Comparative whole genome sequencing reveals phenotypic tRNA gene duplication in spontaneous Schizosaccharomyces pombe La mutants

We used a genetic screen based on tRNA-mediated suppression (TMS) in a Schizosaccharomyces pombe La protein (Sla1p) mutant. Suppressor pre-tRNASerUCA-C47:6U with a debilitating substitution in its variable arm fails to produce tRNA in a sla1-rrm mutant deficient for RNA chaperone-like activity. The parent strain and spontaneous mutant were analyzed using Solexa sequencing. One synonymous single-nucleotide polymorphism (SNP), unrelated to the phenotype, was identified. Further sequence analyses found a duplication of the tRNASerUCA-C47:6U gene, which was shown to cause the phenotype. Ninety percent of 28 isolated mutants contain duplicated tRNASerUCA-C47:6U genes. The tRNA gene duplication led to a disproportionately large increase in tRNASerUCA-C47:6U levels in sla1-rrm but not sla1-null cells, consistent with non-specific low-affinity interactions contributing to the RNA chaperone-like activity of La, similar to other RNA chaperones. Our analysis also identified 24 SNPs between ours and S. pombe 972h- strain yFS101 that was recently sequenced using Solexa. By including mitochondrial (mt) DNA in our analysis, overall coverage increased from 52% to 96%. mtDNA from our strain and yFS101 shared 14 mtSNPs relative to a ‘reference’ mtDNA, providing the first identification of these S. pombe mtDNA discrepancies. Thus, strain-specific and spontaneous phenotypic mutations can be mapped in S. pombe by Solexa sequencing

Decreased Expression of the DNA Mismatch Repair Gene Mlh1 under Hypoxic Stress in Mammalian Cells

The hypoxic tumor microenvironment has been shown to contribute to genetic instability. As one possible mechanism for this effect, we report that expression of the DNA mismatch repair (MMR) gene Mlh1 is specifically reduced in mammalian cells under hypoxia, whereas expression of other MMR genes, including Msh2, Msh6, and Pms2, is not altered at the mRNA level. However, levels of the PMS2 protein are reduced, consistent with destabilization of PMS2 in the absence of its heterodimer partner, MLH1. The hypoxia-induced reduction in Mlh1 mRNA was prevented by the histone deacetylase inhibitor trichostatin A, suggesting that hypoxia causes decreased Mlh1 transcription via histone deacetylation. In addition, treatment of cells with the iron chelator desferrioxamine also reduced MLH1 and PMS2 levels, in keeping with low oxygen tension being the stress signal that provokes the altered MMR gene expression. Functional MMR deficiency under hypoxia was detected as induced instability of a (CA)(29) dinucleotide repeat and by increased mutagenesis in a chromosomal reporter gene. These results identify a potential new pathway of genetic instability in cancer: hypoxia-induced reduction in the expression of key MMR proteins. In addition, this stress-induced genetic instability may represent a conceptual parallel to the pathway of stationary-phase mutagenesis seen in bacteria

Abstract 4319: Lupus antibody-based cancer therapy

A subset of autoantibodies produced by patients with systemic lupus erythematosus (SLE) penetrates into cell nuclei and binds DNA, and we believe that such antibodies may have applications in cancer therapy. We have discovered that the cell-penetrating, nuclear-localizing anti-DNA lupus antibody 3E10 inhibits key steps in DNA single- and double-strand break repair and has potential for development as a targeted therapy for tumors harboring deficiencies in DNA repair. 3E10 preferentially binds DNA substrates with free single-strand tails and interferes with both base excision repair and homology-directed repair (HDR) in vitro, and HDR efficiency is reduced in cells treated with 3E10 as measured in the chromosome-based DR-GFP fluorescent reporter assay. The binding of 3E10 to DNA can be directly visualized under electron microscopy (EM), and EM studies confirmed that 3E10 interferes with RAD51 filament formation, which is a critical step in HDR. The 3E10 single chain variable fragment penetrates into human tumor xenografts in nude mice, and 3E10 sensitizes cancer cells and tumors to DNA-damaging therapy. In addition, 3E10, by itself, is toxic to BRCA2-deficient cancer cells but not to repair-proficient cells, and when combined with a DNA-damaging agent, 3E10 has a very large cytotoxic effect on BRCA2-deficient cancer cells. The synthetically lethal effect of 3E10 on BRCA2-deficient cancer cells is consistent with our finding that 3E10 inhibits DNA repair, and it suggests that 3E10 has potential as a targeted therapy for tumors harboring deficiencies in DNA repair, such as certain breast, ovarian, and prostate cancers. Of note, patients with SLE have lower than expected incidence rates of breast, ovarian, and prostate cancers, and it is tempting to speculate that the circulating cell-penetrating anti-DNA autoantibodies provide patients with SLE some protection against the development of DNA repair-deficient tumors. In summary, our work with the 3E10 antibody has provided proof of principle for the development of a lupus antibody as a cancer therapy and opened up new avenues for exploration into the biology of lupus antibodies