Mitochondrion-IMC contact sites are critical for cofactor biosynthesis and egress signaling in Toxoplasma gondii

Toxoplasma gondii is a single-celled parasite belonging to the Apicomplexa phylum. Toxoplasmas single mitochondrion is highly dynamic, changing its morphology as the parasite undergoes egress and invasion. Recently, we have demonstrated that mitochondrial morphology is driven by a protein named Lasso Maintenance Factor 1 (LMF1). This protein interacts with IMC10, a protein present at the parasites inner membrane complex (IMC), mediating a unique membrane contact site between the IMC and mitochondrion. Interestingly, parasites lacking either LMF1 or IMC10 have abnormal mitochondrial morphology, cell division defects, and delayed propagation in tissue culture. Although both components of the tether were identified, the functions of this contact site remain unknown. In this work, we show that {Delta}lmf1 parasites exhibit upregulation of egress signaling and downregulation in folate metabolism and pantothenate biosynthesis. {Delta}lmf1 parasites exhibit increased intracellular calcium levels, leading to greater sensitivity to ionophore-induced egress and microneme secretion. We have confirmed that parasites have decreased levels of tetrahydrofolate and coenzyme A, showing a limitation in cofactor production. Interestingly, the {Delta}lmf1 parasites prefer glutamine instead of glucose as a catabolic substrate. Accordingly, we demonstrate for the first time that proper mitochondrial positioning is crucial for folate and Coenzyme A metabolism as well as egress signaling. IMPORTANCEToxoplasma gondii is the causative agent of Toxoplasmosis, a disease that affects a third of the worlds population. This parasite has a single, highly dynamic mitochondrion. The parasites mitochondrion changes shape depending on environmental conditions (inside or outside the host cell) or on stressors, such as drugs. Our laboratory characterized the proteins involved in regulating mitochondrial dynamics in the parasite, but the functional importance of these mitochondrial changes has not yet been described. Here, we show that the shape of Toxoplasmas mitochondrion is important for the synthesis of key cofactors, such as folates and coenzyme A. We show that mitochondrial shape in this parasite is important for signaling the parasites exit from the host cell, a critical process in its life cycle. These findings review a previously unknown function of a parasite-specific organelle contact site, providing new insights into the importance of mitochondria for these parasites.