Subpopulation Of Breast Cancer Cells Research Articles

Chromosome 1q21.3 amplification is a trackable biomarker and actionable target for breast cancer recurrence.

Tumor recurrence remains the main reason for breast cancer-associated mortality, and there are unmet clinical demands for the discovery of new biomarkers and development of treatment solutions to benefit patients with breast cancer at high risk of recurrence. Here we report the identification of chromosomal copy-number amplification at 1q21.3 that is enriched in subpopulations of breast cancer cells bearing characteristics of tumor-initiating cells (TICs) and that strongly associates with breast cancer recurrence. Amplification is present in ∼10-30% of primary tumors but in more than 70% of recurrent tumors, regardless of breast cancer subtype. Detection of amplification in cell-free DNA (cfDNA) from blood is strongly associated with early relapse in patients with breast cancer and could also be used to track the emergence of tumor resistance to chemotherapy. We further show that 1q21.3-encoded S100 calcium-binding protein (S100A) family members, mainly S100A7, S100A8, and S100A9 (S100A7/8/9), and IL-1 receptor-associated kinase 1 (IRAK1) establish a reciprocal feedback loop driving tumorsphere growth. Notably, this functional circuitry can be disrupted by the small-molecule kinase inhibitor pacritinib, leading to preferential impairment of the growth of 1q21.3-amplified breast tumors. Our study uncovers the 1q21.3-directed S100A7/8/9-IRAK1 feedback loop as a crucial component of breast cancer recurrence, serving as both a trackable biomarker and an actionable therapeutic target for breast cancer.

Abstract 3318: A critical role for c-Jun N-terminal kinase in autophagy and cell survival of breast cancer cells

Antiestrogen resistance is the major impediment to the eradication of estrogen receptor positive (ER+) breast cancer. Approximately 30% of ER+ breast tumors initially responsive to antiestrogen therapy will acquire resistance. One approach to reducing the occurrence of acquired antiestrogen resistance is to identify and target key signaling nodes that specifically attenuate the ability of antiestrogens to kill cancer cells. Toward this goal, we identified MEK/MAPK1/2 as a key molecular target based on the general inability of antiestrogens to effectively block MEK1/MAPK1/2-mediated phosphorylation of BimEL in breast cancer cells. BimEL is a pro-apoptotic member of the BH3 family of proteins that is inactivated (degraded by the proteasome) when phosphorylated by MAPK1/2. The combination of an antiestrogen and MEK1 inhibitor robustly-induced BimEL-dependent breast cancer cell apoptosis (Periyasamy-Thandavan et al., 2012). However, a subpopulation of breast cancer cells survive this combined treatment via an autophagy-dependent mechanism. Based on the key role of JNK in regulating autophagy in cancer cells via BimEL phosphorylation, we hypothesized that JNK was a key effector of autophagy in breast cancer cells surviving antiestrogen treatment when used as a single agent or in combination with a MEK inhibitor. To test this hypothesis, we utilized the selective JNK inhibitor SP600125 as a single agent or in combination with estradiol (E2), 4-hydroxytamoxifen (4-OHT), and/or U0126 (a selective MEK1 inhibitor). Treatments were conducted with the antiestrogen-sensitive cell lines MCF-7 and T-47D and the antiestrogen resistant cell line TR5, previously derived in our laboratory by a step-wise 4-OHT selection. Effects on cell death (determination of apoptosis) and autophagy (determination of autophagy levels and flux) were evaluated for the various hormonal treatments conducted in the presence or absence of JNK inhibition. These studies showed that: (1) targeting JNK in antiestrogen sensitive breast cancer cells induces apoptosis with caspase-dependent cleavage of PARP as a surrogate marker of apoptosis; (2) JNK activity is elevated in antiestrogen resistant TR5 cells and JNK inhibition induces TR5 cell death; and (3) antiestrogen sensitive and resistant breast cancer cells dying as a result of JNK inhibition can show extensive cytosolic vacuolization with the autophagy protein LC3 (ATG8) localized to the aberrant vacuoles. Overall, our results support the conclusion that JNK plays a key autophagy-dependent survival role in breast cancer cells. Ongoing studies aim to identify the specific JNK protein(s) that disrupt autophagy and enhance death of breast cancer cells toward the goal of identifying specific molecular targets to block autophagy in breast cancer cells. Citation Format: Rohit Munagala, Carol Joseph, Annie Liu, Kebin Liu, Muthusamy Thangaraju, Patricia V. Schoenlein. A critical role for c-Jun N-terminal kinase in autophagy and cell survival of breast cancer cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3318. doi:10.1158/1538-7445.AM2017-3318

