Targeting Plasmodium with constrained peptides and peptidomimetics.
Leah G HeltonEileen J KennedyPublished in: IUBMB life (2020)
Malaria remains a worldwide health concern with an estimated quarter of a billion people infected and nearly half a million deaths annually. Malaria is caused by a parasite infection from Plasmodium strains which are transmitted from mosquitoes into the human host. Although several small molecule inhibitors have been found to target the early stages of transmission and prevent parasite proliferation, multiple drug resistant parasite strains have emerged and drug resistance remains a major hurdle. As an alternative to small molecule inhibition, several peptide-based therapeutics have been explored for their potential as antimalarial compounds. Chemically constrained peptides or peptidomimetics were developed to target large binding interfaces of parasite-based proteins that have historically been difficult to selectively inhibit using small molecules. Here, we review ongoing research aimed at developing constrained peptides targeting protein-protein interactions pertinent to malaria pathogenesis. These targets include Falcipain-2, the J domain of CDPK1, myosin A tail domain interacting protein, the PKA signaling pathway, and an unclear signaling pathway involving angiotensin-derived peptides. Diverse synthetic methods were also used for each target. Merging parasite biology with synthetic strategies may provide new opportunities to develop alternative methods for uncovering novel antimalarials and may offer an alternate source for targeting drug-resistant parasite strains.
Keyphrases
- plasmodium falciparum
- drug resistant
- small molecule
- signaling pathway
- multidrug resistant
- acinetobacter baumannii
- escherichia coli
- protein protein
- amino acid
- cancer therapy
- pi k akt
- public health
- endothelial cells
- binding protein
- mental health
- drug delivery
- induced apoptosis
- health information
- oxidative stress
- zika virus
- pseudomonas aeruginosa
- climate change
- cell proliferation
- dengue virus
- endoplasmic reticulum stress
- dna binding