The mechanism of insulin action on islet amyloid polypeptide fiber formation

The pathology of type II diabetes includes the presence of cytotoxic amyloid deposits in the islets of Langerhans. The main component of these deposits, islet amyloid polypeptide (IAPP), is a hormone involved in glucose metabolism and is normally co-secreted with insulin by the beta-cells of the pancreas. Here, we perform in vitro IAPP fibrillogenesis experiments in the presence and in the absence of insulin to elucidate the mechanism by which insulin acts on fiber formation. We find that insulin is an exceptionally potent inhibitor. In contrast to the vast excess of insulin over IAPP in vivo, substoichiometric amounts of insulin inhibit seeded and unseeded reactions by more than tenfold in vitro. Unusually, the magnitude of the inhibitory effect is dependent on the concentration of insulin, yet independent of the concentration of IAPP. In addition, insulin appears to bind non-specifically to fiber surfaces, giving rise to altered morphology. IAPP fiber formation in vitro requires a minimum of three steps: fiber-independent nucleation, elongation, and fiber-dependent nucleation. Furthermore, these steps are attenuated by the presence of a dispersed-phase transition. We interpret these data in the context of the phase-mediated fibrillogenesis model (PMF) and conclude through experiment and kinetic simulation that the dominant effect of insulin is to act on the elongation portion of the reaction. These results suggest that amyloid formation in type II diabetes involves either an additional agent that acts as an accelerant, or a step that segregates IAPP from insulin.     

Interaction of membrane-bound islet amyloid polypeptide with soluble and crystalline insulin

Islet amyloid polypeptide (IAPP, also known as amylin) is the major protein component of pancreatic amyloid fibers in type II diabetes and is normally cosecreted with insulin from the beta-cells of the pancreas. IAPP forms amyloid fibrils rapidly at concentrations well below those found in vivo, yet progression of type II diabetes occurs over many years. Insulin, a known inhibitor of IAPP fibrillogenesis, exists as a dense crystalline or near-crystalline core in the secretory vesicle, while IAPP localizes to the region between the crystal and the secretory vesicle membrane. In vitro, IAPP fibrillogenesis is both accelerated by lipid membranes and inhibited by monomeric insulin. In this work, we investigate insulin-IAPP-lipid interactions in vitro under conditions chosen to approximate native secretory vesicle physiology and the amyloid disease state. The effect of insulin on IAPP fibrillogenesis is investigated using fluorescence spectrometry. Additionally, interactions of IAPP and lipids with crystalline insulin are studied using fluorescence microscopy. We find that, while soluble states of insulin and IAPP do not interact significantly, large assemblies of either insulin (crystals) or IAPP (fibers) can lead to stable IAPP-insulin interactions. The results raise the possibility of multiple physiological interactions between these two beta-cell hormones.     

Recent computational studies of membrane interaction and disruption of human islet amyloid polypeptide: Monomers,oligomers and protofibrils

The amyloid deposits of human islet amyloid polypeptide (hIAPP) are found in type 2 diabetes patients. hIAPP monomer is intrinsically disordered in solution, whereas it can form amyloid fibrils both in vivo and in vitro. Extensive evidence suggests that hIAPP causes the disruption of cellular membrane, and further induces cytotoxicity and the death of islet β-cells in pancreas. The presence of membrane also accelerates the hIAPP fibril formation. hIAPP oligomers and protofibrils in the early stage of aggregation were reported to be the most cytotoxic, disrupting the membrane integrity and giving rise to the pathological process. The detailed molecular mechanisms of hIAPP-membrane interactions and membrane disruption are complex and remain mostly unknown. Here in this review, we focus on recent computational studies that investigated the interactions of full length and fragmentary hIAPP monomers, oligomers and protofibrils with anionic, zwitterionic and mixed anionic-zwitterionic lipid bilayers. We mainly discuss the binding orientation of monomers at membrane surface, the conformational ensemble and the oligomerization of hIAPP inside membranes, the effect of lipid composition on hIAPP oligomers/protofibrils-membrane interactions, and the hIAPP-induced membrane perturbation. This review provides mechanistic insights into the interactions between hIAPP and lipid bilayers with different lipid composition at an atomistic level, which is helpful to understand the hIAPP cytotoxicity mediated by membrane. This article is part of a Special Issue entitled: Protein Aggregation and Misfolding at the Cell Membrane Interface edited by Ayyalusamy Ramamoorthy.     

