Julius-von-Sachs-Institut für Biowissenschaften
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- Antigen CD23 (1)
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- Beta-1-Rezeptor (1)
- CD23 (1)
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- Pax-5 (1)
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- Medizinische Klinik und Poliklinik I (2) (entfernen)
Functionally active (conformational) autoantibodies directed against the β1-adrenergic receptor (β1-AR) are supposed to have a pathogenic relevance in human heart failure, particularly in idiopathic dilated cardiomyopathy (DCM). Prevalence of anti-β1-autoantibodies (anti-β1-aabs) in the healthy population is almost negligible, whereas it amounts to up to 30% in heart failure patients with idiopathic DCM. As β1-ARs are not restricted to the heart and are also highly expressed in particular segments of the nephron, it is conceivable that such autoantibodies might also affect kidney function to some extent through the activation of renal β1-ARs.
In the kidney, β1-ARs are highly abundant in the juxtaglomerular apparatus, the distal convoluted tubules, the collecting duct, and the renal arteries. However, the functional significance of β1-ARs at these particular sites along the nephron is poorly understood, as are the effects of conformational stimulating anti-β1-aabs on renal β1-ARs. From the available literature, it is well known that the β1-adrenergic system is involved in, e.g., the regulation of renin-secretion from juxtaglomerular cells. In addition, the β1-adrenergic system is thought to be involved in the regulation of the urine pH via type B-intercalated cells in the collecting duct. In contrast, the regulation of salt- and fluid-secretion in the medullary collecting duct appears to occur independently from the SNS.
As a consequence, the present work aimed to unravel the potential pathophysiological links between renal function, alterations in the cardiovascular system, and circulating agonist-like anti- β1-abs. We analyzed possible renal effects of anti-β1-abs in a human-analogous rat model. After immunization with a GST-fusion protein containing the second extracellular loop (β1-ECII) of the human β1-AR, Lewis-rats develop functionally active, stimulating, conformational anti-β1-ECII-abs. Within the first 6 months, anti-β1-ECII-ab-positive animals develop a hypertensive phenotype, which after 9 months evolves into a DCM phenotype.
In n=40 GST/ β1-ECII-immunized Lewis rats and n=40 age-matched, 0.9% NaCl-injected control animals, we sequentially (i.e. at months 1, 2, 3, 6, 9, 12, 15, and 18 after start of immunization) analyzed the changes in renal function on a molecular, functional, and structural level. We could show that the presence of stimulating anti-β1-ECII-abs – even though having detrimental effects on the heart – has only a minor impact on kidney function and structure. Within the first 3 months after induction of anti-β1-ECII-abs, the levels and activity of renin were significantly increased in immunized compared to corresponding control animals, which was confirmed by experiments on isolated perfused kidneys, in which anti-β1-ECII-abs were able to directly induce the liberation of renin. However, within several weeks the initial anti-β1-ECII-ab-mediated RAAS activation was counter-regulated by auto-regulatory mechanisms activated in the kidney. Similarly, glomerular filtration rate (GFR) and renal blood flow (RBF) were initially decreased in the presence of the stimulating anti-β1-ECII-abs, but returned to control values within 3 months after immunization of the animals. Although expression of several pro-fibrotic markers was significantly up-regulated in anti-β1-ECII-ab-positive rats, no significant differences were noted on a histomorphological level with regard to the occurrence of renal fibrosis, glomerular damage, tubular damage, and perivascular fibrosis. Only a mild decrease in glomerular filtration function was observed in the kidneys of anti-β1-ECII-ab-positive animals from immunization-month 12 on, apparent by increased levels of urinary protein.
Even though anti-β1-ECII-abs were able to induce mild changes in renal function, their effects were not strong enough to critically damage the kidneys in our rat-model. Differences between immunized anti-β1-ECII-ab-positive and corresponding control rats at later time-points (that is, from immunization-month 12 on) are most likely secondary to the progressive heart failure phenotype that immunized animals develop in the course of the experiment.
