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. 2017 Jul 18;292(37):15225–15239. doi: 10.1074/jbc.M117.802702

Figure 9.

Figure 9.

A prototype model featuring the function of TgPEPCKmt as a metabolic shunt in central carbon metabolism of tachyzoites. Schemes are constructed based on this study and earlier work. In cells with an intact glycolysis (left), the mitochondrial PEPCK maintains a homeostatic bidirectional flow of glucose and glutamine-derived carbon, which may enable integrated use of both nutrients and rapid metabolic rewiring in response to nutritional oscillations within and/or outside host cells. Neither glucose nor glutamine alone produces significant amounts of fully labeled citrate, suggesting co-usage of both nutrients to operate the TCA cycle (depicted by green/red colors). A minor amount of (+6)-citrate that is produced from glucose requires a pool of sugar-derived oxaloacetate probably generated by TgPEPCKmt, because TgPyC and TgPEPCKnet are not expressed and expendable during the lytic cycle. On the other hand, in glycolysis-impaired cells (right), TgPEPCKmt allows glutamine-fueled gluconeogenic flux to ensure the biosynthetic activities and thereby parasite survival. Likewise, TgPEPCKmt-derived PEP and ensuing recycling of pyruvate can sustain a glutamine-fueled TCA cycle that is critical to produce energy and reducing equivalents. The work also implicates the presence of a PEP transporter in the membrane of the mitochondrion.