Functional evidence for the regulation of cytosolic Ca2+ activity via V1A-receptors and beta-adrenoceptors in rat CCD

Vasopressin Increases Urinary Acidification via V1a Receptors in Collecting Duct Intercalated Cells

BACKGROUND

Antagonists of the V1a vasopressin receptor (V1aR) are emerging as a strategy for slowing progression of CKD. Physiologically, V1aR signaling has been linked with acid-base homeostasis, but more detailed information is needed about renal V1aR distribution and function.

METHODS

We used a new anti-V1aR antibody and high-resolution microscopy to investigate Va1R distribution in rodent and human kidneys. To investigate whether V1aR activation promotes urinary H⁺ secretion, we used a V1aR agonist or antagonist to evaluate V1aR function in vasopressin-deficient Brattleboro rats, bladder-catheterized mice, isolated collecting ducts, and cultured inner medullary collecting duct (IMCD) cells.

RESULTS

Localization of V1aR in rodent and human kidneys produced a basolateral signal in type A intercalated cells (A-ICs) and a perinuclear to subapical signal in type B intercalated cells of connecting tubules and collecting ducts. Treating vasopressin-deficient Brattleboro rats with a V1aR agonist decreased urinary pH and tripled net acid excretion; we observed a similar response in C57BL/6J mice. In contrast, V1aR antagonist did not affect urinary pH in normal or acid-loaded mice. In ex vivo settings, basolateral treatment of isolated perfused medullary collecting ducts with the V1aR agonist or vasopressin increased intracellular calcium levels in ICs and decreased luminal pH, suggesting V1aR-dependent calcium release and stimulation of proton-secreting proteins. Basolateral treatment of IMCD cells with the V1aR agonist increased apical abundance of vacuolar H⁺-ATPase in A-ICs.

CONCLUSIONS

Our results show that activation of V1aR contributes to urinary acidification via H⁺ secretion by A-ICs, which may have clinical implications for pharmacologic targeting of V1aR.

Vasopressin and the regulation of aquaporin-2

Water excretion is regulated in large part through the regulation of osmotic water permeability of the renal collecting duct epithelium. Water permeability is controlled by vasopressin through regulation of the water channel, aquaporin-2 (AQP2). Two processes contribute: (1) regulation of AQP2 trafficking to the apical plasma membrane; and (2) regulation of the total amount of the AQP2 protein in the cells. Regulation of AQP2 abundance is defective in several water-balance disorders, including many polyuric disorders and the syndrome of inappropriate antidiuresis. Here we review vasopressin signaling in the renal collecting duct that is relevant to the two modes of water permeability regulation.

Mechanism of vasopressin-induced contraction of renal medullary interstitial cells

BACKGROUND/AIMS

Previous studies have identified a contractile function for renomedullary interstitial cells (RMIC). Such studies focused on the mechanism of endothelin-1-induced RMIC contraction; however, vasopressin (AVP) was also noted to contract RMIC. Since AVP-induced RMIC contraction may be relevant to the medullary effects of AVP on urinary concentration, these initial observations have been extended to examination of the mechanism of AVP-induced RMIC contraction.

METHODS

Cultured rat RMIC were exposed to AVP and other agents, and examined using video microscopy.

RESULTS

AVP caused a slowly developing and dose-dependent reduction in RMIC surface area. AVP-induced RMIC contraction was abolished by blockade of V1, but not V2, receptors. Nifedipine and nickel reduced AVP-stimulated RMIC contraction, indicating that this effect is dependent upon dihydropyridine-sensitive calcium channels. H7, a protein kinase C inhibitor, completely abrogated AVP action, while the nitric oxide synthase inhibitor, NMMA, had no effect. Indomethacin enhanced AVP-induced RMIC contraction, and addition of PGE2 together with indomethacin reduced AVP action.

