Introduction of human telomerase reverse transcriptase to normal human fibroblasts enhances DNA repair capacity

Purpose: From numerous reports on proteins involved in DNA repair and telomere maintenance that physically associate with human telomerase reverse transcriptase (hTERT), we inferred that hTERT/telomerase might play a role in DNA repair. We investigated this possibility in normal human oral fibroblasts (NHOF) with and without ectopic expression of hTERT/telomerase. Experimental Design: To study the effect of hTERT/telomerase on DNA repair, we examined the mutation frequency rate, host cell reactivation rate, nucleotide excision repair capacity, and DNA end-joining activity of NHOF and NHOF capable of expressing hTERT/telomerase (NHOF-T). NHOF-T was obtained by transfecting NHOF with hTERT plasmid. Results: Compared with parental NHOF and NHOF transfected with empty vector (NHOF-EV), we found that (a) the N-methyl-N'-nitro-N-nitrosoguanidine-induced mutation frequency of an exogenous shuttle vector was reduced in NHOF-T, (b) the host cell reactivation rate of N-methyl-N'-nitro-N-nitrosoguanidine-damaged plasmids was significantly faster in NHOF-T; (c) the nucleotide excision repair of UV-damaged DNA in NHOF-T was faster, and (d) the DNA end-joining capacity in NHOF-T was enhanced. We also found that the above enhanced DNA repair activities in NHOF-T disappeared when the cells lost the capacity to express hTERT/telomerase. Conclusions: These results indicated that hTERT/telomerase enhances DNA repair activities in NHOF. We hypothesize that hTERT/telomerase accelerates DNA repair by recruiting DNA repair proteins to the damaged DNA sites.