In the past 30 years there were several studies that have thoroughly characterized the structure and the physiological function of the ubiquitin proteasome system. This is a sophisticated 2.5 MDa protein complex named 26S proteasome, which consists of 20S core particle and two terminal 19S regulatory particles. The proteasome is a complex multicatalytic enzymatic system that regulates vital physiological and pathological cellular processes through selective breakdown of the proteins. Identification and removal of misfolded, damaged and toxic proteins is crucial for the regulation and maintenance of cell homeostasis. Proteins that are involved in the processes of carcinogenesis and cancer cell survival are also substrates for the proteasome. Its inhibition in cancer cells therefore leads to accumulation of pro-apoptotic proteins and induction of cell death. The cancer drug discovery puts a significant emphasis on the identification of new and cancer-specific molecular targets. One of the most recently discovered and very promising targets is also the immunoproteasome, tightly regulated, highly-specific system that is responsible for cellular protein turnover. The discovery that cancer cells are more susceptive to proteasome inhibition than other cells had a strong impact on the discovery and synthesis of novel therapeutically useful inhibitors. The knowledge and recent findings associated with the structure and the functions of the ubiquitin proteasome system make this enzyme machinery a promising target in cancer treatment. Within this masters degree, we successfully synthesized several potential imunoproteasome inhibitors. The prepared compounds had a psoralen core scaffold with methyl group bound at the position 4. With the aim to explore the chemical space, we introduced several carefully planned substituents on the main psoralen structure. The synthesis of compounds was performed in several consecutive reaction steps. Firstly, we synthesized the 7-hydroxycoumarin ring by reacting diethyl 2-acethylsuccinate or diethyl 2-acetylpentanedionate with resorcinol. Then, different 2-bromoacetophenones were introduced to properly modify the hydroxyl group. Afterwards, the condensation reaction was carried out, leading to the formation of the core psoralen ring. Finally, we introduced three different electrophilic moieties at the C-terminus, such as 1- hydroxypyrrolidine-2,5-dione, 2-aminoacetonitrile or 2-(methylamino)acetonitrile. The purpose of this last step was to achieve covalent bonding with the catalytic amino acid in the immunoproteasome active site. All compounds were biochemically evaluated at the Department of Clinical Biochemistry. The residual activities of the chymotrypsin-like imunoproteasome subunit after the addition of compounds were determined. Based on the data, compund 5c showed the most potent inhibitory activity. On the basis of results from inhibition assays, we can also conclude that the transformation of the C-terminal carboxylic acid into an activated ester is crucial for improving inhibition; most probably because of the formation of covalent bonds within the active site of the immunoproteasome. Introduction of an amide bond and Ncianomethylamides as electrophiles did not improve inhibitory effect. In addition, bromine at the para position of the phenyl fragment led to diminished affinity for binding into the active site of the immunoproteasome.