from the values of transepithelial resistance (R_T) and fractional apical membrane resistance (fR_A). The R_T increases progressively along the collecting duct, as does the fR_A. This latter parameter is defined as the resistance of the apical membrane divided by the resistances of the apical plus basolateral membranes and indicates a marked reduction of the apical membrane conductance in the medullary segments. Similar findings are also obseved in the rat collecting duct (265, 275, 305).

The CCD can be subdivided into the initial collecting tubule (ICT), which together with the connecting tubule (CNT) constitutes the "late distal tubule" in in vivo micropuncture studies, and the portion in the medullary ray that corresponds to the cortical collecting tubule in isolated perfused tubule segments (138, 182, 331). The CCD plays a dominant role in regulating K⁺ excretion by the nephron (78, 94, 96, 105, 118, 151, 173, 184-186, 212-224, 237-239, 267-269, 287, 302-309, 316, 318) (Table 1 and Fig. 1).

The cells lining the CCD can be divided into at least two cell types: principal cells and intercalated (IC) cells (76, 125, 138, 166, 182, 216, 224, 235, 256, 272, 302) (Fig. 2). In analogy with the denomination of cell types in the other collecting ducts, which also may have heterogeneous cell populations, in this review I use "collecting duct cell" or "CD cell" instead of "principal cell," according to the recommendation of the Renal Commission of the International Union of Physiological Science (331). The CD cells total ~70-75% of all cells, whereas the IC cells represent the remaining 25-30% of cells (138, 182, 235, 350). The CD cell is mainly involved in the secretion of K⁺ and the reabsorption of Na⁺ (Fig. 2). Transport involves both passive movement through ionic conductances at both cell borders and active movement through the Na⁺-K⁺-ATPase pump (Na⁺-K⁺ pump) at the basolateral border of the cell (61, 115, 151, 213-224, 235, 237-239, 267, 269, 275, 281). K⁺ secretion in the CD cell is an active process directly linked to the active Na⁺ reabsorption via the basolateral membrane Na⁺-K⁺ pump. This is followed by the passive diffusion of K⁺ from the cell into the lumen, down a favorable electrochemical gradient via an apical membrane K⁺ conductance. K⁺ also recycles across the basolateral membrane by passive diffusion along a favorable electrochemical gradient via a basolateral membrane K⁺ conductance. Both exit steps of K⁺ are inhibited by Ba²⁺. On the other hand, Na⁺ is reabsorbed passively from lumen to cell along its electrochemical gradient via the apical Na⁺ conductance and is transported actively from cell to blood by the basolateral Na⁺-K⁺ pump. This apical membrane Na⁺ conductance is blocked by amiloride. In rat and rabbit CCDs, both Na⁺ reabsorption and K⁺ secretion are active in nature; however, in the normal rat CCD, transport of Na⁺ or K⁺ is not detectable (46, 254, 334) and V_T is near 0 mV (46, 254, 334), whereas the normal rabbit CCD has measurable transport rates of Na⁺ and K⁺ (31, 81, 115, 124, 216, 217, 287, 315, 317, 318) and a lumen-negative V_T (31, 61, 81, 115, 124, 133, 151, 172, 212-222, 224, 234, 238, 239, 267, 269, 270, 287, 310, 315, 317, 318, 325, 326, 379) (see Table 1). In addition, the basolateral membrane of the CD cell has only K⁺ conductance in the rat CCD (279); however, in the rabbit CCD, this membrane has an additionally large Cl conductance exceeding the K⁺ conductance (216, 224, 238, 270, 267) (Fig. 2). Microperfusion studies of superficial distal tubules of rat (67) and of isolated rabbit CCDs (378) have provided evidence for an electroneutral K⁺-Cl cotransport mechanism in the apical membrane (Fig. 2).

View larger version (43K): [in this window] [in a new window]   Fig. 2. Major transport systems in the cortical collecting duct (CCD). Models are based on data obtained in the rabbit CCD (61, 115, 151, 206, 213-224, 234-239, 256, 267-270, 283, 298, 315, 317, 318, 325, 326, 369-371, 381). CD cell, collecting duct cell (principal cell); -IC cell, -intercalated cell (type A intercalated cell); -IC cell, -intercalated cell (type B intercalated cell).

The carbonic anhydrase-rich IC cells consist of at least two cell types with distinct functional polarities: -IC cells (or type A IC cells) are organized for H⁺ secretion and -IC cells (or type B-IC cells) for HCO₃ secretion (33, 34, 125, 138, 166, 182, 283, 285, 286, 345, 370, 371). The presence of both types of IC cells in the CCD supports the findings that the CCD can secrete H⁺ or HCO₃ depending on the acid-base status of the whole animal (134, 164, 172, 196-198, 310). Posturated transport pathways in - and -IC cells are also illustrated in Figure 2. The V_B in both types of the IC cells is much lower than the surrounding CD cells, averaging 30 to 40 mV, compared with 70 to 80 mV in the CD cells (212, 216, 221, 224, 235). The Na⁺-K⁺-ATPase in the basolateral membrane of both - and -IC cells has a much lower activity than that of the CD cells (74, 219, 272). The apical membrane of both IC cells does not appear to contain appreciable ion conductances (216, 224). Thus there are several important functional differences between IC cells and CD cells. Although both - and -IC cells have a large Cl conductance (216, 224) and a small K⁺ conductance (216, 224) at the basolateral membrane, the distribution of the H⁺-ATPase pump (H⁺ pump) and the Cl/HCO₃ exchange are opposite (33, 125, 283, 285, 286, 345, 370, 371). The -IC cell possesses a H⁺ pump at the apical membrane and a Cl/HCO₃ exchange at the basolateral membrane, whereas the -IC cell has a H⁺ pump at the basolateral membrane and a Cl/HCO₃ exchange at the apical membrane. The basolateral Cl/HCO₃ exchange is immunologically similar to the Cl/HCO₃ exchange of the mammalian red blood cell, band 3 protein (283, 345) and is sensitive to the disulfonic stilbenes (219, 283), whereas the apical Cl/HCO₃ exchange binds peanut lectin (283, 345) and is resistant to the disulfonic stilbenes (219, 283). Both types of IC cells are not responsible for any direct transcellular transport of Na⁺ or K⁺ under normal conditions. In addition, there is axial heterogeneity of both types of IC cells along the collecting ducts; that is, the number of -IC cells is greater in the cortex, whereas the number of -IC cells is greater in the outer medulla (224, 283). In contrast to CD cells, an H⁺-K⁺ exchange pump is identified at the apical membrane of both - and -IC cells (206, 298, 369). Under K⁺ depletion, the apical H⁺-K⁺ pump reabsorbs K⁺ (393).

