Triple Negative Breast Cancer (TNBC), the most aggressive subtype of breast cancer, is characterized by the absence of hormone receptors usually targeted by hormone therapies like Tamoxifen. Because therapy success and survival rates for TNBC lag far behind other breast cancer subtypes, there is significant interest in developing novel anti-TNBC agents that can target TNBC specifically, with minimal effects on non-malignant tissue. To this aim, our study describes the anti-TNBC effect of strictinin, an ellagitanin previously isolated from Myrothamnus flabellifolius . Using various in silico and molecular techniques, we characterized the mechanism of action of strictinin in TNBC. Our results suggest strictinin interacts strongly with Receptor Tyrosine Kinase Orphan like 1 (ROR1). ROR1 is an oncofetal receptor highly expressed during development but not in normal adult tissue. It is highly expressed in several human malignancies however, owing to its numerous pro-tumor functions. Via its interaction and inhibition of ROR1, strictinin reduced AKT phosphorylation on ser-473, inhibiting downstream phosphorylation and inhibition of GSK3β. The reduction in AKT phosphorylation also correlated with decreased cell survival and activation of the caspase-mediated intrinsic apoptotic cascade. Strictinin treatment also repressed cell migration and invasion in a beta-catenin independent manner, presumably via the reactivated GSK3ß’s repressing effect on microtubule polymerization and focal adhesion turnover. This could be of potential therapeutic interest considering heightened interest in ROR1 and other receptor tyrosine kinases as targets for development of anti-cancer agents. Further studies are needed to validate these findings in other ROR1-expressing malignancies but also in more systemic models of TNBC. Our findings do however underline the potential of strictinin and other ROR1-targeting agents as therapeutic tools to reduce TNBC proliferation, survival and motility.
Triple Negative Breast Cancer (TNBC) is the most lethal subtype of breast cancer. Despite the successes of emerging targeted therapies, relapse, recurrence, and therapy failure rates in TNBC significantly outpace other subtypes of breast cancer. Mounting evidence suggests accumulation of therapy resistant Cancer Stem Cell (CSC) populations within TNBCs contributes to poor clinical outcomes. These CSCs are enriched in TNBC compared to non-TNBC breast cancers. The mechanisms underlying CSC accumulation have been well-characterized and discussed in other reviews. In this review, we focus on TNBC-specific mechanisms that allow the expansion and activity of self-renewing CSCs. We highlight cellular signaling pathways and transcription factors, specifically enriched in TNBC over non-TNBC breast cancer, contributing to stemness. We also analyze publicly available singlecell RNA-seq data from basal breast cancer tumors to highlight the potential of emerging bioinformatic approaches in identifying novel drivers of stemness in TNBC and other cancers.
Chemoresistance is one of the leading causes of mortality in breast cancer (BC). Understanding the molecules regulating chemoresistance is critical in order to combat chemoresistant BC. Drug efflux pump ABCB1 is overexpressed in chemoresistant neoplasms where it effluxes various chemotherapeutic agents from cells. Because it is expressed in normal and cancerous cells alike, attempts at targeting ABCB1 directly have failed due to low specificity and disruption of normal tissue. A proposed method to inhibit ABCB1 is to target its cancer-specific, upstream regulators, mitigating damage to normal tissue. Few such cancer-specific upstream regulators have been described. Here we characterize ROR1 as an upstream regulator of ABCB1. ROR1 is highly expressed during development but not expressed in normal adult tissue. It is however highly expressed in several cancers. ROR1 is overexpressed in chemoresistant BC where it correlates with poor therapy response and tumor recurrence. Our data suggests, ROR1 inhibition sensitizes BC cells to chemo drugs. We also show ROR1 regulates ABCB1 stability and transcription via MAPK/ERK and