Autoantibody mimicry of hormone action at the thyrotropin receptor.

Thyroid hormones are vital in metabolism, growth and development1. Thyroid hormone synthesis is controlled by thyrotropin (TSH), which acts at the thyrotropin receptor (TSHR)2. In patients with Graves' disease, autoantibodies that activate the TSHR pathologically increase thyroid hormone activity3. How autoantibodies mimic thyrotropin function remains unclear. Here we determined cryo-electron microscopy structures of active and inactive TSHR. In inactive TSHR, the extracellular domain lies close to the membrane bilayer. Thyrotropin selects an upright orientation of the extracellular domain owing to steric clashes between a conserved hormone glycan and the membrane bilayer. An activating autoantibody from a patient with Graves' disease selects a similar upright orientation of the extracellular domain. Reorientation of the extracellular domain transduces a conformational change in the seven-transmembrane-segment domain via a conserved hinge domain, a tethered peptide agonist and a phospholipid that binds within the seven-transmembrane-segment domain. Rotation of the TSHR extracellular domain relative to the membrane bilayer is sufficient for receptor activation, revealing a shared mechanism for other glycoprotein hormone receptors that may also extend to other G-protein-coupled receptors with large extracellular domains.

Research resource: novel structural insights bridge gaps in glycoprotein hormone receptor analyses.

The first version of a glycoprotein hormone receptor (GPHR) information resource was designed to link functional with structural GPHR information, in order to support sequence-structure-function analysis of the LH, FSH, and TSH receptors (http://ssfa-gphr.de). However, structural information on a binding- and signaling-sensitive extracellular fragment (∼100 residues), the hinge region, had been lacking. A new FSHR crystal structure of the hormone-bound extracellular domain has recently been solved. The structure comprises the leucine-rich repeat domain and most parts of the hinge region. We have not only integrated the new FSHR/FSH structure and the derived homology models of TSHR/TSH, LHCGR/CG, and LHCGR/LH into our web-based information resource, but have additionally provided novel tools to analyze the advanced structural features, with the common characteristics and distinctions between GPHRs, in a more precise manner. The hinge region with its second hormone-binding site allows us to assign functional data to the new structural features between hormone and receptor, such as binding details of a sulfated tyrosine (conserved throughout the GPHRs) extending into a pocket of the hormone. We have also implemented a protein interface analysis tool that enables the identification and visualization of extracellular contact points between interaction partners. This provides a starting point for comparing the binding patterns of GPHRs. Together with the mutagenesis data stored in the database, this will help to decipher the essential residues for ligand recognition and the molecular mechanisms of signal transduction, extending from the extracellular hormone-binding site toward the intracellular G protein-binding sites.

TSH binding site structures in human eye muscle fractions identified by using covalent-crosslinking.

125I-labelled human TSH was crosslinked to the human thyroid and extraocular eye muscle membrane and cytosol fractions (which were obtained by centrifugation). Studying crosslinking of 125I-labelled TSH to the thyroid fractions, TSH binding sites' structures were demonstrated on the eye muscle membranes and in the cytosol fractions. The binding of 125I-labelled TSH was inhibited by the addition of 120 mIU/mL of unlabelled TSH (and not with 12 mIU/mL) which confirmed the presence of TSH binding sites structures (MW about 66,000 Da) on the eye muscle membrane and in its cytosol. Adding purified IgG fractions from the sera from controls and Graves' disease (with high titer of antibodies against TSH receptor) to the thyroid and eye muscle membranes and cytosol fractions, the binding of 125I-labelled human TSH was inhibited by molecular weight of about 66,000 Da in the cytosol fractions. The affinity constant of the binding sites in the human eye muscle cytosol and the number of TSH receptors were found to be 146 x 10(9) M-1 and 9.8 x 10(10) molecules/mg/mL by Scatchard analysis, respectively.