The outer stripe of the OMCD (OMCDo) in both rats and rabbits is morphologically similar to that of the CCD. The OMCDo is composed of two cell types: CD cells and IC cells (33, 149, 150, 161-163, 182, 256) (Fig. 3). The CD cell reabsorbs Na⁺ and secretes K⁺, but at rates below those found in the CCD (318) (Table 1). The cellular model of the CD cell in this segment is similar to that described above for the CCD, but some important differences do exist. The apical membrane of the CD cell is dominated by a Na⁺ conductance, and only a small K⁺ conductance is observed (318). This is in contrast to the apical membrane of the CD cell in the CCD, where the K⁺ conductance predominates (see Fig. 2). In addition, the only appreciable conductive pathway in the basolateral membrane of the CD cell in this segment is for K⁺ (149). No Cl conductance has been demonstrated (149). Because the OMCDo has only been found to secrete H⁺, most of the IC cells in this segment are acid-secreting -IC cells (33, 149, 150, 162-164, 172, 199, 256). An H⁺-K⁺ exchange pump is also identified at the apical membrane of the IC cell in this segment (38, 40, 161, 381). Therefore, the transport properties of the IC cells in this segment are virtually identical to those described for the -IC cells of the CCD (see Figs. 2 and 3).

View larger version (32K): [in this window] [in a new window]   Fig. 3. Major transport systems in the outer stripe of outer medullary collecting duct (OMCDo). Models are based on data obtained in the rabbit OMCDo (149, 150, 161-164, 172, 199, 256). Definitions are as in Figure 2.

The inner stripe of the OMCD (OMCDi) differs morphologically between rats and rabbits. In the rat, the OMCDi appears to be similar to the OMCDo in that both CD and -IC cells are present (182). However, in the rabbit, the cells cannot be classified as either IC cells or CD cells based on their ultrastructural features (256), although morphological (255) and immunocytochemical (283) studies suggest that the rabbit OMCDi is heterogeneous with respect to cell composition. Functionally, the rabbit OMCDi specializes in urine acidification (116, 134, 148, 224, 318) and does not participate in either Na⁺ or K⁺ transport under normal conditions (148, 219, 224, 318) (Table 1). Therefore, this segment is functionally composed of only one cell type: the acid-secreting cell (148, 162, 163, 172, 219, 224, 380) (Fig. 4). The presence of only the acid-secreting cell type in the OMCDi supports the findings that the OMCDi always secretes H⁺, irrespective of the acid-base status of the whole animal (134, 164, 172, 319, 320). The apical membrane contains a H⁺-ATPase, which behaves as a constant current source extruding positive charges from the cell. No other ion conductances have been identified in this membrane. Cellular HCO₃ exits across the basolateral membrane in exchange for Cl (148, 224). This process is electrically silent and is inhibited by the disulfonic stilbenes (148, 219). The Cl that is brought into the cell by the exchanger recycles across the basolateral membrane. This conductive exit step for Cl together with the apical membrane H⁺-ATPase leads to the bath-to-lumen flow of positive current and results in the generation of a lumen-positive V_T. The lumen-positive V_T in turn provides a driving force for the paracellular movement of ions. Because the paracellular pathway of this segment is relatively nonselective (148), the lumen-positive V_T can drive either cation reabsorption (e.g., K⁺) or anion secretion (e.g., Cl). An active H⁺/K⁺ exchange mechanism has been detected in the apical membrane of this segment and has been activated in K⁺-deficient rabbits (9, 161, 376, 380) and rats (226). Activation of this transporter contributes to the stimulation of K⁺ reabsorption and H⁺ secretion that is observed under K⁺ depletion. Thus the transport characteristics of the cells in the OMCDi from rabbits are similar to those of the -IC cells from the CCD (see Figs. 2 and 4).

View larger version (28K): [in this window] [in a new window]   Fig. 4. Major transport systems in the inner stripe of outer medullary collecting duct (OMCDi). Models are based on data obtained in the rabbit OMCDi (9, 148, 161, 163, 219, 224, 256, 286, 315, 376). Definitions are as in Figure 2.

On the basis of morphological and functional data, the IMCD can be subdivided into two regions: the initial IMCD (IMCDi) and the terminal IMCD (IMCDt) (138, 182, 256). The IMCDi comprises the initial one-third to one-half of the IMCD. In the rat, the IMCDi consists of 90% CD cells and 10% acid-secreting -IC cells (182). In the rabbit, the IMCDi is composed entirely of CD cells (138, 256). This cell has positive staining for carbonic anhydrase and Na⁺-K⁺-ATPase in the basolateral membrane (256) and therefore appears to be involved in urine acidification. In both species, the IMCDt is also composed of a single cell type (138, 182, 256). Although referred to as CD cells, they do not have the same ultrastructural features of the CD cells of either the CCD or OMCD (182, 256, 308) and therefore are called IMCD cells. The cells possess Na⁺-K⁺-ATPase in the basolateral membrane (256, 329) but do not stain for carbonic anhydrase (182, 256).

The postulated transport pathways in the IMCD are summarized in Figure 5. When single tubules are perfused in vitro with symmetrical solutions, the V_T of IMCDi is 2 to 3 mV (258, 305), while the V_T of the IMCDt under similar conditions is near 0 mV (129, 158, 259). The V_B in the IMCDi is 50 mV (305), whereas in the IMCDt it is 80 mV (129). The fR_A values in the IMCDi and IMCDt are 0.94 (305) and 0.98 (129), respectively, indicating that the apical membrane conductance in both IMCD subsegments is very low. In the IMCD, Na⁺ absorption has been demonstrated but at very low rates compared with the CCD (158, 265). Na⁺ enters the cell across the two classes of epithelial Na⁺ channels in the apical membrane (168, 229, 241, 349) and exits across the Na⁺-K⁺ pump in the basolateral membrane (129, 305). One class of the epithelial Na⁺ channels is a nonselective cation channel (168, 229, 241). Another class of the Na⁺ channels is a highly selective Na⁺ channel (240, 349). These two classes of Na⁺ channels can be inhibited by amiloride (168, 229, 241, 349). In contrast, net K⁺ transport does not occur under normal circumstances. It requires extreme alterations in K⁺ intake to affect net K⁺ secretion or absorption (57). The H⁺-K⁺-ATPase is present in the apical membrane of the IMCDt from rat kidneys (222) and in cultured IMCDt cells (352) and appears to be involved in K⁺ absorption under K⁺ depletion (225). In the basolateral membrane, Ba²⁺-sensitive K⁺ conductance (129, 305), furosemide-sensitive Na⁺-K⁺-2Cl cotransport (108, 258, 390), and DIDS-sensitive HCO₃ conductance (308) are present. There is no evidence for a Cl-conductive pathway in the basolateral membrane (308).

