Tew has co-authored 2 books focusing on carcinogenesis and cancer treatment strategies. He co-wrote
Preclinical and Clinical Modulation of Anticancer Drugs with Peter J. Houghton and Janet A. Houghton, providing an analysis of theoretical and practical approaches to the design and implementation of modulation principles. His collaborative work with Gary D. Kruh,
Basic Science of Cancer, explored the advancements in cancer research, covering interrelated topics such as
tumor suppressor genes,
apoptosis,
transcriptional regulation, pharmacology of anticancer drugs,
cytogenetic techniques,
oncogenes, and
signal transductions. Tew co-edited books from the series
Advances in Cancer Research alongside Paul B. Fisher, where they provided reviews on diverse cancer research topics. In a review published in the
Journal of Medicinal Chemistry, Thomas J. Bardos wrote about the series, "This rapidly growing series of volumes containing many excellent, highly informative, in-depth reviews on a variety of timely topics relating to cancer research has always been most representative in the areas of tumor biology and immunology."
Drug development Tew's work on redox and pharmacogenetics focused on the discovery and development of drugs. Alongside colleagues, he introduced a novel zebrafish model with a glutathione S-transferase π1 (gstp1) knockout, revealing insights into redox homeostasis, reductive stress, and responses to drugs inducing endoplasmic reticulum stress and the unfolded protein response. His research has looked into the role of GTSP in cellular redox homeostasis and its over-expression in cancer drug resistance, particularly in the context of preclinical and clinical testing of the GSTP inhibitor TLK199 (Telintra) for treating myelodysplastic syndrome. He further revealed that the absence of microsomal glutathione transferase 1 (MGST1) impacts melanin biosynthesis and melanoma growth in mice and that, in numerous species, members of the GST family are involved in early hematopoiesis, and that the lack of GSTP in dendritic cells leads to increased proliferation, ROS levels and ERα levels, suggesting a role for GSTP in controlling ERα activity and dendritic cell function. Additionally, Tew and colleagues investigated how S-glutathionylation of the protein BiP, mediated by GSTP, contributes to acquired resistance to the multiple myeloma treatment bortezomib (Btz) by impacting BiP's foldase and ATPase activities. In another collaborative study published in
Scientific Reports, he found that S-glutathionylated serpins, specifically A1 and A3, are elevated in the blood of prostate cancer patients after radiation therapy, suggesting their potential as biomarkers for radiation exposure. He also explored melanoma cell lines resistant to reductive stress agents, showcasing changes in cell and mitochondrial morphology, metabolic preferences, and adaptive mechanisms in lethal reductive stress conditions.
Cancer treatment strategies Tew has studied cancer strategies to devise new treatments. In a joint research, he highlighted the significance of microsomal glutathione transferase 1 (MGST1) in melanin biosynthetic pathways, revealing its role as a determinant of tumor progression, with MGST1 knockdown leading to depigmentation, increased oxidative stress, and hindered tumor growth. He also determined that inhibiting microsomal glutathione S-transferase 1 (MGST1) in melanoma enhances oxidative stress, increases sensitivity to anticancer drugs, and reduces metastasis, improving the effectiveness of therapies. Tew examined ME-344, a second-generation isoflavone with anticancer properties in 2019, demonstrating its impact on redox homeostasis, mitochondrial function, and specific targeting of heme oxygenase 1 (HO-1) in lung cancer cells. In 2020, he determined that ME-344 targets VDAC1 and VDAC2 in lung cancer cells, leading to ROS generation, Bax translocation, cytochrome c release, and apoptosis, highlighting their potential as therapeutic targets. He also assessed how reactive oxygen species (ROS) play a dual role in cancer evolution, influencing both tumorigenesis and cell death, and highlighted tumor cell adaptations in metabolism and antioxidant defenses to manage ROS levels during different stages of cancer development. ==Awards and honors==