Implicating TFAM in the Mitochondrial Dysfunction that Accelerates Immune Aging
This short commentary looks at just one cell type, T cells of the adaptive immune system, in which loss of mitochondrial function produces issues such as cellular senescence that contribute to broader degenerative aging throughout the body. Every cell contains hundreds of mitochondria, responsible for producing adenosine triphosphate, an energy store molecule used to power cellular processes. When that supply diminishes, everything suffers as a consequence: cell function, tissue function, health. With age, mitochondrial function is observed to decline throughout the body. This is likely the result of signaling and gene expression changes that hinder the quality control mechanism of mitophagy, and thus worn and damaged mitochondria are not effectively recycled. Deeper connections to the root causes of aging are not yet well understood, however.
Mitochondrial dysfunction is a key event in many pathologies and contributes to the ageing process. Mitochondria have been shown to participate in every aspect of ageing, from a decline in stem cell function and cellular senescence, through to the development of the low grade inflammatory state. Alterations that occur to mitochondria with age are numerous and can be observed in many different cells and tissues. Indeed, we have shown that human CD8+ T cells were more susceptible to senescence compared to their CD4+ counterparts as they displayed a lower mitochondrial content and postulated loss of mitochondrial function controls the senescence phenotype in T cells as well as other cell types. However the mechanism remained elusive, that is until recent work demonstrated that mitochondrial dysfunction was controlled by mitochondrial transcription factor A (TFAM).
In order to examine the links between mitochondrial loss and ageing, researchers used TFAM deficient mice, Tfamfl/flCd4Cre. TFAM is a nuclear gene that controls the stabilisation and replication of mitochondrial DNA. They found T cell mitochondrial content declined along with the loss of components of the electron transport chain causing a switch in T cell metabolism towards glycolysis. Interestingly they found young Tfamfl/flCd4Cre mice had a metabolic profile that resembled wild type 22 month mice, which was associated with Th1 skewing and increased expression of the Th1 master regulator T-bet. Additionally Tfamfl/flCd4Cre mice were also immunocompromised.
Further evidence for TFAM being associated with ageing came from the observation that 7 month Tfamfl/flCd4Cre mice had an elevated inflammatory burden or inflammageing more usually seen in older animals. This increased inflammation is a predictor of multimorbidity during ageing and Tfamfl/flCd4Cre mice were found to have premature loss of muscular, cardiovascular, and cognitive fitness together with a shorten life span. TFAM deficient animals were found to be less active and slower with less hypodermal fat than controls despite a higher energy expenditure.
The authors validated that this multimorbidity phenotype was due to a mitochondrial defect specifically in T cells by creating a T cell-specific Tfam deficient mouse model, Tfamfl/flLckCre. These animals also showed a prematurely aged phenotype by elevated expression of the senescence-associated markers p21 and p53. Incubation of hepatocytes or pre-adipocytes with serum from Tfamfl/flCd4Cre animals or with TNFα also increased p21 expression, supporting the idea that inflammation induces senescence and premature ageing. They also gave Tfamfl/flCd4Cre animals nicotinamide riboside (NR), the NAD+ precursor that declines with age and is a metabolic cofactor with a critical role in mitochondrial function. The use of NR was found to be protective against premature senescence and most but not all features of multimorbidity.
The paper concludes that T cells are capable of regulating both health and lifespan as well as highlighting the importance of tight immunometabolic control during ageing and the onset of age-related diseases. Finally, this work cements the idea that mitochondria play a causal role in senescence and that increasing mitochondrial biogenesis when coupled with mitochondrial degradation confers a survival advantage at both the cellular and organismal level.