View larger version (33K): [in this window] [in a new window]   Fig. 5. Major transport systems in the inner medullary collecting duct (IMCD). Models are based on studies done in the rat IMCD (108, 168, 225, 229, 240, 241, 258, 305, 349, 352, 390). Definitions are as in Figure 2.

	III. POTASSIUM CHANNELS IN THE COLLECTING DUCT

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Two types of K⁺ channels, low-conductance K⁺ channel and maxi K⁺ channel, have been found in the apical membrane of the CCD of both rats and rabbits (83, 84, 93, 97, 120, 127, 128, 156, 157, 271, 354-360, 364, 365).

The low-conductance K⁺ channel is identified in the apical membrane of the CD cells from both rat (84, 93, 360) and rabbit (271) CCDs. This K⁺ channel is inwardly rectifying with an inward slope conductance of 25 pS and an outward slope conductance of 9 pS at room temperature, and the open probability of the channel is near 0.9 over a wide range of membrane potentials (84, 360). The channel is blocked by Ba²⁺ from outside the cell (84) and by reduced intracellular pH (279, 356, 360) and is permeant to Rb⁺ (84). Furthermore, it is insensitive to Ca²⁺ in the cytoplasmic side (84) and to tetraethylammonium (TEA) from outside the cell (360). Thus the properties of the channels make them strong candidates responsible for K⁺ secretion in the CCD (83, 84). Table 2 summarizes the regulation of the low-conductance K⁺ channel.

The number of low-conductance K⁺ channel at the apical membrane of the CD cell in the rabbit CCD increases during postnatal life most likely to contribute to the maturational increase in net K⁺ secretion (271).

ATP-sensitive K⁺ channels, found in tissues such as heart, pancreatic -cells, skeletal muscles, smooth muscles, central nervous sytem, and kidney, are a family of K⁺ channels defined by their inhibition in response to increased cytosolic ATP concentrations (12, 28, 132, 154, 155, 167). The apical low-conductance K⁺ channel of the CCD is also a member of the ATP-sensitive K⁺ channels. This is supported by several lines of evidence. Channel activity was inhibited by high concentrations of ATP (1 mM) in inside-out patches (356, 360). The application of an inhibitor of ATP-sensitive K⁺ channels, glyburide, inhibited the low-conductance K⁺ channel activity (364), whereas an opener of ATP-sensitive K⁺ channels, cromakalim, antagonized the inhibitory effect of ATP on low-conductance K⁺ channel activity (354). Although millimolar ADP inhibited channel activity, it abolished the inhibitory effect of ATP on channel activity (356, 360). In addition, application of a nonhydrolyzable ATP caused no effect on channel activity (356, 360). Therefore, the cytosolic ATP/ADP ratio rather than the total ATP concentration is the important regulator of the apical low-conductance K⁺ channel (356, 360). In the proximal tubule, basolateral ATP-sensitive K⁺ channel activity is increased by stimulating transcellular Na⁺ transport, which reduces intracellular ATP concentrations (337). If a similar mechanism is present in the CD cell, activation of the basolateral Na⁺-K⁺ pump could consume more ATP and produce more ADP, and the resulting decline in the ATP/ADP ratio would be expected to release the apical K⁺ channel from ATP inhibition. The inhibitory effect of high concentrations of ATP (1 mM) on channel activity in inside-out patches is attenuated by the addition of an exogenous protein kinase A (PKA) catalytic subunit to the bath (356). On the other hand, the channel activity in inside-out patches is restored by low concentrations of ATP (0.05-0.1 mM) in the presence of PKA (356). Thus ATP has dual effects on the channel activity. It has been postulated that ATP at low concentrations is a substrate for PKA that phosphorylates the K⁺ channel to maintain normal function, whereas ATP at high concentrations inhibits the channel activity by the inhibition of the PKA-induced channel phosphorylation (356).

The apical low-conductance K⁺ channel activity declines progressively upon membrane excision in ATP-free solution (356). This channel rundown can be explained by dephosphorylation induced by membrane-bound protein phosphatases, which are okadaic acid sensitive and Mg²⁺ dependent (156, 356).

As mentioned above, K⁺ secretion in the CCD occurs by two separate steps: active uptake of K⁺ into the cell via the basolateral Na⁺-K⁺-ATPase and passive diffusion of K⁺ from the cell to lumen via the apical K⁺ conductance. The tight coupling between the apical K⁺ conductance and the basolateral Na⁺-K⁺-ATPase turnover may play a crucial role in K⁺ secretion. Possible mechanisms that could account for the coupling between the basolateral and apical transport have been proposed. They include ATP/ADP ratio and intracellular Ca²⁺ concentration (366). In the rat CCD, intracellular Ca²⁺ plays a key role in the coupling between the basolateral and apical transporters (366), as shown in the following observations. Inhibition of the basolateral Na⁺-K⁺-ATPase by strophanthidin or by removal of bath K⁺, a manipulation that raises intracellular Ca²⁺ concentrations through a mechanism involving inhibition of the basolateral Na⁺/Ca²⁺ exchange, inhibits apical low-conductance K⁺ channel activity, whereas removal of extracellular Ca²⁺ inhibits this effect. The effect of the pump inhibition on channel activity is mimicked by raising intracellular Ca²⁺ with ionomycin, a Ca²⁺ ionophore. Also, the K⁺ channel is not sensitive to Ca²⁺ in inside-out patches (84). Therefore, the Ca²⁺-induced coupling modulation between the basolateral Na⁺-K⁺-ATPase and the apical low-conductance K⁺ channel is indirect (366). At least two Ca²⁺-dependent signal transduction mechanisms are involved in the inhibitory effect of Ca²⁺ on the channel activity: protein kinase C (PKC) (157, 357, 366) and Ca²⁺/calmodulin-dependent kinase II (157). In addition to the direct effect of PKC on channel activity, PKC also activates phospholipase A₂, which cleaves phospholipids at the sn-2 position to generate lysophospholipids and free fatty acids such as arachidonic acid (13, 98). Arachidonic acid and cis-unsaturated fatty acids are also involved in the downregulation of the apical low-conductance K⁺ channel activity in the rat CCD (355).

