Canonical fibroblast growth factors (FGFs) activate FGF receptors (FGFRs) through paracrine or autocrine mechanisms in a process that requires cooperation with heparan sulfate proteoglycans, which function as co-receptors for FGFR activation. By contrast, endocrine FGFs (FGF19, FGF21 and FGF23) are circulating hormones that regulate critical metabolic processes in a variety of tissues. FGF19 regulates bile acid synthesis and lipogenesis, whereas FGF21 stimulates insulin sensitivity, energy expenditure and weight loss. Endocrine FGFs signal through FGFRs in a manner that requires klothos, which are cell-surface proteins that possess tandem glycosidase domains. Here we describe the crystal structures of free and ligand-bound β-klotho extracellular regions that reveal the molecular mechanism that underlies the specificity of FGF21 towards β-klotho and demonstrate how the FGFR is activated in a klotho-dependent manner. β-Klotho serves as a primary 'zip code'-like receptor that acts as a targeting signal for FGF21, and FGFR functions as a catalytic subunit that mediates intracellular signalling. Our structures also show how the sugar-cutting enzyme glycosidase has evolved to become a specific receptor for hormones that regulate metabolic processes, including the lowering of blood sugar levels. Finally, we describe an agonistic variant of FGF21 with enhanced biological activity and present structural insights into the potential development of therapeutic agents for diseases linked to endocrine FGFs.
Augmentor α and β (FAM150) are ligands of the receptor tyrosine kinases ALK and LTK: Hierarchy and specificity of ligand–receptor interactions
Receptor tyrosine kinases (RTKs) are a class of cell surface receptors that, upon ligand binding, stimulate a variety of critical cellular functions. The orphan receptor anaplastic lymphoma kinase (ALK) is one of very few RTKs that remain without a firmly established protein ligand. Here we present a novel cytokine, FAM150B, which we propose naming augmentor-α (AUG-α), as a ligand for ALK. AUG-α binds ALK with high affinity and activates ALK in cells with subnanomolar potency. Detailed binding experiments using cells expressing ALK or the related receptor leukocyte tyrosine kinase (LTK) demonstrate that AUG-α binds and robustly activates both ALK and LTK. We show that the previously established LTK ligand FAM150A (AUG-β) is specific for LTK and only weakly binds to ALK. Furthermore, expression of AUG-α stimulates transformation of NIH/3T3 cells expressing ALK, induces IL-3 independent growth of Ba/F3 cells expressing ALK, and is expressed in neuroblastoma, a cancer partly driven by ALK. These experiments reveal the hierarchy and specificity of two cytokines as ligands for ALK and LTK and set the stage for elucidating their roles in development and disease states.cell signaling | surface receptors | phosphorylation | cancer | protein kinases R eceptor tyrosine kinases (RTKs) are cell surface receptors that serve as a signaling relay across the membrane for growth factors, cytokines, and hormones. They function to coordinate proliferation, differentiation, cell survival, and metabolism in multicellular organisms. The era of RTK study began more than half of a century ago (reviewed in ref. 1) and has significantly advanced over the last 3 decades, with numerous studies shedding light on the function, structure, and regulation of RTKs and their ligands (2-4).The RTK anaplastic lymphoma kinase (ALK) was originally identified in anaplastic large-cell non-Hodgkin's lymphoma as an oncogenic fusion protein with nucleophosmin resulting from a 2;5 chromosomal translocation (5, 6). The ALK gene is a hotspot for a variety of chromosomal translocations that result in the formation of fusion proteins that undergo spontaneous dimerization, leading to constitutive activation of the ALK kinase domain (reviewed in refs. 7 and 8). These chimeric ALK proteins were shown to drive numerous human cancers, both in hematopoietic malignancies and in solid tumors (7). Full-length, nonchimeric ALK is a driving force in neuroblastoma (NBL), where genetic studies have identified it as a major target of genetic alterations (i.e., gene amplification and somatic and germline mutations) (7,(9)(10)(11)(12). The majority of missense mutations in ALK found in NBL are located in the kinase domain and lead to constitutive receptor activation. Amplification of ALK and coamplification with the N-myc proto-oncogene (MYCN) (both genes are located on chromosome 2p) drive and cooperate in NBL progression (13). Collectively, these studies underscore the role of ALK in tumorigenesis, along with approval by the US Food and Drug Administration of an ALK inhibit...
