Structure-Activity Relationships Reveal Key Features of 8-Oxoguanine: A Mismatch Detection by the MutY Glycosylase.

Base excision repair glycosylases locate and remove damaged bases in DNA with remarkable specificity. The MutY glycosylases, unusual for their excision of undamaged adenines mispaired to the oxidized base 8-oxoguanine (OG), must recognize both bases of the mispair in order to prevent promutagenic activity. Moreover, MutY must effectively find OG:A mismatches within the context of highly abundant and structurally similar T:A base pairs. Very little is known about the factors that initiate MutY's interaction with the substrate when it first encounters an intrahelical OG:A mispair, or about the order of recognition checkpoints. Here, we used structure-activity relationships (SAR) to investigate the features that influence the in vitro measured parameters of mismatch affinity and adenine base excision efficiency by E. coli MutY. We also evaluated the impacts of the same substrate alterations on MutY-mediated repair in a cellular context. Our results show that MutY relies strongly on the presence of the OG base and recognizes multiple structural features at different stages of recognition and catalysis to ensure that only inappropriately mispaired adenines are excised. Notably, some OG modifications resulted in more dramatic reductions in cellular repair than in the in vitro kinetic parameters, indicating their importance for initial recognition events needed to locate the mismatch within DNA. Indeed, the initial encounter of MutY with its target base pair may rely on specific interactions with the 2-amino group of OG in the major groove, a feature that distinguishes OG:A from T:A base pairs. These results furthermore suggest that inefficient substrate location in human MutY homologue variants may prove predictive for the early onset colorectal cancer phenotype known as MUTYH-Associated Polyposis, or MAP.

CD63 is an essential cofactor to leukocyte recruitment by endothelial P-selectin.

The activation of endothelial cells is critical to initiating an inflammatory response. Activation induces the fusion of Weibel-Palade Bodies (WPB) with the plasma membrane, thus transferring P-selectin and VWF to the cell surface, where they act in the recruitment of leukocytes and platelets, respectively. CD63 has long been an established component of WPB, but the functional significance of its presence within an organelle that acts in inflammation and hemostasis was unknown. We find that ablating CD63 expression leads to a loss of P-selectin-dependent function: CD63-deficient HUVECs fail to recruit leukocytes, CD63-deficient mice exhibit a significant reduction in both leukocyte rolling and recruitment and we show a failure of leukocyte extravasation in a peritonitis model. Loss of CD63 has a similar phenotype to loss of P-selectin itself, thus CD63 is an essential cofactor to P-selectin.