Characterization of Residues in the 5-HT3 Receptor M4 Region That Contribute to Function.

5-HT3 receptors are members of the family of pentameric ligand gated ion channels (pLGICs). Each subunit has four transmembrane α-helices (M1-M4), with M4 being most distant from the central pore. Residues in this α-helix interact with adjacent lipids and the neighboring M1 and M3 helices, contributing to both receptor assembly and channel function. This study probes the role of each M4 receptor residue in the 5-HT3A receptor using mutagenesis and subsequent expression in HEK293 cells, probing functional parameters using fluorescence membrane potential sensitive dye. The data show that only one residue in M4 (Y441) and two flanking residues (D434 and W459) result in nonfunctional receptors when substituted with Ala: D434A and W459A-containing receptors ablate expression, while Y441A-containing receptor do not, suggesting the latter is involved in channel gating. Most other altered residues have wild-type-like properties, which is inconsistent with data from other pLGICs. Substitution of Y441 and W459 with other aromatics restores function, suggesting the π ring is important. Further substitutions indicate interactions of Y441 with D238 in M1, W459 with F144 in the Cys loop, and D434 with R251 in M2, data consistent with recently published structures. These regions are critical for transducing binding into gating, and thus interactions of these residues can explain their importance in the function of the 5-HT3 receptor. We also conclude that the small number of critical M4 residues compared to related receptors supports the hypothesis that M4 does not behave identically in all pLGICs.

Effects of TSH receptor mutations on binding and biological activity of monoclonal antibodies and TSH.

The effects of an extensive series of mutations in the TSH receptor (TSHR) leucine-rich domain (LRD) on the ability of thyroid-stimulating monoclonal antibodies (TSMAbs) and TSH to bind to the receptor and stimulate cyclic AMP production in TSHR-transfected CHO cells has been investigated. In addition, the ability of a mouse monoclonal antibody with blocking (i.e., antagonist) activity (RSR-B2) to interact with mutated receptors has been studied. Several amino acids distributed along an extensive part of the concave surface of the LRD were found to be important for binding and stimulation by the thyroid-stimulating human MAb M22 but did not appear to be important for TSH binding and stimulation. Most of these amino acids important for M22 interactions were also found to be important for the stimulating activity of six different mouse TSMAbs and a hamster TSMAb. Furthermore, most of these same amino acids were important for stimulation by TSHR autoantibodies in a panel of sera from patients with Graves' disease. Amino acid R255 was the only residue found to be unimportant for TSH stimulation but critical for stimulation by all thyroid-stimulating antibodies tested (23 patient serum TSHR autoantibodies, M22, and all seven animal TSMAbs). About half the amino acids (all located in the N-terminal part of the LRD) found to be important for M22 activity were also important for the blocking activity of RSR-B2 and although the epitopes for the two MAbs overlap they are different. As the two MAbs have similar affinities, their epitope differences are probably responsible for their different activities. Overall our results indicate that different TSMAbs and different patient sera thyroid-stimulating autoantibodies interact with the same region of the TSHR, but there are subtle differences in the actual amino acids that make contact with the different stimulators.

A mouse monoclonal antibody to the TSHR.

INTRODUCTION: Mouse monoclonal antibodies (mAbs) with the ability to inhibit thyrotropin (TSH) binding to the TSH receptor (TSHR) are useful tools to study TSH-TSHR interaction. The 3C3 mAb we produced was found to inhibit binding of TSH to human (h)TSHR but not to porcine (p)TSHR. MATERIAL/METHODS: Purified 3C3 immunoglobulin G (IgG) and its antibody-binding fragment were prepared using standard methods and their ability to inhibit TSH binding to hTSHR or pTSHR was analyzed using a coated tube assay. The TSHR epitope reactive with 3C3 IgG was determined using Western blotting, ELISA based on peptides corresponding to the TSHR sequence, and the SPOT synthesis technique. RNA was isolated from 3C3 hybridoma cells and the mAb variable (V) region genes were sequenced and analyzed. RESULTS: 3C3 mAb had a 1 x 108 l/mol binding affinity to the hTSHR as assessed by Scatchard analysis. 3C3 reacted with the hTSHR region between amino acids (aa) 212-230, and two aa differences were found between the corresponding regions in the hTSHR and pTSHR. The light chain (LC) genes of 3C3 were derived from the Vk21 germ-line (97.6% homology) and Jk2 genes. The heavy chain (HC) genes were from the V130 germ-line (94.6% homology) combined with a D gene (not identified) and JH3 gene. The replacement/ silent mutation ratios of 6.0 and 6.5 for the LC and the HC V regions, respectively, indicated that 3C3 underwent antigen-driven maturation. CONCLUSIONS: Mouse mAbs of this type should be useful in studying the interactions between the TSHR, TSH, and mAbs in more detail.

