Grace R. Jeschke scite author profile

Phosphorylation is a universal mechanism for regulating cell behavior in eukaryotes. Although protein kinases are known to target short linear sequence motifs on their substrates, the rules for kinase substrate recognition are not completely understood. We used a rapid peptide screening approach to determine consensus phosphorylation site motifs targeted by 61 of the 122 kinases in Saccharomyces cerevisae. Correlation of these motifs with kinase primary sequence has uncovered previously unappreciated rules for determining specificity within the kinase family, including a residue determining P−3 Arg specificity among members of the CMGC group of kinases. Furthermore, computational scanning of the yeast proteome enabled the prediction of thousands of new kinase-substrate relationships. We experimentally verified several candidate substrates of the Prk1 family of kinases in vitro and in vivo, and we identified a protein substrate of the kinase Vhs1. Together, these results elucidate how kinase catalytic domains recognize their phosphorylation targets and suggest general avenues for the identification of new kinase substrates across eukaryotes.

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Active-site determinants of substrate recognition by the metalloproteinases TACE and ADAM10

Caescu

Jeschke

Turk

2009

160

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The metalloproteinases TACE (ADAM17) and ADAM10 are the primary enzymes responsible for catalyzing release of membrane anchored proteins from the cell surface in metazoan organisms. While the repertoire of protein substrates for these two proteases is partially overlapping, each one appears to target a subset of unique proteins in vivo. The mechanisms by which the two proteases achieve specificity for particular substrates are not completely understood. We have used peptide libraries to define the cleavage site selectivity of TACE and ADAM10. The two proteases have distinct primary sequence requirements at multiple positions surrounding the cleavage site in their substrates, which allowed us to generate peptide substrates that are highly specific for each of these proteases. The major difference between the two protease specificities maps to the P1′ position (immediately downstream of the cleavage site) of the substrate. At this position, TACE is selective for smaller aliphatic residues, while ADAM10 can accommodate aromatic amino acids. Using mutagenesis we identify three residues in the S1′ pockets of these enzymes that dramatically influence specificity for both peptide and protein substrates. Our results suggest that substrate selectivity of TACE and ADAM10 can be at least partly rationalized by specific features of their active sites.

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Crenolanib is a selective type I pan-FLT3 inhibitor

Smith

Lasater²,

Lin³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

191

148

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Tyrosine kinase inhibitors (TKIs) represent transformative therapies for several malignancies. Two critical features necessary for maximizing TKI tolerability and response duration are kinase selectivity and invulnerability to resistance-conferring kinase domain (KD) mutations in the intended target. No prior TKI has demonstrated both of these properties. Aiming to maximize selectivity, medicinal chemists have largely sought to create TKIs that bind to an inactive (type II) kinase conformation. Here we demonstrate that the investigational type I TKI crenolanib is a potent inhibitor of Fms tyrosine kinase-3 (FLT3) internal tandem duplication, a validated therapeutic target in human acute myeloid leukemia (AML), as well as all secondary KD mutants previously shown to confer resistance to the first highly active FLT3 TKI quizartinib. Moreover, crenolanib is highly selective for FLT3 relative to the closely related protein tyrosine kinase KIT, demonstrating that simultaneous FLT3/KIT inhibition, a prominent feature of other clinically active FLT3 TKIs, is not required for AML cell cytotoxicity in vitro and may contribute to undesirable toxicity in patients. A saturation mutagenesis screen of FLT3-internal tandem duplication failed to recover any resistant colonies in the presence of a crenolanib concentration well below what has been safely achieved in humans, suggesting that crenolanib has the potential to suppress KD mutation-mediated clinical resistance. Crenolanib represents the first TKI to exhibit both kinase selectivity and invulnerability to resistance-conferring KD mutations, which is unexpected of a type I inhibitor. Crenolanib has significant promise for achieving deep and durable responses in FLT3-mutant AML, and may have a profound impact upon future medicinal chemistry efforts in oncology.sorafenib | activation-loop mutations | D835 mutations P ioneering studies demonstrated that imatinib, the first small molecule tyrosine kinase inhibitor (TKI), binds to an inactive kinase conformation of the Abelson protein tyrosine kinase (ABL) (1). Compounds that bind to kinases in this manner have been termed "type II", whereas "type I" inhibitors bind to an active conformation. Type II inhibitors typically target the ATP binding region and an adjacent allosteric site available only in an inactive conformation. Because this region is less well conserved among kinases than the ATP binding region, interactions with this area allow for greater selectivity.Despite the clinical success of imatinib for the treatment of chronic myeloid leukemia (CML), durability of response is compromised by secondary kinase domain (KD) mutations in BCR-ABL (1), many of which destabilize the inactive conformation required for imatinib binding (1). Second-generation ABL inhibitors, dasatinib (type I) and nilotinib (type II), were subsequently developed to retain efficacy against most imatinib-resistant BCR-ABL KD mutants, and each are vulnerable to only approximately five resistance-conferring mutations (2, 3). In contrast, the third-gene...

