Tyrosinemia Type II is a genetic disorder caused by a mutation in the enzyme tyrosine aminotransferase (TAT), which leads to an elevated level of tyrosine in the blood. If untreated, individuals with tyrosinemia develop life-threatening clinical symptoms that include an increased tendency to bleed, damage to the nervous system, damage to the eyes, and organ failure. Unexpectedly, mutation of TAT in the nematode Caenorhabditis elegans results in animals that are long lived in comparison with wild-type (WT) worms. This study aims to elucidate the cellular mechanism and workings of TAT in the mitochondria, its role in the pathology of the disease, and its possible links with aging in C. elegans. Thus far, we have developed a simple method to measure the CO2 output of the worms and shown that the TAT mutant’s metabolism is about 50% compared to WT. This significant decrease in CO2 output was matched comparable to a strain deficient for mitochondrial Cytochrome C Oxidase, which served as a positive control. Cytochrome C Oxidase, or Electron Transport Chain Complex IV, is one of the three complexes that create the proton gradient inside the mitochondrial matrix upon accepting electrons. Notably, mutation of the gene acting downstream to TAT in the tyrosine degradation pathway, which causes Tyrosinemia Type III in people, or any other mutation in tyrosine metabolism that we have tested, causes no significant change in CO2 output of C. elegans. Furthermore, through our preliminary metabolomics assay we have identified three metabolites that are accumulated to extremely high levels in comparison to positive and negative controls. The future steps will include determining whether these metabolites play a direct role in the effects of TAT mutation on mitochondrial function and aging.