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Item Augmented Concentration of Isopentyl-Deoxynyboquinone in Tumors Selectively Kills NAD(P)H Quinone Oxidoreductase 1-Positive Cancer Cells through Programmed Necrotic and Apoptotic Mechanisms(MDPI, 2023-12-14) Wang, Jiangwei; Su, Xiaolin; Jiang, Lingxiang; Boudreau, Matthew W.; Chatkewitz, Lindsay E.; Kilgore, Jessica A.; Zahid, Kashif Rafiq; Williams, Noelle S.; Chen, Yaomin; Liu, Shaohui; Hergenrother, Paul J.; Huang, Xiumei; Biochemistry and Molecular Biology, School of MedicineLung and breast cancers rank as two of the most common and lethal tumors, accounting for a substantial number of cancer-related deaths worldwide. While the past two decades have witnessed promising progress in tumor therapy, developing targeted tumor therapies continues to pose a significant challenge. NAD(P)H quinone oxidoreductase 1 (NQO1), a two-electron reductase, has been reported as a promising therapeutic target across various solid tumors. β-Lapachone (β-Lap) and deoxynyboquinone (DNQ) are two NQO1 bioactivatable drugs that have demonstrated potent antitumor effects. However, their curative efficacy has been constrained by adverse effects and moderate lethality. To enhance the curative potential of NQO1 bioactivatable drugs, we developed a novel DNQ derivative termed isopentyl-deoxynyboquinone (IP-DNQ). Our study revealed that IP-DNQ treatment significantly increased reactive oxygen species generation, leading to double-strand break (DSB) formation, PARP1 hyperactivation, and catastrophic energy loss. Notably, we discovered that this novel drug induced both apoptosis and programmed necrosis events, which makes it entirely distinct from other NQO1 bioactivatable drugs. Furthermore, IP-DNQ monotherapy demonstrated significant antitumor efficacy and extended mice survival in A549 orthotopic xenograft models. Lastly, we identified that in mice IP-DNQ levels were significantly elevated in the plasma and tumor compared with IB-DNQ levels. This study provides novel preclinical evidence supporting IP-DNQ efficacy in NQO1+ NSCLC and breast cancer cells.Item Inhibition of TXNRD or SOD1 overcomes NRF2-mediated resistance to β-lapachone(Elsevier, 2020-02) Torrente, Laura; Prieto-Farigua, Nicolas; Falzone, Aimee; Elkins, Cody M.; Boothman, David A.; Haura, Eric B.; DeNicola, Gina M.; Biochemistry and Molecular Biology, School of MedicineAlterations in the NRF2/KEAP1 pathway result in the constitutive activation of NRF2, leading to the aberrant induction of antioxidant and detoxification enzymes, including NQO1. The NQO1 bioactivatable agent β-lapachone can target cells with high NQO1 expression but relies in the generation of reactive oxygen species (ROS), which are actively scavenged in cells with NRF2/KEAP1 mutations. However, whether NRF2/KEAP1 mutations influence the response to β-lapachone treatment remains unknown. To address this question, we assessed the cytotoxicity of β-lapachone in a panel of NSCLC cell lines bearing either wild-type or mutant KEAP1. We found that, despite overexpression of NQO1, KEAP1 mutant cells were resistant to β-lapachone due to enhanced detoxification of ROS, which prevented DNA damage and cell death. To evaluate whether specific inhibition of the NRF2-regulated antioxidant enzymes could abrogate resistance to β-lapachone, we systematically inhibited the four major antioxidant cellular systems using genetic and/or pharmacologic approaches. We demonstrated that inhibition of the thioredoxin-dependent system or copper-zinc superoxide dismutase (SOD1) could abrogate NRF2-mediated resistance to β-lapachone, while depletion of catalase or glutathione was ineffective. Interestingly, inhibition of SOD1 selectively sensitized KEAP1 mutant cells to β-lapachone exposure. Our results suggest that NRF2/KEAP1 mutational status might serve as a predictive biomarker for response to NQO1-bioactivatable quinones in patients. Further, our results suggest SOD1 inhibition may have potential utility in combination with other ROS inducers in patients with KEAP1/NRF2 mutations.Item Interleukin-20 exacerbates acute