The low-conductance K⁺ channel is inactivated by the application of actin filament disruptors cytochalasins B and D (365). The inhibitory effect of cytochalasins on channel activity was blocked by pretreatment with a compound that stabilizes the actin filaments, phalloidin (365). Therefore, the apical low-conductance K⁺ channel activity depends on the integrity of the actin cytoskeleton.

A low-Na⁺ diet (high plasma aldosterone levels) for rats has no effect on the density of the low-conductance K⁺ channel in the rat CCD (84, 246). In contrast to the effects of a low-Na⁺ diet, the density of low-conductance K⁺ channel at the apical membrane of the CCD is elevated in rats adapted to a high-K⁺ diet, which also elevates the endogenous aldosterone levels (360). The reason for the discrepancy in the effects of a low-Na⁺ diet and a high-K⁺ diet on low-conductance K⁺ channel activity is unclear. On the other hand, the mineralocorticoid-induced increase in K⁺ secretion in the rat CCD occurs through an increase in the net driving force for K⁺ exit across the apical membrane, but not through an increase in the apical membrane K⁺ conductance (275). The discrepancy between the two results is unknown.

The maxi K⁺ channels (80-140 pS) are identified at the apical membrane of the CCDs from both rabbits (127, 128, 271) and rats (83, 120, 278). The channels are considerably more abundant on the apical membrane of IC cells than on that of CD cells of both rat and rabbit CCDs (245). They are rarely open at intracellular Ca²⁺ concentration <1 µM and at normal membrane potentials (83, 127, 128). The channels are stimulated by membrane depolarization and by increased cytosolic Ca²⁺ concentrations and are inhibited by Ba²⁺ (83, 127, 128, 278). Channel activity is pH insensitive at high Ca²⁺ concentrations but is decreased by lowering cytosolic pH or by exposure to millimolar concentrations of ATP at more physiologically low Ca²⁺ concentrations (120). Channel activity is also inhibited by quinine, quinidine, and high concentrations of Mg²⁺ (278). The Ca²⁺ channel antagonists verapamil and diltiazem also inhibit this channel activity (278). NH₄⁺ is conducted exclusively by this K⁺ channel (83). Furthermore, the channel activity is also inhibited by the scorpion venom charybdotoxin, but not by the bee venom apamin (278). The channels are blocked by millimolar TEA from outside the cell (83, 278) and are impermeant to Rb⁺ (83). These conductive properties are in sharp contrast to observations from microperfusion studies in which TEA has no effect on either the V_T of the rabbit CCD (83) or the apical membrane voltage of the CD cell in the rat CCD (280), and in which a significant Rb⁺ secretion is present (83, 368). These properies of the maxi K⁺ channels make it unlikely for them to be major candidates for K⁺ secretion in the CCD (83, 84, 245). This channel has also been identified in the amphibian proximal tubule and diluting segments and in many types of excitable cells (359). Table 2 summarizes the regulation of the maxi K⁺ channel.

Stretch activation of the maxi K⁺ channel in either cell-attached or inside-out patches on the rabbit IC cells occurs through a Ca²⁺-independent mechanism when pipette suction is applied (245). When the rat CCD is exposed to hypotonic stress, cell swelling causes an increased intracellular Ca²⁺ concentration, which depends on the extracellular Ca²⁺ concentration (120). At this time, cell swelling stimulates the maxi K⁺ channel activity and hyperpolarizes the membrane potential of the CCD cell (120). Studies in everted, perfused CCDs of rats also demonstrate the presence of apical maxi K⁺ channels whose activity increases with the perfusion of either the lumen with hypotonic saline solutions in the presence of bath vasopressin or the bath with hypotonic solutions (321). Therefore, a possible physiological function of the maxi K⁺ channel may be the reduction of the intracellular K⁺ concentration after cell swelling. This confirms the findings of activation of apical K⁺ conductance of the rabbit CCD during regulatory volume decrease after inhibition of the basolateral Na⁺-K⁺ pump by ouabain (322). The maxi K⁺ channel might also play a role in the flow-dependent K⁺ secretion in the late distal tubule and/or the CCD. Increased uptake of Na⁺, associated with increased delivery of Na⁺, would make the tubule lumen more negative and thereby increase the driving force for K⁺ exit into the lumen. Thus the increased flow rate associated with increased luminal pressure could activate the maxi K⁺ channels, resulting in an increased K⁺ secretion. In fact, in the rabbit CNT apical membrane, the maxi K⁺ channel is responsible for the flow-dependent K⁺ secretion by coupling with the stretch-activated cation channel (328). However, it is presently unknown whether the maxi K⁺ channel in the CCD could also be involved in the flow-dependent K⁺ secretion.

The presence of K⁺ channels in the basolateral membrane of the CD cell allows part of the K⁺ that is taken up into the cell by the Na⁺-K⁺-ATPase to recycle across this membrane (97, 148, 216, 268, 269, 276, 282, 358, 361). In the rat CCD (276), but not in the rabbit CCD (216), this recycling is necessary for maximal reabsorption of Na⁺, because inhibition of the basolateral K⁺ conductance by Ba²⁺ reduces the transport rate of the Na⁺-K⁺-ATPase, and thus Na⁺ reabsorption as well as K⁺ secretion (274).

Two methods have been used to identify basolateral K⁺ channels in the rat CCD. Hirsch and Schlatter (121) have tried to digest the basement membrane of the rat CCD enzymatically by using a combination of in vivo and in vitro enzymatic treatment of the kidney with collagenase and to obtain single kidney tubule cells. They identified two types of basolateral K⁺ channels with low and intermediate conductances. The slope conductance of the low-conductance K⁺ channel was 67 pS in cell-attached patches and 28 pS in excised patches with asymmetrical KCl solutions, whereas the slope conductance of the intermediate-conductance K⁺ channel was 147 pS in cell-attached patches, 85 pS in the excised patches with asymmetrical KCl solutions, and 198 pS in symmetrical high KCl solutions. On the other hand, Wang et al. (367) studied the lateral membrane K⁺ channel of the rat CCD by removing single cells mechanically from the split open tubule with a suction pipette and advancing the patch-clamp electrodes to the exposed lateral membrane. They also identified two types of K⁺ channels with low and intermediate conductances in the lateral membrane of the rat CCD. In cell-attached patches, the slope conductance of the low-conductance K⁺ channel is 27 pS in asymmetrical solutions and 30 pS in symmetrical KCl solutions, whereas the slope conductance of the intermediate-conductance K⁺ channel is 85 pS in symmetrical solutions and 45 pS in asymmetrical solutions (363, 367). The 85-pS intermediate-conductance K⁺ channel described by Wang and co-workers (363, 367) is activated by hyperpolarization and PKA, whereas the intermediate-conductance K⁺ channel described by Hirsch and Schlatter (121, 122) was not affected by either voltage or PKA. Therefore, the two intermediate-conductance K⁺ channels may not be the same channel. On the other hand, the slope conductance of the low-conductance K⁺ channel in the above two studies is different, but it has been suggested that the channel observed in these two studies may be the same, because both studies have found the same channel conductance in excised patches. In addition, both studies have shown that the low-conductance K⁺ channel activity is regulated by cGMP and is not sensitive to either MgATP or PKA (121, 122, 176, 367). The difference between channel conductance in the two studies may be related to the voltage at which it was measured. Table 3 summarizes the regulation of the K⁺ channels in the basolateral membrane.

