Table 2.
Table showing key genes identified in this study in relation to aging literature.
| Gene | Current Study | Existing Literature |
|---|---|---|
| PARP1 | Decrease in response to old serum (6 days timepoint, qPCR) | PARP1 is overactivated in aging and age-related disease, inhibition of PARP1 was shown to be beneficial in delaying progression [65-67]. |
| UCHL | Increase in response to old serum (6 days timepoint, qPCR) | An increase in UCHL was shown in aging mice. In addition, plasma UCHL levels showed a positive correlation with Parkinson’s disease severity in a recent case-control study [68, 69]. |
| TMEM149 | Increase in response to old serum (6-hour timepoint, identified via microarray, validated by qPCR) | Role of TMEM149 in aging remains largely unexplored. However, a recent longitudinal multiomics profiling study in healthy individuals showed a positive correlation between TMEM149 and age [70]. |
| RFN126 | Decrease in response to old serum (6-hour timepoint, identified via microarray, validated by qPCR) | RNF126 is required for Bag6-dependent ubiquitination and has been shown to initiate degradation of mislocalised and misfolded proteins. This suggests a decrease in RNF126 may be associted to an accumulation of mislocalised and misfolded proteins [71, 72]. |
| ENDOG | Increase in response to old serum (6-day timepoint, identified via microarray, validated by qPCR) | Higher levels of EndoG were found in whole brain lystaes of 34-week-old mice when compared with 5-week-old mice. In addition, nuclear levels of ENGOG were 153% higher in the aged rat plantaris at 24 months, when compared to younger counterparts aged 6 months [73, 74]. |