Protocol for phospho-SrcKD: rPTPεD1 complex preparation and BLI binding assays to demonstrate their exosite interface.

Here, we present a protocol for the in vitro phosphorylation of Src kinase domain (SrcKD), preparation of phospho-SrcKD in complex with the D1 domain of rPTP epsilon (rPTPεD1), and binding assays using biolayer interferometry (BLI). We describe steps for the in vitro phosphorylation of SrcKD and preparation of the phospho-SrcKD: rPTPεD1 complex for small-angle X-ray scattering (SAXS) experiments. We then detail instructions for the BLI binding assay to determine the binding affinity between phospho-SrcKD and rPTPεD1.

An integrative approach unveils a distal encounter site for rPTPε and phospho-Src complex formation.

The structure determination of protein tyrosine phosphatase (PTP): phospho-protein complexes, which is essential to understand how specificity is achieved at the amino acid level, remains a significant challenge for protein crystallography and cryoEM due to the transient nature of binding interactions. Using rPTPεD1 and phospho-SrcKD as a model system, we have established an integrative workflow to address this problem, by means of which we generate a protein:phospho-protein complex model using predetermined protein structures, SAXS and pTyr-tailored MD simulations. Our model reveals transient protein-protein interactions between rPTPεD1 and phospho-SrcKD and is supported by three independent experimental validations.

The discovery of novel heat-stable keratinases from Meiothermus taiwanensis WR-220 and other extremophiles.

Billions of tons of keratin bio-wastes are generated by poultry industry annually but discarded that result in serious environmental pollution. Keratinase is a broad spectrum protease with the unique ability to degrade keratin, providing an eco-friendly way to convert keratin wastes to valuable amino acids. In this report, a feather-degrading thermophilic bacterium, Meiothermus taiwanensis WR-220, was investigated due to its ability to apparently complete feather decay at 65 °C in two days.

An Unexpected Mode Of Binding Defines BMS948 as A Full Retinoic Acid Receptor β (RARβ, NR1B2) Selective Agonist.

Retinoic acid is an important regulator of cell differentiation which plays major roles in embryonic development and tissue remodeling. The biological action of retinoic acid is mediated by three nuclear receptors denoted RARα, β and γ. Multiple studies support that RARβ possesses functional characteristics of a tumor suppressor and indeed, its expression is frequently lost in neoplastic tissues.