Transcription Cofactor LBH is a Direct Target of the Oncogenic WNT Pathway with an Important Role in Breast Cancer

Rieger, Megan Elizabeth

14 July 2010

Limb-Bud and Heart (LBH) is a novel key transcriptional regulator of vertebrate development. However, the molecular mechanisms upstream of LBH and its role in adult development are unknown. Here we show that in epithelial development, LBH expression is tightly controlled by Wnt signaling. LBH is transcriptionally induced by the canonical Wnt pathway, as evident by the presence of functional TCF/LEF binding sites in the LBH locus and rapid beta-catenin-dependent upregulation of endogenous LBH by Wnt3a. In contrast, LBH induction by Wnt/beta-catenin signaling is inhibited by Wnt7a, which in limb development signals through a non-canonical pathway involving Lmx1b. Furthermore, we show that Lbh is aberrantly overexpressed in mammary tumors of MMTV-Wnt1 transgenic mice and in aggressive basal-subtype human breast cancers that display Wnt/beta-catenin hyperactivation. Deregulation of LBH in human breast cancer appears to be Wnt/beta-catenin dependent as DKK1 and Wnt7a inhibit LBH expression in breast tumor cells. RNAi mediated knockdown of LBH in basal breast cancer cell lines resulted in loss of CD44high/CD24low tumor cells, luminal differentiation, reduced cell growth, reduced colony forming ability, and increased apoptosis, suggesting a novel pro-survival and stem cell maintenance function of LBH in breast cancer. Reciprocal overexpression studies in the basal breast carcinoma line BT549 resulted in increased tumorigenicity in vitro, suggesting that LBH overexpression is indeed oncogenic. Finally, we further characterized LBH protein expression patterns and post-transcriptional regulation. Collectively, this thesis demonstrates that LBH is a direct Wnt target gene in both development and basal breast cancer that promotes the undifferentiated phenotype and survival of basal breast tumor cells.

Serotonergic Antagonists Affect the Activity of Breast Tumor Initiating Cells in Human and Mouse Models of Breast Cancer / ON SEROTONERGIC SIGNALING AND BREAST TUMOR INITIATING CELLS

Gwynne, William D.

January 2019

DOCTOR OF PHILOSOPHY (2019) McMaster University, Hamilton, Ontario (Medical Sciences) TITLE: Serotonergic antagonists affect the activity of breast tumor initiating cells in human and mouse models of breast cancer. AUTHOR: William D. Gwynne, BSc SUPERVISOR: Dr. John A. Hassell NUMBER OF PAGES: XXI; 255 / Breast cancer is the most frequently diagnosed cancer and the leading cause of cancer-related death amongst women worldwide. The relatively unchanging breast cancer-associated mortality rate is in part due to the existence of rare tumor cells (breast tumor initiating cells; BTIC) that possess stem-like properties permitting them to survive therapy and initiate disease recurrence. Hence, identifying agents capable of eradicating these cells would be a favourable therapeutic strategy to improve the durability of breast cancer remissions. To achieve the latter objective our lab screened over 35,000 small molecules for their capacity to inhibit the viability of BTIC-enriched mouse tumor cells. Unexpectedly, several antagonists of the serotonin (5-hydroxytryptamine; 5-HT) transporter and select receptors were among the hit compounds identified in the screen. This thesis aims to establish a connection between serotonergic activity and BTIC. We accomplished the latter by assessing whether components of the 5-HT signaling system are expressed in mouse and human breast tumor cells and whether inhibition of their activity affects BTIC frequency using multiple orthogonal assays. Our data suggest that breast tumor cells of both mouse and human origin express the components necessary for 5-HT synthesis, activity and metabolism and that inhibition of these proteins with selective antagonists reduces the capacity of these cells to form tumorspheres. We demonstrate that highly selective antagonists of SERT and HTR5A target BTIC as established ex vivo cell transplantation assays. We also discovered that these agents synergize with chemotherapy in vivo to affect the growth of mouse breast tumor allografts and human breast tumor xenografts. To validate the molecular targets of these agents, we attempted to phenocopy their effects in functional assays by knocking out their respective genes using CRISPR-Cas9 technology. Collectively, this thesis contributes to an understanding of how 5-HT signaling affects BTIC and identifies serotonergic antagonists as novel anticancer agents. / Dissertation / Doctor of Philosophy (PhD) / Despite improvements in screening technologies and the development of targeted therapies breast cancer remains the second leading cause of cancer-related death among Canadian women. Whereas the current standard of care is effective at treating the majority of patients diagnosed with breast cancer, there remains a substantial proportion of patients that experience relapse after undergoing therapy. Recurrence is due in part to the existence of rare, stem-like tumor cells, termed breast tumor-initiating cells (BTIC) that are insensitive to existing anticancer agents. Hence, identifying drugs capable of targeting these cells is a desirable goal. To pursue the latter, our lab screened approximately 35,000 compounds for their capacity to affect the growth of BTIC-enriched tumor cell populations. Among the hit compounds were antagonists of the serotonin transporter and serotonin receptors, including FDA-approved psychiatric medications. Here, we explore a connection between serotonin-related proteins and BTIC activity with the aim of identifying novel therapeutic agents.

