Tamjeed Saleh scite author profile

Protein kinases intrinsically sample a number of conformational states with distinct catalytic and binding activities. We used nuclear magnetic resonance spectroscopy to describe in atomic-level detail how Abl kinase interconverts between an active and two discrete inactive structures. Extensive differences in key structural elements among the conformational states give rise to multiple intrinsic regulatory mechanisms. The findings explain how oncogenic mutants can counteract inhibitory mechanisms to constitutively activate the kinase. Energetic dissection revealed the contribution of the activation loop, the DFG motif, the regulatory spine and the gatekeeper residue to kinase regulation. Characterization of the transient conformation to which the drug imatinib binds enabled the elucidation of drug resistance mechanisms. Structural insight into inactive states highlights how they can be leveraged for the design of selective inhibitors.

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Proline cis-trans Isomerization Controls Autoinhibition of a Signaling Protein

Sarkar

et al. 2007

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Autoinhibition is being widely used in nature to repress otherwise constitutive protein activities and is typically regulated by extrinsic factors. Here we show that autoinhibition can be controlled by an intrinsic intramolecular switch afforded by prolyl cis-trans isomerization. We find that a proline on the linker tethering the two SH3 domains of the Crk adaptor protein interconverts between the cis and trans conformation. In the cis conformation, the two SH3 domains interact intramolecularly, thereby forming the basis of an autoinhibitory mechanism. Conversely, in the trans conformation Crk exists in an extended, uninhibited conformation that is marginally populated but serves to activate the protein upon ligand binding. Interconversion between the cis and trans, and, hence, of the autoinhibited and activated conformations, is accelerated by the action of peptidyl-prolyl isomerases. Proline isomerization appears to make an ideal switch that can regulate the kinetics of activation, thereby modulating the dynamics of signal response.

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Structural basis for regulation of the Crk signaling protein by a proline switch

et al. 2010

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Proline switches, controlled by cis–trans isomerization, have emerged as a particularly effective regulatory mechanism in a wide range of biological processes. Here we report the structures of both the cis and trans conformers of a proline switch in Crk signaling protein. Proline isomerization toggles Crk between two conformations: an autoinhibitory, stabilized by the intramolecular association of two tandem SH3 domains in the cis form, and an uninhibited, activated conformation promoted by the trans form. In addition to acting as a structural switch the heterogeneous proline recruits cyclophilin A, which accelerates the interconversion rate between the isomers thereby regulating the kinetics of Crk activation. The data provide atomic insight into the mechanisms that underpin the functionality of this binary switch and elucidate its remarkable efficiency. The results also reveal novel SH3 binding surfaces highlighting the binding versatility and expanding the non-canonical ligand repertoire of this important signaling domain.

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Domain organization differences explain Bcr-Abl's preference for CrkL over CrkII

et al. 2012

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CrkL is a key signaling protein that mediates the leukemogenic activity of Bcr-Abl. CrkL is thought to adopt a structure that is similar to that of its CrkII homolog. The two proteins share high sequence identity and indistinguishable ligand binding preferences; yet they have distinct physiological roles. Here we show that the structures of CrkL and phosphorylated CrkL are drastically different than the corresponding structures of CrkII. As a result, the binding activities of the SH2 and SH3 domains in the two proteins are regulated in a distinct manner and to a different extent. The different structural architecture of CrkL and CrkII may account for their distinct functional roles. The data show that CrkL forms a constitutive complex with Abl thus explaining the strong preference of Bcr-Abl for CrkL. The results also highlight how the structural organization of the modular domains in adaptor proteins can control signaling outcome.

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Atomic view of the energy landscape in the allosteric regulation of Abl kinase

Saleh

Rossi

2017

Nat Struct Mol Biol

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The activity of protein kinases is often regulated in an intramolecular fashion by signaling domains, which feature several phosphorylation or protein-docking sites. How kinases integrate such distinct binding and signaling events to regulate their activities is unclear, especially in quantitative terms. We have used NMR spectroscopy to show how structural elements within the Abl regulatory module (RM) form synergistically a multilayered allosteric mechanism that enables Abl kinase to function as a finely-tuned switch. We dissected the structure and energetics of the regulatory mechanism to precisely measure the effect of various stimuli, activating or inhibiting, on the Abl kinase activity. The data provide the mechanistic basis for explaining genetic observations and reveal a novel activator region within Abl. Our findings show that drug-resistant mutations in the Abl RM exert their allosteric effect by promoting the activated state of Abl and not by decreasing the drug affinity for the kinase.

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Tamjeed Saleh

Conformational states dynamically populated by a kinase determine its function

Proline cis-trans Isomerization Controls Autoinhibition of a Signaling Protein

Structural basis for regulation of the Crk signaling protein by a proline switch

Domain organization differences explain Bcr-Abl's preference for CrkL over CrkII

Atomic view of the energy landscape in the allosteric regulation of Abl kinase

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