The low-conductance K⁺ channel described by Wang et al. (367) has a high open probability (~0.8) and is not voltage dependent. The channel activity in excised patches is reduced by the decrease in bath pH from 7.4 to 6.7 (367). With this acidification, a reduction in channel current amplitude is observed (367). The channel activity is also inhibited by bath Ba²⁺ (367) but is not affected by either ATP, TEA, or quinidine (177).

Nitric oxide (NO) has a biphasic effect on the channel activity: low concentrations of NO stimulate the channel activity through a cGMP-dependent process (122, 176), whereas high concentrations of NO inhibit it via a cGMP-independent process. NO reacts with O₂ to form OONO, which inhibits channel activity (178). The basolateral low-conductance K⁺ channel is coupled with the apical Na⁺ channel via Ca²⁺-dependent NO generation (175). PKC is also involved in the activation of the channel: the stimulatory effect of PKC on the channel activity occurs, at least in part, through phosphorylation of NO synthase (177). Although the low-conductance K⁺ channel in the basolateral membrane of the rat CCD has a channel conductance similar to that of the apical low-conductance K⁺ channel, the regulation of the basolateral low-conductance K⁺ channel is in opposite direction to that of the apical low-conductance K⁺ channel: PKC activates the basolateral low-conductance K⁺ channel (177), whereas it inhibits the apical low-conductance K⁺ channel (156, 357) (see Tables 2 and 3).

The 85-pS intermediate-conductance K⁺ channel described by Wang et al. (367) has a low open probability (~0.2) at normal membrane potentials and is voltage dependent so that hyperpolarization activates channel activity. Thus this channel may not be mainly responsible for determining membrane potential under normal conditions, but this hyperpolarization-activated K⁺ channel may be important for the rapid response to the stimulation of the Na⁺-K⁺-ATPase. Ba²⁺ inhibits the channel activity (367). The addition of TEA or quinidine to the bath also inhibits the channel activity in excised patches (363). The channel activity is reduced by decreasing the bath pH from 7.4 to 6.7 (363). With this acidification, this channel showed a reduction in open probability (363). The simultaneous addition of the catalytic subunit of PKA and MgATP to the bath stimulates channel activity in excised patches (363). These characteristics of the channel are similar to those observed in the low-conductance K⁺ channel of the apical membrane of the rat CCD (93, 356). Therefore, PKA-mediated phosphorylation plays an important role in the regulation of the intermediate-conductance K⁺ channel.

The 147-pS conductance K⁺ channel described by Hirsch and Schlatter (121) shows no rectification. This channel is regulated by intracellular pH; reduction in cytosolic pH decreases open probability (121, 279). An inhibition of this channel with Ba²⁺ was observed in excised inside-out and outside-out patches (121). TEA blocked the channel activity in outside-out oriented membranes only (121). Verapamil induced a fast "flicker" block of this channel. This channel was reversibly inhibited by charybdotoxin but not by apamin (120). The channel showed a decrease in open probability with high cytosolic Ca²⁺ concentrations (121). With physiologically low Ca²⁺ concentrations in excised membrane patches, this channel was highly activated (121). This Ca²⁺ dependence is in contrast to the Ca²⁺ dependence of the apical maxi K⁺ channel of which it is activated by increasing cytosolic Ca²⁺ concentrations (120, 127, 128, 278). This channel is not sensitive to ATP (121). In excised patches, this channel is activated by cGMP but is inhibited by an inhibitor of cGMP-dependent protein kinase, KT 5823 (122). Furthermore, this channel activity is stimulated by the addition of a NO donor, nitroprusside (122). Inhibitors of protein phosphatases 1 and 2A, calyculin A and okadaic acid, also increased the channel activity in cell-attached patches (122). The low-conductance K⁺ channel described by Hirsch and Schlatter (121) is very often colocalized with the intermediate-conductance K⁺ channel and have similar properties to those of the intermediate-conductance K⁺ channel (121, 122). Thus the basolateral two K⁺ channels described by Hirsch and Schlatter (121, 122) appear to be regulated in the same way. The only differences between these channels are their conductance properties and their mean open and closed dwell times (121). Therefore, one cannot exclude the possibility that the two K⁺ channels are actually different functional states of one complex transport protein (121, 122).

Several groups have reported clones or partial clones for putative K⁺ channels in the distal tubule and collecting ducts. They include ATP-sensitive K⁺ channels in the distal nephron of rats (ROMK) (27, 123, 392), maxi K⁺ channel -subunit in the rabbit kidney (207), low-conductance K⁺ channel of the basolateral membrane in the mouse M1CCD cell (CCD-IRK3) (373), double-pore K⁺ channels in the rabbit distal nephron (KCNK1) (242), and Shaker-like voltage-gated K⁺ channels in primary cultures of the rabbit distal tubule (KC22) (56), in rabbit renal papillary epithelial cell line GRB-PAP1 (348), and in rabbit renal medulla (rabK_v1.3) (386). Among these cloned K⁺ channels, ROMK channels have been extensively characterized.