hepatitis and bacterial infection by downregulating IκBζ target genes in hepatocytes(Elsevier, 2021) He, Yong; Feng, Dechun; Hwang, Seonghwan; Mackowiak, Bryan; Wang, Xiaolin; Xiang, Xiaogang; Rodrigues, Robim M.; Fu, Yaojie; Ma, Jing; Ren, Tianyi; Ait-Ahmed, Yeni; Xu, Mingjiang; Liangpunsakul, Suthat; Gao, Bin; Medicine, School of MedicineBackground & aims: Interleukin (IL)-20 and IL-22 belong to the IL-10 family. IL-10 is a well-documented anti-inflammatory cytokine while IL-22 is well known for epithelial protection and its antibacterial function, showing great therapeutic potential for organ damage; however, the function of IL-20 remains largely unknown. Methods: Il20 knockout (Il20-/-) mice and wild-type littermates were generated and injected with Concanavalin A (ConA) and Klebsiella pneumoniae (K.P.) to induce acute hepatitis and bacterial infection, respectively. Results: Il20-/- mice were resistant to acute hepatitis and exhibited selectively elevated levels of the hepatoprotective cytokine IL-6. Such selective inhibition of IL-6 by IL-20 was due to IL-20 targeting hepatocytes that produce high levels of IL-6 but a limited number of other cytokines. Mechanistically, IL-20 upregulated NAD(P)H: quinone oxidoreductase 1 (NQO1) expression and subsequently promoted the protein degradation of transcription factor IκBζ, resulting in selective downregulation of the IκBζ-dependent gene Il6 as well several other IκBζ-dependent genes including lipocalin-2 (Lcn2). Given the important role of IL-6 and LCN2 in limiting bacterial infection, we examined the effect of IL-20 on bacterial infection and found Il20-/- mice were resistant to K.P. infection and exhibited elevated levels of hepatic IκBζ-dependent antibacterial genes. Moreover, IL-20 upregulated hepatic NQO1 by binding to IL-22R1/IL-20R2 and activating ERK/p38MAPK/NRF2 signaling pathways. Finally, the levels of hepatic IL1B, IL20, and IκBζ target genes were elevated, and correlated with each other, in patients with severe alcoholic hepatitis. Conclusions: IL-20 selectively inhibits hepatic IL-6 production rather than exerting IL-10-like broad anti-inflammatory properties. Unlike IL-22, IL-20 aggravates acute hepatitis and bacterial infection. Thus, anti-IL-20 therapy could be a promising option to control acute hepatitis and bacterial infection. Lay summary: Several interleukin (IL)-20 family cytokines have been shown to play important roles in controllimg inflammatory responses, infection and tissue damage, but the role of IL-20 remains unclear. Herein, we elucidated the role of IL-20 in liver disease and bacterial infection. We show that IL-20 can aggravate hepatitis and bacterial infection; thus, targeting IL-20 holds promise for the treatment of patients with liver disease.Item Isopentyl-Deoxynboquinone Induces Mitochondrial Dysfunction and G2/M Phase Cell Cycle Arrest to Selectively Kill NQO1-Positive Pancreatic Cancer Cells(Mary Ann Liebert, Inc., 2024) Jiang, Lingxiang; Liu, Yingchun; Tumbath, Soumya; Boudreau, Matthew W.; Chatkewitz, Lindsay E.; Wang, Jiangwei; Su, Xiaolin; Zahid, Kashif Rafiq; Li, Katherine; Chen, Yaomin; Yang, Kai; Hergenrother, Paul J.; Huang, Xiumei; Radiation Oncology, School of MedicineAims: Pancreatic cancer is among the top five leading causes of cancer-related deaths worldwide, with poor overall survival rates. Current therapies for pancreatic cancer lack tumor specificity, resulting in harmful effects on normal tissues. Therefore, developing tumor-specific agents for the treatment of pancreatic cancer is critical. NAD(P)H:quinone oxidoreductase 1 (NQO1), highly expressed in pancreatic cancers but not in associated normal tissues, makes NQO1 bioactivatable drugs a potential therapy for selectively killing NQO1-positive cancer cells. Our previous studies have revealed that the novel NQO1 bioactivatable drug deoxynyboquinone (DNQ) is 10-fold more potent than the prototypic NQO1 bioactivatable drug β-lapachone in killing of NQO1-positive cancer cells. However, DNQ treatment results in high-grade methemoglobinemia, a significant side effect that limits clinical development. Results: