Oximic compounds as potential inhibitors of metacaspase-2 (TbMCA2) of Trypanosoma brucei.

Metacaspases are a distinct class of cysteine proteases predominantly found in plants, fungi, and protozoa, crucial for regulating programmed cell death (PCD). They possess unique structural features and differ markedly from caspases in their activation mechanisms and substrate specificities, with a notable preference for binding basic residues in substrates. In this study, we introduced vanillin-derived oximic compounds to explore their pharmaceutical potential. We evaluated these compounds for their inhibitory effects on TbMCA2, a metacaspase in Trypanosoma brucei, identifying AO-7, AO-12, and EO-20 as promising inhibitors. AO-12 showed significant potential as a non-competitive inhibitor with notable IC50 values. Molecular docking studies were also conducted to evaluate the binding affinity of these compounds for TbMCA2. This research is particularly relevant given the urgent need for more effective and less toxic treatments for trypanosomiasis, a parasitic disease caused by trypanosomes. The absence of available vaccines and the limitations imposed by drug toxicity underscore the importance of these findings. Our study represents a significant advancement in developing therapeutic agents targeting metacaspases in trypanosomatids and highlights the necessity of understanding metacaspase regulation across various species. It provides valuable insights into inhibitor sensitivity and potential species-specific therapeutic strategies. In conclusion, this research opens promising avenues for novel therapeutic agents targeting metacaspases in trypanosomatids, addressing a critical gap in combating neglected diseases associated with these pathogens. Further research is essential to refine the efficacy and safety profiles of these compounds, aiming to deliver more accessible and effective therapeutic solutions to populations afflicted by these debilitating diseases.

Metacaspase of Saccharomyces cerevisiae (ScMCA-Ia) presents different catalytic cysteine in a processed and non-processed form.

Metacaspases are cysteine proteases belonging to the CD clan of the C14 family. They possess important characteristics, such as specificity for cleavage after basic residues (Arg/Lys) and dependence on calcium ions to exert their catalytic activity. They are defined by the presence of a large subunit (p20) and a small subunit (p10) and are classified into types I, II, and III. Type I metacaspases have a characteristic pro-domain at the N-terminal of the enzyme, preceding a region rich in glutamine and asparagine. In the yeast Saccharomyces cerevisiae, a type I metacaspase is found. This organism encodes a single metacaspase that participates in the process of programmed cell death by apoptosis. The study focuses on cloning, expressing, and mutating Saccharomyces cerevisiae metacaspase (ScMCA-Ia). Mutations in Cys155 and Cys276 were introduced to investigate autoprocessing mechanisms. Results revealed that Cys155 plays a crucial role in autoprocessing, initiating a conformational change that activates ScMCA-Ia. Comparative analysis with TbMCA-IIa highlighted the significance of the N-terminal region in substrate access to the active site. The study proposes a two-step processing mechanism for type I metacaspases, where an initial processing step generates the active form, followed by a distinct intermolecular processing step. This provides new insights into ScMCA-Ia's activation and function. The findings hold potential implications for understanding cellular processes regulated by metacaspases. Overall, this research significantly advances knowledge in metacaspase biology.

Cysteine proteases as potential targets for anti-trypanosomatid drug discovery.

Leishmaniasis and trypanosomiasis are endemic neglected disease in South America and Africa and considered a significant public health problem, mainly in poor communities. The limitations of the current available therapeutic options, including the lack of specificity, relatively high toxicity, and the drug resistance acquiring, drive the constant search for new targets and therapeutic options. Advances in knowledge of parasite biology have revealed essential enzymes involved in the replication, survival, and pathogenicity of Leishmania and Trypanosoma species. In this scenario, cysteine proteases have drawn the attention of researchers and they are being proposed as promising targets for drug discovery of antiprotozoal drugs. In this systematic review, we will provide an update on drug discovery strategies targeting the cysteine proteases as potential targets for chemotherapy against protozoal neglected diseases.