The Relaxin Receptor-binding Site Geometry Suggests a Novel Gripping Mode of Interaction

Relaxin has a unique, clearly identifiable, mixed function receptor-binding region comprising amino acid residues that evolve sequentially from the central portion of the B chain α-helix. Two arginine residues in positions B13 and B17 that project like forefinger and middle finger from the helix pro...

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Bibliographic Details
Published in:The Journal of biological chemistry 2000-11, Vol.275 (45), p.35276-35280
Main Authors: Büllesbach, Erika E., Schwabe, Christian
Format: Article
Language:English
Subjects:
Amino Acid Sequence
Animals
Arginine - chemistry
Binding Sites
Brain - metabolism
Chromatography, High Pressure Liquid
Circular Dichroism
Disulfides
Dose-Response Relationship, Drug
Estrogens - pharmacology
Female
Guanidine - chemistry
Humans
Hydrocarbons
Isoleucine - chemistry
Kinetics
Methane - analogs & derivatives
Methane - chemistry
Mice
Models, Molecular
Molecular Sequence Data
Peptides - chemistry
Phenylalanine - chemistry
Protein Binding
Pubic Symphysis - metabolism
Receptors, G-Protein-Coupled
Receptors, Peptide - chemistry
Receptors, Peptide - metabolism
Sequence Homology, Amino Acid
Thermodynamics
Ultraviolet Rays
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Summary:Relaxin has a unique, clearly identifiable, mixed function receptor-binding region comprising amino acid residues that evolve sequentially from the central portion of the B chain α-helix. Two arginine residues in positions B13 and B17 that project like forefinger and middle finger from the helix provide the electrostatic element opposed by the hydrophobic (thumb) element isoleucine (B20), offset from the arginines by about 40°. The binding intensity of relaxin to its receptor decreases by 3 orders of magnitude if alanine is substituted for the newly discovered binding component isoleucine in position B20. The arginine residues cannot be replaced by other positive charges, nor can the guanidinium group be presented on a longer or shorter hydrocarbon chain. In contrast, the hydrophobic interaction is incremental in nature, and the contribution to the total binding energy is roughly proportional to the number of hydrocarbon units in the side chain. It appears that a hydrophobic surface exists on the receptor that offers optimal van der Waals' interaction with β-branched hydrophobic amino acids. The binding energy increases roughly 10-fold with each methylene group whereby β-branching is more effective per surface unit than chain elongation. Aromatic side chains appear to demarcate the extent of the binding region in so far as residues larger than phenylalanine decrease receptor binding. The exceptional clarity of binding site geometry in relaxin makes for an excellent opportunity to design peptido-mimetics.
ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M005728200