A cDNA encoding an inwardly rectifying, ATP-regulated K⁺ channel (ROMK1) (Kir1.1a) was initially isolated by expression cloning from the outer medulla of a rat kidney (123) (Fig. 6A). The ~2-kb cDNA ROMK1 predicts a 45-kDa protein (123). In contrast to channel proteins belonging to the superfamily of voltage-gated and second messenger-gated ion channels, the ROMK1 protein has only two potential membrane-spanning segments (M1 and M1) (123). However, the protein conserves an amino acid segment that is homologous to the pore-forming H5 region of the voltage-gated K⁺ channels (123). In addition, a single putative ATP-binding site (P-loop) that is associated with a cluster of potential phosphorylation sites and basic amino acids may form a regulatory domain (123). Other inwardly rectifying K⁺ channels with a similar topology have been cloned (12, 28, 132, 154, 155, 167) and together with the ROMK1 channel (123) define a new family of K⁺ channels, inwardly rectifying K⁺ channel (IRK) family.

View larger version (20K): [in this window] [in a new window]   Fig. 6. A: schematic representation of the predicted structural model for ROMK channel protein. The nucleotide binding regulatory domain contains a high density of basic residues, a Walker A motif for potential nucleotide binding (PO4 loop) (123), and several potential protein kinase A (PKA; ) and protein kinase C (PKC) phosphorylation sites () (123). The site for N-linked glycosylation (asparagine at position 117) is also shown. B: aligned amino-terminal amino acid sequence for splice varients ROMKI, ROMK2, and ROMK3 (23). Note that ROMK2 lacks the first 19 amino acids found in ROMK1 and ROMK3 contains a 7-amino acid extension, but otherwise they are identical. Asterisks show two potential PKC phosphorylation sites (23).

Furthermore, splice variants of ROMK1 have been identified (27, 392) (Fig. 6B). They display alternative splicing at the 5'-end and give rise to channel proteins differing in their amino-terminal amino acid sequences: ROMK2 (Kir1.1b) lacks the first 19 amino acids of ROMK1, whereas ROMK3 (Kir1.1c) contains a 7-amino acid extension. These alternatively spliced isoforms are differentially expressed along the distal nephron, from the medullary thick ascending limb of Henle's loop (MTAL) to the OMCD (27); ROMK1 transcript is specifically expressed in the CCD and the OMCD (27), and ROMK3 transcript is expressed in the MTAL, macula densa, distal convoluted tubule (DCT), and CNT (27), whereas ROMK2 transcript is widely distributed from the MTAL to the CCD (165). The ROMK protein is also localized at the apical border of the thick ascending limb of Henle's loop (TAL), macula densa, DCT, CNT, CCD, and OMCD (384). Within the CCD and OMCD, this protein is expressed in CD cells, but not in IC cells (384). This localization of ROMK mRNA and protein, together with the observed electrophysiological and regulatory properties of ROMK channels (123, 391, 392), strongly indicates that ROMK forms the low-conductance K⁺ channels identified in the apical membrane of the distal nephron segments. A low level of ROMK expression is observed in the IMCD by tissue and isolated tubule in situ hybridization (165).

ROMK channels expressed in Xenopus oocytes exhibit biophysical properties comparable to those of the low-conductance K⁺ channel identified in the apical membrane of both TAL (25, 361, 362) and CCD (84, 93, 360) of rats. They include a single-channel conductance of 30-40 pS in symmetrical KCl solutions (123, 392), high K⁺ selectivity (123, 392), high channel open probability at physiological potentials (123, 392), weak inward rectification from block by intracellular Mg²⁺ and/or polyamines (47, 228, 392), marked sensitivity to external Ba²⁺ but not to TEA (123), marked sensitivity to intracellular pH (73, 340), inhibition by arachidonic acid (188, 189), channel rundown or loss of channel activity in excised patches in the absence of MgATP that involves dephosphorylation by a protein phosphatase (protein phosphatase 2C in Xenopus oocytes) (203), reactivation of channels after rundown by reexposure to MgATP and catalytic subunit of PKA (203, 204), and inhibition by glibenclamide (i.e., when ROMK2 is coexpressed with cystic fibrosis transmembrane conductance regulator, CFTR) (200). Therefore, ROMK channels are identical to the low-conductance K⁺ channel in the apical membrane of the TAL and CCD. Mutations in the ROMK gene result in one variant of Bartter's syndrome, thus confirming the dependence of NaCl reabsorption in the K⁺ flux mediated by these channels (299). However, the mechanisms whereby the mutation in the ROMK gene impairs K⁺ channel activity remain unknown.

ROMK channels expressed in Xenopus oocytes are regulated by phosphorylation and dephosphorylation processes, with activation of channel activity by PKA (203). The predicted ROMK1 and ROMK2 channel proteins contain only three PKA consensus phosphorylation sites (123) (see Fig. 6A). These PKA sites containing serine residues at positions 25, 200, and 294 are demonstrated to be essential for ROMK2 channel activity (385). The phosphorylation sites on the carboxy-terminal serine residues at positions 200 and 294 modulate the open probability of the channel by regulating the stability of the open state, whereas the phosphorylation site on the amino-terminal serine residue at position 25 determines the number of conducting channels observed at the plasma membrane (181). Also, PKA-induced activation of ROMK1 channel occurs via phosphatidylinositol 4,5-bisphosphate-dependent mechanism (171).

As described above, ROMK channel protein contains a putative ATP-binding site (P-loop) in the carboxy terminus (123) (see Fig. 6A). This loop contains a high density of basic residues, a glycine-rich Walker A motif [GXGX2G]. The Walker A mutation of histidine at position 206 to glycine auguments the ATP sensitivity of ROMK2 (204). Thus the Walker A segment in ROMK2 is involved in MgATP binding inhibition interactions (204).

The common functional property shared by the IRKs is their inwardly rectifying current-voltage relationship. Rectification may be weak or strong and is due to a voltage-dependent inhibition of the channel pore by intracellular Mg²⁺ (194) and polyamines (72, 77, 174). Two members of the IRKs, IRK1 and ROMK1, which share 40% amino acid identity, markedly differ in single-channel K⁺ conductance and in sensitivity to channel inhibition by intracellular Mg²⁺ (171). In voltage-gated channels (15, 190, 330, 387, 388) and in cyclic nucleotide-gated channels (104), the H5 regions are thought to line the pore. Because of sequence homology, the H5 has been suggested to line the pore of IRKs (123). However, the exchange of the H5 region between IRK1 and ROMK1 had no effect on rectification and little or no effect on K⁺ conductance (327). In contrast, the exchange of the amino- and carboxy-terminal regions together transferred Mg²⁺ blockade and K⁺ conductance of IRK1 to ROMK1. The exchange of the carboxy terminus but not the amino terminus caused a similar effect. These findings suggest that the carboxy terminus appears to have a major role in specifying the pore properties of IRKs (327). Furthermore, the mutation of aspartate to asparagine at position 172 within the putative transmembrane domain M2 in IRK1 produced ROMK1-like gating, whereas the reverse mutation in ROMK1, the mutation of asparagine to aspartate at position 172, produced IRK1-like gating (374). Therefore, a single negatively charged amino acid residue seems to be a crucial determinant of gating.

