Polarized trafficking and surface expression of the AQP4 water channel are coordinated by serial and regulated interactions with different clathrin-adaptor complexes.

Aquaporin 4 (AQP4) is the predominant water channel in the brain. It is targeted to specific membrane domains of astrocytes and plays a crucial role in cerebral water balance in response to brain edema formation. AQP4 is also specifically expressed in the basolateral membranes of epithelial cells. However, the molecular mechanisms involved in its polarized targeting and membrane trafficking remain largely unknown. Here, we show that two independent C-terminal signals determine AQP4 basolateral membrane targeting in epithelial MDCK cells. One signal involves a tyrosine-based motif; the other is encoded by a di-leucine-like motif. We found that the tyrosine-based basolateral sorting signal also determines AQP4 clathrin-dependent endocytosis through direct interaction with the mu subunit of AP2 adaptor complex. Once endocytosed, a regulated switch in mu subunit interaction changes AP2 adaptor association to AP3. We found that the stress-induced kinase casein kinase (CK)II phosphorylates the Ser276 immediately preceding the tyrosine motif, increasing AQP4-mu 3A interaction and enhancing AQP4-lysosomal targeting and degradation. AQP4 phosphorylation by CKII may thus provide a mechanism that regulates AQP4 cell surface expression.

Potentiation of receptor-mediated cAMP production: role in the cross-talk between vasopressin V1a and V2 receptor transduction pathways.

Cross-talk between the phospholipase C and adenylyl cyclase signalling pathways was investigated in Chinese hamster ovary (CHO) cells transfected with the V1a and V2 vasopressin receptors. Cell lines expressing V1a, V2, or both V1a and V2 receptors, were established and characterized. Stimulation of V2 receptors by vasopressin induced a dose-dependent increase in cAMP accumulation, whereas stimulation of V1a receptor resulted in an increase in intracellular calcium without any change in basal cAMP. The simultaneous stimulation of V2 and V1a receptors by vasopressin elicited an intracellular cAMP accumulation which was twice that induced by stimulation of V2 receptor alone with deamino-[d-Arg8]vasopressin. This potentiation between V1a and V2 receptors was mimicked by activation of protein kinase C (PKC) with PMA, and was suppressed when PKC activity was inhibited by bisindolylmaleimide. The potentiation was observed in the presence or absence of 1 mM 3-isobutyl-1-methylxanthine, a phosphodiesterase inhibitor, implying that an alteration in cAMP hydrolysis was not involved. Vasopressin, as well as PMA, had no effect on the forskolin-induced cAMP accumulation, suggesting that PKC did not directly stimulate the cyclase activity. On the other hand, vasopressin, like PMA, potentiated the cAMP accumulation induced by cholera toxin, an activator of Galphas protein. These results suggest that, in CHO cells, vasopressin V1a receptor potentiates the cAMP accumulation induced by the V2 receptor through a PKC-dependent increase in the coupling between Gs protein and adenylyl cyclase.

Angiotensin II potentiates vasopressin-dependent cAMP accumulation in CHO transfected cells. Mechanisms of cross-talk between AT1A and V2 receptors.

The V2 vasopressin and the AT1A angiotensin II receptors are respectively coupled to the adenylyl cyclase and the phosphoinositide pathways. The cross-talk between these two receptors and their transduction pathways were investigated in CHO cells transfected with cDNA of both AT1A and V2 receptors. In these cells, angiotensin II induced an increase in intracellular calcium, and vasopressin a rise in intracellular cAMP accumulation. The simultaneous addition of angiotensin II and vasopressin potentiated the production of cAMP by the V2 receptor. This potentiation was dose-dependent and, at a concentration of 10(-7) M angiotensin II, the accumulation of cAMP was 4-fold greater than that induced by 10(-7) M vasopressin alone. Such cross-talk occurred in the presence and absence of cyclic nucleotide phosphodiesterase inhibitors, indicating that inhibition of phosphodiesterase activity was not the principal cause of potentiation. This was confirmed by the absence of calcium-inhibitable isoforms of phosphodiesterases in CHO cells. The addition of angiotensin II to forskolin, which stimulates the adenylyl cyclase, did not modify the production of cAMP. Phorbol 12-myristate 13-acetate (PMA), an activator of protein kinase C (PKC), partially mimicked, and staurosporine, an inhibitor of PKC, partially inhibited the effect of angiotensin II on vasopressin. Chelation of intracellular calcium with BAPTA-AM markedly reduced the potentiation of V2 receptor by angiotensin II. However, increase in intracellular calcium with thapsigargin did not modify the cAMP accumulation induced by vasopressin. It was concluded that, in CHO cells, activation of the AT1A receptor by angiotensin II potentiates the V2 receptor through activation of protein kinase C in the presence of intracellular calcium at a step located between the receptor and the adenylyl cyclase.