Here, we report for the first time on a DNQ derivative, isopentyl-deoxynboquinone (IP-DNQ), which selectively kills pancreatic ductal adenocarcinoma (PDAC) cells in an NQO1-dependent manner with equal potency to the parent DNQ. IP-DNQ evokes massive reactive oxygen species (ROS) production and oxidative DNA lesions that result in poly(ADP-ribose)polymerase-1 (PARP1) hyperactivation, mitochondrial catastrophe, and G2/M phase cell cycle arrest, leading to apoptotic and necrotic programmed cell death. Importantly, IP-DNQ treatment causes only mild methemoglobinemia in vivo, with a threefold improvement in the maximum tolerated dose (MTD) compared with DNQ, while it significantly suppresses tumor growth and extends the life span of mice in subcutaneous and orthotopic pancreatic cancer xenograft models. Innovation and Conclusion: Our study demonstrates that IP-DNQ is a promising therapy for NQO1-positive pancreatic cancers and may enhance the efficacy of other anticancer drugs. IP-DNQ represents a novel approach to treating pancreatic cancer with the potential to improve patient outcomes.Item KP372-1-Induced AKT Hyperactivation Blocks DNA Repair to Synergize With PARP Inhibitor Rucaparib Inhibiting FOXO3a/GADD45α Pathway(Frontiers, 2022-09) Jiang, Lingxiang; Liu, Yingchun; Su, Xiaolin; Wang, Jiangwei; Zhao, Ye; Tumbath, Soumya; Kilgore, Jessica A.; Williams, Noelle S.; Chen, Yaomin; Wang, Xiaolei; Mendonca, Marc S.; Lu, Tao; Fu, Yang-Xin; Huang, Xiumei; Radiation Oncology, School of MedicinePoly (ADP-ribose) polymerase (PARP) inhibitors (PARPi) have exhibited great promise in the treatment of tumors with homologous recombination (HR) deficiency, however, PARPi resistance, which ultimately recovers DNA repair and cell progress, has become an enormous clinical challenge. Recently, KP372-1 was identified as a novel potential anticancer agent that targeted the redox enzyme, NAD(P)H:quinone oxidoreductase 1 (NQO1), to induce extensive reactive oxygen species (ROS) generation that amplified DNA damage, leading to cancer cell death. To overcome PARPi resistance and expand its therapeutic utility, we investigated whether a combination therapy of a sublethal dose of KP372-1 with a nontoxic dose of PARPi rucaparib would synergize and enhance lethality in over-expressing cancers. We reported that the combination treatment of KP372-1 and rucaparib induced a transient and dramatic AKT hyperactivation that inhibited DNA repair by regulating FOXO3a/GADD45α pathway, which enhanced PARPi lethality and overcame PARPi resistance. We further found that PARP inhibition blocked KP372-1-induced PARP1 hyperactivation to reverse NAD/ATP loss that promoted Ca-dependent autophagy and apoptosis. Moreover, pretreatment of cells with BAPTA-AM, a cytosolic Ca chelator, dramatically rescued KP372-1- or combination treatment-induced lethality and significantly suppressed PAR formation and γH2AX activation. Finally, we demonstrated that this combination therapy enhanced accumulation of both agents in mouse tumor tissues and synergistically suppressed tumor growth in orthotopic pancreatic and non-small-cell lung cancer xenograft models. Together, our study provides novel preclinical evidence for new combination therapy in solid tumors that may broaden the clinical utility of PARPi.Item NQO1-dependent, tumor-selective radiosensitization of non-small cell lung cancers(American Association for Cancer Research, 2019-04-15) Motea, Edward A.; Huang, Xiumei; Singh, Naveen; Kilgore, Jessica; Williams, Noelle; Xie, Xian-Jin; Gerber, David E.; Beg, Muhammad Shaalan; Bey, Erik A.; Boothman, David A.; Biochemistry and Molecular Biology, School of MedicinePurpose: Development of tumor-specific therapies for the treatment of recalcitrant non-small cell lung cancers (NSCLCs) are urgently needed. Here, we investigated the ability of ß-lapachone (ß-lap, ARQ761 in clinical form) to selectively potentiate the effects of ionizing radiation (IR, 1–3 Gy) in NSCLCs that over-express NAD(P)H:Quinone Oxidoreductase 1 (NQO1). Experimental Design: The mechanism of lethality of low dose IR in combination with sublethal