Browsing by Subject "Transcription regulation"

Now showing 1 - 6 of 6
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    The butterfly effect in viral infection: From a host DNA single nucleotide change to HBV episome steadiness
    (Elsevier, 2019-02-10) Kim, Elena S.; Guo, Haitao; Microbiology and Immunology, School of Medicine
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    The curcumin analog HO-3867 selectively kills cancer cells by converting mutant p53 protein to transcriptionally active wildtype p53
    (American Society for Biochemistry and Molecular Biology, 2018-03-23) Madan, Esha; Parker, Taylor M.; Bauer, Matthias R.; Dhiman, Alisha; Pelham, Christopher J.; Nagane, Masaki; Kuppusamy, M. Lakshmi; Holmes, Matti; Holmes, Thomas R.; Shaik, Kranti; Shee, Kevin; Kiparoidze, Salome; Smith, Sean D.; Park, Yu-Soon A.; Gomm, Jennifer J.; Jones, Louise J.; Tomás, Ana R.; Cunha, Ana C.; Selvendiran, Karuppaiyah; Hansen, Laura A.; Fersht, Alan R.; Hideg, Kálmán; Gogna, Rajan; Kuppusamy, Periannan; Surgery, School of Medicine
    p53 is an important tumor-suppressor protein that is mutated in more than 50% of cancers. Strategies for restoring normal p53 function are complicated by the oncogenic properties of mutant p53 and have not met with clinical success. To counteract mutant p53 activity, a variety of drugs with the potential to reconvert mutant p53 to an active wildtype form have been developed. However, these drugs are associated with various negative effects such as cellular toxicity, nonspecific binding to other proteins, and inability to induce a wildtype p53 response in cancer tissue. Here, we report on the effects of a curcumin analog, HO-3867, on p53 activity in cancer cells from different origins. We found that HO-3867 covalently binds to mutant p53, initiates a wildtype p53-like anticancer genetic response, is exclusively cytotoxic toward cancer cells, and exhibits high anticancer efficacy in tumor models. In conclusion, HO-3867 is a p53 mutant-reactivating drug with high clinical anticancer potential.
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    An expanded role for Dipeptidyl peptidase 4 (DPP4) in cell regulation
    (Wolters Kluwer, 2020) Ropa, James; Broxmeyer, Hal E.; Microbiology and Immunology, School of Medicine
    Purpose of review: Dipeptidyl peptidase 4 (DPP4) is a serine protease with diverse regulatory functions in healthy and diseased cells. Much remains unknown about the mechanisms and targets of DPP4. Here we discuss new studies exploring DPP4-mediated cellular regulation, provide an updated list of potential targets of DPP4, and discuss clinical implications of each. Recent findings: Recent studies have sought enhanced efficacy of targeting DPP4's role in regulating hematopoietic stem and progenitor cells for improved clinical application. Further studies have identified DPP4 functions in different cellular compartments and have proposed ways to target this protein in malignancy. These findings, together with an expanded list of putative extracellular, cell surface, and intracellular DPP4 targets, provide insight into new DPP4-mediated cell regulation. Summary: DPP4 posttranslationally modifies proteins and peptides with essential roles in hematopoietic cell regulation, stem cell transplantation, and malignancy. Targets include secreted signaling factors and may include membrane proteins and transcription factors critical for different hematopoietic functions. Knowing these targets and functions can provide insight into new regulatory roles for DPP4 that may be targeted to enhance transplantation, treat disease, and better understand different regulatory pathways of hematopoiesis.
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    FASN regulates cellular response to genotoxic treatments by increasing PARP-1 expression and DNA repair activity via NF-κB and SP1
    (National Academy of Sciences, 2016-10-24) Wu, Xi; Dong, Zizheng; Wang, Chao J.; Barlow, Lincoln James; Fako, Valerie; Serrano, Moises A.; Zou, Yue; Liu, Jing-Yuan; Zhang, Jian-Ting; Department of Pharmacology and Toxicology, School of Medicine
    Fatty acid synthase (FASN), the sole cytosolic mammalian enzyme for de novo lipid synthesis, is crucial for cancer cell survival and associates with poor prognosis. FASN overexpression has been found to cause resistance to genotoxic insults. Here we tested the hypothesis that FASN regulates DNA repair to facilitate survival against genotoxic insults and found that FASN suppresses NF-κB but increases specificity protein 1 (SP1) expression. NF-κB and SP1 bind to a composite element in the poly(ADP-ribose) polymerase 1 (PARP-1) promoter in a mutually exclusive manner and regulate PARP-1 expression. Up-regulation of PARP-1 by FASN in turn increases Ku protein recruitment and DNA repair. Furthermore, lipid deprivation suppresses SP1 expression, which is able to be rescued by palmitate supplementation. However, lipid deprivation or palmitate supplementation has no effect on NF-κB expression. Thus, FASN may regulate NF-κB and SP1 expression using different mechanisms. Altogether, we conclude that FASN regulates cellular response against genotoxic insults by up-regulating PARP-1 and DNA repair via NF-κB and SP1.