Abstract 1928: The lung microenvironment promotes stem-like phenotype and behavior of breast cancer cells

Abstract Ninety percent of breast cancer-related mortalities result from metastasis, a process whereby the primary tumour disseminates and targets distant secondary organs. We have previously demonstrated that stem-like breast cancer cells expressing high levels of aldehyde dehydrogenase (ALDH) and CD44 are critical for metastasis. These ALDHhiCD44+ cells preferentially migrate and/or metastasize to the lung and bone microenvironments, where secondary tumours can severely impede organ function. However, the specific role of the lung and bone marrow (BM) microenvironments in supporting and/or promoting metastasis of ALDHhiCD44+ cells remains poorly understood, and this is the purpose of the current study. Using a 2D ex vivo model, lung and bone marrow (BM) conditioned media (CM) enriched in tissue-specific soluble proteins were generated from murine tissues and utilized in cell culture to assess their ability to influence the stem-like phenotype and behavior of MDA-MB-468 human breast cancer cells. Exposure to lung-CM promoted the generation of a viable, non-adherent (“floating”) breast cancer cell subpopulation that was not observed in response to BM-CM or basal media (p<0.05). Phenotypic analysis by flow cytometry and gene expression analysis by RT-qPCR revealed notable differences in ALDH/CD44 phenotype in whole cell populations, adherent subpopulations, and/or non-adherent subpopulations in response to 72 hour exposure to lung-CM relative to basal media. In particular, the non-adherent breast cancer cell subpopulation generated in response to lung-CM demonstrated increased CD44 and ALDH1A3 gene expression and decreased ALDH1A1 gene expression relative to the adherent subpopulation (p<0.05). No significant phenotypic or gene expression differences were observed in MDA-MB-468 breast cancer cells in response to BM-CM. Taken together with our previous studies, these findings suggest that while both the lung and bone microenvironments support breast cancer cells with a pre-existing ALDHhiCD44+ phenotype, the lung microenvironment may additionally help to even further promote stem-like phenotype and behavior in the secondary metastatic site. Ongoing studies are aimed at elucidating the mechanisms by which aggressive ALDHhiCD44+ breast cancer cells interact with and/or are influenced by the lung microenvironment during metastatic progression. Citation Format: Ashkan Sadri, Alison L. Allan. The lung microenvironment promotes stem-like phenotype and behavior of breast cancer cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1928. doi:10.1158/1538-7445.AM2017-1928

Abstract 3899: Synthetic small molecule targeting CD24-/CD44+/ALDH+ cell population inhibits cancer stem cell activities in breast cancer

Abstract Purpose of the study: Cancer stem cells (CSCs) have been described as the “seed of tumor”, and have been suggested as the driving force of tumor relapses. In this study we aimed to isolate small molecules via screening of the combinatorial chemical library. The isolated molecules bind CD24-/CD44+/ALDH+ breast cancer cell subpopulation with high selectivity and specificity. Experimental design and plan: Through the unbiased cell based chemical library screening, we identified compound candidates that specifically bind the stem-like cancer cell subpopulations in breast cancer cells and tissues. By performing in vitro, tissue and in vivo-based assessments on ligand-binding specificity and functional activities, we ensured that the isolated ligands target tumorigenic stem-like breast cell or tissue preferentially. Summary of discoveries and findings: The in vitro compound binding validations proved the specificity of the isolated compound candidates toward breast cancer cells and tissues displaying cancer stem cell properties. The compound-targeting cell populations display significantly-higher expressions of the well-known stem cell markers than the unbound cell populations. On the other hand, a series of biological and biochemical functional assays also confirmed the compound candidates exert tumor-suppression activities on breast cancer cell lines, such as slow down proliferation and reduce cell viability. More importantly, our study demonstrated that both isolated compounds have preferential selectivity and higher binding affinity to the TNBC cells and tissues, which have been reported for higher percentage of stem-like cancer cell population detected than in non-TNBC cells or tissues. Through mouse xenograft study followed by histological analysis, we further confirmed the binding specificity of the compound towards cell line models could be retained in vivo in mouse xenograft model. Conclusion: We demonstrated our ligand screening technique is able to identify synthetic compounds targeting cell subgroups or sub-populations of defined interest within one particular type of tumor. High specificity of the isolated molecules could be utilized to develop chemical probes for quantification of percentage of CSC in the tumor, which facilitates clinical evaluation of tumor relapse risk. The screening strategy also provides a new methodology in discovering novel drug targeting CSC subpopulations, not only in breast tumor, but also other types of human cancers. Funding: This project is supported by the Cancer Prevention and Research Institute of Texas (CPRIT) grant, award ID: RP150713. Citation Format: Luxi Chen, Chao Long, Kha A. Tran, Jiyong Lee. Synthetic small molecule targeting CD24-/CD44+/ALDH+ cell population inhibits cancer stem cell activities in breast cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3899. doi:10.1158/1538-7445.AM2017-3899

