Project description:Breast cancer stem cells (BCSCs), known to fuel TNBC malignancy, are now being exploited as the vulnerability for TNBC treatment. In this study, we dissected the transcriptome of BCSCs and identified Kinesin Family Member 20A (KIF20A) as an essential gene for BCSC survival and TNBC tumorigenesis. To understand the potential mechanism, we infected MDA-MB-231 cells with either control or V5-tagged KIF20A followed by V5 antibody pull down and mass spectrometry to identify KIF20A interaction proteins that may mediate its effect on gene regulation and TNBC cancer stem cell phenotype.

Project description:Triple negative breast cancer (TNBC) lacks targeted therapy options. TNBC is enriched in breast cancer stem cells (BCSCs), which play a key role in metastasis, chemoresistance, relapse and mortality. γδ T cells hold great potential in immunotherapy against cancer, and might be an alternative to target TNBC. γδ T cells are commonly observed to infiltrate solid tumors and have an extensive repertoire of tumor sensing, recognizing stress-induced molecules and phosphoantigens (pAgs) on transformed cells. We show that patient derived triple negative BCSCs are efficiently recognized and killed by ex vivo expanded γδ T cells from healthy donors. Orthotopically xenografted BCSCs, however, were refractory to γδ T cell immunotherapy. Mechanistically, we unraveled concerted differentiation and immune escape: xenografted BCSCs lost stemness, expression of γδ T cell ligands, adhesion molecules and pAgs, thereby evading immune recognition by γδ T cells. Indeed, neither pro-migratory engineered γδ T cells, nor anti-PD 1 checkpoint blockade significantly prolonged overall survival of tumor-bearing mice. BCSC immune escape was independent of the immune pressure exerted by the γδ T cells, and could be pharmacologically reverted by Zoledronate or IFN-α treatment. These results pave the way for novel combinatorial immunotherapies for TNBC.

Project description:Breast cancer stem cells (bCSCs) have been implicated in tumor progression and therapeutic resistance; however, the molecular mechanisms that define bCSC-state are unclear. We have performed concurrent human miRNome-wide gain- and loss-of-function screens to identify switcher miRNAs controling the choice between bCSC self-renewal and differentiation. These analysis enlightened miR-600 whose silencing resulted in bCSC expansion. Mechanistically, miR-600 targets the stearoyl desaturase 1 (SCD1), an enzyme required to produce active, lipid-modified WNT proteins. To explore further miR-600 interactions and WNT-pathway, SUM159 cell line constructions were made and FACS-sorted to select the bCSCs. We compared gene expression profiles from native, miR-600 'over-expressed', miR-600'knock-down' and siSCD1 bCSCs. We showed that in the absence of miR-600, WNT signaling is maintained active and promotes self-renewal, whereas overexpression of miR-600 inhibits the production of active WNT proteins and promotes bCSC differentiation. These findings highlight a miR-600-centered signaling network that governs bCSC-fate decision and influences tumor progression.

Project description:Background: Breast cancer stem cells (BCSCs) are considered responsible for cancer relapse and drug-resistance. Understanding the identity of BCSCs may open new avenues in breast cancer therapy. Although several discoveries have been made on BCSCs characterization, the factors critical to BCSCs is largely unclear. This study was aimed to determine whether genomic mutation contributes to the acquisition of cancer stem-like phenotype, and to investigate the genetic and transcriptional features of BCSCs. Methods: We detected the potential mutation hotspot regions by using whole genome sequencing on parental cancer cells and derived serial-generation spheroids in increasing order of BCSC frequency, and then performed target deep DNA sequencing in the level of bulk-cell and single-cell. To identify the transcriptional program associated with BCSCs, bulk-cell and single-cell RNA sequencing were performed. Results: By analyzing whole genome sequencing of bulk cells, potential BCSCs associated mutation hotspot regions were detected. Validation by target deep sequencing, in both bulk-cell and single-cell levels, revealed no genetic changes specifically associated with BCSC phenotype. Moreover, single-cell RNA sequencing showed that cancer cells display profound transcriptional variability at the single-cell level that predicts BCSC features. Notably, this transcriptomic variability is enriched in transcription of a number of genes, revealed as BCSC markers. Individuals with breast cancer in a high-risk recurrence group exhibited higher expression of these transcriptomic variabilities, highlighting their clinical significance. Conclusions: Transcriptional variability, not genetic mutations, distinguish BCSCs from non-BCSCs. The identified BCSCs markers can become novel targets for BCSCs.

