Molecular Probing of the HPV-16 E6 Protein Alpha Helix Binding Groove with Small Molecule Inhibitors

The human papillomavirus (HPV) HPV E6 protein has emerged as a central oncoprotein in HPV-associated cancers in which sustained expression is required for tumor progression. A majority of the E6 protein interactions within the human proteome use an alpha-helix groove interface for binding. The UBE3A/E6AP HECT domain ubiquitin ligase binds E6 at this helix-groove interface. This enables formation of a trimeric complex with p53, resulting in destruction of this tumor suppressor. While recent x-ray crystal structures are useful, examples of small molecule probes that can modulate protein interactions at this interface are limited. To develop insights useful for potential structure-based design of ligands for HPV E6, a series of 2,6-disubstituted benzopyranones were prepared and tested as competitive antagonists of E6-E6AP helix-groove interactions. These small molecule probes were used in both binding and functional assays to evaluate recognition features of the E6 protein. Evidence for an ionic functional group interaction within the helix groove was implicated by the structure-activity among the highest affinity ligands. The molecular topographies of these protein-ligand interactions were evaluated by comparing the binding and activities of single amino acid E6 mutants with the results of molecular dynamic simulations. A group of arginine residues that form a rim-cap over the E6 helix groove offer compensatory roles in binding and recognition of the small molecule probes. The flexibility and impact on the overall helix-groove shape dictated by these residues offer new insights for structure-based targeting of HPV E6.     

Determination of platinum by neutron activation analysis in nerve tissue from rats treated with cisplatin

Biological Trace Element Research - The analytical method used for the determination of traces of platinum and gold in different tissues of Wistar rats is based on neutron activation analysis with...     

Salicylic acid antagonism of EDS1‐driven cell death is important for immune and oxidative stress responses in Arabidopsis

Reactive oxygen species (ROS) have emerged as signals in the responses of plants to stress. Arabidopsis Enhanced Disease Susceptibility1 (EDS1) regulates defense and cell death against biotrophic pathogens and controls cell death propagation in response to chloroplast‐derived ROS. Arabidopsis Nudix hydrolase7 (nudt7) mutants are sensitized to photo‐oxidative stress and display EDS1‐dependent enhanced resistance, salicylic acid (SA) accumulation and initiation of cell death. Here we explored the relationship between EDS1, EDS1‐regulated SA and ROS by examining gene expression profiles, photo‐oxidative stress and resistance phenotypes of nudt7 mutants in combination with eds1 and the SA‐biosynthetic mutant, sid2. We establish that EDS1 controls steps downstream of chloroplast‐derived O₂^?? that lead to SA‐assisted H₂O₂ accumulation as part of a mechanism limiting cell death. A combination of EDS1‐regulated SA‐antagonized and SA‐promoted processes is necessary for resistance to host‐adapted pathogens and for a balanced response to photo‐oxidative stress. In contrast to SA, the apoplastic ROS‐producing enzyme NADPH oxidase RbohD promotes initiation of cell death during photo‐oxidative stress. Thus, chloroplastic O₂^?? signals are processed by EDS1 to produce counter‐balancing activities of SA and RbohD in the control of cell death. Our data strengthen the idea that EDS1 responds to the status of O₂^?? or O₂^??‐generated molecules to coordinate cell death and defense outputs. This activity may enable the plant to respond flexibly to different biotic and abiotic stresses in the environment.     

Follistatin antagonizes transforming growth factor-beta3-induced epithelial-mesenchymal transition in vitro: implications for murine palatal development supported by microarray analysis

Abstract Epithelial–mesenchymal transition (EMT) is involved in normal embryonic development as well as in tumor progression and invasiveness. This process is also known to be a crucial step in palatogenesis during fusion of the bi-lateral palatal processes. Disruption of this step results in a cleft palate, which is among the most frequent birth defects in humans. A number of genes and encoded proteins have been shown to play a role in this developmental stage. The central role is attributed to the cytokine transforming growth factor-β3 (TGF-β3), which is expressed in the medial edge epithelium (MEE) already before the fusion process. The MEE covers the tips of the growing palatal shelves and eventually undergoes EMT or programmed cell death (apoptosis). TGF-β3 is described to induce EMT in embryonic palates. With regard to the early expression of this molecule before the fusion process, it is not well understood which mechanisms prevent the TGF-β3 producing epithelial cells from undergoing differentiation precociously. We used the murine palatal fusion to study the regulation of EMT. Specifically, we analyzed the MEE for the expression of known antagonists of TGF-β molecules using in situ hybridization and detected the gene coding for Follistatin to be co-expressed with TGF-β3. Further, we could show that Follistatin directly binds to TGF-β3 and that it completely blocks TGF-β3-induced EMT of the normal murine mammary gland (NMuMG) epithelial cell line in vitro . In addition, we analyzed the gene expression profile of NMuMG cells during TGF-β3-induced EMT by microarray hybridization, detecting strong changes in the expression of apoptosis-regulating genes.     

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