Presence of islet amyloid polypeptide in rat islet B and D cells determines parallelism and dissociation between rat pancreatic islet amyloid polypeptide and insulin content.

The islet amyloid polypeptide (IAPP) immunoreactivity of the adult rat pancreas is located in insulin-containing B cells as well as in somatostatin-containing D cells. In both cell types, the IAPP immunoreactivity is identical to rat synthetic IAPP in terms of its elution position after reversed phase HPLC and its binding to IAPP antibodies. The IAPP content per 10(6) B-cells is more than 100 fold lower than the corresponding insulin content, but comparable to the IAPP content of D cells. After induction of diabetes by streptozotocin, pancreatic IAPP seems predominantly located in somatostatin-containing cells. In normal rats, pancreatic insulin and IAPP content increase 20 fold from birth to 12 weeks of age; beyond week 12, the further rise in pancreatic insulin was not paralleled by an increase in IAPP content.     

Membrane interaction of islet amyloid polypeptide

Increasing evidence suggests that the misfolding and deposition of IAPP plays an important role in the pathogenesis of type II, or non-insulin-dependent diabetes mellitus (T2DM). Membranes have been implicated in IAPP-dependent toxicity in several ways: Lipid membranes have been shown to promote the misfolding and aggregation of IAPP. Thus, potentially toxic forms of IAPP can be generated when IAPP interacts with cellular membranes. In addition, membranes have been implicated as the target of IAPP toxicity. IAPP has been shown to disrupt membrane integrity and to permeabilize membranes. Since disruption of cellular membranes is highly toxic, such a mechanism has been suggested to explain the observed IAPP toxicity. Here, we review IAPP-membrane interaction in the context of (1) catalyzing IAPP misfolding and (2) being a potential origin of IAPP toxicity.     

Membrane interaction of islet amyloid polypeptide

Increasing evidence suggests that the misfolding and deposition of IAPP plays an important role in the pathogenesis of type II, or non-insulin-dependent diabetes mellitus (T2DM). Membranes have been implicated in IAPP-dependent toxicity in several ways: Lipid membranes have been shown to promote the misfolding and aggregation of IAPP. Thus, potentially toxic forms of IAPP can be generated when IAPP interacts with cellular membranes. In addition, membranes have been implicated as the target of IAPP toxicity. IAPP has been shown to disrupt membrane integrity and to permeabilize membranes. Since disruption of cellular membranes is highly toxic, such a mechanism has been suggested to explain the observed IAPP toxicity. Here, we review IAPP-membrane interaction in the context of (1) catalyzing IAPP misfolding and (2) being a potential origin of IAPP toxicity.     

胰岛淀粉样多肽的研究进展

由蛋白错误折叠后聚集所产生的淀粉样蛋白沉积是导致老年痴呆症、疯牛病、2型糖尿病等多种疾病的重要因素。由胰岛淀粉样多肽(islet amyloid polypeptide,IAPP)所形成的淀粉样蛋白沉积,具有破坏胰岛β细胞膜结构、诱导β细胞凋亡和损伤β细胞功能的作用,被认为是2型糖尿病的重要致病原因之一。对IAPP的聚集性、聚集体的结构,以及其对β细胞的毒性作用研究,不但有助于明确2型糖尿病的发病机制,而且最新研究也表明抑制IAPP的聚集可有效减少β细胞的凋亡,提高胰岛移植的成功率。因此,IAPP已成为2型糖尿病治疗中一个具有良好前景的靶点。该文对IAPP研究的最新进展进行了简要介绍。     

Differential effects of serine side chain interactions in amyloid formation by islet amyloid polypeptide

