Through fragment-based drug design focused on engaging the active site of IRAK4 and leveraging three-dimensional topology in a ligand-efficient manner, a micromolar hit identified from a screen of a Pfizer fragment library was optimized to afford IRAK4 inhibitors with nanomolar potency in cellular assays. The medicinal chemistry effort featured the judicious placement of lipophilicity, informed by co-crystal structures with IRAK4 and optimization of ADME properties to deliver clinical candidate PF-06650833 (compound 40). This compound displays a 5-unit increase in lipophilic efficiency from the fragment hit, excellent kinase selectivity, and pharmacokinetic properties suitable for oral administration.
The acetyl post-translational modification of chromatin at selected histone lysine residues is interpreted by an acetyl-lysine specific interaction with bromodomain reader modules. Here we report the discovery of the potent, acetyl-lysine competitive and cell active inhibitor PFI-3 that binds to certain Family VIII bromodomains while displaying significant, broader bromodomain family selectivity. The high specificity of PFI-3 for Family VIII was achieved through a novel bromodomain binding mode of a phenolic head group that led to the unusual displacement of water molecules that are generally retained by most other bromodomain inhibitors reported to date. The medicinal chemistry program that led to PFI-3 from an initial fragment screening hit is described in detail and additional analogues with differing Family VIII bromodomain selectivity profiles are also reported. We also describe the full pharmacological characterization of PFI-3 as a chemical probe, along with phenotypic data on adipocyte and myoblast cell differentiation assays.
Compound 4 (PF-04971729) belongs to a new class of potent and selective sodium-dependent glucose cotransporter 2 inhibitors incorporating a unique dioxa-bicyclo[3.2.1]octane (bridged ketal) ring system. In this paper we present the design, synthesis, preclinical evaluation, and human dose predictions related to 4. This compound demonstrated robust urinary glucose excretion in rats and an excellent preclinical safety profile. It is currently in phase 2 clinical trials and is being evaluated for the treatment of type 2 diabetes.
Crystal
structure prediction (CSP) calculations can reduce risk
and improve efficiency during drug development. Traditionally, CSP
calculations use lattice energies computed through density functional
theory. While this approach is often successful in predicting the
low energy structures, it neglects the crucial role of thermal effects
on polymorph stabilities. In the present study, we develop a robust
and efficient protocol for predicting the relative stability of polymorphs
at different temperatures. The protocol is executed on a highly parallel
cloud computing infrastructure to produce results at time scales useful
for drug development timelines. We demonstrate this protocol on molecule
XXIII from the sixth crystal structure prediction blind test. Our
results predict that Form D is the most stable experimentally observed
polymorph at ambient temperature and Form C is the most stable at
low temperature consistent with experiments also conducted in the
present study.
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