The present study is the first to focus on the effects of stimulating anti-β1-ECII-abs on the kidney, and on the prevalence of these effects for the heart (referred to as cardio-renal crosstalk). Although our results were obtained in a rat model, they might contribute to better understand the situation in anti-β1-AR-aab-positive human patients. Following the results of our experiments, treatment of such patients should focus on direct and specific neutralization/elimination of stimulating anti-β1-ECII-aab or at least comprise therapeutic strategies that counteract the anti-β1-ECII-aab-effects on the heart by standard treatment for heart failure (i.e. ACE inhibitors, AT1-receptor blockers, and β-blockers) according to current guidelines.
Two isoforms of human CD23 (CD23a and CD23b) have been described. They differ by only 6-7 residues in the N-terminal cytoplasmic tail. CD23a is restrictively expressed on B-cells while CD23b is inducible on B-cells, as well as monocytes, eosinophils, macrophages and a variety of other cell types, after IL-4 stimulation. The two isoforms seems to have different functions. CD23a appears to be the isoform associated with endocytosis of IgE immune complexes and mediating antigen presentation on B-cells. CD23b has a phagocytosis motif and seems to be involved in the phagocytosis of IgE-coated particles, cytokine release and the generation of superoxides. Previous studies indicate that the two isoforms connect to different signal transduction pathways. Comparing the cells that express only one or both CD23 isoforms suggests that CD23b is involved in upregulating cAMP and iNOS, whereas CD23a mediates an increase in intracellular calcium. In the main part of the study we investigated how the CD23a B-cell specific expression is regulated. Pax-5 is a B-cell restricted transcription factor with an essential role in early and late B-cell development. Putative Pax-5 binding sites have been predicted in the CD23a proximal promoter. Analyses of the CD23a promoter revealed three putative Pax-5 binding sites with more than 50% homology to the consensus sequence. One of these sites, named CD23-1 can compete a high affinity Pax-5 binding site or can directly bind Pax-5 protein in electrophoretic mobility shift assays. Introducing mutations into this site abrogates the binding. A different approach, in which overlapping peptides covering the length of the CD23a promoter were tested in competition assays against a high affinity binding site, also revealed CD23-1 as the only site that directly binds Pax-5 protein. Expression of Pax-5 in 293 cells resulted in a 7-fold activation of a CD23a core promoter construct. Co-transfection together with STAT6 showed that Pax-5 cooperates with this transcription factor in enhancing the level of transcription of a CD23a extended promoter construct. Most importantly, ectopic expression of Pax-5 in the monocytic cell line U-937 that regularly expresses only the CD23b isoform enabled a significant CD23a expression after stimulation with IL-4 and PMA. Our results suggest that Pax-5 is a key regulator of the B-cell restricted expression of the CD23a isoform. In the second part of the project, we used a yeast two-hybrid system (CytoTrapTM from Stratagene) in order to look for cytoplasmic interaction partners for the CD23 receptor. The system was established in order to reach a high efficiency of transformation and different bait vector constructs were made. The screening was performed using a human spleen library cloned in the target vector of the system. The first bait constructs used (pSosCD23a and pSosCD23b) expressed the very short (22 amino acids) cytoplasmic tails of the isoforms at the C-terminal end of the fusion protein (human SOS). Improved bait constructs, (pSosCD23a+Linker and pSos CD23b+Linker) expressed the cytoplasmic tail of CD23a/b at the N-terminal side of the human SOS and had in consequence the N-terminal part free as a bait, as it occurs in vivo. A flexible linker region separated the fusion proteins in order to make the small amino acid bait chain more obvious. Approximately three million library clones were screened with these various constructs. No “true positive” interaction was detected. A relatively high number of “false positive” clones were obtained and checked in another two-hybrid system. A new bait construct, in which the tyrosine residue in the cytoplasmic tail of CD23a was replaced by a glutamic acid residue will be used for future screening. The system was also used in order to test the interaction between CD23 and p59fyn, a member of the Src family of protein kinases that was mentioned to associate with CD23a. No interaction was detected by using the CytoTrap two-hybrid system. In conclusion, the key result of the study demonstrates that Pax-5 is a main regulator of the B-cell specific expression of the CD23a isoform. In addition, a two-hybrid system was established and employed in order to look for cytoplasmic interaction partners for CD23.