Serotonin signaling

Breast tumor initiating cells

Investigating the Influence of Nanotopography on the Migratory State of Glioblastoma Multiforme Cells

Beliveau, Alexander

28 January 2016

Glioblastoma multiforme (GBM) is an aggressive Grade IV astrocytoma with a poor survival rate. This is largely due to the GBM tumor cells migrating away from the primary tumor site along white matter tracts and blood vessels leading to secondary tumor sites. It is unknown whether the microenvironment nanotopography influences the biomechanical properties of the tumor cells. Although these tumor cells have an innate propensity to migrate, we believe that the nanotopography changes the biomechanical properties to enhance the migratory phenotype. To study this, we used an in vitro polycaprolactone aligned nanofiber film that mimics the nanotopography of the white matter tracts and blood vessels to investigate the mechanical properties of the GBM tumor cells. Our data demonstrate that the cytoskeletal stiffness, traction force, and focal adhesion area are inherently lower in invasive GBM tumor cells compared to healthy astrocytes. Moreover, the tumor cytoskeletal stiffness was significantly reduced when cultured on the aligned nanofiber films compared to smooth and randomly aligned nanofibers films. Analysis of gene expression also showed that tumor cells cultured on the aligned nanotopography upregulated key migratory genes and downregulated key proliferative genes. In addition, cell cycle analysis exhibited a reduced proliferative state on aligned nanofibers, highlighting the dichotomy between proliferation and migration observed in GBM. Finally, focal adhesions of tumor cells were larger and more elliptical when grown on the aligned fibers, suggesting a more migratory state. Therefore, our data demonstrate that the invasive potential is elevated when the tumor cells are cultured on an aligned nanotopography. This in vitro model can further be used to identify the GBM tumor cells’ response in a mimetic in vivo tumor microenvironment and elucidate how the aligned nanotopography transduces into altered gene and protein expression, thus providing a mechanism to target to inhibit the enhanced migratory behavior observed in these cells.

Cytoskeletal stiffness

Migration

Cancer initiating cells

Nanotopography

Glioblastoma multiforme

Targeting triple negative human breast cancer with omega-3 docosahexaenoic acid (DHA) and tocotrienol

