%0 Generic
%A Pavlovic Rosman, Dina
%D 2005
%F heidok:6084
%K transition-metal complexes , artificial peptidase
%R 10.11588/heidok.00006084
%T Transition-Metal Complexes as Enzyme-Like Reagents for Protein Cleavage
%U https://archiv.ub.uni-heidelberg.de/volltextserver/6084/
%X In this thesis, metal-promoted hydrolytic cleavage of the amide bond in histidine-containing dipeptides, has been studied.  Transition-metal complexes are emerging as new reagents for selective cleavage of unactivated amide bonds in proteins. Such complexes bind to the side chains of methionine and histidine forming an inert complex with the N-terminal amino acid in the peptide. This binding is a prerequisite for subsequent cleavage, which occurs near these “anchoring” residues.  We designed transition metal complexes for the cleavage of the first peptide bond downstream from the anchoring side chain of histidine. For this purpose, a series of ligands and their corresponding metal complexes, containing various divalent metal ions, such as Pd(II), Zn(II), Cu(II), Co(II), Ni(II) and Cd(II) have been synthesized. To complete their characterization, beside 1H and 13C NMR data, FAB/ESI-MS data and elemental analysis, crystallographic data of nine complexes have been obtained. They gave further insight into the geometry and nature of binding in synthesized metal complexes. In the course of this thesis, the role of the synthesized transition metal complexes as the promotores in the cleavage of the amide bond in small peptides, was examined. To supress the formation of hydrolytically inactive promoter-substrate complexes, the N-terminus of the dipeptides was protected by the acetylation. The histidine residue was placed either on the  N- (AcHisGly) or C-terminus (AcbAlaHis) of the dipeptides. The rate of cleavage was monitored by following the 1H NMR resonances of free glycine. In addition, the possibilities to couple one of the new ligands with NTA (N-nitrilotriacetic acid) moiety, were investigated. In that compound, metal complex of the ligand could act as a peptidase, while the NTA moiety is known as an important and well characterized chelator for the oligo-histidine tag. It could be shown that, in this case, the carbodiimide method and mixed anhydride method are coupling methods of choice.  To summerize, in this study a new Pd(II) complex was identified, which showed very good regioselectivity in promoting hydrolytic cleavage of dipeptides. Using this complex, almost 80% of the peptide was cleaved after five days. Our results prove that a scissile bond on the carboxylic side of the anchoring histidine residue is necessary for hydrolysis: when the peptide bond is on the N-terminus of the anchoring histidine residue, no hydrolytic cleavage was  observed.