Islet amyloid polypeptide (IAPP), a 37 residue polypeptide, is the main protein component of islet amyloid deposits produced in the pancreas in Type 2 diabetes. Human IAPP contains five serine residues at positions 19, 20, 28, 29, and 34. Models of the IAPP amyloid fibril indicate a structure composed of two closely aligned columns of IAPP monomers with each monomer contributing to two intermolecular β‐strands. Ser 19 and Ser 20 are in the partially ordered β‐turn region, which links the two strands, whereas Ser 28, Ser 29, and Ser 34 are in the core region of the amyloid fibril. Ser 29 is involved in contacts between the two columns of monomers and is the part of the steric zipper interface. We undertook a study of individual serine substitutions with the hydrophobic isostere 2‐aminobutyric acid (2‐Abu) to examine the site‐specific role of serine side chains in IAPP amyloid formation. All five variants formed amyloid. The Ser 19 to 2‐Abu mutant accelerates amyloid formation by a factor of 3 to 4, while the Ser 29 to 2‐Abu mutation modestly slows the rate of amyloid formation. 2‐Abu replacements at the other sites had even smaller effects. The data demonstrate that the cross‐column interactions made by residue 29 are not essential for amyloid formation and also show that cross‐strand networks of hydrogen‐bonded Ser side chains, so called Ser‐ladders, are not required for IAPP amyloid formation. The effect of the Ser 19 to 2‐Abu mutant suggests that residues in this region are important for amyloid formation by IAPP.     

Inhibitors can arrest the membrane activity of human islet amyloid polypeptide independently of amyloid formation.

Human islet amyloid polypeptide (hIAPP), co-secreted with insulin from pancreatic beta cells, misfolds to form amyloid deposits in non-insulin-dependent diabetes mellitus (NIDDM). Like many amyloidogenic proteins, hIAPP is membrane-active: this may be significant in the pathogenesis of NIDDM. Non-fibrillar hIAPP induces electrical and physical breakdown in planar lipid bilayers, and IAPP inserts spontaneously into lipid monolayers, markedly increasing their surface area and producing Brewster angle microscopy reflectance changes. Congo red inhibits these activities, and they are completely arrested by rifampicin, despite continued amyloid formation. Our results support the idea that non-fibrillar IAPP is membrane-active, and may have implications for therapy and for structural studies of membrane-active amyloid.     

Fibril structure of human islet amyloid polypeptide

Misfolding and amyloid fibril formation by human islet amyloid polypeptide (hIAPP) are thought to be important in the pathogenesis of type 2 diabetes, but the structures of the misfolded forms remain poorly understood. Here we developed an approach that combines site-directed spin labeling with continuous wave and pulsed EPR to investigate local secondary structure and to determine the relative orientation of the secondary structure elements with respect to each other. These data indicated that individual hIAPP molecules take up a hairpin fold within the fibril. This fold contains two β-strands that are much farther apart than expected from previous models. Atomistic structural models were obtained using computational refinement with EPR data as constraints. The resulting family of structures exhibited a left-handed helical twist, in agreement with the twisted morphology observed by electron microscopy. The fibril protofilaments contain stacked hIAPP monomers that form opposing β-sheets that twist around each other. The two β-strands of the monomer adopt out-of-plane positions and are staggered by about three peptide layers (∼15 Å). These results provide a mechanism for hIAPP fibril formation and could explain the remarkable stability of the fibrils. Thus, the structural model serves as a starting point for understanding and preventing hIAPP misfolding.     

Aggregation-induced conformation changes dictate islet amyloid polypeptide (IAPP) membrane affinity

Islet amyloid polypeptide (IAPP) is a 37 residue intrinsically disordered protein whose aggregation is associated with Type II diabetes. Like most amyloids, it appears that the intermediate aggregates (“oligomers”) of IAPP are more toxic than the mature fibrils, and interaction with the cell membrane is likely to be an integral component of the toxicity. Here we probe the membrane affinity and the conformation of the peptide as a function of its aggregation state. We find that the affinity of the peptide for artificial lipid bilayers is more than 15 times higher in the small oligomeric state (hydrodynamic radius ~ 1.6 nm) compared to the monomeric state (hydrodynamic radius ~ 0.7 nm). Binding with RIN-m5F cell membranes also shows qualitatively similar behavior. The monomeric state, as determined by Forster Resonance Energy Transfer, has a much larger end to end distance than the oligomeric state, suggesting conformational change between the monomers and the oligomers. Raman and Infrared spectroscopic measurements show the presence of considerable alpha helical content in the oligomers, whereas the larger aggregates have largely beta sheet character. Therefore, the conformation of the small oligomers is distinct from both the smaller monomers and the larger oligomers, and this is associated with an enhanced membrane affinity. This provides a possible structural basis for the enhanced toxicity of amyloid oligomers. Such change is also reminiscent of amyloid beta, another aggregation prone amyloidogenic peptide, though the nature of the conformational change is quite different in the two cases. We infer that conformational change underlying oligomer formation is a key factor in determining the enhanced membrane affinity of disease causing oligomers, but the toxic “oligomer fold” may not be universal.     

