Synthesis of a stable isotopically labeled universal surrogate peptide for use as an internal standard in LC-MS/MS bioanalysis of human IgG and Fc-fusion protein drug candidates.

The synthesis of a 16-residue, stable isotopically labeled peptide is described for use as a LC-MS/MS (Liquid chromatography-mass spectrometry/mass spectrometry) internal standard in bioanalytical studies. This peptide serves as a single universal surrogate peptide capable of quantifying a wide variety of immunoglobulin G and Fc-fusion protein drug candidates in animal species used in pre-clinical drug development studies. An efficient synthesis approach for this peptide was developed using microwave-assisted solid phase peptide synthesis (SPPS) techniques, which included the use of a pseudoproline dipeptide derivative. The corresponding conventional room temperature SPPS was unsuccessful and gave only mixtures of truncated products. Stable-labeled leucine was incorporated as a single residue via manual coupling of commercially available Fmoc-[(13) C6 , (15) N]-l-leucine onto an 11-unit segment followed by automated microwave-assisted elaboration of the final four residues. Using this approach, the desired labeled peptide was prepared in high purity and in sufficient quantities for long-term supplies as a bioanalytical internal standard. The results strongly demonstrate the importance of utilizing both microwave-assisted peptide synthesis and pseudoproline dipeptide techniques to allow the preparation of labeled peptides with highly lipophilic and sterically hindered side-chains.

Identification of potent 11mer glucagon-like peptide-1 receptor agonist peptides with novel C-terminal amino acids: Homohomophenylalanine analogs.

We report the identification of potent agonists of the Glucagon-Like Peptide-1 Receptor (GLP-1R). These compounds are short, 11 amino acid peptides containing several unnatural amino acids, including (in particular) analogs of homohomophenylalanine (hhPhe) at the C-terminal position. Typically the functional activity of the more potent peptides in this class is in the low picomolar range in an in vitro cAMP assay, with one example demonstrating excellent in vivo activity in an ob/ob mouse model of diabetes.

Exploration of structure-activity relationships at the two C-terminal residues of potent 11mer Glucagon-Like Peptide-1 receptor agonist peptides via parallel synthesis.

We report the identification of potent agonists of the Glucagon-Like Peptide-1 receptor (GLP-1R) via evaluation of two positional scanning libraries and a two-dimensional focused library, synthesized in part on SynPhase Lanterns. These compounds are 11 amino acid peptides containing several unnatural amino acids, including (in particular) analogs of biphenylalanine (Bip) at the two C-terminal positions. Typical activities of the most potent peptides in this class are in the picomolar range in an in vitro functional assay using human GLP-1 receptor.

Eleven amino acid glucagon-like peptide-1 receptor agonists with antidiabetic activity.

Glucagon-like peptide 1 (GLP-1) is a 30 or 31 amino acid peptide hormone that contributes to the physiological regulation of glucose homeostasis and food intake. Herein, we report the discovery of a novel class of 11 amino acid GLP-1 receptor agonists. These peptides consist of a structurally optimized 9-mer, which is closely related to the N-terminal 9 amino acids of GLP-1, linked to a substituted C-terminal biphenylalanine (BIP) dipeptide. SAR studies resulted in 11-mer GLP-1R agonists with similar in vitro potency to the native 30-mer. Peptides 21 and 22 acutely reduced plasma glucose excursions and increased plasma insulin concentrations in a mouse model of diabetes. These peptides also showed sustained exposures over several hours in mouse and dog models. The described 11-mer GLP-1 receptor agonists represent a new tool in further understanding GLP-1 receptor pharmacology that may lead to novel antidiabetic agents.

NEMO binding domain of IKK-2 encompasses amino acids 735-745.

NF-kappaB activation is mediated by the IKK signalsome. Though this signalsome is comprised of IKK-1, IKK-2, and NEMO/IKKgamma, it is the interaction between IKK-2 and NEMO that is critical to formation of a functional signalsome. More specifically, previous reports have indicated that this interaction involves the C-terminal LDWSWL residues of IKK-2 (called the Nemo Binding Domain (NBD)) and the N-terminus of NEMO. In an effort to characterize the IKK-2:NEMO interaction, we have investigated several NBD-containing peptides for their ability to bind NEMO and inhibit the critical IKK-2:NEMO interaction. The six residue NBD peptide, LDWSWL, showed modest binding to NEMO and little inhibition of the IKK-2:NEMO interaction, whereas peptides containing the NBD plus additional flanking amino acids (NBD-containing peptides) more effectively bound NEMO and inhibited the interaction. These longer NBD-containing peptides may be required to give the NBD an appropriate conformation for recognition by NEMO and/or to provide for additional interactions with NEMO.

An inhibitor binding pocket distinct from the catalytic active site on human beta-APP cleaving enzyme.

Beta-APP cleaving enzyme (BACE) is responsible for the first of two proteolytic cleavages of the APP protein that together lead to the generation of the Alzheimer's disease-associated Abeta peptide. It is widely believed that halting the production of Abeta peptide, by inhibition of BACE, is an attractive therapeutic modality for the treatment of Alzheimer's disease. BACE is an aspartyl protease, and there is significant effort in the pharmaceutical community to apply traditional design methods to the development of active site-directed inhibitors of this enzyme. We report here the discovery of a ligand binding pocket within the catalytic domain of BACE that is distinct from the enzymatic active site (i.e., an exosite). Peptides, initially identified from combinatorial phage peptide libraries, contain the sequence YPYF(I/L)P(L/I) and bind specifically to this exosite, even in the presence of saturating concentrations of active site-directed inhibitors. Binding of peptides to the BACE exosite leads to a concentration-dependent inhibition of proteolysis for APP-related, protein-based substrates of BACE. The discovery of this exosite opens new opportunities for the identification and development of novel and potentially selective small molecule inhibitors of BACE that act through exosite, rather than active site, binding interactions.