Human thrombopoietin structure-function relationships: identification of functionally important residues.

Thrombopoietin (TPO) is a haematopoietic growth factor responsible for megakaryocyte progenitor proliferation and differentiation. It belongs to the four-helix-bundle cytokine family and exerts its biological effects through binding to a specific receptor, c-Mpl. With the use of site-directed mutagenesis we have generated 20 TPO mutants. Each of the TPO mutants was produced in a eukaryotic expression system and the mutants' ability to induce the proliferation of factor-dependent c-Mpl-expressing megakaryoblastic M-O7e cells was compared with that of wild-type TPO. Among the mutations studied, 10 lead to a significant decrease in TPO bioactivity. Of these ten residues, three are located in helix A of the protein (Arg10, Lys14 and Arg17) and four in helix D (His133, Gln132, Lys138 and Phe141), indicating that in TPO, as in other cytokines, these two helices are important for functional cytokine/receptor interactions. Surprisingly, mutant Arg10-->Ala (R10A) lacked any proliferative activity, despite the fact that this mutation was recently reported to have no effect on TPO/c-Mpl binding in a TPO phage ELISA [Pearce, Potts, Presta, Bald, Fendly and Wells (1997) J. Biol. Chem. 272, 20595-20602]. The lack of M-O7e proliferation is probably due to an inability of R10A mutant to promote receptor dimerization and thus receptor activation. Moreover we found that the Arg10 and Arg17 residues of TPO seem to be specific determinants for TPO/c-Mpl recognition. We also demonstrate that the O-glycosylation site located at position 110 of TPO is not necessary for the bioactivity of the cytokine.

Binding sites and transduction process of the cholecystokininB receptor: involvement of highly conserved aromatic residues of the transmembrane domains evidenced by site-directed mutagenesis.

The functional significance of the extracellular amino-terminal region and of three highly conserved aromatic residues present in the fifth (TM-V) and sixth (TM-VI) transmembrane domains of the rat cholecystokinin (CCK)B receptor, transfected in Cos-7 cells, was investigated by site-directed mutagenesis. The amino-terminal region of the CCKB receptor seemed to be weakly involved in CCK binding in that the affinities of CCK8 and selective agonists and antagonists were not modified by truncation of this region. Substitution of Phe347 in TM-VI with alanine produced a mutant receptor that displays the same affinity and selectivity as the wild-type receptor for agonists, but a slightly increased affinity for the selective CCKB antagonist L-365,260. However, the addition of saturating CCK8 concentrations to cells expressing this mutant did not result in the production of inositol phosphates, demonstrating the critical role of Phe347 in CCKB receptor to G protein coupling. Substitution of Phe227 with alanine was without effect on the affinities of CCKB ligands and on phosphoinositide turnover but modified the affinity of the CCKA antagonist L-364,718. Residue Trp351 located within the CCKB receptor TM-VI is involved in the binding of CCK8 and CCK4 and of the CCK4-based antagonist PD-134,308, as illustrated by the decreased affinities of these ligands in W351A mutant. The lower affinity for CCK8 observed with this mutated CCKB receptor accounts for the higher EC50 value for phosphotidylinositol hydrolysis. This study suggests that at least part of the binding site for the agonist is located inside the transmembrane domain of the CCKB receptor, partially overlapping that of antagonists, and gives new insights into the regions involved in the transduction process.

His381 of the rat CCKB receptor is essential for CCKB versus CCKA receptor antagonist selectivity.

A great interest is devoted to antagonists of the cholecystokinin type B (CCKB) receptor such as L-365,260, which reduces panic attacks in humans and to antagonists of the cholecystokinin type A (CCKA) receptor, such as L-364,718 which might be efficient in mental diseases. The A/B specificity of these antagonists was proposed to be mainly dependent on the amino acid sequence of the seventh transmembrane domain (Mantamadiotis and Baldwin (1994) Biochem. Biophys. Res. Commun. 201,1382). In our study, one of these residues, His381 was replaced in the rat CCKB receptor by leucine (the corresponding residue in the CCKA receptor), phenylalanine or arginine using site-directed mutagenesis. Changing histidine for leucine or phenylalanine did not modify significantly the affinity of the CCKB receptor antagonists, L-365,260 and PD-134,308 although both compounds belong to different chemical classes, but strongly improved the affinity of the CCKA receptor antagonists tested. Interestingly, the A selectivity of these CCKA receptor antagonists was recovered by substituting His381 by arginine. Moreover, these results are discussed on the basis of a three dimentional model of the CCKB receptor. The mutated receptors possessed unchanged binding properties for agonists, suggesting that determinants confering specificity for agonists and antagonists are different.

Mutation of Asp100 in the second transmembrane domain of the cholecystokinin B receptor increases antagonist binding and reduces signal transduction.

We examined the functional significance of two residues present in the second (Asp100) and seventh (Asn391) transmembrane domains of the rat cholecystokininB (CCKB) receptor that are highly conserved among the members of the G protein-coupled receptor family. Substitution of Asn for Asp100 by using site-directed mutagenesis did not change the affinity and selectivity for agonists but slightly increased the affinity of three CCKB-selective antagonists of different chemical structures. Cells expressing the mutant receptor exhibited a 50% reduction in CCKB-induced phosphoinositide turnover compared with cells expressing the wild-type receptor, suggesting a critical role for this residue in the coupling of the CCKB receptor to G protein. This latter was shown to be insensitive to pertussis toxin treatment and could therefore belong to the Gq family. Replacement of Asn391 by Asp located in the seventh transmembrane domain did not change agonist binding or phosphoinositide turnover. This suggests that in contrast to the gonadotropin-releasing hormone receptor, there is no direct interaction in the CCKB receptor between Asp100 and Asn391. However, a rhodopsin-based molecular modeling of the CCKB receptor showed a spatial proximity between Asp100 and the carboxyl terminal part of the third intracellular loop, known to interact with G protein. This could explain the reduction in phosphoinositide turnover observed with the Asn100 mutant.

Identification and characterization of various cholecystokinin B receptor mRNA forms in rat brain tissue and partial determination of the cholecystokinin B receptor gene structure.

Using the powerful method of DNA amplification, we have been able to isolate several cholecystokinin B (CCKB) receptor (CCKB-R) mRNA forms from rat brain tissue, allowing the detection of a truncated mRNA species and the determination of the CCKB-R gene structure. Unspliced precursor mRNA and the mature form were identified in the cerebral cortex, hypothalamus, and hippocampus in apparently differing proportions according to the region examined, suggesting that the expression of the CCKB-R could be modulated at a posttranscriptional level. In the case of the cerebellum, only a completely unspliced mRNA form was detected, in agreement with previous studies in which CCKB ligand binding sites were not observed. In contrast, a truncated CCKB-R mRNA, lacking 250 bp, was detected in all the studied brain regions except for the cerebellum. This mRNA, for which a cellular function has not been assigned, potentially encodes a protein consisting of 168 amino acids.