Introduction

Figure 1. AMYR with RAMP3 and Amylin Peptide

The human amylin receptor is a G-coupled protein receptor.

Amylin

Amylin is a neuroendocrine hormone that is synthesized with insulin in the beta cells of pancreatic islets. It can cross the blood-brain barrier and regulates glucose homeostasis via inhibiting gastric emptying, inhibiting the release of glucagon, and inducing meal-ending satiety. In doing so, it prevents spikes in blood glucose and overeating, making it a suitable target for Type 2 Diabetes. Type 2 Diabetes treatments and therapies. Seeing as Type 2 Diabetes is a major risk factor for Alzheimer's Disease, as Type 2 Diabetes cases continue to increase, there will likely be a spike in Alzheimer’s Disease as well. Therefore, it is vital that amylin, its receptor, and analogs such as pramlintide are understood to aid in rational drug design.

Structure

Amylin Receptor

The amylin receptor (AMYR) is the result of the heterodimerization of the calcitonin receptor (CT) and a receptor-activity modifying protein (RAMP). The patterns of peptide interaction between CT and AMYR are very similar overall, but amylin has a higher affinity for AMYR1 and AMYR3 than AMYR2.

Calcitonin Receptor and G-alpha Interactions

RAMPs

Amylin Binding

Amylin Receptor Functional Overview

Hydrophobic Interactions

The tyrosine on the C-terminus of the amylin peptide has extensive van der Waals interactions with the CT and RAMP3. The pi stacking and hydrophobic interactions increase the affinity and interactions between the amylin peptide, CT, and RAMP3, aiding in their association.

Amidated C-Terminus

R11

R18

T9 Water Network

Disease

Pramlintide Analogue

The first human amylin analogue, pramlintide, was developed in 1995, and marked a significant advancement in the treatment of Type II Diabetes. As of 2024, it is the only FDA-approved drug for the treatment of Type II Diabetes using the AMYR as a target. Recent studies in rodent Alzheimer’s Disease models suggest that pramlintide reduces amyloid-beta plaques, making it a potential therapeutic target for Alzheimer’s Disease.

There is limited knowledge about how human amylin binds to the human AMYR, so many studies utilize rat amylin as the peptide for the human AMYR. Rat amylin and pramlintide showcase very similar structures and maintain a high sequence similarity. For instance, the N-term lysine residue is conserved between rat amylin and pramlintide, as well as human amylin, suggesting that the lysine is integral for binding to AMYR. The residue changes between the two include INSERt INSERT, INSERT, INSERT. While these residues differ, the overall properties of the various residues remain consistent, so many of the same interactions with AMYR are likely still able to form.

Human amylin and pramlintide only differ at 3 residues, with all three being changed to proline in pramlintide. The Ala25Pro, Ser28Pro, and Ser29Pro mutations break the helical nature present in human amylin, which likely prevents the aggregation of amyloid beta plaques in Alzheimer’s Disease.

Relevance

Structural highlights

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