Xiong, Ailian

10 October 2013

Triple negative breast cancers (TNBCs) account for ~15-20% of human breast cancers in Western countries. TNBCs are associated with poor prognosis and a low five year survival rate due, in part, to high rates of tumor recurrence, multi-drug resistance, metastasis, and therapeutic toxicity. Tumor initiating cells (TICs) or cancer stem cells (CSCs) are proposed to be responsible for the origin and maintenance of tumors as well as cancer recurrence, metastasis and drug resistance. Nutritionally-based low- to non-toxic therapeutic nutrients that eliminate both bulk tumor cells (non-TICs) and TICs have potential for prevention and treatment of primary and metastatic cancers, including TNBCs. Omega-3 fatty acid-docosahexaenoic acid (DHA) and certain vitamin E compounds [gamma- and delta- tocopherols [mathematical symbols] and tocotrienols [mathematical symbols]], separately and in combination, were investigated for their ability to eliminate non-TICs and TICs in human TNBCs and the mechanisms of action were studied. DHA induced apoptosis in several human TNBC cell lines via activation of endoplasmic-reticulum stress (ER stress) mediated C/EBP (CCAAT/enhancer binding protein) homologous protein (CHOP)/death receptor-5 (DR5) pro-apoptotic signaling involving caspases-8 and 9. DHA eliminated TICs as measured by elimination of aldehyde dehydrogenase active (ALDH⁺) population and inhibition of mammosphere formation. DHA eliminated TICs via suppression of phosphorylated Signal transducers and activators of transcription 3 (pStat-3) as well as downstream mediators cellular myelocytomatosis oncogene (c-Myc) and cyclin D1. SiRNA to Stat-3 reduced the number of ALDH⁺ TNBCs cells and reduced pStat-3, c-Myc, and cyclin D1 mediators, showing that Stat-3 is necessary for maintaining ALDH⁺ population and that c-Myc and cyclin D1 are downstream mediators of Stat-3. Studies also demonstrated that vitamin E compounds possess distinct anticancer activities. In summary, studies provide novel insights into therapeutic potential of DHA and certain vitamin E compounds for treatment of TNBCs. / text

Vitamin E

Apoptosis

Breast cancer

Tumor initiating cells

Docosahexaenoic acid

Interplay Between Cell of Origin and Oncogenic Activation in Glioma

Jiang, Yiwen

January 2012

Glioma is the most frequent primary tumor of the central nervous system. By using the RCAS/tv-a mouse glioma model, we have studied mechanisms controlling glioma development and the effect of cell of origin on these processes. SOX5 was identified as a brain tumor locus in a retroviral insertional mutagenesis screen of PDGF-B induced mouse gliomas. Here we found that SOX5 could suppress PDGFB-induced glioma development particularly in Ink4a-/- mice. Analysis of putative PDGF-B signaling pathways revealed that the underlying mechanism could involve the activation of AKT and p27, which caused an acute cellular senescence. When cultured in a highly selective serum free medium, glioma-initiating cells could be isolated from mouse GBMs and their self-renewal and proliferation was independent on exogenous EGF and FGF2. Addition of serum into the medium induced aberrant differentiation that was reversible. Specific depletion of viral PDGF-B demonstrated that PDGF-B was necessary for stemness and tumorigenicity of GICs by preventing them to differentiate. Subsequently, by applying the same culture conditions, GICs of APC, NSC and OPC origins were isolated from mouse GBMs. GICs derived from NSCs exhibited higher self-renewal, faster proliferation and more potent tumorigenicity than those of APC or OPC origin. Furthermore, addition of 5% serum significantly inhibited the proliferation of APC- and OPC-derived GICs, but did not in NSC-derived GICs. Transcriptome analysis revealed that GICs of the same cell of origin displayed distinct expression profiles. In the last study, we showed that OPCs could serve as the origin for astrocytic glioma. Results from immunostainings revealed that these tumors might belong to a different molecular subtype than the oligodendroglial tumors induced in OPCs. We also found differences in tumorigenic potential between OPCs in neonatal and adult mice, which suggest that developmental age of the cell of origin is important for its susceptibility to oncogenic transformation.

Glioma

PDGF

cell of origin

Sox5

glioma initiating cells

CD146 is a novel marker for highly tumorigenic cells and a potential therapeutic target in malignant rhabdoid tumor / CD146は悪性ラブドイド腫瘍の腫瘍形成細胞を同定しかつ治療標的である

Noudomi, Seishiro

23 September 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19965号 / 医博第4155号 / 新制||医||1017(附属図書館) / 33061 / 京都大学大学院医学研究科医学専攻 / (主査)教授 野田 亮, 教授 伊達 洋至, 教授 山下 潤 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

