Erxi Wu Ph.D.

Qin, T., Chen, K., Li, J., Qian, W., Xiao, Y., Wu, E., Ma, J., Chen, Z., Wang, Z., Ma, Q. and Wu, Z. (2022). “Heat shock factor 1 inhibition sensitizes pancreatic cancer to gemcitabine via the suppression of cancer stem cell-like properties.” Biomed Pharmacother 148: 112713.

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Pancreatic cancer is a fatal disease with poor prognosis. Gemcitabine has been regarded as the mainstay of chemotherapy for pancreatic cancer; however, it is accompanied with a high rate of chemoresistance. Cancer stem cells (CSCs) are characterized by resistance to traditional chemo- and radiotherapies. We have previously reported that heat shock factor 1 (HSF1) is involved in the invasion and metastasis of pancreatic cancer, a highly conserved transcriptional factor that mediates the canonical proteotoxic stress response. Here, we investigate whether HSF1 contributes to the chemoresistance of pancreatic cancer cells caused by gemcitabine and explore the underlying mechanisms. Genetically engineered mice (LSL-Kras(G12D/+); Trp53(fl/+); Pdx1-Cre mice), which spontaneously develop pancreatic cancer, were used to examine the sensitivity of pancreatic cancer to gemcitabine in vivo. We found that HSF1 was enriched in sphere-forming cancer cells. Panc-1 and MiaPaCa-2 cells treated chronically with gemcitabine displayed increased transcription and expression of CSC-associated markers. In addition, gemcitabine-surviving Panc-1 and MiaPaCa-2 cells showed an increased ability to form tumorspheres. Moreover, we observed that gemcitabine treatment increased the activity and expression of HSF1, as well as transcription of its downstream targets. Finally, HSF1 inhibition significantly suppressed the expression of CSC-associated markers, augmented the cancer-killing property of gemcitabine, and increased chemosensitivity to gemcitabine in vivo. Our study reveals a novel mechanism in which HSF1 promotes the chemoresistance of pancreatic cancer to gemcitabine by modulating CSC-like properties. Targeting HSF1 could be thus a rational strategy to improve treatment outcomes.

Chen, X., Sheng, L., Ma, J., Qi, D., Li, X., Wang, Z., Wu, Z., Wong, L., Huang, J. H., Wu, E., Ma, Q. and Zhang, D. (2022). “4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone provokes progression from chronic pancreatitis to pancreatic intraepithelial neoplasia.” iScience 25(1): 103647.

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The risk of pancreatic cancer is higher among people who are cigarette smokers than among non-smokers; however, the action mechanisms of cigarette metabolites are not yet fully understood. In this study, we investigated the effect of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) in cigarette smoking on chronic pancreatitis and pancreatic cancer as well as the biological mechanism of NNK causing malignant transformation. We show that smoking may promote Kras mutation and P16 promoter methylation from clinical samples and NNK markedly facilitates the growth and migration of pancreatic cancer cells via the activation of Sonic Hedgehog signaling. We demonstrate that NNK promotes acinar-to-ductal metastasis and pancreatic intraepithelial neoplasia in rats with chronic pancreatitis, accompanied by desmoplastic reaction and Gli1 overexpression. Together, we here present evidence that NNK provokes the progression of chronic pancreatitis toward pancreatic cancer and highlight potential strategies and targets for early prevention of pancreatic cancer and its therapeutics.

Qi, D., Liu, Y., Li, J., Huang, J.H., Hu, X. and Wu, E. (2021). “Salinomycin as a potent anticancer stem cell agent: State of the art and future directions.” Med Res Rev Nov 16. [Epub ahead of print].

