Jürgen Klar

The Calcium Paradoxon of Renin Release. Calcium Suppresses Renin Exocytosis by Inhibition of Calcium-Dependent Adenylate Cyclases AC5 and AC6

An increase in the free intracellular calcium concentration promotes exocytosis in most secretory cells. In contrast, renin release from juxtaglomerular (JG) cells is suppressed by calcium. The further downstream signaling cascades of this so called “calcium paradoxon” of renin secretion have been incompletely defined. Because cAMP is the main intracellular stimulator of renin release, we hypothesized that calcium might exert its suppressive effects on renin secretion via the inhibition of the calcium-regulated adenylate cyclases AC5 and AC6. In primary cultures of JG cells, calcium-dependent inhibitors of renin release (angiotensin II, endothelin-1, thapsigargin) suppressed renin secretion, which was paralleled by decreases in intracellular cAMP levels [cAMP]. When [cAMP] was clamped by membrane permeable cAMP derivates, renin release was not suppressed by any of the calcium liberators. Additionally, both endothelin and thapsigargin suppressed cAMP levels and renin release in isoproterenol or forskolin-pretreated As4.1 cells, a renin-producing cell line that expresses AC5 and AC6. The calcium-dependent inhibition of intracellular cAMP levels and renin release was prevented by small interfering RNA-mediated knockdown of AC5 and/or AC6 expression, underlining the functional significance of these AC isoforms in renin-producing cells. Finally, in isolated perfused mouse kidneys, angiotensin II completely inhibited the stimulation of renin secretion induced by adenylate cyclase activation (isoproterenol) but not by membrane permeable cAMP analogs, supporting the conclusion that the suppressive effect of calcium liberators on renin release is mediated by inhibition of adenylate cyclase activity.

Calcium Inhibits Renin Gene Expression by Transcriptional and Posttranscriptional Mechanisms

The aim of this study was to investigate the role of cytosolic calcium for renin gene expression in juxtaglomerular cells. For this purpose, we used the immortalized juxtaglomerular mouse cell line As4.1. To increase cytosolic calcium concentration, we treated the cells with thapsigargin and cyclopiazonic acid, inhibitors of the endoplasmatic reticulum Ca− ATPase. Thapsigargin and cyclopiazonic acid inhibited renin gene expression in a characteristic time and concentration-dependent manner. This effect was concentration-dependently blocked by BAPTA-AM, an intracellular Ca2+ chelator. Pharmacological blocking of protein kinase C activity by calphostin, Gö6976, and Gö6983 did not change the effect of thapsigargin on renin gene expression. Experiments with renin1C–promoter–reporter constructs revealed that thapsigargin inhibited renin gene transcription. Analysis of deletion constructs of the renin1C promoter indicated that regulatory elements involved in the calcium-mediated inhibition of renin gene transcription are located in the enhancer region of the renin gene and that ≥3 transcription factor-binding sites are involved in this process. In addition, thapsigargin reduced the renin mRNA half-life from 10 hours (control conditions) to 4 hours. Knockdown studies with small interfering RNA directed to dynamin-1 mRNA revealed that dynamin-1 is likely to be involved in the calcium-mediated destabilization of renin mRNA. These data suggest that calcium inhibits renin gene expression in juxtaglomerular cells via a concerted action of inhibition of renin gene transcription and destabilization of renin mRNA.

Temporal-spatial co-localisation of tissue transglutaminase (Tgase2) and matrix metalloproteinase-9 (MMP-9) with SBA-positive micro-fibres in the embryonic kidney cortex

Growth of the kidney is a complex process piloted by the collecting duct (CD) ampullae. The dichotomous arborisation and consecutive elongation of this tubular element determines the exact site and time for the induction of nephrons in the overlaying mesenchymal cap condensates. The mechanism by which the CD ampullae find the correct orientation is currently unknown. Recently, we have demonstrated micro-fibres that originate from the basal aspect of the CD ampullae and extend through the mesenchyme to the organ capsule. The micro-fibres are assumed to be involved in the growth and arborisation process of the CD ampulla. Therefore, we have investigated the specific distribution of the micro-fibres during branching morphogenesis. We have also analysed whether the micro-fibres co-localise with extracellular matrix (ECM)-modulating enzymes and whether the co-localisation pattern changes during CD ampulla arborisation. Micro-fibres were detected in all stages of CD ampulla arborisation. Tissue transglutaminase (Tgase2) co-localised with soybean agglutinin (SBA)-positive micro-fibres, whose presence depended upon the degree of CD branching. Matrix metalloproteinase-9 (MMP-9) also co-localised with micro-fibres, but its expression pattern was different from that for Tgase2. Western blotting experiments demonstrated that Tgase2 and MMP-9 co-migrated with SBA-labelled proteins. Thus, the micro-fibres are developmentally modulated by enzymes of the ECM in embryonic kidney cortex. These findings illustrate the importance of micro-fibres in directing CD ampulla growth.