Mechanism of Visible Light-Mediated Alkene Aminoarylation with Arylsulfonylacetamides.

Alkene aminoarylation with arylsulfonylacetamides via a visible-light mediated radical Smiles-Truce rearrangement represents a convenient approach to the privileged arylethylamine pharmacaphore traditionally generated by circuitous, multi-step sequences. Herein, we report detailed synthetic, spectroscopic, kinetic, and computational studies designed to interrogate the proposed mechanism, including the key aryl transfer event. The data are consistent with a rate-limiting 1,4-aryl migration occurring either via a stepwise process involving a radical Meisenheimer-like intermediate or in a concerted fashion dependent on both arene electronics and alkene sterics. Our efforts to probe the mechanism have significantly expanded the substrate scope of the transformation with respect to the migrating aryl group and provide further credence to the synthetic potential of radical aryl migrations.

RAD18 and associated proteins are immobilized in nuclear foci in human cells entering S-phase with ultraviolet light-induced damage.

Proteins required for translesion DNA synthesis localize in nuclear foci of cells with replication-blocking lesions. The dynamics of this process were examined in human cells with fluorescence-based biophysical techniques. Photobleaching recovery and raster image correlation spectroscopy experiments indicated that involvement in the nuclear foci reduced the movement of RAD18 from diffusion-controlled to virtual immobility. Examination of the mobility of REV1 indicated that it is similarly immobilized when it is observed in nuclear foci. Reducing the level of RAD18 greatly reduced the focal accumulation of REV1 and reduced UV mutagenesis to background frequencies. Fluorescence lifetime measurements indicated that RAD18 and RAD6A or poleta only transferred resonance energy when these proteins colocalized in damage-induced nuclear foci, indicating a close physical association only within such foci. Our data support a model in which RAD18 within damage-induced nuclear foci is immobilized and is required for recruitment of Y-family DNA polymerases and subsequent mutagenesis. In the absence of damage these proteins are not physically associated within the nucleoplasm.

RAD18 signals DNA polymerase IOTA to stalled replication forks in cells entering S-phase with DNA damage.

Endogenously generated reactive oxygen species and genotoxic carcinogens can covalently modify bases in cellular DNA. If not recognized and removed prior to S-phase of the cell cycle, such modifications can block DNA replication fork progression. If blocked forks are not are not resolved, they result in double strand breaks and cell death. Recent data indicate that the process of translesion DNA synthesis (TLS) is a highly conserved mechanism for bypassing lesions in template DNA. Although not fully understood, in yeast a ubiquitin ligase (RAD18) signals error-prone Y family polymerases to the blocked fork to bypass the damage with potentially mutagenic consequences. Homologs of the yeast proteins are found in higher eukaryotic cells, including human. We are examining the hypothesis that RAD18 acts as a proximal signal to Y-family polymerases to bypass damage, in a manner analogous to yeast but with additional layers of complexity. Here we report that RAD18 accumulates in nuclear foci after UV irradiation only in cells entering S-phase with DNA damage. These foci co-localize with proliferating cell nuclear antigen (PCNA). In addition, a newly described DNA polymerase, pol iota, also forms nuclear foci in a damage- and S-phase dependent manner. These data support our overall hypothesis that RAD18 accumulates at blocked forks and initiates the signal to recruit TLS polymerases.

Translesion DNA replication proteins as molecular targets for cancer prevention.

Mutations in DNA are generally considered to have an etiologic role in the development of cancer. If so, it follows that reducing the frequency of such mutations will reduce the incidence of cancer induced by mutagens. Recent advances in elucidating the molecular mechanisms of carcinogen-induced mutagenesis indicate that replication of DNA templates that contain replication-blocking adducts is accomplished with error-prone DNA polymerases. These polymerases have relaxed base-pairing requirements, and can insert bases across from adducted templates, but with potentially mutagenic consequences. In principle, these proteins present new and attractive molecular targets to reduce mutagenesis. If this can be done in vivo without increasing cytotoxic responses to carcinogens, then novel chemopreventive strategies can be designed to reduce the risk of cancer in exposed populations prior to the appearance of disease symptoms.

REV1 accumulates in DNA damage-induced nuclear foci in human cells and is implicated in mutagenesis by benzo[a]pyrenediolepoxide.

The REV1 gene encodes a Y-family DNA polymerase that has been postulated to have both catalytic and structural functions in translesion replication past UV photoproducts in mammalian cells. To examine if REV1 is implicated in DNA damage tolerance mechanisms after exposure of human cells to a chemical carcinogen, we generated a plasmid expressing REV1 protein fused at its C-terminus with green fluorescent protein (GFP). In transient transfection experiments, virtually all of the transfected cells had a diffuse nuclear pattern in the absence of carcinogen exposure. In contrast, in cells exposed to benzo[a]pyrenediolepoxide, the fusion protein accumulated in a focal pattern in the nucleus in 25% of the cells, and co-localized with PCNA. These data support the idea that REV1 is present at stalled replication forks. We also examined the mutagenic response at the HPRT locus of human cells that had greatly reduced levels of REV1 mRNA due to the stable expression of gene-specific ribozymes, and compared them to wild-type cells. The mutant frequency was greatly reduced in the ribozyme-expressing cells. These data indicate that REV1 is implicated in the mutagenic DNA damage tolerance response to BPDE and support the development of strategies to target this protein to prevent such mutations.

Decreased frequency and highly aberrant spectrum of ultraviolet-induced mutations in the hprt gene of mouse fibroblasts expressing antisense RNA to DNA polymerase zeta.

In the budding yeast Saccharomyces cerevisiae, DNA polymerase zeta (pol zeta) is responsible for the great majority of mutations generated during error-prone translesion replication of DNA that contains UV-induced lesions. The catalytic subunit of pol zeta is encoded by the Rev3 gene. The orthologue of Rev3 has been cloned from higher eukaryotic cells, including human, but its role in mutagenesis and carcinogenesis remains obscure. Investigation into the cellular function of pol zeta has been hindered by the fact that Rev3 knockout mice do not survive beyond midgestation, and embryonic stem cells used to derive these mice are not genetically stable. We have generated a transgenic mouse that expresses antisense RNA transcripts to mRev3 endogeneous RNA. These mice are viable, have greatly reduced levels of Rev3 transcript, and have reduced levels of B cells and impaired development of high-affinity memory B cells. Here, we report that exposure of fibroblasts derived from these mice to UV resulted in a 4-5-fold reduction in mutant frequency at the hprt locus at every dose examined, and the mutation spectrum was highly aberrant compared with the control cells. In the control cells, 80% of the mutations were transitions and approximately 75% of these arose from photoproducts in the putative leading strand template. Strikingly, in transgenic cells, most of the mutations were transversions and there was a complete loss of strand bias. This mutation spectrum is highly aberrant and is similar to that induced by UV in human xeroderma pigmentosum variant cells, which lack polymerase eta. These data indicate that most UV-induced mutations are dependent on DNA pol zeta, a function that has been conserved from yeast to higher eukaryotic cells. However, in mammalian cells, other DNA polymerase(s) may accomplish error-prone translesion replication and are responsible for residual UV mutagenesis observed in the absence of pol zeta. Further, these data support a central role for DNA polymerase eta in the error-free bypass of UV photoproducts. The antisense Rev3 mice should be a useful model to study mutagenic lesion bypass by pol zeta in mammalian cells and to investigate the role this polymerase plays in carcinogenesis.