Browsing by Author "VanderVere-Carozza, Pamela"
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Item Design and Structure-Guided Development of Novel Inhibitors of the Xeroderma Pigmentosum Group A (XPA) Protein–DNA Interaction(ACS Publications, 2017-09-21) Gavande, Navnath S.; VanderVere-Carozza, Pamela; Mishra, Akaash K.; Vernon, Tyler L.; Pawelczak, Katherine S.; Turchi, John J.; Biochemistry and Molecular Biology, School of MedicineXPA is a unique and essential protein required for the nucleotide excision DNA repair pathway and represents a therapeutic target in oncology. Herein, we are the first to develop novel inhibitors of the XPA–DNA interaction through structure-guided drug design efforts. Ester derivatives of the compounds 1 (X80), 22, and 24 displayed excellent inhibitory activity (IC50 of 0.82 ± 0.18 μM and 1.3 ± 0.22 μM, respectively) but poor solubility. We have synthesized novel amide derivatives that retain potency and have much improved solubility. Furthermore, compound 1 analogs exhibited good specificity for XPA over RPA (replication protein A), another DNA-binding protein that participates in the nucleotide excision repair (NER) pathway. Importantly, there were no significant interactions observed by the X80 class of compounds directly with DNA. Molecular docking studies revealed a mechanistic model for the interaction, and these studies could serve as the basis for continued analysis of structure–activity relationships and drug development efforts of this novel target.Item The novel, small-molecule DNA methylation inhibitor SGI-110 as an ovarian cancer chemosensitizer(American Association for Cancer Research, 2014-12-15) Fang, Fang; Munck, Joanne; Tang, Jessica; Taverna, Pietro; Wang, Yinu; Miller, David F. B.; Pilrose, Jay; Choy, Gavin; Azab, Mohammad; Pawelczak, Katherine S.; VanderVere-Carozza, Pamela; Wagner, Michael; Lyons, John; Matei, Daniela; Turchi, John J.; Nephew, Kenneth P.; Department of Medicine, IU School of MedicinePURPOSE: To investigate SGI-110 as a "chemosensitizer" in ovarian cancer and to assess its effects on tumor suppressor genes (TSG) and chemoresponsiveness-associated genes silenced by DNA methylation in ovarian cancer. EXPERIMENTAL DESIGN: Several ovarian cancer cell lines were used for in vitro and in vivo platinum resensitization studies. Changes in DNA methylation and expression levels of TSG and other cancer-related genes in response to SGI-110 were measured by pyrosequencing and RT-PCR. RESULTS: We demonstrate in vitro that SGI-110 resensitized a range of platinum-resistant ovarian cancer cells to cisplatin (CDDP) and induced significant demethylation and reexpression of TSG, differentiation-associated genes, and putative drivers of ovarian cancer cisplatin resistance. In vivo, SGI-110 alone or in combination with CDDP was well tolerated and induced antitumor effects in ovarian cancer xenografts. Pyrosequencing analyses confirmed that SGI-110 caused both global (LINE1) and gene-specific hypomethylation in vivo, including TSGs (RASSF1A), proposed drivers of ovarian cancer cisplatin resistance (MLH1 and ZIC1), differentiation-associated genes (HOXA10 and HOXA11), and transcription factors (STAT5B). Furthermore, DNA damage induced by CDDP in ovarian cancer cells was increased by SGI-110, as measured by inductively coupled plasma-mass spectrometry analysis of DNA adduct formation and repair of cisplatin-induced DNA damage. CONCLUSIONS: These results strongly support further investigation of hypomethylating strategies in platinum-resistant ovarian cancer. Specifically, SGI-110 in combination with conventional and/or targeted therapeutics warrants further development in this setting.Item Testing the metal of ERCC2 in predicting the response to platinum-based therapy(American Association for Cancer Research, 2014-10) Turchi, John J.; Woods, Derek S.; VanderVere-Carozza, Pamela; Department of Medicine, IU School of MedicineDNA repair has been shown to affect the cellular response to platinum-based therapy in a variety of cancers; however, translating this knowledge to the clinic has proven difficult and yielded mixed results. In this issue of Cancer Discovery, Van Allen and colleagues have analyzed responders and nonresponders to neoadjuvant platinum-based therapy with locally advanced urothelial cancer and identified a series of mutations in the nucleotide excision repair (NER) gene ERCC2 that correlate with the response to platinum-based therapy. This work provides evidence that defects in NER can be exploited to maximize the efficacy of conventional platinum-based chemotherapy.Item Unraveling the Complexities of DNA-Dependent Protein Kinase Autophosphorylation(American Society for Microbiology (ASM), 2014-06) Neal, Jessica A.; Sugiman-Marangos, Seiji; VanderVere-Carozza, Pamela; Wagner, Mike; Turchi, John; Lees-Miller, Susan P.; Junop, Murray S.; Meek, Katheryn; Department of Medicine, IU School of MedicineDNA-dependent protein kinase (DNA-PK) orchestrates DNA repair by regulating access to breaks through autophosphorylations within two clusters of sites (ABCDE and PQR). Blocking ABCDE phosphorylation (by alanine mutation) imparts a dominant negative effect, rendering cells hypersensitive to agents that cause DNA double-strand breaks. Here, a mutational approach is used to address the mechanistic basis of this dominant negative effect. Blocking ABCDE phosphorylation hypersensitizes cells to most types of DNA damage (base damage, cross-links, breaks, and damage induced by replication stress), suggesting that DNA-PK binds DNA ends that result from many DNA lesions and that blocking ABCDE phosphorylation sequesters these DNA ends from other repair pathways. This dominant negative effect requires DNA-PK's catalytic activity, as well as phosphorylation of multiple (non-ABCDE) DNA-PK catalytic subunit (DNA-PKcs) sites. PSIPRED analysis indicates that the ABCDE sites are located in the only contiguous extended region of this huge protein that is predicted to be disordered, suggesting a regulatory role(s) and perhaps explaining the large impact ABCDE phosphorylation has on the enzyme's function. Moreover, additional sites in this disordered region contribute to the ABCDE cluster. These data, coupled with recent structural data, suggest a model whereby early phosphorylations promote initiation of nonhomologous end joining (NHEJ), whereas ABCDE phosphorylations, potentially located in a “hinge” region between the two domains, lead to regulated conformational changes that initially promote NHEJ and eventually disengage NHEJ.