Abstract P1-01-07: Maintenance of genomic integrity in dormant circulating tumor cells

Abstract More than 67% of deaths in breast cancer patients occur after the initial 5-year survival period while residual disease can be dormant for periods longer than 20 years. Patients are asymptomatic because circulating tumor cells (CTCs) remain dormant and are undetectable by current clinical tools. Dormant CTCs may retain their long-term tumor-initiating (LTI) potential by adhering to their original genome, unlike rapidly cycling cancer cells that are known to have increased genomic instability. We hypothesized that hyperactive mechanisms of DNA repair preserve the genomic make-up of dormant CTCs allowing them to retain their LTI potential, ultimately causing disease relapse. We isolated and characterized breast cancer CTCs by mutiparametric flow cytometry and DEPArrayTM. Individually isolated breast cancer CTCs had a large proportion (>40%) of dormant (Ki67-/PCNA-) cells. Dormant CTCs had a lower incidence of double-strand DNA breaks (DSB) than proliferating cells as assessed by the phosphorylation status of Serine139 on gamma H2AX. This observation was further validated in a panel of eight genetically distinct breast cancer cell lines. Second, to understand whether dormant cells are inherently more resistant to DSB, we induced DSB in breast cancer cells by UV radiation and bleomycin treatment, and measured residual DSB at regular intervals. Results showed that besides being more resistant to DSB de novo, dormant breast cancer cells were also more efficient repairing their DNA. There are two distinct phases of DSB repair - early [within 2 hours of DSB using Non-Homologous End Joining (NHEJ) methods] and late [evident after 24 hours using Homologous Recombination (HR)]. Unlike proliferating (S-G2M) cells, dormant (G0) cells lack the sister chromatid and repair their DNA exclusively by NHEJ methods. Therefore, and third, we investigated key players of the NHEJ pathway and examined their roles in maintaining genomic integrity. We found that the human telomere-associated protein RIF1, a mediator of alternative NHEJ, was significantly up-regulated in a dormant CTC subset. Dormant sub-populations of breast cancer cells confirmed RIF1 foci formation in areas of DNA damage. Fourth, mis-sense mutation of RIF1 in CAMA-1 cells (ΔRIF1 E1598K) as well as shRNA mediated RIF1 knockdown in HCC1954 and ZR-75-1 cell lines attenuated resistance of the dormant subset to UV and bleomycin treatment. Finally, RIF1 knockdown activated both p38 and pERK pathways albeit to varying degrees in multiple cell lines resulting in metastatic inefficiency in xenograft and syngeneic mouse models. Collectively, these findings suggest that RIF1 may play functional roles in maintaining the genomic integrity of dormant CTCs and be a potential biomarker of breast cancer CTC survival while in circulation. Citation Format: Boral D, Vishnoi M, Liu HN, Yin W, Marchetti D, Hong DS, Scamardo A. Maintenance of genomic integrity in dormant circulating tumor cells [abstract]. In: Proceedings of the 2016 San Antonio Breast Cancer Symposium; 2016 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2017;77(4 Suppl):Abstract nr P1-01-07.

Abstract P3-07-14: Targeting ERR-α regulated lactate metabolism eliminates drug-resistant breast cancer cells