CD146

Malignant rhabdoid tumor

Tumor initiating cells

Antibody

Apoptosis

490

THE USE OF NICOTINIC ACETYLCHOLINE RECEPTOR ANTAGONISTS TO TARGET BREAST TUMOR-INITIATING CELLS

Beilschmidt, Melissa Kathleen

11 1900

The high rate of relapse often seen in breast cancer patients has been suggested to be the result of a small subset of chemotherapy-resistant cancer stem cells (CSCs), believed to be responsible for initiating tumor formation. These CSCs possess the capability to self-renew and give rise to a hierarchy of cells which makes up the bulk of a tumor. Neurotransmitters have been suggested to influence CSC self-renewal and proliferation capabilities, and antagonists of neurotransmission pathways have been implicated as possible treatment methods for chemo-resistant tumors. Using nicotinic acetylcholine receptor (nAChR) antagonists in sphere-forming assays, we have identified a very promising candidate compound: MG624. We found this compound to have a high selectivity for sphere-forming cells over non-sphere-forming cells in vitro, in a dose-dependent relationship, across a panel of cell lines as well as in patient-derived xenograft cells. This was validated in two ex vivo assays, where tumor formation was significantly delayed in mice injected with MG624-treated HCC1954 cells at both the IC50 and IC90 of the compound, indicating that MG624 does indeed target functional BTICs. MG624 was also found to synergize with both taxotere and doxorubicin chemotherapies in vitro, and shrink tumors in NOD/SCID mice when combined with taxotere in vivo. MG624 in combination with taxotere was found to induce apoptosis, and prevent cells from entering into the M-phase of the cell cycle. Interestingly, MG624 was found to eliminate intratumoral fibroblasts in combination with taxotere, despite taxotere being found to recruit fibroblasts to the tumor site when used on its own. Most importantly, the combination of MG624 and taxotere was found to significantly delay tumor progression/relapse in mice, indicating that MG624 may be an excellent candidate compound to one day be combined with chemotherapy to provide durable remission to breast cancer patients. / Thesis / Master of Science (MSc)

Identifying the Signaling Pathways Downstream of the Serotonin Receptor 5A in Breast Cancer

Shakeel, Mirza Shahbaz

January 2019

Breast cancer therapy resistance and disease recurrence are driven by an infrequent population of stem-like tumor cells, termed breast cancer stem cells or tumor-initiating cells (BTIC). Whereas drugs that target BTIC could be combined with conventional therapies to provide durable remissions, identifying such agents has been difficult. To achieve the latter, our lab screened more than 35,000 compounds for their capacity to reduce the activity of BTIC-enriched mouse mammary tumorspheres, wherein we identified numerous antagonists of multiple serotonin receptors (HTRs). The serotonergic antagonist that prevented sphere formation with the highest potency is a highly selective antagonist of HTR5A, SB-699551. We subsequently demonstrated that this agent affects BTIC activity in breast tumor cell lines representative of all clinical and molecular subtypes of breast cancer. Whereas the primary target of SB-699551 is known, the downstream signaling pathways responsible for its anti-BTIC effect remains enigmatic. The goal of this thesis work was to elucidate the signaling pathways downstream of HTR5A in human breast tumor cell lines. We used a phospho-proteomic approach to establish that treatment of human SB-699551 affects the phosphorylation of proteins involved in the Gi-coupled and the PI3K/AKT/mTOR signaling axes. Moreover, we demonstrated that selective antagonists of PI3K, AKT, and mTOR phenocopied the effect of SB-699551 in tumorsphere forming assays. Taken together, our data suggests that SB-699551 elicits its effect through the PI3K/AKT/mTOR signaling pathways downstream of HTR5A. / Thesis / Master of Health Sciences (MSc) / Accumulating data suggests that the progression of breast cancer is driven by a rare population of breast tumor-initiating cells (BTIC). BTIC lie dormant during conventional therapy and initiate recurrence after such therapies are withdrawn. Hence, there is an urgent need to develop drugs that target BTIC that can be combined with the current standard of care to improve the durability of remission. With the latter objective in mind, our lab previously determined that antagonists of serotonin signaling target BTIC. One of the agents that we identified in our screen inhibits the activity of serotonin receptor 5A (HTR5A). The exact signaling mechanism whereby inhibition of HTR5A leads to a loss in BTIC activity was enigmatic. Hence, this thesis aims to elucidate the signaling pathways downstream of HTR5A in breast cancer. Knowledge of the latter will help identify a plausible mechanism in addition to identifying biomarkers of therapy efficacy.