Project description:Conjunctival melanoma (CM) is a rare and fatal malignant eye tumor, it is life-threatening, mainly because of the lack of diagnostic biomarkers or drug access. In this study, we deciphered a novel anti-CM mechanism of a natural tetracyclic compound isolated from a Cucurbitaceae family plant and named as Cucurbitacin B (CuB). We found that CuB remarkably inhibited the proliferation of CRMM2 cells at a submicromolar level (IC50=0.15 μM) without toxicity to normal cells via G2/M cell cycle arrest and subsequent cell apoptosis. RNA-seq screening identified the Kinesin family member 20A (KIF20A) as a key gene which was abolished by the CuB treatment and proved to be a downstream effector of FOXM1 pathway. Further target identification by the activity-based protein profiling (ABPP) chemoproteomic approach revealed that 78 KDa Glucose-Regulated Protein (GRP78) is a potential target of CuB. Several lines of evidence demonstrated that CuB interacted with GRP78 and bound with a Kd value of 0.11 μM. Furthermore, functional experiments showed that CuB suppressed the ATPase activity of GRP78 both in human recombinant GRP78 and cellular lysates. Knockdown of the GRP78 gene significantly induced the downregulation of FOXM1 and related pathway genes including KIF20A, underlying an interesting therapeutic perspective. Taken together, our current work proved a substantial therapeutic potential of the traditional medicine CuB, and it needs to be explored further for future CM therapies.

Project description:Breast cancer stem cells (BCSCs) are responsible for tumor recurrence and therapy resistance. We have established primary BCSC cultures from human tumors of triple-negative breast cancer (TNBC), a subgroup of breast cancer likely driven by BCSCs. Primary BCSCs generate xenografts phenocopying the tumors of origin, representing a suitable model to investigate breast cancer targeting strategies. In the TNBC cell line MDA-MB-468, we previously screened kinases whose depletion elicited a differentiation response, among which IRAK2 was identified. Since IRAK2 is highly enriched in primary BCSCs we wondered if its depletion could affect their growth. Primary BCSCs and MDA-MB-468 presenting IRAK2 downregulation exhibited decreased proliferation and sphere-forming capacity, evidencing the role of IRAK2 in cellular growth and self-renewal. When transplanted orthotopically into immunocompromised mice, IRAK2 knockdown cells originated smaller xenografts in comparison with control cells, suggesting that IRAK2 downregulation may delay tumor development. Investigating the molecular pathways affected by the knockdown, NF-κB and ERK phosphorylation, IL-6 and cyclin D1 expression, ERN1 signaling and autophagy were decreased in a cell line-dependent way. Transcriptome analysis confirmed that the cells were to some extent differently affected by the knockdown, indicating that their heterogeneity, different mutations, genetic background, expression of IRAK2 and level of its downregulation could influence the outcome of the knockdown. Given that overall IRAK2 downregulation decreased cellular ability to sustain aggressive growth and to endure cellular stress, IRAK2 may be considered an interesting target to compromise TNBC progression, positively contributing to TNBC clinical outcome.

Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor samples and xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites. Breast cancer cells from patient were sorted using flow cytometry to select for cells that were ALDH+. Gene expression profiles of these cells were compared with profiles of ALDH- cells.

Project description:The cancer stem cell (CSC) hypothesis postulates that tumors are maintained by a self-renewing CSC population that is also capable of differentiating into non-self renewing cell populations that constitute the bulk of the tumor. Targeting breast CSC (BCSC) self-renewal represents an avenue for developing therapeutics; however, the molecular mechanisms that govern self-renewal of BCSCs are poorly understood. Our data show the small molecule ID8 decreases overall cell growth, but increases the self-renewal of Aldefluor+ BCSCs and increases functional metastatic BCSCs in a xenograft model. Microarray analysis showed that ID8 is a pleotropic molecule by increasing numerous pathways, including cytokines and chemokines. However, inhibition of those pathways does not abrogate the ID8-induced increase in Aldefluor+ BCSCs. Rather, ID8 is able to activate MAPK pathway through upregulation of the scaffold protein LAMTOR3 and inhibition of MEK prevented the increase in Aldefluor+ BCSCs. By using ID8 as a molecular tool, we identified a new function of the MAPK pathway in regulating BCSC growth and self-renewal.

Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor samples and xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites.

Project description:Breast cancer stem cells (BCSCs) are a rare cell population that are responsible for tumour initiation, metastasis, chemoresistance and tumour relapse. Despite this, the mechanism by which BCSCs withstand genotoxic stress is largely unknown. Here, we uncover a pivotal role for the arginine methyltransferase PRMT5 in mediating BCSC chemoresistance by modulation of DNA repair efficiency. Notably, PRMT5 inhibitors synergise with cisplatin and radiotherapy, inducing defective DNA repair thereby potentiating BCSC apoptosis. Mechanistically, we demonstrate the crucial function of PRMT5 in ensuring splicing fidelity of DNA damage response genes, particularly those integral to the Fanconi Anaemia and homologous recombination pathways. A comparison of BCSCs and their bulk cell progeny identified shared (ATM, DDX11, EXO1, FAN1, SLX4) and unique (ATR, RAD17, RAD51D, RUVBL1) PRMT5-dependent alternative splicing events. Surprisingly, these events rarely repressed gene expression, suggesting that PRMT5 inhibition predominantly results in nuclear detention of intron-containing transcripts and the production of non-canonical isoforms with compromised protein function. This study thus reveals promising strategies to improve the therapeutic efficacy of PRMT5 inhibitors that promote effective BCSC eradication.