Focused On-demand Libraries - Receptor.AI Collaboration


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.


From a virtual chemical space containing more than 60 billion molecules, we precisely choose certain compounds. Reaxense aids in their synthesis and provision.


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 top-notch dedicated system is used to design specialised libraries.


 

Fig. 1. The screening workflow of Receptor.AI

By deploying molecular simulations, our approach comprehensively covers a broad array of proteins, tracking their flexibility and dynamics individually and within complexes. Ensemble virtual screening is utilised to take into account conformational dynamics, identifying pivotal binding sites located within functional regions and at allosteric locations. This thorough exploration ensures that every conceivable mechanism of action is considered, aiming to identify new therapeutic targets and advance lead compounds throughout a vast spectrum of biological functions.


Our library is unique due to several crucial aspects:


  • Receptor.AI compiles all relevant data on the target protein, such as past experimental results, literature findings, known ligands, and structural data, thereby enhancing the likelihood of focusing on the most significant compounds.

  • By utilizing advanced molecular simulations, the platform is adept at locating potential binding sites, rendering the compounds in the focused library well-suited for unearthing allosteric inhibitors and binders for hidden pockets.

  • The platform is supported by more than 50 highly specialized AI models, all of which have been rigorously tested and validated in diverse drug discovery and research programs. Its design emphasizes efficiency, reliability, and accuracy, crucial for producing focused libraries.

  • Receptor.AI extends beyond just creating focused libraries; it offers a complete spectrum of services and solutions during the preclinical drug discovery phase, with a success-dependent pricing strategy that reduces risk and fosters shared success in the project.


PARTNER
Receptor.AI
 
UPACC
Q9HD67

UPID:
MYO10_HUMAN

ALTERNATIVE NAMES:
Unconventional myosin-10

ALTERNATIVE UPACC:
Q9HD67; A7E2D1; O94893; Q8IVX5; Q9NYM7; Q9P110; Q9P111; Q9UHF6

BACKGROUND:
Unconventional myosin-X, also known as Unconventional myosin-10, is a key player in cellular mechanics and signaling. It possesses ATPase activity and is involved in the directed movement along actin filaments, showing enhanced activity on actin bundles. This protein is essential for regulating cell morphology, adhesion, and motility, and it significantly influences filopodia formation and elongation. In neurons, Unconventional myosin-X is crucial for dendritic spine formation and the regulation of synaptic structure by modulating the localization of actin-remodeling proteins. It also contributes to the podosome belt formation in osteoclasts, indicating its role in cell structure and function.

THERAPEUTIC SIGNIFICANCE:
Understanding the role of Unconventional myosin-X could open doors to potential therapeutic strategies.

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