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    STAT3 in the systemic inflammation of cancer cachexia
    (Elsevier, 2016-06) Zimmers, Teresa A.; Fishel, Melissa L.; Bonetto, Andrea; Surgery, School of Medicine
    Weight loss is diagnostic of cachexia, a debilitating syndrome contributing mightily to morbidity and mortality in cancer. Most research has probed mechanisms leading to muscle atrophy and adipose wasting in cachexia; however cachexia is a truly systemic phenomenon. Presence of the tumor elicits an inflammatory response and profound metabolic derangements involving not only muscle and fat, but also the hypothalamus, liver, heart, blood, spleen and likely other organs. This global response is orchestrated in part through circulating cytokines that rise in conditions of cachexia. Exogenous Interleukin-6 (IL6) and related cytokines can induce most cachexia symptomatology, including muscle and fat wasting, the acute phase response and anemia, while IL-6 inhibition reduces muscle loss in cancer. Although mechanistic studies are ongoing, certain of these cachexia phenotypes have been causally linked to the cytokine-activated transcription factor, STAT3, including skeletal muscle wasting, cardiac dysfunction and hypothalamic inflammation. Correlative studies implicate STAT3 in fat wasting and the acute phase response in cancer cachexia. Parallel data in non-cancer models and disease states suggest both pathological and protective functions for STAT3 in other organs during cachexia. STAT3 also contributes to cancer cachexia through enhancing tumorigenesis, metastasis and immune suppression, particularly in tumors associated with high prevalence of cachexia. This review examines the evidence linking STAT3 to multi-organ manifestations of cachexia and the potential and perils for targeting STAT3 to reduce cachexia and prolong survival in cancer patients.
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    Transcription factor old astrocyte specifically induced substance is a novel regulator of kidney fibrosis
    (Wiley, 2021) Yamamoto, Ayaha; Morioki, Hitomi; Nakae, Takafumi; Miyake, Yoshiaki; Harada, Takeo; Noda, Shunsuke; Mitsuoka, Sayuri; Matsumoto, Kotaro; Tomimatsu, Masashi; Kanemoto, Soshi; Tanaka, Shota; Maeda, Makiko; Conway, Simon J.; Imaizumi, Kazunori; Fujio, Yasushi; Obana, Masanori; Pediatrics, School of Medicine
    Prevention of kidney fibrosis is an essential requisite for effective therapy in preventing chronic kidney disease (CKD). Here, we identify Old astrocyte specifically induced substance (OASIS)/cAMP responsive element-binding protein 3-like 1 (CREB3l1), a CREB/ATF family transcription factor, as a candidate profibrotic gene that drives the final common pathological step along the fibrotic pathway in CKD. Although microarray data from diseased patient kidneys and fibrotic mouse model kidneys both exhibit OASIS/Creb3l1 upregulation, the pathophysiological roles of OASIS in CKD remains unknown. Immunohistochemistry revealed that OASIS protein was overexpressed in human fibrotic kidney compared with normal kidney. Moreover, OASIS was upregulated in murine fibrotic kidneys, following unilateral ureteral obstruction (UUO), resulting in an increase in the number of OASIS-expressing pathological myofibroblasts. In vitro assays revealed exogenous TGF-β1 increased OASIS expression coincident with fibroblast-to-myofibroblast transition and OASIS contributed to TGF-β1-mediated myofibroblast migration and increased proliferation. Significantly, in vivo kidney fibrosis induced via UUO or ischemia/reperfusion injury was ameliorated by systemic genetic knockout of OASIS, accompanied by reduced myofibroblast proliferation. Microarrays revealed that the transmembrane glycoprotein Bone marrow stromal antigen 2 (Bst2) expression was reduced in OASIS knockout myofibroblasts. Interestingly, a systemic anti-Bst2 blocking antibody approach attenuated kidney fibrosis in normal mice but not in OASIS knockout mice after UUO, signifying Bst2 functions downstream of OASIS. Finally, myofibroblast-restricted OASIS conditional knockouts resulted in resistance to kidney fibrosis. Taken together, OASIS in myofibroblasts promotes kidney fibrosis, at least in part, via increased Bst2 expression. Thus, we have identified and demonstrated that OASIS signaling is a novel regulator of kidney fibrosis.