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The synthesis of pterin-dithiolene ligands was achieved by employing the radical nucleophilic substitution, i.e. the so-called “Minisci- Reaction”1. This protocol was used for the first time by Professor W. Pfleiderer on pterin substrates2 and proved a powerful method for the preparation of 6 acyl-pterins in course of this work. Subsequent construction of the dithiolene ring facilitates the synthesis of pterin-dithiolene ligands with completely unprotected pterin moieti.
The molybdenum cofactor is probably one of the most relevant discoveries in the recent history of pterin chemistry and biochemistry. Many efforts have been made for the preparation of compounds able to mimic the features of the Moco ligand system called "Molybdopterin". In fact, the study of MPT models enables a deeper understanding of the “mechanism of function” of this cofactor and most importantly, lays the foundation for a potential treatment for the Moco related diseases MoCOD and iSOD.
Molybdenum dependent enzymes are involved in essential metabolic transformations in bacteria, plants, and human beings. The extreme instability of the molybdenum cofactor (Moco) prevents its use as an effective treatment for patients with a Moco deficiency. Therefore, the design, develop and execute the artificial molybdenum cofactor models are essential.
In the present thesis, the asymmetric molybdopterin (mpt) model precursors with oxygen functionality and various electronic structures and their Moco model complexes mimicking the natural cofactor have been synthesized and comprehensively investigated through multi-nuclear NMR, MS, IR, resonance Raman, X-ray crystallography, UV-Vis, and electrochemical methods. Notably, the asymmetrically substituted dithiolenes in this thesis are confirmed through a significant push-pull effect, which is tuning its electronic structure. The redox behavior of Moco model complexes was investigated by temperature-dependent cyclic voltammetry. Electronic and vibrational spectral studies were investigated in detail to understand substituents effect on the electronic structure of model complexes and to elucidate roles of mpt in catalysis. Since the model complexes can be considered as structural models for the Moco dependent oxidoreductases, catalytic oxygen atom transfer (OAT) reactions in DMSO/PPh3 were investigated.
The main focus of the present thesis was achieved through the development of various synthetic routes that address phosphonate bearing dithiolene ligands, inspiring the natural mpt. Simultaneously the Minisci protocol was applied for the synthesis of new pterin ketophosphonates, taking into consideration the essential aspects of the natural molybdopterin, including the phosphate anchor group. Even though some aspects of this protocol require further optimizations, but the mentioned synthetic route has exceptional potential and flexibility.