Identification of a Highly Conserved Allosteric Binding Site on Mnk1 and Mnk2.

Elevated levels of phosphorylated eukaryotic initiation factor 4E (eIF4E) have been implicated in many tumor types, and mitogen activated protein kinase-interacting kinases (Mnks) are the only known kinases that phosphorylate eIF4E at Ser209. The phosphorylation of eIF4E is essential for oncogenic transformation but is of no significance to normal growth and development. Pharmacological inhibition of Mnks therefore provides a nontoxic and effective strategy for cancer therapy. However, a lack of specific Mnk inhibitors has confounded pharmacological target validation and clinical development. Herein, we report the identification of a novel series of Mnk inhibitors and their binding modes. A systematic workflow has been established to distinguish between type III and type I/II inhibitors. A selection of 66 compounds was tested for Mnk1 and Mnk2 inhibition, and 9 out of 20 active compounds showed type III interaction with an allosteric site of the proteins. Most of the type III inhibitors exhibited dual Mnk1 and Mnk2 activities and demonstrated potent antiproliferative properties against the MV4-11 acute myeloid leukemia cell line. Interestingly, ATP-/substrate-competitive inhibitors were found to be highly selective for Mnk2, with little or no activity for Mnk1. Our study suggests that Mnk1 and Mnk2 share a common structure of the allosteric inhibitory binding site but possess different structural features of the ATP catalytic domain. The findings will assist in the future design and development of Mnk targeted anticancer therapeutics.

From information management to protein annotation: preparing protein structures for drug discovery.

In contrast to academic pursuits of structural genomics, Structural GenomiX (SGX) solves protein structures at high throughput for the main purpose of enhancing drug-discovery projects, either internally or in partnership with pharmaceutical/biotechnology companies. This involves a radical redesign of the pipeline of methods that turn a gene sequence into a three-dimensional protein structure. The various processes all report electronically to a Laboratory Information Management System (LIMS) to make sure all the parameters of the experiment are recorded in an accessible and 'mineable' form, helping guarantee reproducibility of results. Quality control at several key points keeps the process from branching out on a wrong hypothesis. Protein annotation, in a broad sense, takes care of the interpretation of a protein crystal structure or the crystal structure of one or several protein-ligand complexes. This interpretation both gathers all necessary biological information (protein function, mechanism, specific features within a protein family etc.) and hands over this information in a form accessible to medicinal chemistry teams designing specific small-molecule agonists or antagonists.