Structural characterisation of islet amyloid polypeptide fibrils

Islet amyloid is found in many patients suffering from type 2 diabetes. Amyloid fibrils found deposited in the pancreatic islets are composed of a 37-residue peptide, known as islet amyloid polypeptide (IAPP) (also known as amylin) and are similar to those found in other amyloid diseases. Synthetic IAPP peptide readily forms amyloid fibrils in vitro and this has allowed fibril formation kinetics and the overall morphology of IAPP amyloid to be studied. Here, we use X-ray fibre diffraction, electron microscopy and cryo-electron microscopy to examine the molecular structure of IAPP amyloid fibrils. X-ray diffraction from aligned synthetic amyloid fibrils gave a highly oriented diffraction pattern with layer-lines spaced 4.7 A apart. Electron diffraction also revealed the characteristic 4.7 A meridional signal and the position of the reflection could be compared directly to the image of the diffracting unit. Cryo-electron microscopy revealed the strong signal at 4.7 A that has been previously visualised from a single Abeta fibre. Together, these data build up a picture of how the IAPP fibril is held together by hydrogen bonded beta-sheet structure and contribute to the understanding of the generic structure of amyloid fibrils.     

Amyloidogenicity and cytotoxicity of islet amyloid polypeptide

Insoluble amyloid formation by islet amyloid polypeptide (IAPP) in the islets of Langerhans of the pancreas is a major pathophysiological feature of noninsulin dependent diabetes mellitus (NIDDM) or type II diabetes. Because in vivo formed amyloid colocalizes with areas of cell degeneration and IAPP amyloid aggregates are cytotoxic per se, the process of IAPP amyloid formation has been strongly associated with the progressive pancreatic cell degeneration and thus much of the pathology of type II diabetes. IAPP is a pancreatic polypeptide of 37 residues that, in its soluble form, is believed to play a role as a regulator of glucose homeostasis. The molecular cause and mechanism of the conversion of soluble IAPP into insoluble amyloid aggregates in vivo and its role in disease progress still remain to be clarified. Nevertheless, in the past few years significant progress has been made in understanding the amyloidogenesis pathway of IAPP in vitro and gaining insight into the structural and conformational "requirements" of IAPP amyloidogenesis and related cytotoxic effects. Importantly, several of the studies have revealed significant similarities of the above features of IAPP to other amyloidogenic polypeptides such as the beta-amyloid polypeptide Abeta. This suggests that, at the molecular level, amyloidogenesis, and possibly related cell degeneration and disease pathogenesis by completely different polypeptide sequences, may obey to common structural and conformational "rules" and follow similar molecular pathways. This review describes studies on the structural and conformational features of IAPP amyloid formation and cytotoxicity, and the application of the obtained knowledge for the understanding of the molecular mechanism of the IAPP amyloidogenesis pathway and the related cytotoxicity.     

Porcine islet amyloid polypeptide fragments are refractory to amyloid formation

Of 10 variation sites between sequences of amyloid-resistant porcine islet amyloid polypeptide (pIAPP) and amyloid-prone human IAPP (hIAPP), seven locate within residues 17–29, the most amyloidogenic fragment within hIAPP. To investigate how these variations affect amyloidogenicity, 26 IAPP(17–29) or IAPP(20–29) variants were synthesized and their secondary structures, amyloidogenicity, oligomerization and cytotoxicity were studied. Our results indicated that pIAPP fragments are refractory to amyloid formation and significantly less cytotoxic compared with hIAPP fragments. A novel stable dimer was observed in pIAPP(20–29) solution, whereas hIAPP(20–29) exists mostly as monomers and trimers. Among all human to porcine substitutions, S20R caused the most prolonged lag time and significantly attenuated cytotoxicity. The different oligomerization and amyloidogenic properties of hIAPP and pIAPP fragments are discussed.

