Abstract
Human pathogenic trypanosomatid parasites harbor a unique form of peroxisomes termed glycosomes that are essential for parasite viability. We and others previously identified and characterized the essential Trypanosoma brucei ortholog TbPEX3, which is the membrane-docking factor for the cytosolic receptor PEX19 bound to the glycosomal membrane proteins. Knockdown of TbPEX3 expression leads to mislocalization of glycosomal membrane and matrix proteins, and subsequent cell death. As an early step in glycosome biogenesis, the PEX3–PEX19 interaction is an attractive drug target. We established a high-throughput assay for TbPEX3–TbPEX19 interaction and screened a compound library for small-molecule inhibitors. Hits from the screen were further validated using an in vitro ELISA assay. We identified three compounds, which exhibit significant trypanocidal activity but show no apparent toxicity to human cells. Furthermore, we show that these compounds lead to mislocalization of glycosomal proteins, which is toxic to the trypanosomes. Moreover, NMR-based experiments indicate that the inhibitors bind to PEX3. The inhibitors interfering with glycosomal biogenesis by targeting the TbPEX3–TbPEX19 interaction serve as starting points for further optimization and anti-trypanosomal drug development.
Highlights
Trypanosomatids are vector-borne protozoan parasites responsible for highly divergent range of eukaryotic infections in humans and animals
The PEX3–PEX19 interaction is the key step for the peroxisomal targeting and insertion of Peroxisomal membrane protein (PMP)
The AlphaScreen assay was established with purified GST-TbPEX3d44 and His-tagged full-length TbPEX19 (TbPEX19FL-His) (Figure 1A, Supplementary Figure S1A)
Summary
Trypanosomatids are vector-borne protozoan parasites responsible for highly divergent range of eukaryotic infections in humans and animals. In the tropical and sub-tropical regions of the world, Trypanosoma brucei (T. brucei), T. cruzi, and various Leishmania species cause African and American trypanosomiases and leishmaniasis, respectively. T. brucei sub-species cause human infections termed African sleeping sickness (human African trypanosomiasis, HAT), and its close related species T. congolense and T. vivax cause animal infections termed nagana disease in subSaharan regions. The human infections are fatal without treatment and affect across 36 countries in sub-Sahara African area, and majority of the reported cases (>95%) were caused by the sub-species T. brucei gambiense (Kennedy, 2019; WHO). More than 20 million people are currently infected with T. cruzi or Leishmania, leading to over 30 thousand deaths each year. With the fact that there is no effective vaccine against HAT due to the antigenic variation, chemotherapies
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