Abstract Novel therapeutic strategies to eliminate chemo-resistant tumour cells responsible for the development of secondary lesions are essential in order to prevent breast cancer relapse. We have developed an in vitro model system enabling isolation of a putative metastasis-initiating breast cancer cell sub-population with a mitotically quiescent, drug-resistant phenotype. We hypothesise that this population is able to utilise oestrogen-related receptor-alpha (ERR-α)-regulated oxidative lactate metabolism and that inhibition of this critical survival pathway will result in elimination of tumour cells that have survived anti-cancer therapies. Flow cytofluormetric monitoring of Vybrant® DiD retention identified a mitotically quiescent sub-population (~0.05%) in MDA-MB-231 human breast cancer cells grown under high glucose (11mM) conditions. DiD-retaining cells accumulated in the G2/M phase of the cell cycle and were shown to be non-senescent following cytochemical analysis of β-galactosidase activity. Cytotoxicity assays with doxorubicin (0.40μM for 72 hours) demonstrated increased survival in the quiescent fraction (40.76%) compared with the rapidly dividing bulk cell population (1.63%, P ≤ 0.0001). Isolated drug-resistant cells contained a sub-fraction (~1%) that was able to form new clonal populations following cessation of treatment. Mitotically quiescent cells were cultured under high glucose (11mM) or glucose-depleted conditions with high lactate (22mM) in the presence of ERR-α inhibitors Cpd29 (10μM) or XCT790 (10μM). Colony formation was completely eliminated in Cpd29- and XCT790-treated samples compared to untreated controls. Drug-resistant sub-clones were isolated from the quiescent population following 72 hours treatment with doxorubicin (0.40μM) and were cultured under glucose-depleted conditions with high lactate (22mM) in the presence of ERR-α inhibitors Cpd29 (10μM) or XCT790 (10μM). In both instances, colony formation was completely prevented. We provide the first evidence that blocking cellular energy production through inhibition of ERR-α regulated oxidative lactate metabolism can eradicate a chemo-resistant, quiescent breast cancer cell population. Our data suggest that ERR-α inhibitors may be used in combination with chemotherapy to eliminate minimal residual disease and reduce breast cancer recurrence. Citation Format: Quayle L, Park S, McDonnell DP, Ottewell PD, Holen I. Targeting ERR-α regulated lactate metabolism eliminates drug-resistant breast cancer cells [abstract]. In: Proceedings of the 2016 San Antonio Breast Cancer Symposium; 2016 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2017;77(4 Suppl):Abstract nr P3-07-14.

Clinicopathological analysis of CD44 and CD24 expression in invasive breast cancer.

A subpopulation of breast cancer cells with cluster of differentiation (CD)44-positive and CD24-negative expression has been reported to have stem cell properties and to have a higher tumorigenic capacity than other cells. However, the clinicopathological characteristics of this subpopulation are not fully understood. In this study, we aimed to identify the correlations between the expression of CD44 and CD24 and clinicopathological parameters and overall survival. We studied specimens from 262 patients with invasive breast cancer. Immunohistochemical staining for CD44 and CD24 was performed using tissue microarrays. The clinicopathological factors were evaluated from the patients' medical records. In correlation analysis, CD44 expression was significantly associated with human epidermal growth factor receptor 2 (HER2)-negative status (P<0.001). Conversely, CD24 expression was significantly associated with HER2-positive status (P<0.001). CD44 and CD24 expression did not demonstrate any correlation with the age, tumor size, axillary lymph node metastasis status, tumor stage, histological grade, estrogen receptor status and progesterone receptor status of patients. Upon survival analysis, there was no statistical difference in overall survival according to the expression of CD44 and CD24. The results from this study suggest that CD44 and CD24 are clinically significant markers associated with breast tumorigenesis, but not sufficient factors in determining the prognosis of invasive breast cancer.

Abstract 3143: Deciphering mechanisms of circulating tumor cells in breast cancer dormancy

Abstract More than 67% of deaths in breast cancer patients occur after the initial 5-year survival period while residual disease can be dormant for periods longer than 20 years. Patients are asymptomatic because circulating tumor cells (CTCs) remain dormant and are undetectable by current clinical tools. Dormant CTCs may retain their long-term tumor-initiating (LTI) potential by adhering to their original genome, unlike rapidly cycling cancer cells that are known to have increased genomic instability. We hypothesized that hyperactive mechanisms of DNA repair preserve the genomic make-up of dormant CTCs allowing them to retain their LTI potential, ultimately causing disease relapse. We isolated and characterized EpCAM-negative breast cancer CTCs by mutiparametric flow cytometry and DEPArrayTM. Individually isolated breast cancer CTCs had a large proportion (&amp;gt;40%) of dormant (Ki67-/PCNA-) cells. Dormant CTCs had a lower incidence of double-strand DNA breaks (DSB) than proliferating cells as assessed by the phosphorylation status of Serine139 on gamma H2AX. This observation was further validated in a panel of eight genetically distinct breast cancer cell lines. Second, to understand whether dormant cells are inherently more resistant to DSB, we induced DSB in breast cancer cells by UV radiation and bleomycin treatment, and measured residual DSB at regular intervals. Results showed that besides being more resistant to DSB de novo, dormant breast cancer cells were also more efficient in repairing their DNA. There are two distinct phases of DSB repair - early [within 2 hours of DSB using Non-Homologous End Joining (NHEJ) methods] and late [evident after 24 hours using Homologous Recombination (HR)]. Unlike proliferating (S-G2M) cells, dormant (G0) cells lack the sister chromatid and repair their DNA exclusively by NHEJ methods. Therefore, and third, we investigated key players of the NHEJ pathway and examined their roles in maintaining genomic integrity. We found that the human telomere-associated protein RIF1, a mediator of alternative NHEJ, was significantly up-regulated in a dormant CTC subset. Dormant sub-populations of breast cancer cells confirmed RIF1 foci formation in areas of DNA damage. Fourth, mis-sense mutation of RIF1 in CAMA-1 cells (ΔRIF1 E1598K) attenuated resistance of the dormant subset to UV and bleomycin treatment. Collectively, these findings suggest that RIF1 may play functional roles in maintaining the genomic integrity of dormant CTCs. Further investigations are being pursued to assess RIF1 contributions to retain CTC LTI potential leading to CTC-driven metastasis. Citation Format: Debasish Boral, Haowen N. Liu, Wei Yin, Monika Vishnoi, Antonio Scamardo, Goldy C. George, David S. Hong, Dario Marchetti. Deciphering mechanisms of circulating tumor cells in breast cancer dormancy. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3143.

