Altered protein kinase C activation of Na+/Ca2+ exchange in mesangial cells from salt-sensitive rats

Sodium Glucose Cotransporter 2 (SGLT2) Plays as a Physiological Glucose Sensor and Regulates Cellular Contractility in Rat Mesangial Cells

PURPOSE

Mesangial cells play an important role in regulating glomerular filtration by altering their cellular tone. We report the presence of a sodium glucose cotransporter (SGLT) in rat mesangial cells. This study in rat mesangial cells aimed to evaluate the expression and role of SGLT2.

METHODS

The SGLT2 expression in rat mesangial cells was assessed by Western blotting and reverse transcription-polymerase chain reaction (RT-PCR). Changes in the mesangial cell surface area at different glucose concentrations and the effects of extracellular Na+ and Ca2+ and of SGLT and Na+/Ca2+ exchanger (NCX) inhibitors on cellular size were determined. The cellular sizes and the contractile response were examined during a 6-day incubation with high glucose with or without phlorizin, an SGLT inhibitor.

RESULTS

Western blotting revealed an SGLT2 band, and RT-PCR analysis of SGLT2 revealed the predicted 422-bp band in both rat mesangial and renal proximal tubular epithelial cells. The cell surface area changed according to the extracellular glucose concentration. The glucose-induced contraction was abolished by the absence of either extracellular Na+ or Ca2+ and by SGLT and NCX inhibitors. Under the high glucose condition, the cell size decreased for 2 days and increased afterwards; these cells did not contract in response to angiotensin II, and the SGLT inhibitor restored the abolished contraction.

CONCLUSIONS

These data suggest that SGLT2 is expressed in rat mesangial cells, acts as a normal physiological glucose sensor and regulates cellular contractility in rat mesangial cells.

Age-dependent salt hypertension in Dahl rats: fifty years of research

Fifty years ago, Lewis K. Dahl has presented a new model of salt hypertension - salt-sensitive and salt-resistant Dahl rats. Twenty years later, John P. Rapp has published the first and so far the only comprehensive review on this rat model covering numerous aspects of pathophysiology and genetics of salt hypertension. When we summarized 25 years of our own research on Dahl/Rapp rats, we have realized the need to outline principal abnormalities of this model, to show their interactions at different levels of the organism and to highlight the ontogenetic aspects of salt hypertension development. Our attention was focused on some cellular aspects (cell membrane function, ion transport, cell calcium handling), intra- and extrarenal factors affecting renal function and/or renal injury, local and systemic effects of renin-angiotensin-aldosterone system, endothelial and smooth muscle changes responsible for abnormal vascular contraction or relaxation, altered balance between various vasoconstrictor and vasodilator systems in blood pressure maintenance as well as on the central nervous and peripheral mechanisms involved in the regulation of circulatory homeostasis. We also searched for the age-dependent impact of environmental and pharmacological interventions, which modify the development of high blood pressure and/or organ damage, if they influence the salt-sensitive organism in particular critical periods of development (developmental windows). Thus, severe self-sustaining salt hypertension in young Dahl rats is characterized by pronounced dysbalance between augmented sympathetic hyperactivity and relative nitric oxide deficiency, attenuated baroreflex as well as by a major increase of residual blood pressure indicating profound remodeling of resistance vessels. Salt hypertension development in young but not in adult Dahl rats can be attenuated by preventive increase of potassium or calcium intake. On the contrary, moderate salt hypertension in adult Dahl rats is attenuated by superoxide scavenging or endothelin-A receptor blockade which do not affect salt hypertension development in young animals.

Characterization of a Madin-Darby canine kidney cell line stably expressing TRPV5

To provide a cell model for studying specifically the regulation of Ca2+ entry by the epithelial calcium channel transient receptor potential-vanilloid-5 (TRPV5), green fluorescent protein (GFP)-tagged TRPV5 was expressed stably in Madin-Darby canine kidney type I (MDCK) cells. The localization of GFP-TRPV5 in this cell line showed an intracellular granular distribution. Ca2+ uptake in GFP-TRPV5-MDCK cells cultured on plastic supports was threefold higher than in non-transfected cells. Moreover, apical Ca2+ uptake in GFP-TRPV5-MDCK cells cultured on permeable supports was eightfold higher than basolateral Ca2+ uptake, indicating that GFP-TRPV5 is expressed predominantly in the apical membrane. Patch-clamp analysis showed the presence of typical electrophysiological features of GFP-TRPV5, such as inwardly rectifying currents, inhibition by divalent cations and Ca2+-dependent inactivation. Moreover, the TRPV5 inhibitor ruthenium red completely inhibited Ca2+ uptake in GFP-TRPV5-MDCK cells, whereas Ca2+ uptake in non-transfected cells was not inhibited. The characterized GFP-TRPV5-MDCK cell line was used to assess the regulation of TRPV5. The protein kinase C activator phorbol 12-myristate 13-acetate and the cAMP-elevating compounds forskolin/3-isobutyl-1-methylxanthine, 8-Br-cAMP and PGE2 stimulated TRPV5 activity in GFP-TRPV5-MDCK cells by 121+/-7, 79+/-5, 55+/-4 and 61+/-7%, respectively. These compounds did not affect Ca2+ uptake in non-transfected cells. In conclusion, the GFP-TRPV5-MDCK cell line provides a model to specifically study the regulation of TRPV5 activity.

