The trypanosomatid dynamin-like protein associates with glycosomes

Subcellular organelles must undergo periodic fission to be evenly distributed during cell division. These division events are mediated by protein members of the dynamin family, including dynamin-related proteins. Protozoan parasites, including trypanosomatids such as Trypanosoma brucei, have several single-copy organelles, suggesting tightly regulated systems for organelle fission and segregation. However, trypanosomatid genomes typically encode only one dynamin-like protein (DLP), which in T. brucei has multiple roles including endocytosis and mitochondrial fission. How DLPs are recruited to different membranes, and how their fission activity is regulated, are unknown. We used tandem-affinity purification in the related trypanosomatid Crithidia fasciculata to identify interacting partners of DLP. Surprisingly, we found that CfDLP co-purified with multiple proteins predicted to localize to glycosomes, peroxisome-related glycolytic organelles. Using expansion microscopy, we confirmed the localization of CfDLP to glycosomes, specifically those that appear to be undergoing division. To see if changes in the levels of DLP could alter glycosome morphology, we conducted RNAi-mediated knockdown and inducible overexpression experiments in T. brucei. TbDLP knockdown causes subtle changes in glycosome size, while overexpression of TbDLP1 causes an increase cytoplasmic vesicles and altered permeability of glycosomal membranes. These results suggest that the multifunctional DLP of trypanosomatids plays a role in glycosome maintenance. Author SummaryTrypanosomatids are eukaryotic parasites that cause devastating diseases in humans and animals. Like all eukaryotic cells, they must maintain their subcellular compartments through organelle division and other membrane remodeling events. Dynamin-like proteins are enzymes that work with other proteins to apply mechanical force to membranes. The dynamin-like proteins of Trypanosoma brucei, the causative agent of human African trypanosomiasis, have been implicated in endocytosis and mitochondrial division, although how these activities are regulated is not known. We have used a model trypanosomatid, the mosquito parasite Crithidia fasciculata, to look for dynamin-interacting proteins. In addition to proteins of unknown function, we show that dynamin-like protein associates with proteins found on glycosomes, trypanosomatid-specific organelles that contain enzymes required for breakdown of sugars. Knockdown and overexpression of dynamin-like proteins in T. brucei causes changes in glycosomes, supporting a role in organelle maintenance. Dynamin-like proteins likely regulate organelle structure and function, allowing parasites to adapt to different energetic requirements during their life cycle.