390 - Distinct HER2 distribution and homo-dimerization patterns on subpopulations of breast cancer cells − correlative light- and electron microscopy in liquid for cancer stem cell characterization

390 - Distinct HER2 distribution and homo-dimerization patterns on subpopulations of breast cancer cells − correlative light- and electron microscopy in liquid for cancer stem cell characterization

Hinokitiol inhibits vasculogenic mimicry activity of breast cancer stem/progenitor cells through proteasome-mediated degradation of epidermal growth factor receptor.

Hinokitiol, alternatively known as β-thujaplicin, is a tropolone-associated natural compound with antimicrobial, anti-inflammatory and antitumor activity. Breast cancer stem/progenitor cells (BCSCs) are a subpopulation of breast cancer cells associated with tumor initiation, chemoresistance and metastatic behavior, and may be enriched by mammosphere cultivation. Previous studies have demonstrated that BCSCs exhibit vasculogenic mimicry (VM) activity via the epidermal growth factor receptor (EGFR) signaling pathway. The present study investigated the anti-VM activity of hinokitiol in BCSCs. At a concentration below the half maximal inhibitory concentration, hinokitiol inhibited VM formation of mammosphere cells derived from two human breast cancer cell lines. Hinokitiol was additionally indicated to downregulate EGFR protein expression in mammosphere-forming BCSCs without affecting the expression of messenger RNA. The protein stability of EGFR in BCSCs was also decreased by hinokitiol. The EGFR protein expression and VM formation capability of hinokitiol-treated BCSCs were restored by co-treatment with MG132, a proteasome inhibitor. In conclusion, the present study indicated that hinokitiol may inhibit the VM activity of BCSCs through stimulating proteasome-mediated EGFR degradation. Hinokitiol may act as an anti-VM agent, and may be useful for the development of novel breast cancer therapeutic agents.

Identification of Distinct Breast Cancer Stem Cell Populations Based on Single-Cell Analyses of Functionally Enriched Stem and Progenitor Pools

SummaryThe identification of breast cancer cell subpopulations featuring truly malignant stem cell qualities is a challenge due to the complexity of the disease and lack of general markers. By combining extensive single-cell gene expression profiling with three functional strategies for cancer stem cell enrichment including anchorage-independent culture, hypoxia, and analyses of low-proliferative, label-retaining cells derived from mammospheres, we identified distinct stem cell clusters in breast cancer. Estrogen receptor (ER)α+ tumors featured a clear hierarchical organization with switch-like and gradual transitions between different clusters, illustrating how breast cancer cells transfer between discrete differentiation states in a sequential manner. ERα− breast cancer showed less prominent clustering but shared a quiescent cancer stem cell pool with ERα+ cancer. The cellular organization model was supported by single-cell data from primary tumors. The findings allow us to understand the organization of breast cancers at the single-cell level, thereby permitting better identification and targeting of cancer stem cells.

High mitochondrial mass identifies a sub-population of stem-like cancer cells that are chemo-resistant.

