Relationship between Thyrotropin Receptor Hinge Region Proteolytic Posttranslational Modification and Receptor Physiological Function

The glycoprotein hormone receptor hinge region is the least conserved component and the most variable in size; the TSH receptor (TSHR) being the longest (152 amino acids; residues 261–412). The TSHR is also unique among the glycoprotein hormone receptor in undergoing in vivo intramolecular cleavage into disulfide-linked A- and B-subunits with removal of an intervening ‘C-peptide’ region. Experimentally, hinge region amino acids 317–366 (50 residues) can be deleted without alteration in receptor function. However, in vivo, more than 50 amino acids are deleted during TSHR intramolecular cleavage; furthermore, the boundaries of this deleted region are ragged and poorly defined. Studies to determine the extent to which hinge region deletions can be tolerated without affecting receptor function (‘minimal hinge’) are lacking. Using as a template the functionally normal TSHR with residues 317–366 deleted, progressive downstream extension of deletions revealed residue 371 to be the limit compatible with normal TSH binding and coupling with cAMP signal transduction. Based on the foregoing downstream limit, upstream deletion from residue 307 (307–371 deletion) was also tolerated without functional alteration, as was deletion of residues 303–366. Addressing a related issue regarding the functional role of the TSHR hinge region, we observed that downstream hinge residues 377–384 contribute to coupling ligand binding with cAMP signal transduction. In summary, we report the first evaluation of TSHR function in relation to proteolytic posttranslational hinge region modifications. Deletion of TSHR hinge amino acids 303–366 (64 residues) or 307–371 (65 residues) are the maximum hinge region deletions compatible with normal TSHR function.

A sea lamprey glycoprotein hormone receptor similar with gnathostome thyrotropin hormone receptor

The specificity of the vertebrate hypothalamic–pituitary–gonadal and hypothalamic–pituitary–thyroid axes is explained by the evolutionary refinement of the specificity of expression and selectivity of interaction between the glycoprotein hormones GpH (FSH, LH, and TSH) and their cognate receptors GpH-R (FSH-R, LH-R, and TSH-R). These two finely tuned signaling pathways evolved by gene duplication and functional divergence from an ancestral GpH/GpH-R pair. Comparative analysis of the protochordate and gnathostome endocrine systems suggests that this process took place prior or concomitantly with the emergence of the gnathostome lineage. Here, we report identification and characterization of a novel glycoprotein hormone receptor (lGpH-R II) in the Agnathan sea lamprey. This 781 residue protein was found ∼43% identical with mammalian TSH-R and FSH-R representative sequences, and similarly with these two classes of mammalian receptors it is assembled from ten exons. A synthetic ligand containing the lamprey glycoprotein hormone β-chain tethered upstream of a mammalian α-chain activated the lGpH-R II expressed in COS-7 cells but in a lesser extent than lGpH-R I. Molecular phylogenetic analysis of vertebrate GpH-R protein sequences suggests a closer relationship between lGpH-R II and gnathostome thyrotropin receptors. Overall, the presence and characteristics of the lamprey glycoprotein hormone receptors suggest existence of a primitive functionally overlapping glycoprotein hormone/glycoprotein hormone receptor system in this animal.

Genomic Checkpoints for Exon 10 Usage in the Luteinizing Hormone Receptor Type 1 and Type 2

Alternative splicing is a hallmark of glycoprotein hormone receptor gene regulation, but its molecular mechanism is unknown. The LH receptor (LHR) gene possesses 11 exons, but exon 10 is constitutively skipped in the New World monkey lineage (LHR type 2), whereas it is constitutively spliced in the human (LHR type 1). This study identifies the regulatory elements of exon 10 usage. Sequencing of genomic marmoset DNA revealed that the cryptic LHR exon 10 is highly homologous to exon 10 from other species and displays intact splice sites. Functional studies using a minigene approach excluded the contribution of intronic, marmoset-specific long interspersed nucleotide-1 elements to exon 10 skipping. Sequencing of the genomic regions surrounding exon 10 from several primate lineages, sequence comparisons including the human and mouse LHR gene, revealed the presence of unique nucleotides at 3′-intronic position −19 and −10 and at position +26 within exon 10 of the marmoset LHR. Exon trap experiments and in vitro mutagenesis of these nucleotides resulted in the identification of a composite regulatory element of splicing consisting of cis-acting elements represented by two polypyrimidine tracts and a trans-acting element within exon 10, which affect the secondary RNA structure. Changes within this complex resulted either in constitutive exon inclusion, constitutive skipping, or alternative splicing of exon 10. This work delineates the molecular pathway leading to intronization of exon 10 in the LHR type 2 and reveals, for the first time, the essential function of regulatory and structural elements involved in glycoprotein hormone receptor splicing.