The C-terminal third intracellular loop of the rat AT1A angiotensin receptor plays a key role in G protein coupling specificity and transduction of the mitogenic signal.

To identify the role(s) of the third intracellular loop of the angiotensin II (AngII) type 1A (AT1A) receptor in G protein coupling specificity and receptor activation, several chimerae were constructed and characterized. The cDNA sequence encoding the C-terminal segment of the third intracellular loop of the AT1A receptor (residues 234-240) was replaced with the homologous regions of the alpha1B adrenergic (alpha1B-AR), the beta2 adrenergic (beta2-AR), and the AngII type 2 (AT2) receptors. These chimeric receptors were stably expressed in Chinese hamster ovary cells, and their pharmacological and functional properties were characterized, including AngII-induced inositol phosphate and cyclic AMP (cAMP) productions, [3H]thymidine incorporation into DNA, and internalization. The affinities of these chimeric receptors for [Sar1]AngII, [Sar1,Ile8]AngII, and losartan were essentially normal; however, the affinity of these mutants was increased by a factor of 10-40 for the AT2-specific ligand CGP42112A. The functional properties of the alpha1B-AR chimera were essentially identical to those of the wild type AT1A receptor. On the other hand, replacement with the beta2-AR segment produced a partial reduction of the inositol phosphate production, a measurable AngII-induced cAMP accumulation, a reduced internalization, and a total impairment to transduce the mitogenic effect of AngII. The AT2 chimera presented a normal internalization, but was inactive in all the other functional tests. In conclusion, the distal segment of the third intracellular loop of the rat AT1A receptor plays a pivotal role in coupling selectivity and receptor signaling via G protein(s) as well as in the activation of the specific signaling pathways involved in the mitogenic actions of AngII.

Vasopressin V2 receptor mRNA expression and cAMP accumulation in aging rat kidney.

The ability of the kidney to regulate water balance is impaired with age, although the secretion of vasopressin is maintained in senescent animals. This suggests that the cellular response to antidiuretic hormone is reduced in aging kidney. To test this hypothesis, the relationship between the expression of the vasopressin. V2 receptor mRNA and adenosine 3',5'-cyclic monophosphate (cAMP) accumulation was investigated in the medullary thick ascending limb of Henle's loop (MTAL) of adult and aging rats. Tubular suspensions of MTAL were prepared from 10- and 30-mo-old female WAG/Rij rats. The accumulation of cAMP for maximal concentration of vasopressin was 34% larger in adult than in old animals (9.5 +/- 0.5 pmol/4 min, n = 16, and 7.1 +/- 0.6 pmol/4 min, n = 12, respectively). The concentration of vasopressin corresponding to half-maximal stimulation was similar in the two groups (0.66 +/- 0.20 and 0.52 +/- 0.09 nmol, n = 5, in adult and old animals), indicating comparable sensitivity of the renal cells with age. The age-related impaired response to vasopressin of the V2 receptor was specific for females and was not observed in males. Direct stimulation of adenylyl cyclase by forskolin induced a comparable accumulation of cAMP in adult and senescent rats. The V2 receptor mRNA level in the MTAL was constant between 10 and 30 mo whether the animals were normally hydrated or dehydrated for 2 days. These data indicate that, in MTAL, the age-related impaired cAMP accumulation by vasopressin would be linked to a change either in the translation of V2 mRNA or in posttranslational processing mechanisms or in the coupling between the V2 receptor and adenylyl cyclase.

Renin gene expression in the aging kidney: effect of sodium restriction.

The activity of the renin-angiotensin system as well as the ability of the kidney to retain sodium following salt restriction are reduced with age. The relationship between these age-related changes in renal function and the renin gene expression was presently investigated. The concentrations of renin and its mRNA were measured in kidney of 10- and 30-month-old control female WAG/Rij rats and of animals which were salt restricted for 4 days. In the senescent rats, the kidney renin concentration, like the plasma concentration of angiotensin II, was half that in adult rats. The intrarenal content of renin mRNA did not differ between 10- and 30-month-old animals, suggesting that the transcriptional rate of the renin gene is unchanged with age. During the early phase of adaptation to sodium depletion, the systemic angiotensin II concentration was not modified in either age groups. Four-days salt restriction did not significantly change the renal storage of renin. In contrast, this short term salt restriction induced a 2.3-fold increase in the renin mRNA in adult kidney, and a 1.9-fold increase in the senescent kidney. These data suggest that the age-related decrease in renal concentration of renin is linked to a modification in the rate of translation of renin mRNA, or to an alteration in the protein maturation. The difference in adaptation to the early phase of salt restriction with age should not be linked to changes in renin gene transcription, but more likely to a change in the tissue response to the local renin-angiotensin system.