Characterisation of Potential Inhibitors of Calmodulin from Plasmodium falciparum

• Main Authors: Iversen, Alexandra, Nordén, Ebba, Bjers, Julia, Wickström, Filippa, Zhou, Martin, Hassan, Mohamed
• Format: Others
• Language: English
• Published: Linköpings universitet, Institutionen för fysik, kemi och biologi 2020
• Subjects: Plasmodium falciparum; Calmodulin; Malaria; Trifluoperazine; Calmidazolium; Artemisinin; Fentanyl derivatives; Modelling; Docking; Bioinformatics; Engineering and Technology; Teknik och teknologier; Bioinformatics and Systems Biology; Bioinformatik och systembiologi; Biochemistry and Molecular Biology; Biokemi och molekylärbiologi
• Online Access: http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-170268

Each year countless lives are affected and about half a million people die from malaria, a disease caused by parasites originating from the Plasmodium family. The most virulent species of the parasite is Plasmodium falciparum (P. falciparum).   Calmodulin (CaM) is a small, 148 amino acid long, highly preserved and essential protein in all eukaryotic cells. Previous studies have determined that CaM is important for the reproduction and invasion of P. falciparum in host cells. The primary structure of human CaM (CaMhum) and CaM from P. falciparum (CaMpf) differ in merely 16 positions, making differences in their structures and ligand affinity interesting to study. Especially since possible inhibitors of CaMpf in favor of CaMhum, in extension, could give rise to new malaria treatments.   Some antagonists, functioning as inhibitors of CaM, have already been analysed in previous studies. However, there are also compounds that have not yet been studied in regards to being possible antagonists of CaM. This study regards three known antagonists; trifluoperazine (TFP), calmidazolium (CMZ) and artemisinin (ART) and also three recently created fentanyl derivatives; 3-OH-4-OMe-cyclopropylfentanyl (ligand 1), 4-OH-3OMe-4F-isobutyrylfentanyl (ligand 2) and 3-OH-4-OMe-isobutyrylfentanyl (ligand 3).   Bioinformatic methods, such as modelling and docking, were used to compare the structures of CaMhum and CaMpf as well as observe the interaction of the six ligands to CaM from both species. In addition to the differences in primary structure, distinguished with ClustalW, disparities in tertiary structure were observed. Structure analysis of CaMhum and CaMpf in PyMOL disclosed a more open conformation as well as a larger, more defined, hydrophobic cleft in CaMhum compared to CaMpf. Simulated binding of the six ligands to CaM from both species, using Autodock 4.2, indicated that TFP and ART bind with higher affinity to CaMhum which is expected. Ligand 2 and ligand 3 also bound with higher affinity and facilitated stronger binding to CaMhum, which is reasonable since their docking is based on how TFP binds to CaM. However, ligand 1 as well as CMZ both bound to CaMpf with higher affinity. Despite promising results for ligand 1 and CMZ, no decisive conclusion can be made solely based on bioinformatic studies.    To gain a better understanding on the protein-ligand interactions of the six ligands to CaMhum and CaMpf, further studies using e.g. circular dichroism and fluorescence would be advantageous. Based on the results from this study, future studies on the binding of CMZ and ligand 1 to CaM as well as ligands with similar characteristics would be especially valuable. This is because they, based on the results from this study, possibly are better inhibitors of CaMpf than CaMhum and thereby could function as possible antimalarial drugs.