As mentioned above, ROMK1 and ROMK2 channels, when expressed in Xenopus oocytes, have a high sensitivity to internal but not to external pH within the physiological pH range (73, 201, 340). This pH sensitivity of the ROMK1 and ROMK2 channel is similar to that reported for low-conductance K⁺ channels in the apical membrane of the rat CCD (279, 356, 360). When the cytosolic pH is decreased from 7.4 to 7.0, the reduction in channel activity is due primarily to reduction in the number of active channels (i.e., complete channel closure) (201). At cytosolic pH levels below 7.0, the decreased channel activity appears to be a combination of both reduction in the number of open channels together with a modest effect on open probability (201). It has been speculated that any of the nine histidine residues in the ROMK1 sequence may be involved in the pH regulation of the ROMK1 channel (340). When the histidine residue (position 206 in the Walker site) in the carboxy terminus of ROMK (which is involved in MgATP binding inhibition of ROMK channel activity) is mutated to glycine, the curve of pH sensitivity is shifted to the right (201). Furthermore, changing lysine at position 80 to methionine altered the sensitivity of ROMK1 channels to intracellular pH (73). Therefore, the pH-dependent modulation of ROMK may not be entirely attributable to a single amino acid residue (73, 201, 340).

The single N-glycosylation consensus sequence of ROMK1 is located at amino acids 117-119 and has been assigned to the first extracellular loop between the M1 and H5 segments (123) (See Fig. 6A). When glycosylation is inhibited by changing the posision of 117 asparagine to glutamine, or by an inhibition of N-glycosylation with tunicamycin, both whole cell currents and single-channel currents are greatly reduced (284). Thus the N-linked oligosaccharide is involved in the stabilization of the open channel state.

When ROMK1, ROMK2, and ROMK3 channels are expressed in Xenopus oocytes, the ROMK1 channel alone is completely inhibited by arachidonic acid in a manner similar to that of the native channel (188), but not ROMK2 or ROMK3 channels, that lack the serine residue at position 4. ROMK1 variant, in which the amino-terminal animo acids 2-37 were deleted, and a mutant ROMK1, in which the serine residue at position 4 was mutated to alanine, are not sensitive to arachidonic acid (189). Therefore, the phosphorylation of serine residue at position 4 is involved in mediating the effect of arachidonic acid.

Recent evidence suggests that ATP-sensitive K⁺ channels are formed by multimeric subunit interactions. In pancreatic -cells (132, 264), smooth muscle cells (135), cardiac cells (131, 264), and skeletal muscle cells (131, 264), as well as renal distal tubule cells (200), ATP-sensitive K⁺ channels are complexes composed of at least two subunits: the inward-rectifying K⁺ channel subunit and the channel regulator/drug binding subunit. The channel regulator/drug binding subunit belongs to a member of the ATP-binding cassette transporter superfamily with multiple transmembrane-spanning domains and two potential nucleotide-binding folds. This family includes sulfonylurea receptors (SUR1 and SUR2) (2, 8, 131) and CFTR (200). Both types of subunits are necessary for channel functions and sulfonylurea sensitivity (131, 132, 135, 200, 264). For example, in pancreatic -cells, when both subunits (Kir6.2 and SUR) are coexpressed, inwardly rectifying K⁺ channels inhibited by ATP and by sulfonylurea compounds are identified, although neither subunit, when expressed alone, exhibits channel activity (131). Similarly, patch-clamp studies of ROMK2 expressed into Xenopus oocytes demonstrate that coexpression of ROMK2 with CFTR enhances the sensitivity of ROMK2 to the sulfonylurea compound (glibenclamide), although, when expressed alone, ROMK2 is relatively insensitive to glibenclamide (200). Therefore, CFTR not only enhances sulfonylurea sensitivity of ROMK2 but also modulates the outwardly rectifying Cl channel in cultured airway cells (289). The first nucleotide binding fold of the CFTR protein is necessary for the CFTR-ROMK2 interaction that confers sulfonylurea sensitivity (202).

	IV. CONTROL OF POTASSIUM TRANSPORT IN THE COLLECTING DUCT

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The ICT and CCD are the main sites of control of renal K⁺ excretion. Both nephron segments are distinguished by marked cell heterogeneity, and the net transport of K⁺, either in the secretory or reabsorptive direction, results from varying rates of K⁺ secretion through CD cells and K⁺ reabsorption through IC cells.

Luminal factors include the rate of distal fluid and Na⁺ delivery and the composition of fluid entering the distal tubule or CCD (luminal Na⁺ and Cl concentrations) (383). Peritubular factors include changes in ion concentrations (K⁺, H⁺, and HCO₃) and hormones (aldosterone and vasopressin) (383). Systemic changes that affect these factors include adrenal steroids, K⁺ intake, acid-base balance, and vasopressin (383).

Enhanced delivery of fluid and Na⁺ to the distal tubule is one of the most powerful and frequently activated mechanisms of distal tubule K⁺ secretion. Several manipulations increase distal fluid delivery, including osmotic diuresis by mannitol, diuretic therapy, including furosemide and thiazide diuretics, metabolic alkalosis, prolonged diabetes insipidus, postobstructive diuresis, and contralateral nephrectomy. It is important to recognize that sustained diuresis often leads to severe K⁺ depletion. K⁺ adaptation by a high-K⁺ diet (143, 184, 308) or after a mineralocorticoid administration (300, 303, 306) magnifies the response to increases in fluid delivery, whereas K⁺ depletion by a low-K⁺ diet blunts the kaliuretic response to diuresis (143, 184).

Microperfusion studies of the isolated CCD from rabbit kidneys have shown that no relationship exists between K⁺ secretion and perfusion rates in the range of 4-16 nl/min (315). On the other hand, K⁺ secretion is a flow-dependent process below 5-6 nl/min but is saturated at flows of >5-6 nl/min (70). In contrast, flow-dependent K⁺ secretion in the rat distal tubule shows no such saturation even at flows of 30 nl/min (99-101, 143, 159). This discrepancy may reflect a higher maximal capacity for K⁺ secretion in the rat distal tubule than the rabbit CCD (99-101, 143, 159).