Chemo-resistance is a clinical barrier to more effective anti-cancer therapy. In this context, cancer stem-like cells (CSCs) are thought to be chemo-resistant, resulting in tumor recurrence and distant metastasis. Our hypothesis is that chemo-resistance in CSCs is driven, in part, by enhanced mitochondrial function. Here, we used breast cell lines and metastatic breast cancer patient samples to begin to dissect the role of mitochondrial metabolism in conferring the CSC phenotype. More specifically, we employed fluorescent staining with MitoTracker (MT) to metabolically fractionate these cell lines into mito-high and mito-low sub-populations, by flow-cytometry. Interestingly, cells with high mitochondrial mass (mito-high) were specifically enriched in a number of known CSC markers, such as aldehyde dehydrogenase (ALDH) activity, and they were ESA+/CD24-/low and formed mammospheres with higher efficiency. Large cell size is another independent characteristic of the stem cell phenotype; here, we observed a >2-fold increase in mitochondrial mass in large cells (>12-μm), relative to the smaller cell population (4-8-μm). Moreover, the mito-high cell population showed a 2.4-fold enrichment in tumor-initiating cell activity, based on limiting dilution assays in murine xenografts. Importantly, primary human breast CSCs isolated from patients with metastatic breast cancer or a patient derived xenograft (PDX) also showed the co-enrichment of ALDH activity and mitochondrial mass. Most significantly, our investigations demonstrated that mito-high cells were resistant to paclitaxel, resulting in little or no DNA damage, as measured using the comet assay. In summary, increased mitochondrial mass in a sub-population of breast cancer cells confers a stem-like phenotype and chemo-resistance. As such, our current findings have important clinical implications for over-coming drug resistance, by therapeutically targeting the mito-high CSC population.

Regulation of the breast cancer stem cell phenotype by hypoxia-inducible factors.

The small subpopulation of breast cancer cells that possess the capability for self-renewal and formation of secondary tumours that recapitulate the heterogeneity of the primary tumour are referred to as tumour-initiating cells or BCSCs (breast cancer stem cells). The hypoxic tumour microenvironment and chemotherapy actively induce the BCSC phenotype. HIFs (hypoxia-inducible factors) are required and molecular mechanisms by which they promote the BCSC phenotype have recently been delineated. HIF inhibitors block chemotherapy-induced enrichment of BCSCs, suggesting that their use may improve the response to chemotherapy and increase the survival of breast cancer patients.

Nucleolin overexpression in breast cancer cell sub-populations with different stem-like phenotype enables targeted intracellular delivery of synergistic drug combination

Breast cancer stem cells (CSC) are thought responsible for tumor growth and relapse, metastization and active evasion to standard chemotherapy. The recognition that CSC may originate from non-stem cancer cells (non-SCC) through plastic epithelial-to-mesenchymal transition turned these into relevant cell targets. Of crucial importance for successful therapeutic intervention is the identification of surface receptors overexpressed in both CSC and non-SCC. Cell surface nucleolin has been described as overexpressed in cancer cells as well as a tumor angiogenic marker. Herein we have addressed the questions on whether nucleolin was a common receptor among breast CSC and non-SCC and whether it could be exploited for targeting purposes.Liposomes functionalized with the nucleolin-binding F3 peptide, targeted simultaneously, nucleolin-overexpressing putative breast CSC and non-SCC, which was paralleled by OCT4 and NANOG mRNA levels in cells from triple negative breast cancer (TNBC) origin. In murine embryonic stem cells, both nucleolin mRNA levels and F3 peptide-targeted liposomes cellular association were dependent on the stemness status. An in vivo tumorigenic assay suggested that surface nucleolin overexpression per se, could be associated with the identification of highly tumorigenic TNBC cells. This proposed link between nucleolin expression and the stem-like phenotype in TNBC, enabled 100% cell death mediated by F3 peptide-targeted synergistic drug combination, suggesting the potential to abrogate the plasticity and adaptability associated with CSC and non-SCC.Ultimately, nucleolin-specific therapeutic tools capable of simultaneous debulk multiple cellular compartments of the tumor microenvironment may pave the way towards a specific treatment for TNBC patient care.

Selection of a breast cancer subpopulation-specific antibody using phage display on tissue sections.

Breast cancer tumors are composed of heterogeneous cell populations. These populations display a high variance in morphology, growth and metastatic propensity. They respond differently to therapeutic interventions, and some may be more prone to cause recurrence. Studying individual subpopulations of breast cancer may provide crucial knowledge for the development of individualized therapy. However, this process is challenged by the availability of biomarkers able to identify subpopulations specifically. Here, we demonstrate an approach for phage display selection of recombinant antibody fragments on cryostat sections of human breast cancer tissue. This method allows for selection of recombinant antibodies binding to antigens specifically expressed in a small part of the tissue section. In this case, a CD271+ subpopulation of breast cancer cells was targeted, and these may be potential breast cancer stem cells. We isolated an antibody fragment LH 7, which in immunohistochemistry experiments demonstrates specific binding to breast cancer subpopulations. The selection of antibody fragments directly on small defined areas within a larger section of malignant tissue is a novel approach by which it is possible to better target cellular heterogeneity in proteomic studies. The identification of novel biomarkers is relevant for our understanding and intervention in human diseases. The selection of the breast cancer-specific antibody fragment LH 7 may reveal novel subpopulation-specific biomarkers, which has the potential to provide new insight and treatment strategies for breast cancer.Electronic supplementary materialThe online version of this article (doi:10.1007/s12026-015-8657-x) contains supplementary material, which is available to authorized users.