doses of ß-lap were evaluated in NSCLC lines in vitro and validated in subcutaneous and orthotopic xenograph models in vivo. Pharmacokinetics and pharmacodynamics (PK/PD) studies comparing single versus co-treatments were performed to validate therapeutic efficacy and mechanism of action. Results: ß-Lap administration after IR treatment hyperactivated PARP, greatly lowered NAD+/ATP levels, and increased DSB lesions over time in vitro. Radiosensitization of orthotopic, as well as subcutaneous, NSCLCs occurred with high apparent cures (>70%), even though 1/8 ß-lap doses reach subcutaneous versus orthotopic tumors. No methemoglobinemia or long-term toxicities were noted in any normal tissues, including mouse liver that expresses the highest level of NQO1 (~12 Units) of any normal tissue. PK/PD responses confirm that IR + ß-lap treatments hyperactivate PARP activity, greatly lower NAD+/ATP levels and dramatically inhibit DSB repair in exposed NQO1+ cancer tissue, while low NQO1 levels and high levels of Catalase in associated normal tissue were protective. Conclusion: Our data suggest that combination of sublethal doses of ß-lap and IR is a viable approach to selectively treat NQO1-overexpressing NSCLC and warrant a clinical trial using low-dose IR + ß-lapachone against patients with NQO1+ NSCLCs.Item PCNA Inhibition Enhances the Cytotoxicity of β-Lapachone in NQO1-Positive Cancer Cells by Augmentation of Oxidative Stress-induced DNA Damage(Elsevier, 2021) Su, Xiaolin; Wang, Jiangwei; Jiang, Lingxiang; Chen, Yaomin; Lu, Tao; Mendonca, Marc S.; Huang, Xiumei; Biochemistry and Molecular Biology, School of Medicineβ-Lapachone is a classic quinone-containing antitumor NQO1-bioactivatable drug that directly kills NQO1-overexpressing cancer cells. However, the clinical applications of β-lapachone are primarily limited by its high toxicity and modest lethality. To overcome this side effect and expand the therapeutic utility of β-lapachone, we demonstrate the effects of a novel combination therapy including β-lapachone and the proliferating cell nuclear antigen (PCNA) inhibitor T2 amino alcohol (T2AA) on various NQO1+ cancer cells. PCNA has DNA clamp processivity activity mediated by encircling double-stranded DNA to recruit proteins involved in DNA replication and DNA repair. In this study, we found that compared to monotherapy, a nontoxic dose of the T2AA synergized with a sublethal dose of β-lapachone in an NQO1-dependent manner and that combination therapy prevented DNA repair, increased double-strand break (DSB) formation and PARP1 hyperactivation and induced catastrophic energy loss. We further determined that T2AA promoted programmed necrosis and G1/S phase cell cycle arrest in β-lapachone-treated NQO1+ cancer cells. Our findings show novel evidence for a new therapeutic approach that combines of β-lapachone treatment with PCNA inhibition that is highly effective in treating NQO1+ solid tumor cells.Item Targeting Base Excision Repair in Cancer: NQO1-Bioactivatable Drugs Improve Tumor Selectivity and Reduce Treatment Toxicity Through Radiosensitization of Human Cancer(Frontiers, 2020-08-19) Starcher, Colton L.; Pay, S. Louise; Singh, Naveen; Yeh, I.-Ju; Bhandare, Snehal B.; Su, Xiaolin; Huang, Xiumei; Bey, Erik A.; Motea, Edward A.; Boothman, David A.; Biochemistry and Molecular Biology, School of MedicineIonizing radiation (IR) creates lethal DNA damage that can effectively kill tumor cells. However, the high dose required for a therapeutic outcome also damages healthy tissue. Thus, a therapeutic strategy with predictive biomarkers to enhance the beneficial effects of IR allowing a dose reduction without losing efficacy is highly desirable. NAD(P)H:quinone oxidoreductase 1 (NQO1) is overexpressed in the majority of recalcitrant solid tumors in comparison with normal tissue. Studies have shown that NQO1 can bioactivate certain quinone molecules (e.g., ortho-naphthoquinone and β-lapachone) to induce a futile redox cycle leading to the formation of oxidative DNA damage, hyperactivation of poly(ADP-ribose) polymerase 1 (PARP1), and catastrophic depletion of