The tremendous therapeutic potential of peptides has not yet been realized, mainly due to their short in vivo half-life. While conjugation to macromolecules has been a mainstay approach for enhancing the half-life of proteins, the steric hindrance of macromolecules often harms the binding of peptides to target receptors, compromising the in vivo efficacy. Here we report a new strategy for enhancing the in vivo half-life of peptides without compromising their potency. Our approach involves endowing peptides with a small-molecule that binds reversibly to the serum protein, transthyretin. Although there are few reversible albumin-binding molecules, we are unaware of designed small molecules that bind reversibly to other serum proteins and are used for half-life extension in vivo. We show here that our strategy was indeed effective in enhancing the half-life of an agonist for GnRH receptor while maintaining its binding affinity, which was translated into superior in vivo efficacy.
A series of novel 1,3-dithiolane-2-thiones, or cyclic trithiocarbonates, has been prepared by a new simple procedure: a treatment of the corresponding epoxides with the commercially available potassium ethyl xanthogenate, KSC(S)OEt. The stereochemistry of the products was determined by 1 H NMR and in some cases by single-crystal X-ray data. Cyclohexane-based 1,3-dithiolane-2-thiones revealed a trans-fusion of the carbo-and hetero-cycles. The products obtained from the mono-substituted cyclohexene oxides demonstrated an axial position of the substituents. Thus the epoxide transformation into trithiocarbonate can be used as a method for locking cyclic compounds in unstable conformations.
Conformational effects on the proton affinity of oligopeptides have been studied using six alanine (A)-based acetylated dipeptides containing a basic probe that is placed closest to either the C- or the N-terminus. The basic probe includes Lysine (Lys) and two nonproteinogenic Lys-homologues, ornithine (Orn) and 2,3-diaminopropionic acid (Dap). The proton affinities of the peptides have been determined using the extended Cooks kinetic method in a triple quadrupole mass spectrometer. Computational studies have been carried out to search for the lowest energy conformers and to calculate theoretical proton affinities as well as various molecular properties using the density functional theory. The dipeptides containing a C-terminal probe, ALys, AOrn, and ADap, were determined to have a higher proton affinity by 1-4 kcal/mol than the corresponding dipeptides containing an N-terminal probe, LysA, OrnA, and DapA. For either the C-probe peptides or the N-probe peptides, the proton affinity reduces systematically as the side-chain of the probe residue is shortened. The difference in the proton affinities between isomeric peptides is largely associated with the variation of the conformations. The peptides with higher values of the proton affinity adopt a relatively compact conformation such that the protonated peptides can be stabilized through more efficient internal solvation.
Oligopeptides containing 2,3-diaminopropionic acid (Dap) serve as a unique model to study conformational effects on the ionizability of a side-chain group. In this study, conformations of acetylated isomeric dipeptide ions containing alanine (Ala) and Dap, AlaDapH and DapAlaH, are studied by infrared multiple photon dissociation (IRMPD) spectroscopy and computation. The IRMPD spectra are characterized in detail by comparing them with theoretical IR spectra of a set of low-energy conformations calculated at the ωB97X-D/6-311+G(d) level of theory. The averaged IR spectra according to the Boltzmann distribution of the set of conformations have a good match to the IRMPD spectra. The characteristic amide I band of AlaDapH appears to be downshifted compared to that of DapAlaH. The relative positions of the amide band suggest a stronger hydrogen-bonding interaction between the charged side-chain amino group and the amide carbonyl groups in AlaDapH than in DapAlaH. The stronger hydrogen bonding in the former is likely due to a better alignment of the N-H and O═C bonds, which enables an effective sequestering of the positive charge at the amino group. The effect results in a higher proton affinity of acetylated dipeptides with the Dap residue at the C-terminus.
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