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Cancer stem cells (CSCs) are a small subpopulation of cells within a tumor that can both self-renew and differentiate into other cell types forming the heterogeneous tumor bulk. Since CSCs are involved in all aspects of cancer development, including tumor initiation, cell proliferation, metastatic dissemination, therapy resistance, and recurrence, they have emerged as attractive targets for cancer treatment and management. Salinomycin, a widely used antibiotic in poultry farming, was identified by the Weinberg group as a potent anti-CSC agent in 2009. As a polyether ionophore, salinomycin exerts broad-spectrum activities, including the important anti-CSC function. Studies on the mechanism of action of salinomycin against cancer have been continuously and rapidly published since then. Thus, it is imperative for us to update its literature of recent research findings in this area. We here summarize the notable work reported on salinomycin’s anticancer activities, intracellular binding target(s), effects on tumor microenvironment, safety, derivatives, and tumor-specific drug delivery; after that we also discuss the translational potential of salinomycin toward clinical application based on current multifaceted understandings.

Li, J., Qi, D., Hsieh, T.C., Huang, J.H., Wu, J.M. and Wu, E. (2021). “Trailblazing perspectives on targeting breast cancer stem cells.” Pharmacol Ther 223: 107800.

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Breast cancer (BCa) is one of the most prevalent malignant tumors affecting women’s health worldwide. The recurrence and metastasis of BCa have made it a long-standing challenge to achieve remission-persistent or disease-undetectable clinical outcomes. Cancer stem cells (CSCs) possess the ability to self-renew and generate heterogeneous tumor bulk. The existence of CSCs has been found to be vital in the initiation, metastasis, therapy resistance, and recurrence of tumors across cancer types. Because CSCs grow slowly in their dormant state, they are insensitive to conventional chemotherapies; however, when CSCs emerge from their dormant state and become clinically evident, they usually acquire genetic traits that make them resistant to existing therapies. Moreover, CSCs also show evidence of acquired drug resistance in synchrony with tumor relapses. The concept of CSCs provides a new treatment strategy for BCa. In this review, we highlight the recent advances in research on breast CSCs and their association with epithelial-mesenchymal transition (EMT), circulating tumor cells (CTCs), plasticity of tumor cells, tumor microenvironment (TME), T-cell modulatory protein PD-L1, and non-coding RNAs. On the basis that CSCs are associated with multiple dysregulated biological processes, we envisage that increased understanding of disease sub-classification, selected combination of conventional treatment, molecular aberration directed therapy, immunotherapy, and CSC targeting/sensitizing strategy might improve the treatment outcome of patients with advanced BCa. We also discuss novel perspectives on new drugs and therapeutics purposing the potent and selective expunging of CSCs.

Pu, Q., Lin, P., Gao, P., Wang, Z., Guo, K., Qin, S., Zhou, C., Wang, B., Wu, E., Khan, N., Xia, Z., Wei, X. and Wu, M. (2021). “Gut Microbiota Regulate Gut-Lung Axis Inflammatory Responses by Mediating ILC2 Compartmental Migration.” J Immunol Jun 16;ji2001304. [Epub ahead of print].

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Gut microbiota is increasingly linked to the development of various pulmonary diseases through a gut-lung axis. However, the mechanisms by which gut commensal microbes impact trafficking and functional transition of immune cells remain largely unknown. Using integrated microbiota dysbiosis approaches, we uncover that the gut microbiota directs the migration of group 2 innate lymphoid cells (ILC2s) from the gut to the lung through a gut-lung axis. We identify Proteobacteria as a critical species in the gut microbiome to facilitate natural ILC2 migration, and increased Proteobacteria induces IL-33 production. Mechanistically, IL-33-CXCL16 signaling promotes the natural ILC2 accumulation in the lung, whereas IL-25-CCL25 signals augment inflammatory ILC2 accumulation in the intestines upon abdominal infection, parabiosis, and cecum ligation and puncture in mice. We reveal that these two types of ILC2s play critical but distinct roles in regulating inflammation, leading to balanced host defense against infection. Overall results delineate that Proteobacteria in gut microbiota modulates ILC2 directional migration to the lung for host defense via regulation of select cytokines (IL-33), suggesting novel therapeutic strategies to control infectious diseases.