CONCLUSION

These data indicate that AVP potently contracts RMIC via V1 receptor stimulation of PKC and intracellular calcium accumulation, and that AVP-stimulated prostaglandin production downregulates the contractile effect of AVP on RMIC. AVP modulation of RMIC contraction may be involved in the regulation of urinary concentration.

Protein kinase C-mediated inhibition of renal Ca2+ ATPase by physiological concentrations of angiotensin II is reversed by AT1- and AT2-receptor antagonists

Angiotensin II (Ang II) increases the cytosolic Ca2+ concentration in different cell types. In this study, we investigate the effect of Ang II on the Ca2+ ATPase of purified basolateral membranes of kidney proximal tubules. This enzyme pumps Ca2+ out of the cytosol in a reaction coupled to ATP hydrolysis, and it is responsible for the fine-tuned regulation of cytosolic Ca2+ activity. Ca2+-ATPase activity is inhibited by picomolar concentrations of Ang II, with maximal inhibition being attained at approximately 50% of the control values. The presence of raising concentrations (10(-11) to 10(-7) M) of losartan (an AT1-receptor antagonist) or PD123319 (an AT2-receptor antagonist) gradually reverts inhibition by Ang II. Both the phospholipase C (PLC) inhibitor U-73122 (10(-6) M) and the inhibitor of protein kinase C (PKC) staurosporine (10(-7) M) prevent inhibition of the Ca2+ pump by Ang II. Incubation of the previously isolated membranes with a PKC activator-the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (10(-8) M)-mimics the inhibition found with Ang II, and the effects of the compounds are not additive. Taken as a whole, these results indicate the Ang II inhibits Ca2+-ATPase by activation of a PKC system present in primed state in these membranes after binding of the hormone to losartan- and PD123319-sensitive receptors coupled to a PLC. Therefore, inhibition of the basolateral membrane Ca2+-ATPase by kinase-mediated phosphorylation appears to be one of the pathways by which Ang II promotes an increase in the cytosolic Ca2+ concentration of proximal tubule cells.

Myocardial infarction non-invasively induced in rabbits by administering isoproterenol and vasopressin: protective effects exerted by verapamil+

Myocardial infarction is usually induced in small animals by means of invasive procedures: the aim of this study was to cause heart necrosis lesions by non-invasive means. We injected rabbits with isoproterenol (3 mg/kg, i.p.) and vasopressin (0.3 mg/kg/5 min, i.v.) alone and in combination, and studied their effects on myocardial histology, electrocardiographic profiles, the appearance of the plasma cardiac necrosis marker c-troponin I (c-TPN I), hemodynamic parameters (blood pressure, heart rate), the coagulative process partial throboplastine time (PTT), and plasma nitric oxide (NO) levels. In the rabbits treated with vasopressin alone, the ischemic damage was associated with a decrease in NO values, and the appearance of electrocardiographic T-wave inversion and low plasma c-TPN I levels, whereas the animals treated with isoproterenol alone had necrotic bands in the myocardium, plasma c-TPN I, and electrocardiographic modifications (ST-segment changes and T-wave inversion). Combined treatment increased myocardial alterations such as contraction band necrosis, induced the appearance of specific hypoxic lesions such as areas of coagulative necrosis and leukocyte infiltration, and led to higher plasma c-TPN I levels and altered ECG profiles. Both drugs favored a decrease in plasma NO values and further alterations in hemodynamic parameters, such as higher blood pressure and greater procoagulant activity. The myocardial necrosis and modified cardiovascular parameters were attributed to calcium activated processes and the decrease in NO levels. As this model of myocardial damage involves the use of drugs that facilitate the opening of L-calcium channels, we also investigated their effects on cardiovascular parameters and heart histology after pretreatment with the calcium antagonist verapamil; this drug protected against the appearance of histological myocardial lesions, electrocardiographic alterations and high plasma c-TPN I levels, and prevented the hemodynamic and procoagulation changes, but did not affect the decrease in plasma NO values. The protective effects were attributed to the drug's calcium antagonist activity. In conclusion, the injection of isoproterenol and vasopressin induces a myocardial infarction non-invasively and seems to be suitable for studying early myocardial ischemic lesions and the effects of drugs interfering with myocardial damage and its related phenomena.

