Kinin B1 receptor deficiency leads to leptin hypersensitivity and resistance to obesity.

OBJECTIVE: Kinins mediate pathophysiological processes related to hypertension, pain, and inflammation through the activation of two G-protein-coupled receptors, named B(1) and B(2). Although these peptides have been related to glucose homeostasis, their effects on energy balance are still unknown. RESEARCH DESIGN AND METHODS: Using genetic and pharmacological strategies to abrogate the kinin B(1) receptor in different animal models of obesity, here we present evidence of a novel role for kinins in the regulation of satiety and adiposity. RESULTS: Kinin B(1) receptor deficiency in mice (B(1)(-/-)) resulted in less fat content, hypoleptinemia, increased leptin sensitivity, and robust protection against high-fat diet-induced weight gain. Under high-fat diet, B(1)(-/-) also exhibited reduced food intake, improved lipid oxidation, and increased energy expenditure. Surprisingly, B(1) receptor deficiency was not able to decrease food intake and adiposity in obese mice lacking leptin (ob/ob-B(1)(-/-)). However, ob/ob-B(1)(-/-) mice were more responsive to the effects of exogenous leptin on body weight and food intake, suggesting that B(1) receptors may be dependent on leptin to display their metabolic roles. Finally, inhibition of weight gain and food intake by B(1) receptor ablation was pharmacologically confirmed by long-term administration of the kinin B(1) receptor antagonist SSR240612 to mice under high-fat diet. CONCLUSIONS: Our data suggest that kinin B(1) receptors participate in the regulation of the energy balance via a mechanism that could involve the modulation of leptin sensitivity.

Functional rescue of a defective angiotensin II AT1 receptor mutant by the Mas protooncogene.

Earlier studies with Mas protooncogene, a member of the G-protein-coupled receptor family, have proposed this gene to code for a functional AngII receptor, however further results did not confirm this assumption. In this work we investigated the hypothesis that a heterodimeration AT(1)/Mas could result in a functional interaction between both receptors. For this purpose, CHO or COS-7 cells were transfected with the wild-type AT(1) receptor, a non-functional AT(1) receptor double mutant (C18F-K20A) and Mas or with WT/Mas and C18F-K20A/Mas. Cells single-expressing Mas or C18F/K20A did not show any binding for AngII. The co-expression of the wild-type AT(1) receptor and Mas showed a binding profile similar to that observed for the wild-type AT(1) expressed alone. Surprisingly, the co-expression of the double mutant C18F/K20A and Mas evoked a total recovery of the binding affinity for AngII to a level similar to that obtained for the wild-type AT(1). Functional measurements using inositol phosphate and extracellular acidification rate assays also showed a clear recovery of activity for AngII on cells co-expressing the mutant C18F/K20A and Mas. In addition, immunofluorescence analysis localized the AT(1) receptor mainly at the plasma membrane and the mutant C18F-K20A exclusively inside the cells. However, the co-expression of C18F-K20A mutant with the Mas changed the distribution pattern of the mutant, with intense signals at the plasma membrane, comparable to those observed in cells expressing the wild-type AT(1) receptor. These results support the hypothesis that Mas is able to rescue binding and functionality of the defective C18F-K20A mutant by dimerization.

Participation of transmembrane proline 82 in angiotensin II AT1 receptor signal transduction.

Most of the classical physiological effects of the octapeptide angiotensin II (AngII) are produced by activating the AT1 receptor which belongs to the G-protein coupled receptor family (GPCR). Peptidic GPCRs may be functionally divided in three regions: (i) extracellular domains involved in ligand binding; (ii) intracellular domains implicated in agonist-induced coupling to G protein and (iii) seven transmembrane domains (TM) involved in signal transduction. The TM regions of such receptors have peculiar characteristics such as the presence of proline residues. In this project we aimed to investigate the participation of two highly conserved proline residues (Pro82 and Pro162), located in TM II and TM IV, respectively, in AT1 receptor signal transduction. Both mutations did not cause major alterations in AngII affinity. Functional assays indicated that the P162A mutant did not influence the signal transduction. On the other hand, a potent deleterious effect of P82A mutation on signal transduction was observed. We believe that the Pro82 residue is crucial to signal transduction, although it is not possible to say yet if this is due to a direct participation or if due to a structural rearrangement of TM II. In this last hypothesis, the removal of proline residue might be correlated to a removal of a kink, which in turn can be involved in the correct positioning of residues involved in signal transduction.

