Jun N-terminal kinase (JNK) is a stress-activated protein kinase that can be induced by inflammatory cytokines, bacterial endotoxin, osmotic shock, UV radiation, and hypoxia. We report the identification of an anthrapyrazolone series with significant inhibition of JNK1, -2, and -3 (K i ؍ 0.19 M). SP600125 is a reversible ATPcompetitive inhibitor with >20-fold selectivity vs. a range of kinases and enzymes tested. In cells, SP600125 dose dependently inhibited the phosphorylation of c-Jun, the expression of inflammatory genes COX-2, IL-2, IFN-␥, TNF-␣, and prevented the activation and differentiation of primary human CD4 cell cultures. In animal studies, SP600125 blocked (bacterial) lipopolysaccharideinduced expression of tumor necrosis factor-␣ and inhibited anti-CD3-induced apoptosis of CD4 ؉ CD8 ؉ thymocytes. Our study supports targeting JNK as an important strategy in inflammatory disease, apoptotic cell death, and cancer.
Activating mutations in the receptor tyrosine kinase FLT3 are present in up to approximately 30% of acute myeloid leukemia (AML) patients, implicating FLT3 as a driver of the disease and therefore as a target for therapy. We report the characterization of AC220, a second-generation FLT3 inhibitor, and a comparison of AC220 with the first-generation FLT3 inhibitors CEP-701, MLN-518, PKC-412, sorafenib, and sunitinib. AC220 exhibits low nanomolar potency in biochemical and cellular assays and exceptional kinase selectivity, and in animal models is efficacious at doses as low as 1 mg/kg given orally once daily. The data reveal that the combination of excellent potency, selectivity, and pharmacokinetic properties is unique to AC220, which therefore is the first drug candidate with a profile that matches the characteristics desirable for a clinical FLT3 inhibitor. (Blood. 2009; 114:2984-2992) IntroductionThe presence of genetic changes in cancer cells that lead to dysregulated activation of kinases frequently signals that the activated kinase is a contributing driver of disease, 1-4 and inhibitors of activated kinases can have a dramatic impact on disease progression in patients with these genetic alterations. 5,6 To clearly define the role of the dysregulated kinase, and to determine whether inhibition of the mutant kinase is sufficient to induce a therapeutic benefit, requires drugs capable of selectively, potently, and preferably sustainably inhibiting the activated kinase in patients.Activating mutations in the FLT3 receptor tyrosine kinase have been identified in up to 30% of acute myeloid leukemia (AML) patients. 7,8 The most common class of mutation is internal tandem duplications (ITDs) in the juxtamembrane domain 7,9 that lead to constitutive, ligand-independent activation of the kinase. 7,10 The prognosis for patients with FLT3-ITD mutations is significantly worse than that for patients with wild-type FLT3 when treated with standard therapy. [7][8][9][11][12][13][14][15][16] The presence of activating FLT3 mutations and the correlation of FLT3 activation with a poor prognosis strongly suggest that FLT3 is a driver of disease in AML, at least in patients with FLT3-ITD mutations. Several small molecule kinase inhibitors with activity against FLT3 have been evaluated in AML patients, including CEP-701 (lestaurtinib), PKC-412 (midostaurin), MLN-518 (tandutinib; previously known as CT-53518), sunitinib (SU-11248), sorafenib , and KW-2449. The compounds inhibit FLT3 in cellular assays and are efficacious in mouse models of FLT3-ITD AML. [17][18][19][20][21][22] In phase 1 and phase 2 clinical trials, conducted primarily in relapsed or refractory AML patients, responses were consistently observed with each of these drugs, 21,[23][24][25][26][27][28][29][30][31] however, responses generally were relatively limited and not durable. 21,[23][24][25]30 The studies did reveal a relationship between the likelihood of observing a clinical response and the pharmacokinetics/pharmacodynamics of FLT3 inhibition, and highlight...
Treatment of AML patients with small molecule inhibitors of FLT3 kinase has been explored as a viable therapy. However, these agents are found to be less than optimal for the treatment of AML because of lack of sufficient potency or suboptimal oral pharmacokinetics (PK) or lack of adequate tolerability at efficacious doses. We have developed a series of extremely potent and highly selective FLT3 inhibitors with good oral PK properties. The first series of compounds represented by 1 (AB530) was found to be a potent and selective FLT3 kinase inhibitor with good PK properties. The aqueous solubility and oral PK properties at higher doses in rodents were found to be less than optimal for clinical development. A novel series of compounds were designed lacking the carboxamide group of 1 with an added water solubilizing group. Compound 7 (AC220) was identified from this series to be the most potent and selective FLT3 inhibitor with good pharmaceutical properties, excellent PK profile, and superior efficacy and tolerability in tumor xenograft models. Compound 7 has demonstrated a desirable safety and PK profile in humans and is currently in phase II clinical trials.
In 1975, Hamberg et al. reported evidence for the existence of an unstable platelet-aggregating factor which they named thromboxane A2 (TXA2) and for which they proposed a novel bicyclic oxetane structure (1, below) based on the short half-life of the factor (t1/2 (37 degrees C) = 32 s at pH 7.4) and the isolation of degradation products related to thromboxane (TXB2) (2, below). As natural TXA2 has not yet been isolated and characterized as a pure compound, we have synthesized the proposed structure (1) from TXB2 and compared its biological properties with those of authentic, biologically generated material. Here we present evidence that synthetic material having structure (1) is indistinguishable from platelet-derived TXA2 in various biological assays and that the proposed structure (1) for TXA2 is correct.
Adenosine kinase (AK) is an enzyme responsible for converting endogenous adenosine (ADO) to adenosine monophosphate (AMP) in an adenosine triphosphate- (ATP-) dependent manner. The structure of AK consists of two domains, the first a large alpha/beta Rossmann-like nucleotide binding domain that forms the ATP binding site, and a smaller mixed alpha/beta domain, which, in combination with the larger domain, forms the ADO binding site and the site of phosphoryl transfer. AK inhibitors have been under investigation as antinociceptive, antiinflammatory, and anticonvulsant as well as antiinfective agents. In this work, we report the structures of AK in complex with two classes of inhibitors: the first, ADO-like, and the second, a novel alkynylpyrimidine series. The two classes of structures, which contain structurally similar substituents, reveal distinct binding modes in which the AK structure accommodates the inhibitor classes by a 30 degrees rotation of the small domain relative to the large domain. This change in binding mode stabilizes an open and a closed intermediate structural state and provide structural insight into the transition required for catalysis. This results in a significant rearrangement of both the protein active site and the orientation of the alkynylpyrimidine ligand when compared to the observed orientation of nucleosidic inhibitors or substrates.
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