p53. Validating our overall findings, inhibition of ROR1 directly correlated with decreased efflux of chemo-drugs from cells. Overall, our results highlight ROR1's potential as a therapeutic target for multidrug resistant malignancies. ROR1 knockdown potentiates DNA damage induced by chemo drugs.A mechanism of action common to both Pt-based and anthracycline chemotherapeutic agents is induction of DNA double stranded breaks leading to cell death 19 . We thus sought to investigate if ROR1 inhibition would promote chemo-induced DNA double strand breaks. We treated cells transfected with either ROR1 siRNA or control RNA, with Doxorubicin or Cisplatin, and monitored γH2a.x, a marker for DNA double strand breaks via immunofluorescence ( Fig. 3A, Supplementary Fig. 2). We observed potentiation of DNA double strand breaks induced by both drugs in cells where ROR1 was knocked down. γH2a.x foci counts were higher in the siROR1+ (Dox or Cis) groups compared to the siROR1-only and drug-only treatment groups (Fig. 3B). We similarly observed an increase in γH2a.x expression (mean fluorescence intensity) in Cis/Dox treated cells after ROR1 knockdown compared to the control group (Fig. 3C). Altogether, these data suggest ROR1 inhibition promotes chemo drug-induced DNA damage. Scientific RepoRtS |(2020) 10:1821 | https://doi.
Myeloid-derived Suppressor Cells (MDSCs) are a sub-population of leukocytes that are important for carcinogenesis and cancer immunotherapy. During carcinogenesis or severe infections, inflammatory mediators induce MDSCs via aberrant differentiation of myeloid precursors. Although several transcription factors, including C/EBPβ, STAT3, c-Rel, STAT5, and IRF8, have been reported to regulate MDSC differentiation, none of them are specifically expressed in MDSCs. How these lineage-non-specific transcription factors specify MDSC differentiation in a lineage-specific manner is unclear. The recent discovery of the c-Rel−C/EBPβ enhanceosome in MDSCs may help explain these context-dependent roles. In this review, we examine several transcriptional regulators of MDSC differentiation, and discuss the concept of non-modular regulation of MDSC signature gene expression by transcription factors such as c-Rel and C/EBPß.
Neuroblastoma is the most common inheritable, solid neoplasm in children found under the age of 7 and accounts for approximately 7% of childhood cancers. A common treatment that has been prescribed for over a decade is retinoid therapy [using all-trans retinoic acid (RA)]. Treatment with this differentiating agent has been revealed to progress the cells from their stem-cell state to a mature neuronal state gaining classical neuronal characteristics, including the suppression of proliferation. However, the molecular mechanism underlying the action of RA treatment remains to be elucidated. In the present study, a novel mechanism of RA-induced differentiation via regulation of receptor tyrosine kinase-like orphan receptor 1 (ROR1) is reported. ROR1 is overexpressed in neuroblastoma but significantly downregulated in mature differentiated neurons. Hence, it was hypothesized that RA may modulate ROR1 leading to differentiation and termination of cancerous properties. Immunoblotting revealed that following RA treatment, ROR1 levels initially increased then sharply decreased by 96 h. This was paired with synaptophysin, a mature neuron marker, sharply increasing concurrently, providing evidence of differentiation by 96 h. Investigation of the ROR1 pathway confirmed ROR1-dependent downstream activation of the PI3K/AKT signaling axis, a growth pathway previously demonstrated to promote differentiation. Chromatin immunoprecipitation revealed an increase in RAR binding to the promoters of ROR1 and its endogenous ligand, Wnt5a. This research provided compelling evidence that RA is able to modulate the expression of ROR1 and Wnt5a to promote differentiation through the expression of synaptophysin. This data combined with the overarching data from the scientific community regarding proliferation and other proliferative factors in early-stage neurons provides a more in-depth model of the process of differentiation in neurons.