Role of the kinin B1 receptor in insulin homeostasis and pancreatic islet function.

Kinins are potent vasoactive peptides generated in blood and tissues by the kallikrein serine proteases. Two distinct kinin receptors have been described, one constitutive (subtype B2) and one inducible (subtype B1), and many physiological functions have been attributed to these receptors, including glucose homeostasis and control of vascular permeability. In this study we show that mice lacking the kinin B1 receptor (B1-/- mice) have lower fasting plasma glucose concentrations but exhibit higher glycemia after feeding when compared to wild-type mice. B1-/- mice also present pancreas abnormalities, characterized by fewer pancreatic islets and lower insulin content, which leads to hypoinsulinemia and reduced insulin release after a glucose load. Nevertheless, an insulin tolerance test indicated higher sensitivity in B1-/- mice. In line with this phenotype, pancreatic vascular permeability was shown to be reduced in B1 receptor-ablated mice. The B1 agonist desArg9bradykinin injected intravenously can induce the release of insulin into serum, and this effect was not observed in the B1-/- mice or in isolated islets. Our data demonstrate the importance of the kinin B1 receptor in the control of pancreatic vascular homeostasis and insulin release, highlighting a new role for this receptor in the pathogenesis of diabetes and related diseases.

Molecular structure and transcriptional regulation by nuclear factor-kappaB of the mouse kinin B1 receptor gene.

Kinins are important mediators in cardiovascular homeostasis, inflammation, and nociception. Two kinin receptors have been described, B 1 and B 2 . The B 1 receptor is normally absent in healthy tissues, but is highly induced under pathological conditions. To understand the molecular mechanism of B 1 receptor up-regulation, we determined the mouse B 1 receptor gene structure, isolated and characterized the promoter region and studied its transcriptional regulation. The mouse B 1 receptor gene contains two exons (with the entire coding region located in the second exon) and a TATA-less promoter with multiple transcription start sites. A 7.7-kbp portion of the 5'-flanking region was examined for promoter activity in vascular smooth muscle cells (VSMCs). A minimal 92-bp fragment, located immediately upstream of the transcription start region, exerted basal and lipopolysaccharide (LPS)-inducible transcription activity in the sense and antisense orientation, and was thereby identified as an enhancer element. Nuclear extracts from VSMCs showed basal and LPS-inducible binding activity of nuclear factor (NF)-kappaB at this sequence. B 1 receptor transcription activation in response to LPS was abolished by cotransfection with IkappaBalphaDeltaN, an NF-kappaB repressor. In summary, our results reveal the structure of the mouse B 1 receptor gene and the involvement of NF-kappaB in the inducible mouse kinin B 1 receptor expression under pathological conditions.

Transcriptional regulation of the rat bradykinin B2 receptor gene: identification of a silencer element.

Kinins are involved in a variety of physiological and pathophysiological processes related to cardiovascular homeostasis, inflammation, blood flow, and nociception. Under physiological conditions, the bradykinin B2 (BKB2) receptor is constitutively expressed and mediates most of kinins' actions. However, the mechanisms regulating BKB2 receptor gene expression are still poorly understood. In this study, 4.6 kilobases of the 5'-flanking region from the rat BKB2 receptor gene were sequenced, and computer analysis revealed several sites for transcriptional factors. Nine promoter mutants were cloned in luciferase reporter gene vectors and transfected in NG108-15 cells and rat aorta vascular smooth muscle cells (VSMCs), showing several positive and negative regulatory elements. A classical silencer with 56 base pairs (bp) caused a decrease in reporter gene activity in NG108-15 cells and VSMCs and was able to inhibit the thymidine kinase promoter. Using electrophoretic mobility shift assay and surface plasmon resonance assay, protein-DNA interactions in the silencer region were determined and specific sets of protein-silencer complexes were detected in both cell types. More intense complexes were observed in the central 21 bp of the silencer and mutation in a putative SRE-1 site strongly impaired the protein-DNA binding. Down-regulation of the BKB2 receptor population in NG108-15 cells promoted by N(6), 2'-O-dibutyryladenosine 3':5'-cyclic monophosphate was paralleled by an increase in the amount of nuclear proteins bound to the silencer sequence showing an inverse relationship between protein-silencer complexes and the transcription of the BKB2 receptor gene. In summary, these data highlight the cell-specific regulation of the BKB2 receptor and the importance of a silencer element present in the regulatory region of the gene.