Conformation of peptides of the secretin-VIP-glucagon family in solution.

The significance of a well defined molecular architecture in hormone receptor interaction and the methods available for the study of preferred conformations are discussed. The conformational freedom in glucagon is a major obstacle in the determination of its biologically relevant geometry. In the secretin molecule intramolecular forces generate a folded, partially helical conformation. In respect of long range cooperative interactions resulting in a compact molecule with secondary-tertiary structure secretin is similar to globular proteins. In VIP some characteristics of secretin and also of glucagon can be recognized. Further progress in conformation analysis can be expected from the study of rigid, cyclic analogs in which the biological activities of the parent hormones are retained or even enhanced. Such analogs have well defined conformations without external stabilization from membrane mimicking lipids. Therefore, they provide information on the biologically relevant geometry of the hormones and contribute also to our knowledge of receptor sites.

Coupling in the absence of tertiary amines.

In order to avoid base catalyzed side reactions during coupling, attempts were made to render superfluous the addition of tertiary amines to the reaction mixture. Weak acids were applied for the removal of acid labile protecting groups. Acetic acid and other carboxylic acids were considered unsuitable for this purpose coupling step. Pentachlorophenol and 2,4-dinitrophenol cleaved the Bpoc, Nps and Trt groups but more practical rates were reached with solutions of 1-hydroxybenzotriazole (HOBt) in trifluoroethanol, in acetic acid, or in a mixture of phenol and p-cresol. In addition to acidolysis, HOBt salts of amino components could also be obtained through hydrogenolysis of the Z group or thiolysis of the Nps group in the presence of HOBt, or by the displacement of acetic acid from acetate salts with HOBt. Acylation of HOBt salts of amino components with symmetrical or mixed anhydrides or with active esters did not require the addition of tertiary amine.

Side reactions in peptide synthesis. VI. A reexamination of the benzyl group in the protection of the side chains of tyrosine and aspartic acid.

The acid catalyzed O leads to C migration of the benzyl group in the side chain of tyrosine could be reduced by applying HBr in a mixture of phenol and p-cresol instead of BHr in trifluoroacetic acid for acidolytic deprotection. This side reaction occurs also during the removal of Boc groups. The loss of O-benzyl protection and the formation of 3-benzyltyrosine residues could be suppressed by the application of a 7:3 mixture of trifluoroacetic acid and acetic acid. The acid- and base-catalyzed ring closure of beta-benzylaspartyl residues to aminosuccinyl derivatives was also studied. In this case HBr in trifluoroacetic acid was found to be relatively harmless. Deprotection with HBr in a mixture of trifluoroacetic acid and p-cresol can be applied for peptides that contain both beta-benzylaspartyl and O-benzyltyrosyl residues. An attempt to reduce the rate of the base-catalyzed side reaction by application of hindered tertiary amines was abandoned because the tertiary amines which were effective in this respect let to significant reduction of the rate of the desired reaction, the aminolysis of active esters, as well. A satisfactory solution for the problem was found in the selective catalysis of the active ester reaction with 1-hydroxybenzotriazole or 4-dimethyl-aminopyridine. These catalysts do not enhance the rate of ring closure and in their presence essentially pure beta-benzylaspartyl peptides can be produced in good yield.