Cryo-EM exposes diverse polymorphism in IAPP mutants to guide the rational design of peptide-based therapeutics.

In the pursuit of potential therapeutic agents for type 2 diabetes, non-amyloidogenic forms of the human Islet Amyloid Polypeptide (hIAPP) containing site-specific mutations are of significant interest. In the present study, we dissect the three proline mutations present in the core region of the non-amyloidogenic rat IAPP into single-point mutations at A25P, S28P, and S29P sites. We apply high-resolution cryo-electron microscopy and solve the structures of 6 polymorphs formed by these mutants, revealing the peptide's self-assembly patterns and identifying critical interactions that reinforce these structures in the presence of the β-sheet breaker.

Cryo-Electron Microscopy Provides Mechanistic Insights into Solution-Dependent Polymorphism and Cross-Aggregation Phenomena of the Human and Rat Islet Amyloid Polypeptides.

Inhibitors targeting amyloids formed by the human Islet Amyloid Polypeptide (hIAPP) are promising therapeutic candidates for type 2 diabetes. Peptide formulations derived from the nonamyloidogenic rat IAPP (rIAPP) sequence are currently used as hIAPP mimetics to support insulin therapy. rIAPP itself acts as a peptide inhibitor; yet, the structural-level consequences of such inhibition, particularly its impact on amyloid polymorphism, have not been studied in detail.

Improving cryo-EM grids for amyloid fibrils using interface-active solutions and spectator proteins.

Preparation of cryoelectron microscopy (cryo-EM) grids for imaging of amyloid fibrils is notoriously challenging. The human islet amyloid polypeptide (hIAPP) serves as a notable example, as the majority of reported structures have relied on the use of nonphysiological pH buffers, N-terminal tags, and seeding. This highlights the need for more efficient, reproducible methodologies that can elucidate amyloid fibril structures formed under diverse conditions.

Yeast as a tool for membrane protein production and structure determination.

Membrane proteins are challenging targets to functionally and structurally characterize. An enduring bottleneck in their study is the reliable production of sufficient yields of stable protein. Here, we evaluate all eukaryotic membrane protein production experiments that have supported the deposition of a high-resolution structure.