MiR-205 acts as a tumour radiosensitizer by targeting ZEB1 and Ubc13.

Tumor cells associated with therapy resistance (radioresistance and drug resistance) are likely to give rise to local recurrence and distant metastatic relapse. Recent studies revealed microRNA (miRNA)-mediated regulation of metastasis and epithelial-mesenchymal transition; however, whether specific miRNAs regulate tumor radioresistance and can be exploited as radiosensitizing agents remains unclear. Here we find that miR-205 promotes radiosensitivity and is downregulated in radioresistant subpopulations of breast cancer cells, and that loss of miR-205 is highly associated with poor distant relapse-free survival in breast cancer patients. Notably, therapeutic delivery of miR-205 mimics via nanoliposomes can sensitize the tumor to radiation in a xenograft model. Mechanistically, radiation suppresses miR-205 expression through ataxia telangiectasia mutated (ATM) and zinc finger E-box binding homeobox 1 (ZEB1). Moreover, miR-205 inhibits DNA damage repair by targeting ZEB1 and the ubiquitin-conjugating enzyme Ubc13. These findings identify miR-205 as a radiosensitizing miRNA and reveal a new therapeutic strategy for radioresistant tumors.

Abstract 3023: The characterisation of hyaluronan-related enzymes in breast cancer cell subpopulations

Abstract Background:Hyaluronan (HA) has been associated with various facets of tumor biology where it provides structural integrity, maintains hydration homeostasis, and in conjunction with its metabolic receptor, CD44, has been implicated in tumor cell proliferation and migration. There is a direct correlation between treatment-resistant breast carcinomas and the increased synthesis of HA via the over-expression of the HA anabolic enzyme, HA synthase (HAS). It is becoming generally accepted that the failure of cancer treatments can be due to a small subpopulation of slow growing, invasive and drug resistant cells known as cancer stem cells (CSCs) which are often characterized by the presence of CD44. As CD44 is the sole HA metabolic receptor within the tumor microenvironment, this study aimed to characterize the role of HA metabolism in the breast CSC subpopulation and its potential contribution to the persistence of treatment-resistant cancer. Methodology:HA metabolic enzymes [HAS 1-3 and hyaluronidase 1-2 (Hyal)] in breast cancer cell subpopulations were characterised in five cancer cell lines after FACS separation into putative CSC (CD44+/CD24-) and non-stem cell (CD44-/CD24+) subpopulations using quantitative real time PCR. Cell subpopulations were further characterised for cell-growth kinetics and resistance to chemotherapy using an Excelligence proliferation assay. The most highly expressed HAS isoform, HAS2, was knocked down or inserted in different cell lines using stable transfection and the resultant changes in proliferation, invasive and migratory potential and the direct effect on the CSC subpopulation was investigated both in vitro and in vivo. Results:HAS2 and Hyal2 were determined to be preferentially expressed in invasive breast cancer cell lines, where the chemotherapy-resistant CSC subpopulations (CD44+/CD24-) expressed the highest level of these HAS and Hyal isoforms. Transfection-induced attenuation of HAS2 mediated a reduction in the CSC subpopulation while over-expression of HAS2 increased the size of the CD44+/CD24- subpopulation. Both in vitro and in vivo HAS 2 over-expression increased HA production with a concomitant increase in tumorigenesis and metastasis while the counter-effect was observed in HAS2 knock-down breast cancer cells. Conclusions:These preliminary data suggest that HA metabolism is a tightly regulated process and a key component within breast cancer subpopulations and the CSC niche. The direct relationship between increased HAS expression, HA production and enlargement of the CD44+/CD24- subpopulation highlights HA metabolic enzymes as potential therapeutic targets in treatment-resistant breast cancer. Citation Format: Vera Evtimov, Tracey Brown. The characterisation of hyaluronan-related enzymes in breast cancer cell subpopulations. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 3023. doi:10.1158/1538-7445.AM2014-3023

ATM-mediated stabilization of ZEB1 promotes DNA damage response and radioresistance through CHK1.