Analysis of the thyrotropin receptor-thyrotropin interaction by comparative modeling.

We have used the most advanced programs currently available to construct the first three-domain structure of the human thyrotropin receptor (TSHR) using comparative modeling. The model consists of a leucine-rich domain (LRD; amino acids 36-281; porcine ribonuclease inhibitor used as a template for modeling), a cleavage domain (CD; amino acids 282-409; tissue inhibitor of matrix metalloproteinases 2 as template) and transmembrane domain (TMD amino acids 410-699; bovine rhodopsin as template). Models of human, porcine, and bovine TSH were also constructed (human chorionic gonadotropin [hCG] and human follicle stimulating hormone [hFSH] as templates). The LRD has a characteristic horseshoe shape with 10 tandem homologous repeats. The CD consists of beta-barrel and alpha helix structures (OB-like fold) with two disulfide bridges and the structure around these disulfide bridges remains stable after cleavage. The TMD presents the typical seven membrane-spanning helices. The TSH, LRD, CD, and TMD models were brought together in an extensive series of docking experiments. Known features of the TSH-TSHR interaction were used for selection of appropriate complexes that were then validated using a different set of experimental data. A similar approach was used to build a model of a complex between the TSHR and a monoclonal TSHR antibody with weak thyroid stimulating activity. Human thyrotropin (hTSH) alpha chains were found to make contact with many amino acids on the LRD surface and CD surface whereas no interaction between the beta chains and the CD were found. The higher affinity of bovine thyrotropin (bTSH) and porcine thyrotropin (pTSH) (relative to hTSH) for the TSHR is explained well by the models in terms of charge-charge interactions between their alpha chains and the receptor. Experimental observations showing increased sensitivity of the TSHR to hCG after mutation of TSHR Lys209 to Glu are explained well by our model. Furthermore, several mutations in the TMD that are associated with increased TSHR basal activity are predicted from our model to be caused by the formation of new interactions that stabilize the activated form of the TMD.

Thyroid-stimulating monoclonal antibodies.

Thyrotropin (TSH) receptor monoclonal antibodies (TSHR mAbs) were obtained from cDNA-immunized NMRI mice. Three mAb immunoglobulin Gs (IgGs) (TSmAbs 1-3) that had distinct V(H )and V(L) region sequences stimulated cyclic adenosine monophosphate (cAMP) production in isolated porcine thyroid cells greater than 10x basal and as little as 20 ng/mL (0.13 nmol/L) of TSmAb 1 IgG caused a 2x basal stimulation. TSmAb 1 and 2 Fab fragments were also effective stimulators and thyroid-stimulating activities of the IgGs and Fabs were confirmed using TSHR transfected Chinese hamster ovary (CHO) cells. The TSmAbs also inhibited (125)I-labeled TSH binding to TSHR-coated tubes by 50% or more at concentrations of 1 microg/mL or less and gave 15%-20% inhibition at 20-50 ng/mL. (125)I-labeled TSmAbs bound to TSHR-coated tubes with high affinity (approximately 10(10) L/mol) and this binding was inhibited by TSHR autoantibodies with both TSH agonist and antagonist activities. Inhibition of labeled TSmAb binding by Graves' sera correlated well with inhibition of TSH binding (r = 0.96; n = 18; p < 0.001 for TSmAb 2). The TSmAbs have considerable potential as (1) new probes for TSHR structure-function studies, (2) reagents for new assays for TSHR autoantibodies, and (3) alternatives to recombinant TSH in various in vivo applications.

Characterization of the thyrotropin binding pocket.

A panel of monoclonal antibodies (mAbs) to the thyrotropin receptor (TSHR) was prepared using three different immunization strategies. The mAbs obtained (n = 138) reacted with linear epitopes covering most of the TSHR extracellular domain and with conformational epitopes. mAbs that bound to five different regions of the TSHR (amino acids [aa] 32-41, aa 36-42, aa 246-260, aa 277-296, and aa 381-385) were able to inhibit (125)I-labeled thyrotropin (TSH) binding to solubilized TSHR preparations. Fab and immunoglobulin G (IgG) preparations were similarly effective inhibitors for mAbs reactive with aa 246-260, aa 277-291 and aa 381-385 suggesting that these three regions of the TSHR are involved in TSH binding. In contrast mAbs reactive with aa 32-41 and aa 36-42 were not effective at inhibiting TSH binding when Fab preparations were used, suggesting that these N terminal regions of the TSHR were less critical for TSH binding. Our studies suggest that three distinct and discontinuous regions of the TSHR (aa 246-260 and 277-296 on the TSHR A subunit) and aa 381-385 (on the TSHR B subunit) fold together to form a complex TSH binding pocket. Alignment of the aa sequences of these three regions in TSHRs from different species indicates that they are highly conserved.