Cancer cells exhibit several unique metabolic phenotypes that are critical for cell growth and proliferation. Specifically, they over-express the M2 isoform of the tightly regulated enzyme pyruvate kinase (PKM2), which controls glycolytic flux, and they are highly dependent on de novo biosynthesis of serine and glycine. Here we describe a novel rheostat-like mechanistic relationship between PKM2 activity and serine biosynthesis. We show that serine can bind to and activate human PKM2 and that following serine deprivation, PKM2 activity in cells is reduced. This reduction in PKM2 activity shifts cells to a fuel-efficient mode where more pyruvate is diverted to the mitochondria and more glucose derived carbon is channelled into serine biosynthesis to support cell proliferation.
The application of fragment-based screening techniques to cyclin dependent kinase 2 (CDK2) identified multiple (>30) efficient, synthetically tractable small molecule hits for further optimization. Structure-based design approaches led to the identification of multiple lead series, which retained the key interactions of the initial binding fragments and additionally explored other areas of the ATP binding site. The majority of this paper details the structure-guided optimization of indazole (6) using information gained from multiple ligand-CDK2 cocrystal structures. Identification of key binding features for this class of compounds resulted in a series of molecules with low nM affinity for CDK2. Optimisation of cellular activity and characterization of pharmacokinetic properties led to the identification of 33 (AT7519), which is currently being evaluated in clinical trials for the treatment of human cancers.
Here, we describe the identification of a clinical candidate via structure-based optimization of a ligand efficient pyrazole-benzimidazole fragment. Aurora kinases play a key role in the regulation of mitosis and in recent years have become attractive targets for the treatment of cancer. X-ray crystallographic structures were generated using a novel soakable form of Aurora A and were used to drive the optimization toward potent (IC(50) approximately 3 nM) dual Aurora A/Aurora B inhibitors. These compounds inhibited growth and survival of HCT116 cells and produced the polyploid cellular phenotype typically associated with Aurora B kinase inhibition. Optimization of cellular activity and physicochemical properties ultimately led to the identification of compound 16 (AT9283). In addition to Aurora A and Aurora B, compound 16 was also found to inhibit a number of other kinases including JAK2 and Abl (T315I). This compound demonstrated in vivo efficacy in mouse xenograft models and is currently under evaluation in phase I clinical trials.
The cyclin D1-cyclin-dependent kinase 4 (CDK4) complex is a key regulator of the transition through the G1 phase of the cell cycle. Among the cyclin/CDKs, CDK4 and cyclin D1 are the most frequently activated by somatic genetic alterations in multiple tumor types. Thus, aberrant regulation of the CDK4/cyclin D1 pathway plays an essential role in oncogenesis; hence, CDK4 is a genetically validated therapeutic target. Although X-ray crystallographic structures have been determined for various CDK/cyclin complexes, CDK4/cyclin D1 has remained highly refractory to structure determination. Here, we report the crystal structure of CDK4 in complex with cyclin D1 at a resolution of 2.3 Å. Although CDK4 is bound to cyclin D1 and has a phosphorylated T-loop, CDK4 is in an inactive conformation and the conformation of the heterodimer diverges from the previously known CDK/cyclin binary complexes, which suggests a unique mechanism for the process of CDK4 regulation and activation. CDK4 and CDK6 associate with the D-type cyclins (D1, D2, D3) and phosphorylate and inactivate the retinoblastoma (Rb) protein family members (p107, p130, pRb). Phosphorylation of pRb by CDK4/6 then leads to the derepression and activation of E2F target genes, including the E-type cyclins, which facilitate progression through the G 1 phase of the cell cycle.Deregulation of the CDK4/cyclin D pathway has been identified in many cancers (refs. 4 and 5 and references therein and ref. 6). Notably, most genetic alterations target specifically CDK4 or cyclin D1, whereas alterations in other CDKs and cyclins are far less common. The CDK4 gene is amplified in a high percentage of liposarcomas (7), and breast cancers frequently exhibit high cyclin D1 levels, either through genetic amplification of the gene or overexpression (8). Translocation of cyclin D1 to the IgH promoter is a hallmark aberration in mantle cell lymphoma (9). Cyclin D1 translocations can also be detected in many cases of multiple myelomas (10). A mutation of CDK4 (Arg-24-Cys) that renders it refractory to inhibition by the tumor suppressor protein p16INK4a has also been identified, and, similarly, deletion or mutation of the p16INK4a gene results in defective CDK4 inhibition and dysregulated CDK4 activity (11). Finally, genetic inactivation of p16INK4 is among the most frequent tumor suppressor mutations found in human cancers. Taken together, these data indicate that an unchecked or hyperactivated CDK4/cyclin D1 pathway may be responsible for enhanced cellular proliferation in cancers and imply that CDK4 is a promising target for the development of anticancer therapies (reviewed in ref. 12).The molecular basis of CDK activation has been the focus of many studies using cellular, biochemical, and structural approaches (reviewed in ref.3). Maximal CDK activation requires both binding of a cognate cyclin and phosphorylation of residues within the CDK T-loop, and X-ray crystallographic studies of various CDKs and CDK/cyclin complexes have identified the conformational movements associated with ...
We describe the structure-guided optimization of the molecular fragments 2-amino-3-benzyloxypyridine 1 (IC(50) 1.3 mM) and 3-(2-(4-pyridyl)ethyl)indole 2 (IC(50) 35 microM) identified using X-ray crystallographic screening of p38alpha MAP kinase. Using two separate case studies, the article focuses on the key compounds synthesized, the structure-activity relationships and the binding mode observations made during this optimization process, resulting in two potent lead series that demonstrate significant increases in activity. We describe the process of compound elaboration either through the growing out from fragments into adjacent pockets or through the conjoining of overlapping fragments and demonstrate that we have exploited the mobile conserved activation loop, consisting in part of Asp168-Phe169-Gly170 (DFG), to generate significant improvements in potency and kinase selectivity.
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