NAD+ and ATP, which culminates in cellular lethality via NAD+-Keresis. However, NQO1-bioactivatable drugs induce methemoglobinemia and hemolytic anemia at high doses. To circumvent this, NQO1-bioactivatable agents have been shown to synergize with PARP1 inhibitors, pyrimidine radiosensitizers, and IR. This therapeutic strategy allows for a reduction in the dose of the combined agents to decrease unwanted side effects by increasing tumor selectivity. In this review, we discuss the mechanisms of radiosensitization between NQO1-bioactivatable drugs and IR with a focus on the involvement of base excision repair (BER). This combination therapeutic strategy presents a unique tumor-selective and minimally toxic approach for targeting solid tumors that overexpress NQO1.Item Therapeutic Strategies and Biomarkers to Modulate PARP Activity for Targeted Cancer Therapy(MDPI, 2020-04-14) Singh, Naveen; Pay, S. Louise; Bhandare, Snehal B.; Arimpur, Udhaya; Motea, Edward A.; Biochemistry and Molecular Biology, School of MedicinePoly-(ADP-ribose) polymerase 1 (PARP1) is commonly known for its vital role in DNA damage response and repair. However, its enzymatic activity has been linked to a plethora of physiological and pathophysiological transactions ranging from cellular proliferation, survival and death. For instance, malignancies with BRCA1/2 mutations heavily rely on PARP activity for survival. Thus, the use of PARP inhibitors is a well-established intervention in these types of tumors. However, recent studies indicate that the therapeutic potential of attenuating PARP1 activity in recalcitrant tumors, especially where PARP1 is aberrantly overexpressed and hyperactivated, may extend its therapeutic utility in wider cancer types beyond BRCA-deficiency. Here, we discuss treatment strategies to expand the tumor-selective therapeutic application of PARP inhibitors and novel approaches with predictive biomarkers to perturb NAD+ levels and hyperPARylation that inactivate PARP in recalcitrant tumors. We also provide an overview of genetic alterations that transform non-BRCA mutant cancers to a state of “BRCAness” as potential biomarkers for synthetic lethality with PARP inhibitors. Finally, we discuss a paradigm shift for the use of novel PARP inhibitors outside of cancer treatment, where it has the potential to rescue normal cells from severe oxidative damage during ischemia-reperfusion injury induced by surgery and radiotherapy.Item Therapeutic Strategies and Biomarkers to Modulate PARP Activity for Targeted Cancer Therapy(MDPI, 2020-04) Singh, Naveen; Pay, S. Louise; Bhandare, Snehal B.; Arimpur, Udhaya; Motea, Edward A.; Biochemistry and Molecular Biology, School of MedicinePoly-(ADP-ribose) polymerase 1 (PARP1) is commonly known for its vital role in DNA damage response and repair. However, its enzymatic activity has been linked to a plethora of physiological and pathophysiological transactions ranging from cellular proliferation, survival and death. For instance, malignancies with BRCA1/2 mutations heavily rely on PARP activity for survival. Thus, the use of PARP inhibitors is a well-established intervention in these types of tumors. However, recent studies indicate that the therapeutic potential of attenuating PARP1 activity in recalcitrant tumors, especially where PARP1 is aberrantly overexpressed and hyperactivated, may extend its therapeutic utility in wider cancer types beyond BRCA-deficiency. Here, we discuss treatment strategies to expand the tumor-selective therapeutic application of PARP inhibitors and novel approaches with predictive biomarkers to perturb NAD+ levels and hyperPARylation that inactivate PARP in recalcitrant tumors. We also provide an overview of genetic alterations that transform non-BRCA mutant cancers to a state of “BRCAness” as potential biomarkers for synthetic lethality with PARP inhibitors. Finally, we discuss a paradigm shift for the use of novel PARP inhibitors outside of cancer treatment, where it has the potential to rescue normal cells from severe oxidative damage during ischemia-reperfusion injury induced by surgery and radiotherapy.