Nonmutational mechanisms were recently discovered leading to reversible drug tolerance. Despite the rapid elimination of a majority of tumor cells, a small subpopulation of "'drug-tolerant"' cells remain viable with lethal drug exposure, which may further lead to resistance or tumor relapse. Several signaling pathways are involved in the local or systemic inflammatory responses contributing to drug-induced phenotypic switch. Here, we report that Toll-like receptor 4 (TLR4)-interacting lipid docosahexaenoic acid (DHA) restores the cytotoxic effect of doxorubicin (DOX) in the lipopolysaccharide-treated breast tumor cell line 4T1, preventing the phenotypic switch to drug-tolerant cells, which significantly reduces primary tumor growth and lung metastasis in both 4T1 orthotopic and experimental metastasis models. Importantly, DHA in combination with DOX delays and inhibits tumor recurrence following surgical removal of the primary tumor. Furthermore, the coencapsulation of DHA and DOX in a nanoemulsion significantly prolongs the survival of mice in the postsurgical 4T1 tumor relapse model with significantly reduced systemic toxicity. The synergistic antitumor, antimetastasis, and antirecurrence effects of DHA + DOX combination are likely mediated by attenuating TLR4 activation, thus sensitizing tumor cells to standard chemotherapy.
© 2022 The Authors. Published by American Chemical Society.

h4>Background: /h4> Non-mutational mechanisms were recently discovered leading to reversible drug tolerance. Despite the rapid elimination of majority tumor cells, a small sub-population of ‘‘drug-tolerant’’ cells remain viable with lethal drug exposure, which may further lead to resistance or tumor relapse. Several signaling pathways are involved in the local or systemic inflammatory responses contributing to drug-induced phenotypic switch. h4>Results: /h4>: In this study, we report Toll like receptor 4 (TLR4)-interacting lipid docosahexaenoic acid (DHA) restores the cytotoxic effect of doxorubicin (DOX) in the lipopolysaccharide-treated breast tumor cell line 4T1, preventing the phenotypic switch to drug-tolerant cells, which significantly reduces primary tumor growth and lung metastasis in both 4T1 orthotopic and experimental metastasis models. Importantly, DHA in combination with DOX delays and inhibits tumor recurrence following surgical removal of the primary tumor. Furthermore, coencapsulation of DHA and DOX in a nanoemulsion significantly prolongs the survival of mice in the postsurgical 4T1 tumor relapse model with significantly reduced systemic toxicity. h4>Conclusions: /h4>: The synergistic antitumor, anti-metastasis and anti-recurrence effects of DHA plus DOX combination is likely mediated by attenuating TLR4 activation thus sensitizing tumor cells to standard chemotherapy.

Notch signaling primarily determines T-cell fate. However, the molecular mechanisms underlying the maintenance of T-lineage potential in pre-thymic progenitors remain unclear. Here, we established two murine Ebf1-deficient pro-B cell lines, with and without T-lineage potential. The latter expressed lower levels of Lmo2; their potential was restored via ectopic expression of Lmo2. Conversely, the CRISPR/Cas9-mediated deletion of Lmo2 resulted in the loss of the T-lineage potential. Introduction of Bcl2 rescued massive cell death of Notch-stimulated pro-B cells without efficient LMO2-driven Bcl11a expression but was not sufficient to retain their T-lineage potential. Pro-B cells without T-lineage potential failed to activate Tcf7 due to DNA methylation; Tcf7 transduction restored this capacity. Moreover, direct binding of LMO2 to the Bcl11a and Tcf7 loci was observed. Altogether, our results highlight LMO2 as a crucial player in the survival and maintenance of T-lineage potential in T-cell progenitors via the regulation of the expression of Bcl11a and Tcf7.
© 2021, Hirano et al.

Inappropriate functioning of the immune system is observed during sustained systemic inflammation, which might lead to immune deficiencies, autoimmune disorders and cancer. Primary lymphoid organs may progress to a deregulated proliferative state in response to inflammatory signals in order to intensify host defense mechanisms and exacerbate an inflammatory niche. Fluoxetine, a selective serotonin reuptake inhibitor, has recently been projected as an anti-inflammatory agent. This study had been designed to evaluate the potential novel role of fluoxetine in reversing inflammation-induced immune dysfunction. Lipopolysaccharide (LPS) administration in Swiss albino mice potentiated a systemic inflammatory response, along with increased proliferation of thymocytes and peripheral blood mononuclear cells, as evident from increased Ki-67 expression. The proliferative changes in the immune system were mainly associated with increased phosphorylation of PI3k, AKT and IκB along with elevated NFκB-p65 nuclear translocation. The Ki-67high thymocytes obtained from LPS administered mice demonstrated significantly low p53 nuclear activity, which was established to be mediated by NFκB through reduced nuclear translocation of p53 during LPS-induced proliferative conditions, thereby blocking p53-dependent apoptosis. Fluoxetine supplementation not only reversed the proinflammatory condition, but also induced selective apoptosis in the proliferation-dictated Ki-67high thymocytes possibly by modulating the hypothalamus-pituitary-adrenal axis and inducing glucocorticoid receptor activation and apoptosis in these proliferation-biased immune cells, authenticating a novel antiproliferative role of an established drug.
© 2018 Australasian Society for Immunology Inc.

Both anti-PD1/PD-L1 therapy and oncolytic virotherapy have demonstrated promise, yet have exhibited efficacy in only a small fraction of cancer patients. Here we hypothesized that an oncolytic poxvirus would attract T cells into the tumour, and induce PD-L1 expression in cancer and immune cells, leading to more susceptible targets for anti-PD-L1 immunotherapy. Our results demonstrate in colon and ovarian cancer models that an oncolytic vaccinia virus attracts effector T cells and induces PD-L1 expression on both cancer and immune cells in the tumour. The dual therapy reduces PD-L1+ cells and facilitates non-redundant tumour infiltration of effector CD8+, CD4+ T cells, with increased IFN-γ, ICOS, granzyme B and perforin expression. Furthermore, the treatment reduces the virus-induced PD-L1+ DC, MDSC, TAM and Treg, as well as co-inhibitory molecules-double-positive, severely exhausted PD-1+CD8+ T cells, leading to reduced tumour burden and improved survival. This combinatorial therapy may be applicable to a much wider population of cancer patients.