Breast Cancer

Proteomics

Serotonin

Breast tumor-initiating cells

Lab on a chip rare cell isolation platform with dielectrophoretic smart sample focusing, automated whole cell tracking analysis script, and a bioinspired on-chip electroactive polymer micropump

Anders, Lisa Mae

18 July 2014

Dielectrophoresis (DEP), an electrokinetic force, is the motion of a polarizable particle in a non-uniform electric field. Contactless DEP (cDEP) is a recently developed cell sorting and isolation technique that uses the DEP force by capacitavely coupling the electrodes across the channel. The cDEP platform sorts cells based on intrinsic biophysical properties, is inexpensive, maintains a sterile environment by using disposable chips, is a rapid process with minimal sample preparation, and allows for immediate downstream recovery. This platform is highly competitive compared to other cell sorting techniques and is one of the only platforms to sort cells based on phenotype, allowing for the isolation of unique cell populations not possible in other systems. The original purpose of this work was to determine differences in the bioelectrical fingerprint between several critical cancer types. Results demonstrate a difference between Tumor Initiating Cells, Multiple Drug Resistant Cells, and their bulk populations for experiments conducted on three prostate cancer cell lines and treated and untreated MOSE cells. However, three significant issues confounded these experiments and challenged the use of the cDEP platform. The purpose of this work then became the development of solutions to these barriers and presenting a more commercializable cDEP platform. An improved analysis script was first developed that performs whole cell detection and cell tracking with an accuracy of 93.5%. Second, a loading system for doing smart sample handling, specifically cell focusing, was developed using a new in-house system and validated. Experimental results validated the model and showed that cells were successfully focused into a tight band in the middle of the channel. Finally, a proof of concept for an on-chip micropump is presented and achieved 4.5% in-plane deformation. When bonded over a microchannel, fluid flow was induced and measured. These solutions present a stronger, more versatile cDEP platform and make for a more competitive commercial product. However, these solutions are not just limited to the cDEP platform and may be applicable to multitudes of other microfluidic devices and applications. / Master of Science

Dielectrophoresis

Contactless Dielectrophoresis

Lab on a Chip

Sample Enrichment

Tumor Initiating Cells

A novel theranostic strategy for MMP-14 expressing glioblastomas impacts survival

Mohanty, S., Chen, Z., Li, K., Ribeiro Morais, Goreti, Klockow, J., Yerneni, K., Pasani, L., Chin, F.T., Mitra, S., Cheshier, S., Chang, E., Gambhir, S.S., Rao, J., Loadman, Paul, Falconer, Robert A., Daldrup-Link, H.E.

28 June 2017

Yes / Glioblastoma (GBM) has a dismal prognosis. Evidence from preclinical tumor models and human trials indicates the role of GBM initiating cells (GIC) in GBM drug resistance. Here, we propose a new treatment option with tumor enzyme-activatable, combined therapeutic and diagnostic (theranostic) nanoparticles, which caused specific toxicity against GBM tumor cells and GICs. The theranostic cross-linked iron oxide nanoparticles (CLIO) were conjugated to a highly potent vascular disrupting agent (ICT) and secured with a matrix-metalloproteinase (MMP-14) cleavable peptide. Treatment with CLIO-ICT disrupted tumor vasculature of MMP-14 expressing GBM, induced GIC apoptosis and significantly impaired tumor growth. In addition, the iron core of CLIO-ICT enabled in vivo drug tracking with MR imaging. Treatment with CLIO-ICT plus temozolomide achieved tumor remission and significantly increased survival of human GBM bearing mice by more than 2 fold compared to treatment with temozolomide alone. Thus, we present a novel therapeutic strategy with significant impact on survival and great potential for clinical translation. / Heike E Daldrup-Link, NIH, R21CA176519 and R21CA190196; Sanjiv Sam Gambhir, NIH, 1U54CA199075; Jessica Klockow, NCI training grant, T32CA118681, Robert A. Falconer, University of Bradford, UoB-66031

Glioblastoma

Glioblastoma initiating cells

Imaging

Therapy and theranostic nanoparticle