Impaired ability of the Na+/Ca2+ exchanger from the Dahl/Rapp salt-sensitive rat to regulate cytosolic calcium

We previously cloned Na(+)/Ca(2+) exchanger (NCX1) from mesangial cells of salt-sensitive (SNCX = NCX1.7) and salt-resistant (RNCX = NCX1.3) Dahl/Rapp rats. The abilities of these isoforms to regulate cytosolic Ca(2+) concentration ([Ca(2+)](i)) were assessed in fura 2-loaded OK cells expressing the vector (VOK), RNCX (ROK), and SNCX (SOK). Baseline [Ca(2+)](i) was 98 +/- 20 nM (n = 12) in VOK and was significantly lower in ROK (44 +/- 5 nM; n = 12) and SOK (47 +/- 13 nM; n = 12) cells. ATP at 100 microM increased [Ca(2+)](i) by 189 +/- 55 nM (n = 12), 21 +/- 9 nM (n = 12), and 69 +/- 18 nM (n = 12) in VOK, ROK, and SOK cells, respectively. ATP (1 mM) or bradykinin (0.1 mM) caused large increases in [Ca(2+)](i) and ROK but not SOK cells were much more efficient in reducing [Ca(2+)](i) back to baseline levels. Parental Sprague-Dawley rat mesangial cells express both RNCX (SDRNCX) and SNCX (SDSNCX). SDRNCX and RNCX are identical at every amino acid residue, but SDSNCX and SNCX differ at amino acid 218 where it is isoleucine in SDSNCX and not phenylalanine. OK cells expressing SDSNCX (SDSOK) reduced ATP (1 mM)-induced [Ca(2+)](i) increase back to baseline at a rate equivalent to that for ROK cells. PKC downregulation significantly attenuated the rate at which ROK and SDSOK cells reduced ATP-induced [Ca(2+)](i) increase but had no effect in SOK cells. The reduced efficiency of SNCX to regulate [Ca(2+)](i) is attributed, in part, to the isoleucine-to-phenylalanine mutation at amino acid 218.

Cloning of mesangial cell Na(+)/Ca(2+) exchangers from Dahl/Rapp salt-sensitive/resistant rats

The Dahl/Rapp rat model of hypertension is characterized by a marked increase in blood pressure and a progressive fall in glomerular filtration rate when salt-sensitive (S) rats are placed on an 8% NaCl diet. On the same diet, the salt-resistant (R) rat does not exhibit these changes. In previous studies we found that protein kinase C (PKC) upregulates Na(+)/Ca(2+) exchanger activity in afferent arterioles and mesangial cells from R but not S rats. One possible reason for the difference in PKC sensitivity may be due to differences in the S and R Na(+)/Ca(2+) exchanger protein. We now report the cloning of Na(+)/Ca(2+) exchangers from R (RNCX1) and S (SNCX1) mesangial cells. At the amino acid level, SNCX1 differs from RNCX1 at position 218 in the NH(2)-terminal domain where it is isoleucine in RNCX1 but phenylalanine in SNCX1. These two exchangers also differ by 23 amino acids at the alternative splice site within the cytosolic domain. RNCX1 and SNCX1 were expressed in OK-PTH cells and (45)Ca(2+)-uptake studies were performed. Acute phorbol 12-myristate 13-acetate (PMA) treatment (300 nM, 20 min) upregulated exchanger activity in cells expressing RNCX1 but failed to stimulate exchanger activity in SNCX1 expressing cells. Upregulation of RNCX1 could be prevented by prior 24-h pretreatment with PMA, which downregulates PKC. These results demonstrate a difference in PKC-Na(+)/Ca(2+) exchange activity between the isoform of the exchanger cloned from the R vs. the S rat. Lack of PKC activation of SNCX1 may contribute to a dysregulation of intracellular Ca(2+) concentration and enhanced renal vasoreactivity in this model of hypertension.

Store-operated Ca(2+) channels in human glomerular mesangial cells

Experiments were performed to identify the biophysical properties of store-operated Ca(2+) channels (SOC) in cultured human glomerular mesangial cells (MC). A fluorometric technique (fura 2) was utilized to monitor the change in intracellular calcium concentration ([Ca(2+)](i)) evoked by elevating external [Ca(2+)] from 10 nM to 1 mM (Delta[Ca(2+)]). Under control conditions, Delta[Ca(2+)] averaged 6 nM and was unaffected by elevating bath [K(+)]. After treatment with 1 microM thapsigargin to deplete the intracellular Ca(2+) store, the change in [Ca(2+)](i) (Delta[Ca(2+)](th)) averaged 147 +/- 16 nM. In thapsigargin-treated MC studied under depolarizing conditions (75 mM bath K(+)), Delta[Ca(2+)](th) was 45 +/- 7 nM. The Delta[Ca(2+)](th) response of thapsigargin-treated cells was inhibited by La(3+) (IC(50) = 335 nM) but was unaffected by 5 microM Cd(2+). In patch clamp studies, inward currents were observed in cell-attached patches with either 90 mM Ba(2+) or Ca(2+) in the pipette and 140 mM KCl in the bathing solution. The single-channel conductance was 2.1 pS with Ba(2+) and 0.7 pS with Ca(2+). The estimated selectivities were Ca(2+) > Ba(2+) >> K(+). These channels were sensitive to 2 microM La(3+), insensitive to 5 microM Cd(2+), and voltage independent, with an average channel activity (NP(o)) of 1.02 at command potential (-V(p)) ranging from 0 to -80 mV. In summary, MC exhibited an electrogenic Ca(2+) influx pathway that is suggestive of Ca(2+) entry through SOC, as well as a small-conductance divalent-selective channel displaying biophysical properties consistent with SOC. Based on estimates of whole cell Ca(2+) influx derived from our data, we conclude that SOC with low single-channel conductance must be highly abundant in MC to allow significant capacitative Ca(2+) entry in response to depletion of the intracellular store.