Structural dissection of the first events following membrane binding of the islet amyloid polypeptide

Amyloid forming proteins are involved in many pathologies and often belong to the class of intrinsically disordered proteins. One of these proteins is the islet amyloid polypeptide (IAPP), which is the main constituent of the amyloid fibrils found in the pancreas of type 2 diabetes patients. The molecular mechanism of IAPP-induced cell death is not yet understood, however it is known that the cell membrane plays a dual role, being a catalyst of IAPP aggregation and the target of IAPP toxicity. Using FTIR spectroscopy, transmission electron microscopy, and molecular dynamics simulations we investigate the very first molecular steps following IAPP binding to a lipid membrane. In particular, we assess the combined effects of the charge state of amino-acid residue 18 and the IAPP-membrane interactions on the structures of monomeric and aggregated IAPP. Both our experiments and simulations reveal distinct IAPP-membrane interaction modes for the various IAPP variants. Membrane binding causes IAPP to fold into an amphipathic helix, which in the case of H18K- and H18R-IAPP can easily insert below the lipid headgroups. For all IAPP variants but H18E-IAPP, the membrane-bound α-helical structure is an intermediate on the way to IAPP amyloid aggregation, while H18E-IAPP remains in a stable helical conformation. The fibrillar aggregates of wild-type IAPP and H18K-IAPP are dominated by an antiparallel β-sheet conformation, while H18R- and H18A-IAPP exhibit both antiparallel and parallel β-sheets as well as amorphous aggregates. In summary, our results emphasize the importance of residue 18 for the structure and membrane interaction of IAPP. This residue is thus a good target for destabilizing amyloid fibrils of IAPP and inhibit its toxic actions by possible therapeutic molecules.

Membrane interaction and disulphide-bridge formation in the unconventional secretion of Tau

Misfolded, pathological Tau protein propagates from cell to cell causing neuronal degeneration in Alzheimer’s disease and other tauopathies. The molecular mechanisms of this process have remained elusive. Unconventional secretion of Tau takes place via several different routes, including direct penetration through the plasma membrane. Here, we show that Tau secretion requires membrane interaction via disulphide bridge formation. Mutating residues that reduce Tau interaction with membranes or formation of disulphide bridges decrease both Tau secretion from cells, and penetration through artificial lipid membranes. Our results demonstrate that Tau is indeed able to penetrate protein-free membranes in a process independent of active cellular processes and that both membrane interaction and disulphide bridge formation are needed for this process. QUARK-based de novo modelling of the second and third microtubule-binding repeat domains, in which the two cysteine residues of 4R isoforms of Tau are located, supports the concept that this region of Tau could form transient amphipathic helices for membrane interaction.

Synuclein Family Members Prevent Membrane Damage by Counteracting α-Synuclein Aggregation

The 140 amino acid protein α-synuclein (αS) is an intrinsically disordered protein (IDP) with various roles and locations in healthy neurons that plays a key role in Parkinson’s disease (PD). Contact with biomembranes can lead to α-helical conformations, but can also act as s seeding event for aggregation and a predominant β-sheet conformation. In PD patients, αS is found to aggregate in various fibrillary structures, and the shift in aggregation and localization is associated with disease progression. Besides full-length αS, several related polypeptides are present in neurons. The role of many αS-related proteins in the aggregation of αS itself is not fully understood Two of these potential aggregation modifiers are the αS splicing variant αS Δexon3 (Δ3) and the paralog β-synuclein (βS). Here, polarized ATR-FTIR spectroscopy was used to study the membrane interaction of these proteins individually and in various combinations. The method allowed a continuous monitoring of both the lipid structure of biomimetic membranes and the aggregation state of αS and related proteins. The use of polarized light also revealed the orientation of secondary structure elements. While αS led to a destruction of the lipid membrane upon membrane-catalyzed aggregation, βS and Δ3 aggregated significantly less, and they did not harm the membrane. Moreover, the latter proteins reduced the membrane damage triggered by αS. There were no major differences in the membrane interaction for the different synuclein variants. In combination, these observations suggest that the formation of particular protein aggregates is the major driving force for αS-driven membrane damage. The misbalance of αS, βS, and Δ3 might therefore play a crucial role in neurodegenerative disease.