Explore the Potential with AI-Driven Innovation
The focused library is created on demand with the latest virtual screening and parameter assessment technology, supported by the Receptor.AI drug discovery platform. This method is more effective than traditional methods and results in higher-quality compounds with better activity, selectivity, and safety.
Our selection of compounds is from a large virtual library of over 60 billion molecules. The production and distribution of these compounds are managed by our partner Reaxense.
The library includes a list of the most promising modulators annotated with 38 ADME-Tox and 32 physicochemical and drug-likeness parameters. Also, each compound is presented with its optimal docking poses, affinity scores, and activity scores, providing a comprehensive overview.
Our high-tech, dedicated method is applied to construct targeted libraries.
Fig. 1. The sreening workflow of Receptor.AI
Our strategy employs molecular simulations to explore an extensive range of proteins, capturing their dynamics both individually and within complexes with other proteins. Through ensemble virtual screening, we address proteins' conformational mobility, uncovering key binding sites at both functional regions and remote allosteric locations. This comprehensive investigation ensures a thorough assessment of all potential mechanisms of action, with the goal of discovering innovative therapeutic targets and lead molecules across across diverse biological functions.
Our library is unique due to several crucial aspects:
partner
Reaxense
upacc
Q9Y3B6
UPID:
EMC9_HUMAN
Alternative names:
Protein FAM158A
Alternative UPACC:
Q9Y3B6; D3DS60; Q9BUM3
Background:
ER membrane protein complex subunit 9, also known as Protein FAM158A, plays a crucial role in the endoplasmic reticulum (ER) by facilitating the insertion of newly synthesized membrane proteins into the ER membrane. It specifically aids proteins with weakly hydrophobic transmembrane domains or those containing destabilizing features. This protein is essential for the cotranslational and post-translational insertion of multi-pass and tail-anchored membrane proteins, respectively, ensuring correct protein topology and functionality.
Therapeutic significance:
Understanding the role of ER membrane protein complex subunit 9 could open doors to potential therapeutic strategies.