Explore the Potential with AI-Driven Innovation
The specialised, focused library is developed on demand with the most recent virtual screening and parameter assessment technology, guided by the Receptor.AI drug discovery platform. This approach exceeds the capabilities of traditional methods and offers compounds with higher activity, selectivity, and safety.
We carefully select specific compounds from a vast collection of over 60 billion molecules in virtual chemical space. Our partner Reaxense helps in synthesizing and delivering these compounds.
Contained in the library are leading modulators, each labelled with 38 ADME-Tox and 32 physicochemical and drug-likeness qualities. In addition, each compound is illustrated with its optimal docking poses, affinity scores, and activity scores, giving a complete picture.
Our top-notch dedicated system is used to design specialised libraries.
Fig. 1. The sreening 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 distinguishes itself through several key aspects:
partner
Reaxense
upacc
Q96BS2
UPID:
CHP3_HUMAN
Alternative names:
Tescalcin
Alternative UPACC:
Q96BS2; F5H1Y5; Q9NWT9
Background:
Tescalcin, also known as Calcineurin B homologous protein 3, plays a pivotal role in cell pH regulation by modulating Na(+)/H(+) exchange activity. It is crucial for the maturation and function of SLC9A1/NHE1, influencing hematopoietic stem cell differentiation towards megakaryocytic lineage. Tescalcin is essential in linking ERK cascade activation to ETS family gene expression during megakaryocytic differentiation and supports granulocytic differentiation in an ERK-dependent manner. Additionally, it serves as an inhibitor of calcineurin's phosphatase activity.
Therapeutic significance:
Understanding the role of Tescalcin could open doors to potential therapeutic strategies.