M.D. Enos scite author profile

G protein-coupled receptors (GPCRs) are integral membrane proteins that play an essential role in human physiology, yet the molecular processes through which they bind to their endogenous agonists and activate effector proteins remain poorly understood. Thus far, it has not been possible to capture an active-state GPCR bound to its native neurotransmitter. Crystal structures of agonist-bound GPCRs have relied on the use of either exceptionally high-affinity agonists1,2 or receptor stabilization by mutagenesis3-5. Many natural agonists such as adrenaline, which activates the β2-adrenoceptor (β2AR), bind with relatively low affinity, and they are often chemically unstable. Using directed evolution, we engineered a high-affinity camelid antibody fragment that stabilizes the active state of the β2AR, and used this to obtain crystal structures of the activated receptor bound to multiple ligands. Here, we present structures of active-state β2AR bound to three chemically distinct agonists: the ultra high-affinity agonist BI167107, the high-affinity catecholamine agonist hydroxybenzyl isoproterenol, and the low-affinity endogenous agonist adrenaline. The crystal structures reveal a highly conserved overall ligand recognition and activation mode despite diverse ligand chemical structures and affinities that range from 100 nM to ~80 pM. The adrenaline-bound receptor structure is overall similar to the others, but shows substantial rearrangements in extracellular loop three and the extracellular tip of transmembrane helix 6. These structures also reveal a water-mediated hydrogen bond between two conserved tyrosines, which appears to stabilize the active state of the β2AR and related GPCRs.

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Informal learning and the transfer of learning: How managers develop proficiency

Enos¹,

Kehrhahn²,

Bell

2003

Human Resource Dev Quarterly

204

152

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Structural basis of GSK-3 inhibition by N-terminal phosphorylation and by the Wnt receptor LRP6

et al. 2014

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Glycogen synthase kinase-3 (GSK-3) is a key regulator of many cellular signaling pathways. Unlike most kinases, GSK-3 is controlled by inhibition rather than by specific activation. In the insulin and several other signaling pathways, phosphorylation of a serine present in a conserved sequence near the amino terminus of GSK-3 generates an auto-inhibitory peptide. In contrast, Wnt/β-catenin signal transduction requires phosphorylation of Ser/Pro rich sequences present in the Wnt co-receptors LRP5/6, and these motifs inhibit GSK-3 activity. We present crystal structures of GSK-3 bound to its phosphorylated N-terminus and to two of the phosphorylated LRP6 motifs. A conserved loop unique to GSK-3 undergoes a dramatic conformational change that clamps the bound pseudo-substrate peptides, and reveals the mechanism of primed substrate recognition. The structures rationalize target sequence preferences and suggest avenues for the design of inhibitors selective for a subset of pathways regulated by GSK-3.DOI: http://dx.doi.org/10.7554/eLife.01998.001

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Limited dishevelled/Axin oligomerization determines efficiency of Wnt/β-catenin signal transduction

Kan

Enos

Korkmazhan

et al. 2020

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In Wnt/β-catenin signaling, the transcriptional coactivator β-catenin is regulated by its phosphorylation in a complex that includes the scaffold protein Axin and associated kinases. Wnt binding to its coreceptors activates the cytosolic effector Dishevelled (Dvl), leading to the recruitment of Axin and the inhibition of β-catenin phosphorylation. This process requires interaction of homologous DIX domains present in Dvl and Axin, but is mechanistically undefined. We show that Dvl DIX forms antiparallel, double-stranded oligomers in vitro, and that Dvl in cells forms oligomers typically <10 molecules at endogenous expression levels. Axin DIX (DAX) forms small single-stranded oligomers, but its self-association is stronger than that of DIX. DAX caps the ends of DIX oligomers, such that a DIX oligomer has at most four DAX binding sites. The relative affinities and stoichiometry of the DIX-DAX interaction provide a mechanism for efficient inhibition of β-catenin phosphorylation upon Axin recruitment to the Wnt receptor complex.

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Three αSNAP and 10 ATP Molecules Are Used in SNARE Complex Disassembly by N-ethylmaleimide-sensitive Factor (NSF)

Shah

Colbert

Enos

et al. 2015

Journal of Biological Chemistry

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Background:The ATPase NSF works with the adaptor protein ␣SNAP to disassemble SNARE protein complexes involved in membrane fusion.Results: Kinetic assays demonstrate that three ␣SNAP and 10 ATP molecules are required to disassemble a SNARE complex. Conclusion:The energy requirements and functional stoichiometry of ␣SNAP in SNARE complex disassembly are established. Significance:The results suggest models of NSF action.

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M.D. Enos

Adrenaline-activated structure of β2-adrenoceptor stabilized by an engineered nanobody

Informal learning and the transfer of learning: How managers develop proficiency

Structural basis of GSK-3 inhibition by N-terminal phosphorylation and by the Wnt receptor LRP6

Limited dishevelled/Axin oligomerization determines efficiency of Wnt/β-catenin signal transduction

Three αSNAP and 10 ATP Molecules Are Used in SNARE Complex Disassembly by N-ethylmaleimide-sensitive Factor (NSF)

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