Temperature-modulated diversity of TRPV4 channel gating: activation by physical stresses and phorbol ester derivatives through protein kinase C-dependent and -independent pathways

The TRPV4 calcium-permeable channel was cloned from mouse kidney M-1 cells, and the effect of temperature modulation on channel gating/activation by physical and chemical signals was evaluated. A TRPV4 cDNA construct with a C-terminal V5 epitope was stably transfected into human embryonic kidney (HEK) 293 and Chinese hamster ovary cells resulting in high levels of expression at the plasma membrane. Channel activation was assessed from changes in calcium influx (fura-2 fluorescence measurements) or whole cell currents (patch clamp analysis). At room temperature (22-24 degrees C), exposure of TRPV4-transfected cells to hypotonic medium (225 mOsm/liter) or a non-protein kinase C (PKC)-activating phorbol ester derivative, 4alpha-phorbol 12,13-decanoate (100 nm), induces modest channel activation, whereas phorbol 12-myristate 13-acetate (100 nm), a PKC-activating phorbol ester, and shear stress (3-20 dyne/cm2) had minimal or no effect on channel activation. In contrast, at elevated temperatures (37 degrees C) the channel was rapidly activated by all stimuli. Inhibition of PKC by calphostin C (50 nm) or staurosporine (500 nm) abolished phorbol 12-myristate 13-acetate-induced activation of the channel without affecting the response to other stimuli. Ruthenium red (1 microm) effectively blocked the channel activity by all stimuli. It is concluded that temperature is a critical modulator of TRPV4 channel gating, leading to activation of the channel by a diverse range of microenvironmental chemical and physical signals utilizing a least two transduction pathways, one PKC-dependent and one PKC-independent. The convergence of multiple signals and transduction pathways on the same channel indicate that the channel functions as a molecular integrator of microenvironmental chemical and physical signals.

Protein kinase A-independent activation of ERK and H,K-ATPase by cAMP in native kidney cells: role of Epac I

This study aimed at determining the signaling pathways underlying calcitonin- and isoproterenol-induced stimulation of H,K-ATPase in rat renal collecting duct. H,K-ATPase activity was determined in microdissected collecting ducts preincubated with or without either specific inhibitors or antibodies directed against intracellular signaling proteins. Transient cell membrane permeabilization with streptolysin-O allowed intracellular access of antibodies. The stimulation of H,K-ATPase by calcitonin and isoproterenol was mimicked by cAMP analogues and was abolished by adenylyl cyclase inhibition. Protein kinase A inhibition abolished isoproterenol but not calcitonin effect on H,K-ATPase. Calcitonin increased the phosphorylation of extracellular signal-regulated kinase (ERK) in a protein kinase A-independent manner, and the inhibition of the ERK phosphorylation prevented the stimulation of H,K-ATPase by calcitonin. Antibodies directed against either the cAMP-activated guanine-nucleotide exchange factor Epac I, the monomeric G protein Rap-1 or the kinase Raf-B, curtailed the stimulation of H,K-ATPase by calcitonin, whereas antibodies against the related monomeric G protein Ras or kinase Raf-1 had no effect. In conclusion, calcitonin stimulates H,K-ATPase through a cAMP/Epac I/Rap-1/Raf-B/ERK cascade.