Structured summary

pIAPP and pIAPPbind: shown by molecular sieving (view interactions 1, 2)hIAPP and hIAPPbind: shown by molecular sieving (view interactions 1, 2)     

The role of aromatic side-chains in amyloid growth and membrane interaction of the islet amyloid polypeptide fragment LANFLVH

Human islet amyloid polypeptide (hIAPP) is known to misfold and aggregate into amyloid deposits that may be found in pancreatic tissues of patients affected by type 2 diabetes. Recent studies have shown that the highly amyloidogenic peptide LANFLVH, corresponding the N-terminal 12–18 region of IAPP, does not induce membrane damage. Here we assess the role played by the aromatic residue Phe in driving both amyloid formation and membrane interaction of LANFLVH. To this aim, a set of variant heptapeptides in which the aromatic residue Phe has been substituted with a Leu and Ala is studied. Differential scanning calorimetry (DSC) and membrane-leakage experiments demonstrated that Phe substitution noticeably affects the peptide-induced changes in the thermotropic properties of the lipid bilayer but not its membrane damaging potential. Atomic force microscopy (AFM), ThT fluorescence and Congo red birefringence assays evidenced that the Phe residue is not required for fibrillogenesis, but it can influence the self-assembling kinetics. Molecular dynamics simulations have paralleled the outcome of the experimental trials also providing informative details about the structure of the different peptide assemblies. These results support a general theory suggesting that aromatic residues, although capable of affecting the self-assembly kinetics of small peptides and peptide-membrane interactions, are not essential either for amyloid formation or membrane leakage, and indicate that other factors such as β-sheet propensity, size and hydrophobicity of the side chain act synergistically to determine peptide properties.     

Ganglioside-induced amyloid formation by human islet amyloid polypeptide in lipid rafts

Human islet amyloid polypeptide (hIAPP) is the primary component of the amyloid deposits found in the pancreatic islets of patients with type 2 diabetes mellitus. However, it is unknown how amyloid fibrils are formed in vivo. In this study, we demonstrate that gangliosides play an essential role in the formation of amyloid deposits by hIAPP on plasma membranes. Amyloid fibrils accumulated in ganglioside- and cholesterol-rich microscopic domains (‘lipid rafts’). The depletion of gangliosides or cholesterol significantly reduced the amount of amyloid deposited. These results clearly showed that the formation of amyloid fibrils was mediated by gangliosides in lipid rafts.     

Genetic background determines the extent of islet amyloid formation in human islet amyloid polypeptide transgenic mice

Genetic background is important in determining susceptibility to metabolic abnormalities such as insulin resistance and beta-cell dysfunction. Islet amyloid is associated with reduced beta-cell mass and function and develops in the majority of our C57BL/6J x DBA/2J (F(1)) male human islet amyloid polypeptide (hIAPP) transgenic mice after 1 yr of increased fat feeding. To determine the relative contribution of each parental strain, C57BL/6J (BL6) and DBA/2J (DBA2), to islet amyloid formation, we studied male hIAPP mice on each background strain (BL6, n = 13; and DBA2 n = 11) and C57BL/6J x DBA/2J F(1) mice (n = 17) on a 9% (wt/wt) fat diet for 1 yr. At the end of 12 mo, islet amyloid deposition was quantified from thioflavin S-stained pancreas sections. The majority of mice in all groups developed islet amyloid (BL6: 91%, F(1): 76%, DBA2: 100%). However, the prevalence (%amyloid-positive islets; BL6: 14 +/- 3%, F(1): 44 +/- 8%, DBA2: 49 +/- 9%, P < 0.05) and severity (%islet area occupied by amyloid; BL6: 0.03 +/- 0.01%, F(1): 9.2 +/- 2.9%, DBA2: 5.7 +/- 2.3%, p < or = 0.01) were significantly lower in BL6 than F(1) and DBA2 mice. Increased islet amyloid severity was negatively correlated with insulin-positive area per islet, in F(1) (r(2) = 0.75, P < 0.001) and DBA2 (r(2) = 0.87, P < 0.001) mice but not BL6 mice (r(2) = 0.07). In summary, the extent of islet amyloid formation in hIAPP transgenic mice is determined by background strain, with mice expressing DBA/2J genes (F(1) and DBA2 mice) being more susceptible to amyloid deposition that replaces beta-cell mass. These findings underscore the importance of genetic and environmental factors in studying metabolic disease.