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- Paulsson, Johan F., 1976-
(author)
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Proislet Amyloid Polypeptide (proIAPP) : Impaired Processing is an Important Factor in Early Amyloidogenesis in Type 2 Diabetes
- 2006
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Doctoral thesis (other academic/artistic)abstract
- Amyloid is defined as extracellular protein aggregates with a characteristic fibrillar ultra-structure, Congo red affinity and a unique x-ray diffraction pattern. At present, 25 different human amyloid fibril proteins have been identified, and amyloid aggregation is associated with pathological manifestations such as Alzheimer’s disease, spongiform encephalopathy and type 2 diabetes. Amyloid aggregation triggers apoptosis by incorporation of early oligomers in cellular membranes, causing influx of ions. Amyloid is the only visible pathological islet alteration in subjects with type 2 diabetes, and islet amyloid polypeptide (IAPP) is the major islet amyloid fibril component. IAPP is produced by beta-cells and co-localized with insulin in the secretory granules. Both peptides are synthesised as pro-molecules and undergo proteolytic cleavage by the prohormone convertase 1/3 and 2. Although IAPP is the main amyloid constituent, both proIAPP and proIAPP processing intermediates have been identified in islet amyloid.The aim of this thesis was to study the role of impaired processing of human proIAPP in early islet amyloidogenesis. Five cell lines with individual processing properties were transfected with human proIAPP and expression, aggregation and viability were studied. Cells unable to process proIAPP into IAPP or to process proIAPP at the N-terminal processing site accumulated intracellular amyloid-like aggregates and underwent apoptosis. Further, proIAPP immunoreactivity was detected in intracellular amyloid-like aggregates in betacells from transgenic mice expressing human IAPP and in transplanted human beta-cells. ProIAPP was hypothesized to act as a nidus for further islet amyloid deposition, and to investigate this theory, amyloid-like fibrils produced from recombinant IAPP, proIAPP and insulin C-peptide/A-chain were injected in the tail vein of transgenic mice expressing the gene for human IAPP. Pancreata were recovered after 10 months and analysed for the presence of amyloid. Both IAPP and proIAPP fibrils but not des-31,32 proinsulin fibrils, caused an increase in affected islets and also an increase of the amyloid amount. This finding demonstrates a seeding capacity of proIAPP on IAPP fibrillogenesis. IAPP has been known for some time to trigger apoptosis in cultured cells, and a novel method for real time detection of apoptosis in beta-cells was developed. Aggregation of recombinant proIAPP and proIAPP processing intermediates were concluded to be inducers of apoptosis as potent as IAPP fibril formation.From the results of this study, a scenario for initial islet amyloidogenesis is proposed. Initial amyloid formation occurs intracellularly as a result of alterations in beta-cell processing capacity. When the host cell undergoes apoptosis intracellular proIAPP amyloid becomes extracellular and can act as seed for further islet amyloid deposition.
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| 2. |
- Vahdat Shariatpanahi, Aida, 1982-
(author)
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The Importance of Macrophages, Lipid Membranes and Seeding in Experimental AA Amyloidosis
- 2019
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Doctoral thesis (other academic/artistic)abstract
- Amyloidosis is a group of protein misfolding diseases caused by tissue deposition of fibrillary protein aggregates termed amyloid. Amyloid A (AA) amyloidosis is a systemic form of amyloidosis that occurs as a complication of chronic inflammatory diseases, such as rheumatoid arthritis, familial Mediterranean fever and chronic infections, such as tuberculosis. AA amyloid is derived from the precursor protein serum amyloid A and is deposited in several organs preferably kidneys, liver and spleen. AA amyloidosis can be induced in mice by long standing inflammatory stimulation and concurrent administration of tissue extracts of AA amyloid, referred to as amyloid enhancing factor (AEF), reduces the time for amyloid deposition in the marginal zone of the spleen from 5 weeks to 2 days. The general aim of this thesis was to investigate the mechanisms involved in the development of AA amyloid in the mouse model of AA amyloidosis.Amyloid was induced in inflamed mice by injection of AEF and amyloid toxicity to splenic macrophages was investigated. We found that the marginal zone macrophages were very sensitive to amyloid formation and increasing amyloid load caused progressive depletion of these cells, whereas red pulp macrophages and metallophilic marginal zone macrophages appeared unaffected. To clarify the role of splenic macrophages in amyloidogenesis, macrophages were depleted by clodronate containing liposomes. We displayed that in the absence of splenic macrophages, especially marginal zone macrophages, amyloid formation was delayed implying a crucial role of macrophages in amyloid formation.The effect of lipid membranes on amyloid formation was studied and we showed that liposomes exhibited an amyloidogenic effect in inflamed mice although not as powerful as AEF. Following the fate of the liposomes, we showed that liposomes were rapidly cleared by uptake in the spleen and liver and colocalized with lysosomes. A tentative mechanism might be that accumulation of liposomes in lysosomes interfere with the SAA degradation process facilitating amyloid formation.Finally the conformational properties of two AEF (AEF1 and AEF2) preparations were studied using conformation sensitive luminescent-conjugated oligothiophenes (LCOs). We found that AEF1 and AEF2 displayed significantly different ultrastructure as well as conformation and consequently induced different cytotoxicity in vitro. Inducing amyloid formation in inflamed mice by AEF1 and AEF2 revealed that the polymorph of the amyloid aggregates was replicated in vivo.In summary, the results obtained in this thesis indicate an important role for macrophages for the formation of amyloid. The existence of amyloid strains has long been an in vitro finding, but the finding that AEF ultrastructure drives the morphology of newly formed amyloid in vivo opens up for new studies that can help us to understand the formation of homologous and heterologous fibrils. Thus, the fundamental mechanisms of various amyloid diseases are similar and the results presented in the thesis can increase the understanding of other amyloid diseases.
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