Nifedipine-activated Ca(2+) permeability in newborn rat cortical collecting duct cells in primary culture

To characterize Ca(2+) transport in newborn rat cortical collecting duct (CCD) cells, we used nifedipine, which in adult rat distal tubules inhibits the intracellular Ca(2+) concentration ([Ca(2+)](i)) increase in response to hormonal activation. We found that the dihydropyridine (DHP) nifedipine (20 microM) produced an increase in [Ca(2+)](i) from 87.6 +/- 3.3 nM to 389.9 +/- 29.0 nM in 65% of the cells. Similar effects of other DHP (BAY K 8644, isradipine) were also observed. Conversely, DHPs did not induce any increase in [Ca(2+)](i) in cells obtained from proximal convoluted tubule. In CCD cells, neither verapamil nor diltiazem induced any rise in [Ca(2+)](i). Experiments in the presence of EGTA showed that external Ca(2+) was required for the nifedipine effect, while lanthanum (20 microM), gadolinium (100 microM), and diltiazem (20 microM) inhibited the effect. Experiments done in the presence of valinomycin resulted in the same nifedipine effect, showing that K(+) channels were not involved in the nifedipine-induced [Ca(2+)](i) rise. H(2)O(2) also triggered [Ca(2+)](i) rise. However, nifedipine-induced [Ca(2+)](i) increase was not affected by protamine. In conclusion, the present results indicate that 1) primary cultures of cells from terminal nephron of newborn rats are a useful tool for investigating Ca(2+) transport mechanisms during growth, and 2) newborn rat CCD cells in primary culture exhibit a new apical nifedipine-activated Ca(2+) channel of capacitive type (either transient receptor potential or leak channel).

A simplified method for isolation of large numbers of defined nephron segments

We describe a simplified method for the isolation of large numbers of nephron segments from rat and rabbit kidneys. In contrast to most previous protocols, the kidneys are not perfused. After removal from the animal, the kidney is sliced and torn in pieces that are subsequently digested in culture medium containing 0.5 mg/ml of collagenase at 37 degrees C. If the preparation is agitated only very gently and infrequently, then the tissue gradually falls apart into a suspension containing long nephron fragments, often consisting of multiple connected segments. These are easily sorted into homogeneous segment populations that can be used for enzyme assays, protein extraction for immunoblotting, and RNA extraction for reverse transcription-polymerase chain reaction, all of which have been done successfully in our laboratory. For comparison, we have also examined cortical collecting tubule segments and cells prepared by the more rigorous protocol described previously (E. Schlatter, U. Fröbe, and R. Greger. Pflügers Arch. 421: 381-387, 1992). Even after the isolation of single cells in a Ca2+-free medium, the cells maintain their normal architecture and a distinct separation of apical and basolateral membranes.

Receptors for bradykinin and prostaglandin E2 coupled to Ca2+ signalling in rat cortical collecting duct

In freshly isolated rat cortical collecting ducts (CCD) we measured intracellular Ca2+ activity ([Ca2+]j) with the Fura-2 method. Bradykinin (BK) induced a transient and biphasic increase in [Ca2+]j. This increase was concentration dependent and was half maximal at a concentration of 15 nM. The B2 receptor antagonist HOE 140 (100 nM, n = 6) completely abolished BK (100 nM) induced increase in [Ca2+]j. The B1 receptor agonist des-Arg9-bradykinin (100 nM, n = 4) had no effect on [Ca2+]j. In the absence of extracellular Ca2+, the maximal increase in [Ca2+]j, induced by BK was diminished and the secondary plateau phase was completely abolished. Prostaglandin E2 (PGE2) elevated [Ca2+]j, also concentration-dependently and biphasically. A half maximal effect was reached with 1 nM PGE2. The secondary plateau phase was absent when extracellular Ca2+ was removed. Sulprostone (100 nM, n = 6) mimicked the PGE2 (100 nM) induced increase in [Ca2+]j. The effect of BK (100 nM) on [Ca2+]j was not inhibited by the cyclooxygenase inhibitor indomethacin (10 microM, n = 5). Dopamine (1 microM, n = 4) did not significantly alter [Ca2+]j. BK and PGE2 regulate [Ca2+]j in the rat CCD via release of Ca2+ from intracellular Ca2+ stores as well as via Ca2+ influx from extracellular space. BK directly modulates [Ca2+]j, through B2 receptors. EP1 receptors are most likely to be responsible for the PGE2 induced increase in [Ca2+]j.