SH2 domain-mediated interactions represent a crucial step in transmembrane signaling by receptor tyrosine kinases. SH2 domains recognize phosphotyrosine (pY) in the context of particular sequence motifs in receptor phosphorylation sites. However, the modest binding affinity of SH2 domains to pY containing peptides may not account for and likely represents an oversimplified mechanism for regulation of selectivity of signaling pathways in living cells. Here we describe the crystal structure of the activated tyrosine kinase domain of FGFR1 in complex with a phospholipase Cγ fragment. The structural and biochemical data and experiments with cultured cells show that the selectivity of phospholipase Cγ binding and signaling via activated FGFR1 are determined by interactions between a secondary binding site on an SH2 domain and a region in FGFR1 kinase domain in a phosphorylation independent manner. These experiments reveal a mechanism for how SH2 domain selectivity is regulated in vivo to mediate a specific cellular process.
Tyrosine autophosphorylation of receptor tyrosine kinases plays a critical role in regulation of kinase activity and in recruitment and activation of intracellular signaling pathways. Autophosphorylation is mediated by a sequential and precisely ordered intermolecular (trans) reaction. In this report we present structural and biochemical experiments demonstrating that formation of an asymmetric dimer between activated FGFR1 kinase domains is required for transphosphorylation of FGFR1 in FGF-stimulated cells. Transphosphorylation is mediated by specific asymmetric contacts between the N-lobe of one kinase molecule, which serves as an active enzyme, and specific docking sites on the C-lobe of a second kinase molecule, which serves a substrate. Pathological lossof-function mutations or oncogenic activating mutations in this interface may hinder or facilitate asymmetric dimer formation and transphosphorylation, respectively. The experiments presented in this report provide the molecular basis underlying the control of transphosphorylation of FGF receptors and other receptor tyrosine kinases.cell signaling | phosphorylation | protein kinases | protein-protein interactions | surface receptors L igand-induced tyrosine autophosphorylation plays an important role in the control of activation and cell signaling by receptor tyrosine kinases (1-6). Structural and biochemical studies have shown that autophosphorylation of fibroblast growth factor receptor 1 (FGFR1) (7,8) and FGFR2 (9) are mediated by a sequential and precisely ordered intermolecular reaction that can be divided into three phases. The first phase involves transphosphorylation of a tyrosine located in the activation loop (Y653 in FGFR1) of the catalytic core resulting in 50-100-fold stimulation of kinase activity (7). In the second phase, tyrosine residues that serve as docking sites for signaling proteins are phosphorylated including tyrosines in the kinase insert region (Y583, Y585), the juxtamembrane region (Y463), and in the C-terminal tail (Y766) of FGFR1. In the final and third phase, Y654, a second tyrosine located in the activation loop is phosphorylated, resulting in an additional 10-fold increase in FGFR1 kinase activity (7). Interestingly, tyrosines that are adjacent to one another (e.g. Y653, Y654 and Y583, Y585) are not phosphorylated sequentially, suggesting that both sequence and structural specificities dictate the order of phosphorylation. Although tyrosine phosphorylation plays a major role in cell signaling, it is not yet clear what the structural basis for transautophosphorylation is. In other words, the molecular mechanism underlying how one kinase (the enzyme) within the dimerized receptor specifically and sequentially catalyzes phosphorylation of tyrosine(s) of the other kinase (the substrate) is not yet resolved.We previously determined the crystal structure of activated FGFR1 kinase domain bound to a phospholipase Cγ (PLCγ) fragment composed of two SH2 domains and a tyrosine phosphorylation site (Fig. 1) (PDB code 3GQI) (10). In this s...
Attenuation of signaling pathways stimulated by pathologically activated FGF-receptor 2 mutants prevents craniosynostosis
Craniosynostosis, the fusion of one or more of the sutures of the skull vault before the brain completes its growth, is a common (1 in 2,500 births) craniofacial abnormality, Ϸ20% of which occurrences are caused by gain-of-function mutations in FGF receptors (FGFRs). We describe a genetic and pharmacological approach for the treatment of a murine model system of Crouzon-like craniosynostosis induced by a dominant mutation in Fgfr2c. Using genetically modified mice, we demonstrate that premature fusion of sutures mediated by Crouzon-like activated Fgfr2c mutant is prevented by attenuation of signaling pathways by selective uncoupling between the docking protein Frs2␣ and activated Fgfr2c, resulting in normal skull development. We also demonstrate that attenuation of Fgfr signaling in a calvaria organ culture with an Fgfr inhibitor prevents premature fusion of sutures without adversely affecting calvaria development. These experiments show that attenuation of FGFR signaling by pharmacological intervention could be applied for the treatment of craniosynostosis or other severe bone disorders caused by mutations in FGFRs that currently have no treatment.bone disorders ͉ cell signaling ͉ cell surface receptors ͉ protein kinases ͉ skull development
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