Toxoplasma gondii, an intracellular pathogenic protist with a remarkable ability to infect a wide range of host cells, displays an equally exceptional design of its carbon metabolism. There are, however, critical gaps in our understanding of the metabolic network in T. gondii. We characterized the mito-nuclear metabolism and organelle coupling during its acute infection (lytic cycle). The major enzymes of the TCA cycle, i.e., citrate synthase (CS1), succinyl-CoA synthase alpha subunit (SCSα), succinate dehydrogenase (SDHA) and FAD malate dehydrogenase (MDH-FAD) located in the parasite mitochondrion support its asexual reproduction but are not needed for its survival. The SCSα and SDHA mutants are nearly avirulent in a mouse model, and they can protect the host against a lethal challenge infection. Genetic deletion of MDH-FAD dysregulated glucose-derived carbon flux, leading to a collapse of the mitochondrial membrane potential. The parasite also harbors a cytosolic isoform of MDH and a nuclear malic enzyme (ME) contributing to malate oxidation
however, only the latter is essential for the lytic cycle. Expression of ME in the nucleus is crucial for the parasite development. Besides, conditional knockdown of ME impairs the histone acetylation and disrupts the expression of several genes in tachyzoites. Our work discloses novel network design features of T. gondii and highlights the therapeutic and vaccination potential of the parasite metabolism.