Genetic low nephron number hypertension is associated with altered expression of key components of the renin-angiotensin system during nephrogenesis.

AIM: This study investigates key components of the renin-angiotensin system (RAS) which play a central role in nephrogenesis and possibly in fetal programming of arterial hypertension in adult life. METHODS: We compared a genetic rat model with inborn nephron deficit, the Munich Wistar Fromter rat (MWF), to normotensive Wistar rats during nephrogenesis at day 19 of fetal development (E19) and at postnatal day 7 (D7). RESULTS: At E19 renal mRNA of angiotensin II type 1a (AT1a) (-50%, P<0.05) and type 1b (AT1b) (-55%, P<0.05) receptors were significantly decreased and renal mRNA expression of angiotensin II type 2 (AT2) receptor was fivefold increased in MWF (n=8) as compared to Wistar rats (n=8). At D7 renal mRNA expression of AT1a (-42%, P<0.05) remained lower in MWF (n=8) as compared to Wistar (n=7). Renal mRNA expression of AT2 (-30%, P>0.05) decreased in MWF (n=8) to about the level of the Wistar control (n=6). CONCLUSIONS: Altered fetal expression of key molecules of the renin-angiotensin system in MWF indicates a possible role in genetic low nephron number hypertension.

Structural analysis of the DNA-binding domain of the Erwinia amylovora RcsB protein and its interaction with the RcsAB box.

The transcriptional regulator RcsB interacts with other coactivators to control the expression of biosynthetic operons in enterobacteria. While in a heterodimer complex with the regulator RcsA the RcsAB box consensus is recognized, DNA binding sites for RcsB without RcsA have also been identified. The conformation of RcsB might therefore be modulated upon interaction with various coactivators, resulting in the recognition of different DNA targets. We report the solution structure of the C-terminal DNA-binding domain of the RcsB protein from Erwinia amylovora spanning amino acid residues 129-215 solved by heteronuclear magnetic resonance (NMR) spectroscopy. The C-terminal domain is composed of four alpha-helices where two central helices form a helix-turn-helix motif similar to the structures of the regulatory proteins GerE, NarL, and TraR. Amino acid residues involved in the RcsA independent DNA binding of RcsB were identified by titration studies with a RcsAB box consensus fragment. Data obtained from NMR spectroscopy together with surface plasmon resonance measurements demonstrate that the RcsAB box is specifically recognized by the RcsAB heterodimer as well as by RcsB alone. However, the binding constant of RcsB alone at target promoters from Escherichia coli, E. amylovora, and Pantoea stewartii was approximately 1 order of magnitude higher compared with that of the RcsAB heterodimer. We present evidence that the obvious role of RcsA is not to alter the DNA binding specificity of RcsB but to stabilize RcsB-DNA complexes.