Epithelial-mesenchymal transition (EMT) is associated with characteristics of breast cancer stem cells, including chemoresistance and radioresistance. However, it is unclear whether EMT itself or specific EMT regulators play causal roles in these properties. Here we identify an EMT-inducing transcription factor, zinc finger E-box binding homeobox 1 (ZEB1), as a regulator of radiosensitivity and DNA damage response (DDR). Radioresistant subpopulations of breast cancer cells derived from ionizing radiation exhibit hyperactivation of ATM and upregulation of ZEB1, and ZEB1 promotes tumor cell radioresistance in vitro and in vivo. Mechanistically, ATM kinase phosphorylates and stabilizes ZEB1 in response to DNA damage, and ZEB1 in turn directly interacts with USP7 and enhances its ability to deubiquitinate and stabilize CHK1, thereby promoting homologous recombination-dependent DNA repair and resistance to radiation. These findings identify ZEB1 as an ATM substrate linking ATM to CHK1 and as the mechanism underlying the association between EMT and radioresistance.

Epidermal growth factor/heat shock protein 27 pathway regulates vasculogenic mimicry activity of breast cancer stem/progenitor cells.

Tumor vascularization, which is mainly contributed by angiogenesis and vascularization, is necessary for tumor maintenance and progression. Vasculogenic mimicry (VM), vascular-like channels which are lack of the involvement of endothelial cells, has been observed in aggressive cancers and also involves in tumor vascularization. Breast cancer stem/progenitor cells (BCSCs) have been identified as a subpopulation of breast cancer cells with markers of CD24(-)CD44(+), high aldehyde dehydrogenase activity (ALDH(+)) or could be enriched by mammosphere cultivation. These cells have been proven to be associated with tumor vascularization. Here we investigated the molecular mechanisms in VM activity of BCSCs. By periodic acid-Schiff or hematoxylin-eosin stain, we found that there were VM structures in two xenografted human breast cancer tissues established from CD24(-)CD44(+) or ALDH(+) cells. Only ALDH(+) or mammosphere-forming BCSCs could form tube structures on matrigel-coated surface as similar as microvascular endothelial cells. Inhibition of the phosphorylation of epidermal growth factor receptor (EGFR) by gefitinib or knockdown of EGFR by lentiviral shRNA abolished the invitro VM activity of BCSCs. By quercetin treatment, a plant flavonoid compound which is known to suppress heat shock proteins, or siRNA-mediated gene silencing, both Hsp27 expression and VM capability of BCSCs were suppressed. Forced expression of phosphor-mimic form of Hsp27 in ALDH(+) BCSCs could overcome the inhibitory effect of gefitinib. In conclusion, our data demonstrate that VM activity of BCSCs is mediated by EGF/Hsp27 signaling and targeting this pathway may benefit to breast cancer therapy.

A microphysiological system model of therapy for liver micrometastases.

Metastasis accounts for almost 90% of cancer-associated mortality. The effectiveness of cancer therapeutics is limited by the protective microenvironment of the metastatic niche and consequently these disseminated tumors remain incurable. Metastatic disease progression continues to be poorly understood due to the lack of appropriate model systems. To address this gap in understanding, we propose an all-human microphysiological system that facilitates the investigation of cancer behavior in the liver metastatic niche. This existing LiverChip is a 3D-system modeling the hepatic niche; it incorporates a full complement of human parenchymal and non-parenchymal cells and effectively recapitulates micrometastases. Moreover, this system allows real-time monitoring of micrometastasis and assessment of human-specific signaling. It is being utilized to further our understanding of the efficacy of chemotherapeutics by examining the activity of established and novel agents on micrometastases under conditions replicating diurnal variations in hormones, nutrients and mild inflammatory states using programmable microdispensers. These inputs affect the cues that govern tumor cell responses. Three critical signaling groups are targeted: the glucose/insulin responses, the stress hormone cortisol and the gut microbiome in relation to inflammatory cues. Currently, the system sustains functioning hepatocytes for a minimum of 15 days; confirmed by monitoring hepatic function (urea, α-1-antitrypsin, fibrinogen, and cytochrome P450) and injury (AST and ALT). Breast cancer cell lines effectively integrate into the hepatic niche without detectable disruption to tissue, and preliminary evidence suggests growth attenuation amongst a subpopulation of breast cancer cells. xMAP technology combined with systems biology modeling are also employed to evaluate cellular crosstalk and illustrate communication networks in the early microenvironment of micrometastases. This model is anticipated to identify new therapeutic strategies for metastasis by elucidating the paracrine effects between the hepatic and metastatic cells, while concurrently evaluating agent efficacy for metastasis, metabolism and tolerability.