Triple negative breast cancer (TNBC) is a disease that impacts millions of people around the world.There is an urgent need to find new therapies, specific to triple negative cancer cells with minimal effect on normal cells. This study explores the use of Myrothamnus flabellifolius as an anti-TNBC. Using High Performance Liquid Chromatography, the extract was fractionated and each fraction was tested against TNBC cells BT-549 and MDA-MB-231, and a non-malignant breast cell line MCF-10A. The results showed that fraction 7 inhibited the growth of TNBC cells starting at a dry weight concentration of 31.125 μg/mL while there was no significant cell death of the MCF-10A cell line. Using analytical techniques such as Mass Spectrometry (MS-MS) and Nuclear Magnetic Resonance (NMR), the major compound in fraction 7 was determined to be a derivative of galloyl glucose hexahydroxydiphenic acid. The results suggest that this novel compound is the primary anti-TNBC compound in M. flabellifolius and might be a potential candidate for targeted TNBC therapy.
MCL1 is a member of the anti-apoptotic BCL2 family of proteins and plays a critical role in maintaining cellular homeostasis and promoting cell survival. MCL1 amplifications occur frequently in multiple tumor types. It has also been implicated in mediating resistance to chemotherapeutic agents and targeted therapies. We have previously described a novel, potent and orally bioavailable MCL1 inhibitor, PRT1419, that demonstrates anti-tumor efficacy in various preclinical models of cancer and is currently under evaluation in a Phase I clinical trial in patients with relapsed/refractory hematologic malignancies and advanced solid tumors. In an effort to identify novel biomarkers that might predict sensitivity to MCL1 inhibition, we conducted a gene dependency analysis using publicly available human cancer cell line data generated from genome-wide CRISPR/Cas9-mediated cell viability screens. We observed that mutations in the SWI/SNF complex, particularly in lung and ovarian cancer cell lines, conferred a strong functional dependency on MCL1. The mammalian SWI/SNF complex functions as a tumor suppressor in a number of cancers and regulates gene expression via chromatin-remodeling. It is comprised of multiple subunits, including one of two catalytic ATPases (SMARCA2 or SMARAC4), DNA-binding proteins ARID1A, ARID1B and ARID2, and other chromatin-binding subunits. Gene mutations in members of this complex occur in >20% of human cancers, and therapeutic agents targeting its function are under active clinical investigation. We and others have shown potent synthetic lethality with the use of SMARCA2 targeted protein degraders in SMARCA4 deleted lung cancer models. A previously published genome-wide CRISPR screen in SMARCA4-mut lung cancer cell lines demonstrated that loss of MCL1 could sensitize these cells to SMARCA2 degradation. Therefore, we evaluated PRT1419 in combination with a novel and selective SMARCA2 degrader, PRT3789, in SMARCA4 deleted lung cancer models. We observed a potent synergistic interaction in SMARCA4 deleted cell lines in vitro, whereas no additive benefit was seen in SMARCA4 WT lines. Further, combining PRT1419 and PRT3789 in vivo in cell line-derived xenograft models resulted in significant tumor growth inhibition, including tumor regressions. Additionally, we profiled PRT1419 ex vivo in a panel of lung cancer PDX models and observed significant, dose-dependent effects on cell viability in SMARCA4 deleted models with low SMARCA2 expression. In a broader lung cancer cell line viability screen conducted with PRT1419, we observed that the presence of multiple, co-occurring alterations in SWI/SNF family members such as SMARCA4, ARID1A/B mutations and loss of SMARCA2 protein were associated with sensitivity to PRT1419. Based on these findings, preclinical evaluation of PRT1419 in other tumor types with recurrent SWI/SNF mutations is ongoing. Citation Format: Norman Fultang, Neha Bhagwat, Diane Heiser, Alexander Grego, Michael Hulse, Venkat Thodima, Koichi Ito, Kris Vaddi, Bruce Ruggeri, Peggy Scherle. Combination of the MCL1 inhibitor PRT1419 and SMARCA2 degrader PRT3789 shows combinatorial benefit in SMARCA4 deleted lung cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 420.
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