Two separate factors contribute to the markedly enhanced rate of K⁺ secretion following enhanced delivery of fluid and Na⁺ into the distal tubule. First, when flow increases in the distal tubule, the luminal K⁺ concentration decreases moderately (100, 159). However, the reduction of luminal K⁺ concentration is proportionally much smaller than the increase in flow rate, thereby K⁺ secretion increases. The decline in the luminal K⁺ concentration may steepen the chemical concentration gradient of K⁺ across the apical membrane and facilitate K⁺ secretion into the lumen (100). Basolateral K⁺ uptake must increase sharply to maintain cell K⁺ concentration. This idea is based on the data from the rat DCT (100, 159). In contrast, microperfusion studies of the isolated rabbit CCD have shown that there is no significant effect of flow rate on K⁺ secretion when tubules were perfused with a 10-fold increase in the luminal K⁺ concentration (70). The second factor responsible for increased K⁺ secretion, associated with enhanced flow rates, may be the elevation of luminal Na⁺ concentrations following NaCl loading and administration of loop or thiazide diuretics. During NaCl diuresis, Na⁺ delivery into the distal nephron enhances and increases Na⁺ entry into cells across the apical membrane, facilitates the basolateral Na⁺-K⁺ exchange, and thereby increased Na⁺ reabsorption occurs (143, 159). As a result, cell K⁺ concentration would be expected to increase, stimulating the movement of K⁺ from cell to lumen. Also, increased Na⁺ entry into the cell across the apical membrane could cause the apical membrane to depolarize, resulting in an enhanced K⁺ secretion across this membrane. During saline diuresis, luminal K⁺ concentrations undergo only small changes (143), and electron-probe studies have confirmed that K⁺ gradient across the apical membrane of the CD cell remains unaltered (20). Thus the K⁺ gradient across the apical membrane would not be changed. The inhibition of Na⁺ entry into the cell with luminal amiloride inhibited flow-dependent K⁺ secretions in the distal tubule (184). In the isolated perfused rabbit CCD, the rate of Na⁺ reabsorption is also dependent on flow rates and is closely related to that of K⁺ secretion (70).

Malnic et al. (184) distinguished the relevant processes at low and high flow rates. At low flow rates, K⁺ secretion causes significant increase in luminal K⁺ concentrations, which decreases the driving force for K⁺ secretion across the apical membrane. As a consequence, the net flow of K⁺ into the lumen is limited and is far removed from the maximal capacity of the Na⁺-K⁺ transport system. At high flow rates, luminal K⁺ concentration decreases, causing an increased K⁺ chemical gradient. Additionally, the gradual saturation of Na⁺ reabsorption with increased Na⁺ delivery causes an increase in luminal Na⁺ concentrations, with consequent depolarization of the apical membrane also favoring K⁺ secretion. However, the ultimate limit in Na⁺ reabsorption will eventually cause saturation of K⁺ secretion. The continued increase in Na⁺ transport in free-flow experiments may explain the lack of saturation in K⁺ secretion.

Chronic administration of furosemide to rats in vivo caused an increased K⁺ excretion. Under these conditions, K⁺ secretion and Na⁺ reabsorption in the distal tubule were enhanced (309). At the same time, Na⁺-K⁺-ATPase activity in the CCD (69, 277) and DCT (277) was increased. The increased Na⁺-K⁺-ATPase activity is accompanied by amplification of basolateral membrane areas of the DCT cells, CNT cells, and CD cells of the CCD (137, 140). These functional, enzymatic, and morphological alterations by furosemide administration occur independent of plasma aldosterone (69, 140, 309). The increased Na⁺ delivery to the distal nephrons contributes to these changes by furosemide (137, 140, 277).

Several animal models of reduced renal mass demonstrate that K⁺ balance can be maintained effectively, even when the number of nephrons is reduced drastically, due to increased excretions of K⁺ by the remaining nephrons (117, 160, 282, 294). This adaptive response can be attributed largely to enhanced secretions of K⁺ by the ICT and CCD (21, 81, 160, 294). The CCDs from remnant kidneys after a reduction of the renal mass exhibit an adaptive increase in Na⁺ reabsorption (342) and K⁺ secretion (81). These changes are accompanied by an increase in Na⁺-K⁺-ATPase activity (210, 276) and an amplification of the basolateral membrane area of the CD cell (389). The CCDs from remnant kidneys in rabbits, 14 days after uninephrectomy, showed structural hypertrophy and increases in apical Na⁺ and K⁺ conductances, as well as in basolateral Na⁺-K⁺ pump activity and K⁺ conductance, independently of plasma aldosterone (61). Because the initial effect of the nephrectomy on the CD cell is an increase in the apical Na⁺ conductance and the secondary effects are increases in the apical K⁺ conductance and the basolateral Na⁺-K⁺ pump activity and K⁺ conductance (215), increased Na⁺ delivery into the CD cell through increased glomerular filtration rate can stimulate K⁺ secretion. Similar electrical changes have been observed in the CCDs from untouched contralateral kidneys 24 h after unilateral ureteral obstruction (222). The mechanisms for the tight coupling between the basolateral Na⁺-K⁺ pump activity and the apical cation conductances are still unclear at present.

Ureteral obstruction causes abnormalities in Na⁺ (39, 144, 262) and water (39) conservation and in H⁺ (255, 262, 332) and K⁺ (144, 262) secretion in the distal nephron segments, including the CCD. The in vitro microperfusion studies of the rabbit CCD have demonstrated that ureteral obstruction leads to decreases in the lumen-negative V_T (39, 109) and in Na⁺ reabsorption (39). Decreased Na⁺-K⁺-ATPase activity (262) and Na⁺-K⁺ pump in situ turnover (144) are observed in the CCDs from obstructed rat kidneys. Microelectrode studies of the isolated perfused CCD from obstructed kidneys 24 h after ureteral obstruction show that apical membrane Na⁺ and K⁺ conductances as well as basolateral Na⁺-K⁺ pump activity and K⁺ conductance are decreased (222). One of the factors suggested to be responsible for the decreased Na⁺ and K⁺ transports in the CCD after ureteral obstruction is increased intraluminal pressure, since the decreased Na⁺ and K⁺ transport properties of the CD cell in the CCD after ureteral obstruction is partially restored by renal decapsulation (213), a maneuver that partially blocks the increase in renal pressure (111, 142). In addition, other factors that may affect Na⁺ and K⁺ transport in the CCD of obstructed kidneys are a decreased flow rate (70), an increased prostaglandin production (63), and/or a resistance to aldosterone and vasopressin (147).