Abstract
Activation of oxidative stress-responses and downregulation of insulin-like signaling (ILS) is seen in Nucleotide Excision Repair (NER) deficient segmental progeroid mice. Evidence suggests that this is a survival response to persistent transcription-blocking DNA damage, although the relevant lesions have not been identified. Here we show that loss of NTH-1, the only Base Excision Repair (BER) enzyme known to initiate repair of oxidative DNA damage inC. elegans, restores normal lifespan of the short-lived NER deficient xpa-1 mutant. Loss of NTH-1 leads to oxidative stress and global expression profile changes that involve upregulation of genes responding to endogenous stress and downregulation of ILS. A similar, but more extensive, transcriptomic shift is observed in the xpa-1 mutant whereas loss of both NTH-1 and XPA-1 elicits a different profile with downregulation of Aurora-B and Polo-like kinase 1 signaling networks as well as DNA repair and DNA damage response genes. The restoration of normal lifespan and absence oxidative stress responses in nth-1;xpa-1 indicate that BER contributes to generate transcription blocking lesions from oxidative DNA damage. Hence, our data strongly suggests that the DNA lesions relevant for aging are repair intermediates resulting from aberrant or attempted processing by BER of lesions normally repaired by NER.
Highlights
The Base excision repair (BER) pathway is the main mechanism for removal of endogenously generated DNA base damage [1]
We found a high number of differentially expressed transcripts between the N2 reference strain and the nth-1 mutant considering the unstressed conditions of the animals: 2074 probe sets were differentially expressed ≥1.8 fold (Supplemental Table SI)
Based on a large body of evidence indicating that persistent transcription-blocking DNA damage cause attenuation of insulin‐like signaling (ILS) and activation of oxidative stress responses [18,19,20, 47], it is reasonable to speculate that the transcriptome modulation in the xpa-1 mutant reflects accumulation of transcription blocking DNA lesions
Summary
The Base excision repair (BER) pathway is the main mechanism for removal of endogenously generated DNA base damage [1]. There are at least 12 different mammalian DNA glycosylases, of which at least 7 have overlapping specificities towards oxidative DNA damage [3, 4]. Caenorhabditis elegans (C. elegans) is a multicellular animal that encodes only two DNA-glycosylases: UNG1 [5, 6] and NTH-1 [7]. C. elegans is an attractive system in which to study consequences of BER-deficiency in animals. The strong genetic and mechanistic correlation between stress resistance and longevity in C. elegans [8], allows us to probe the contribution of DNA damage, in particular oxidative DNA damage, and its repair to phenotypes associated with oxidative stress in large populations over the entire lifespan
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