Use of Two-Dimensional Agarose-Gel Analysis to Characterize Processing of UV-Irradiated Plasmids and the Composition of the Replisome Following UV-induced Arrest

In this thesis, I address two fundamental questions related to our understanding of how DNA damage is processed and repaired during replication. Using Two-dimensional (2-D) agarose gel analysis, I first examine whether DNA damage on plasmids introduced by transformation is processed in a manner similar to that observed on endogenously replicating plasmids and the chromosome. The original intent for using this approach was to develop a technique that could examine how different DNA adducts would be repaired in various sequence contexts. However, I found that distinct differences exist between the processing of DNA damage on transforming plasmids and the chromosome. The 2-D agarose gel analysis shows that RecA-mediated processing does not contribute to the survival of transforming plasmids and that this effect is likely due to inefficient replication of the plasmids after they are initially introduced into cells. These observations, while important, place limitations on the usefulness of transforming plasmids to characterize cellular repair processes. In a second question, I characterize the composition of the replisome following arrest by UV-induced DNA damage. Using 2-D agarose gel analysis the structural changes that occur in DNA during processing and repair have been well characterized, however, little is known about the fate of the replisome itself during these events. I used thermosensitive replication mutants to compare the DNA structural intermediates induced after disruption of specific components of the replisome to those observed after UV damage. The results show that dissociation of subunits required for polymerase stabilization are sufficient to induce the same processing events observed after UV damage. By contrast, disruption of the helicase-primase complex induces abnormal structures and a loss of replication integrity, suggesting that these components remain intact and bound to the template following replication arrest. I propose that polymerase dissociation provides a mechanism that allows repair proteins to gain access to the lesion while retention of the helicase serves to maintain the integrity and licensing of the fork so that replication can resume from the appropriate site once the lesion has been processed

Inefficient Replication Reduces RecA-mediated Repair of UVdamaged Plasmids introduced into competent \u3ci\u3eEscherichia coli\u3c/i\u3e

Transformation of Escherichia coli with purified plasmids containing DNA damage is frequently used as a tool to characterize repair pathways that operate on chromosomes. In this study, we used an assay that allowed us to quantify plasmid survival and to compare how efficiently various repair pathways operate on plasmid DNA introduced into cells relative to their efficiency on chromosomal DNA. We observed distinct differences between the mechanisms operating on the transforming plasmid DNA and the chromosome. An average of one UV-induced lesion was sufficient to inactivate ColE1-based plasmids introduced into nucleotide excision repair mutants, suggesting an essential role for repair on newly introduced plasmid DNA. By contrast, the absence of RecA, RecF, RecBC, RecG, or RuvAB had a minimal effect on the survival of the transforming plasmid DNA containing UV-induced damage. Neither the presence of an endogenous homologous plasmid nor the induction of the SOS response enhanced the survival of transforming plasmids. Using two-dimensional agarose-gel analysis, both replication- and RecA-dependent structures that were observed on established, endogenous plasmids following UV-irradiation, failed to form on UV-irradiated plasmids introduced into E. coli. We interpret these observations to suggest that the lack of RecA-mediated survival is likely to be due to inefficient replication that occurs when plasmids are initially introduced into cells, rather than to the plasmid’s size, the absence of homologous sequences, or levels of recA expression

Prediction of Response to Neoadjuvant Chemotherapy Using Core Needle Biopsy Samples with the Prosigna Assay.

Most hormone receptor (HR)(+)/HER2(-) breast cancer patients respond unfavorably to neoadjuvant chemotherapy (NAC); however, genomic tests may identify those patients who are likely to benefit. Using the Prosigna assay, we first evaluated the technical performance of core needle biopsy (CNB) tissues. We then determined whether Prosigna risk of relapse (ROR) score and intrinsic subtype predicted response to NAC in HR(+)/HER2(-) patients using CNB samples. Using the NanoString's nCounter Dx analysis system and a development tissue sample set, we established tissue requirements and assay output variance. We then evaluated the concordance in subtype and correlation in ROR between CNBs and corresponding surgical resection specimens (SRS) in a second independent sample set. Finally, we analyzed 180 independent CNB samples from HR(+)/HER2(-) patients who were treated with NAC and correlated ROR and intrinsic subtype with pathologic response. Intra- and interbiopsy variabilities were 2.2 and 6.8 ROR units, respectively. Subtype concordance within multiple CNBs was high for the 4- and 3-subtype classifications (k = 0.885 and 0.889, respectively). Correlation in Prosigna ROR score observed between paired CNBs and SRS was high (r ≥ 0.90), and subtype concordance was also high for the 4- and 3-subtype classifications (kappa = 0.81 and 0.91, respectively). Prosigna results obtained from the HR(+)/HER2(-) patient samples showed that both ROR (P = 0.047) and intrinsic subtype (OR LumA vs. non-LumA = 0.341, P = 0.037) were significant predictors of response to NAC. Prosigna ROR and intrinsic subtype are readily obtained from CNB samples in normal practice and reliably predict response to NAC in HR(+)/HER2(-) patients