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Heterogeneous resistance to quizartinib in acute myeloid leukemia revealed by single-cell analysis

et al. 2017

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Genomic studies have revealed significant branching heterogeneity in cancer. Studies of resistance to tyrosine kinase inhibitor therapy have not fully reflected this heterogeneity because resistance in individual patients has been ascribed to largely mutually exclusive on-target or off-target mechanisms in which tumors either retain dependency on the target oncogene or subvert it through a parallel pathway. Using targeted sequencing from single cells and colonies from patient samples, we demonstrate tremendous clonal diversity in the majority of acute myeloid leukemia (AML) patients with activating internal tandem duplication mutations at the time of acquired resistance to the FLT3 inhibitor quizartinib. These findings establish that clinical resistance to quizartinib is highly complex and reflects the underlying clonal heterogeneity of AML.

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Reciprocal Phosphorylation of Yeast Glycerol-3-Phosphate Dehydrogenases in Adaptation to Distinct Types of Stress

Lee

Jeschke

Roelants

et al. 2012

Molecular and Cellular Biology

106

108

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bEukaryotic cells have evolved mechanisms for ensuring growth and survival in the face of stress caused by a fluctuating environment. Saccharomyces cerevisiae has two homologous glycerol-3-phosphate dehydrogenases, Gpd1 and Gpd2, that are required to endure various stresses, including hyperosmotic shock and hypoxia. These enzymes are only partially redundant, and their unique functions were attributed previously to differential transcriptional regulation and localization. We find that Gpd1 and Gpd2 are negatively regulated through phosphorylation by distinct kinases under reciprocal conditions. Gpd2 is phosphorylated by the AMP-activated protein kinase Snf1 to curtail glycerol production when nutrients are limiting. Gpd1, in contrast, is a target of TORC2-dependent kinases Ypk1 and Ypk2. Inactivation of Ypk1 by hyperosmotic shock results in dephosphorylation and activation of Gpd1, accelerating recovery through increased glycerol production. Gpd1 dephosphorylation acts synergistically with its transcriptional upregulation, enabling long-term growth at high osmolarity. Phosphorylation of Gpd1 and Gpd2 by distinct kinases thereby enables rapid adaptation to specific stress conditions. Introduction of phosphorylation motifs targeted by distinct kinases provides a general mechanism for functional specialization of duplicated genes during evolution.

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Grace R. Jeschke

Deciphering Protein Kinase Specificity Through Large-Scale Analysis of Yeast Phosphorylation Site Motifs

Active-site determinants of substrate recognition by the metalloproteinases TACE and ADAM10

Crenolanib is a selective type I pan-FLT3 inhibitor

Heterogeneous resistance to quizartinib in acute myeloid leukemia revealed by single-cell analysis

Reciprocal Phosphorylation of Yeast Glycerol-3-Phosphate Dehydrogenases in Adaptation to Distinct Types of Stress

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