UNG-initiated base excision repair is the major repair route for 5-fluorouracil in DNA, but 5-fluorouracil cytotoxicity depends mainly on RNA incorporation.

Cytotoxicity of 5-fluorouracil (FU) and 5-fluoro-2'-deoxyuridine (FdUrd) due to DNA fragmentation during DNA repair has been proposed as an alternative to effects from thymidylate synthase (TS) inhibition or RNA incorporation. The goal of the present study was to investigate the relative contribution of the proposed mechanisms for cytotoxicity of 5-fluoropyrimidines. We demonstrate that in human cancer cells, base excision repair (BER) initiated by the uracil-DNA glycosylase UNG is the major route for FU-DNA repair in vitro and in vivo. SMUG1, TDG and MBD4 contributed modestly in vitro and not detectably in vivo. Contribution from mismatch repair was limited to FU:G contexts at best. Surprisingly, knockdown of individual uracil-DNA glycosylases or MSH2 did not affect sensitivity to FU or FdUrd. Inhibitors of common steps of BER or DNA damage signalling affected sensitivity to FdUrd and HmdUrd, but not to FU. In support of predominantly RNA-mediated cytotoxicity, FU-treated cells accumulated ~3000- to 15 000-fold more FU in RNA than in DNA. Moreover, FU-cytotoxicity was partially reversed by ribonucleosides, but not deoxyribonucleosides and FU displayed modest TS-inhibition compared to FdUrd. In conclusion, UNG-initiated BER is the major route for FU-DNA repair, but cytotoxicity of FU is predominantly RNA-mediated, while DNA-mediated effects are limited to FdUrd.

Methylation damage to RNA induced in vivo in Escherichia coli is repaired by endogenous AlkB as part of the adaptive response.

Cytotoxic 1-methyladenine (1-meA) and 3-methylcytosine (3-meC) lesions induced in DNA and RNA in vitro and in pre-damaged DNA and RNA bacteriophages in vivo are repaired by the Escherichia coli (E. coli) protein AlkB and a human homolog, ALKBH3. However, it is not known whether endogenous RNA is repaired in vivo by repair proteins present at physiological concentrations. The concept of RNA repair as a biologically relevant process has therefore remained elusive. Here, we demonstrate AlkB-mediated repair of endogenous RNA in vivo by measuring differences in lesion-accumulation in two independent AlkB-proficient and deficient E. coli strains during exposure to methyl methanesulfonate (MMS). Repair was observed both in AlkB-overproducing strains and in the wild-type strains after AlkB induction. RNA repair appeared to be highest in RNA species below 200 nucleotides in size, mainly comprising tRNAs. Strikingly, at least 10-fold more lesions were repaired in RNA than in DNA. This may be a consequence of some 30-fold higher levels of aberrant methylation in RNA than in DNA after exposure to MMS. A high primary kinetic isotope effect (>10) was measured using a deuterated methylated RNA substrate, D3-1me(rA), demonstrating that it is the catalytic step, and not the search step that is rate-limiting. Our results demonstrate that RNA repair by AlkB takes place in endogenous RNA as part of an adaptive response in wild-type E. coli cells.

Altered expression of PGK1 in a family with phosphoglycerate kinase deficiency.

The X-linked recessive disease phosphoglycerate kinase (PGK) deficiency is caused by altered expression of the PGK1 enzyme, which causes muscle stiffness, hemolytic anemia, and mental retardation. In this study we characterized the PGK1 gene in a family of two brothers, two sisters, and their parents. A single mutation in exon 6, which was associated with the pattern of inheritance of PGK1 deficiency, was observed. This silent G213G; c.639C>T mutation was localized to the conserved exon-intron boundary. We have developed a method for quantification of PGK1 mRNA and demonstrated a marked reduction in PGK1 mRNA in both brothers with the disease. A smaller decrease in PGK1 expression was observed in one sister with symptoms of PGK deficiency and in her mother. Only the normal PGK1 allele was expressed in the two heterozygous women. Whereas most known PGK1 mutations cause amino acid alterations, our study indicates that inhibition of the transcription mechanism is the cause of PGK deficiency.