With a few exceptions, all organisms are restricted to the 20 canonical amino acids for ribosomal protein biosynthesis. Addition of new amino acids to the genetic code can introduce novel functionalities to proteins, broadening the diversity of biochemical as well as chemical reactions and providing new tools to study protein structure, reactivity, dynamics and protein-protein-interactions.
The site directed in vivo incorporation developed by P. G. SCHULTZ and coworkers, using an archeal orthogonal tRNA/aaRS (aminoacyl-tRNA synthase) pair, allows site-specifically insertion of a synthetic unnatural amino acid (UAA) by reprogramming the amber TAG stop codon. A variety of over 80 different UAAs can be introduced by this technique. However by now a very limited number can form kinetically stable bonds to late transition metals.
This thesis aims to develop new catalytically active unnatural amino acids or strategies for a posttranslational modification of site-specific amino acids in order to achieve highly enantioselective metallorganic enzyme hybrids (MOEH). As a requirement a stable protein host has to be established, surviving the conditions for incorporation, posttranslational modification and the final catalytic reactions. mTFP* a fluorescent protein was genetically modified by excluding any exposed Cys, His and Met forming a variant mTFP*, which fulfills the required specifications. Posttranslational chemical modification of
mTFP* allow the introduction of single site metal chelating moieties. For modification on exposed cysteines different maleiimid containing ligand structures were synthesized.
In order to perform copper catalyzed click reactions, suitable unnatural amino acids (para-azido-(L)-phenylalanine, para-ethynyl-(L)-phenylalanine) were synthesized and a non-cytotoxic protocol was established. The triazole ring formed during this reaction may contribute as a moderate σ-donor/π-acceptor ligand to the metal binding site. Since the cell limits the incorporation of boronic acids, an aqueous protocol for Miyaura borylation using a highly active palladacycle catalyst was established and can be transferred to a selective borylation of proteins. It allows subsequent Suzuki cross coupling and therefore broadens the possibilities for chemical modifications and the establishment of new metalloenzymes. Different metal chelating amino acids were investigated, such as Hydrochinolin-Alanine, Bipyridyl-Alanine, Dipyridine-Lysines and phosphorous containing amino acids.
|Date of Award||Oct 2014|
|Original language||English (US)|
- Physical Science and Engineering
|Supervisor||Jorg Eppinger (Supervisor)|
- aqueous catalysis
- palladium catalysis
- cross coupling
- unnatural amino acids
- protein modifications