The Characterization and Therapeutic Targeting of CD133 in Human Glioblastoma

Salim, Sabra

January 2021

CD133, a pentaspan glycoprotein, has long been known to represent aggressive, stem-like populations across various human malignancies. While its expression correlates with numerous clinical outcomes including disease progression, metastasis, recurrence, and poor overall survival in numerous cancers, little is currently known about its function. In the brain cancer glioblastoma (GBM), CD133-expressing cells have previously been shown to initiate tumours, evade therapy and interestingly, self-renew, a key property of cancer stem cells. With an implied signalling role in driving self-renewal, we aim to elucidate the role of CD133 in glioblastoma. To understand the role of CD133, we aim to study its protein-protein interactions using the proximity-dependent labelling technique known as miniTurboID. By tagging proteins of interest with a promiscuous biotin ligase at both protein termini, potential interactors can be biotinylated and identified by subsequent mass spectrometry. While miniTurboID has traditionally been performed by synthetic transgenes expressing the tagged proteins of interest in commercial cell lines, overexpression may not recapitulate its native function. Thus, using CRISPR technology, we aim to insert the miniTurboID ligase at both the N- and C-terminus of CD133 in patient-derived human GBM lines. Although little is currently known about CD133 function, development of targeted therapies has presented a promising strategy in pre-clinical studies. In the Singh Lab, we previously developed a chimeric antigen receptor T-cell, or CAR-T, comprised of a T-cell expressing a synthetic receptor capable of recognizing a tumor-associated antigen and activating cytolytic-killing directed towards the target cell. Currently, CAR-T therapies are autologous, or patient-derived, in nature which may host a myriad of concerns including patient-specific qualitative and quantitative T-cell dysfunction, inconsistent generation of CAR products, and availability to rapidly progressing patients. To circumvent this concern, “off-the-shelf”, donor-derived or allogeneic CAR-T products may be generated for use in GBM patients. However, in addition to CAR integration, allogeneic products must be additionally modified to eradicate expression of the endogenous TCR, as this would induce a phenomenon known as graft versus host disease, in which healthy tissues are targeted. Thus, in this thesis, we show gene editing potential in human GBMs to perform an endogenous genomic knock-in of miniTurboID. With the identification of interacting proteins, defining the subsequent functionality of CD133 may elucidate oncogenic cellular programs, and highlight common nodes of interaction within divergent cell signaling pathways. To develop an allogeneic CAR-T product, we designed a two-step approach in which the CAR sequence was integrated into the TCR gene for simultaneous knock-out. We later show early pre-clinical efficacy in comparison to traditional autologous CAR-T in our patient-derived models of human GBM. Thus, by using CD133 as a centralizing concept in this thesis, we ultimately hope to develop our biological understanding of CD133, while testing the therapeutic development of a donor-derived CAR-T therapy. / Thesis / Master of Science (MSc) / Glioblastoma (GBM) is one of the most common malignant brain tumors in adults. Despite an aggressive therapy regimen, almost all patients relapse 7-9 months post-diagnosis. Therapy failure and poor patient outcome may be attributed to a small population of cells known as glioblastoma stem cells, or GSCs, that are able to escape therapy and seed disease recurrence. GSCs are most notably identified by the cell surface protein CD133, which has previously been shown to associate with pro-tumor properties including treatment resistance, tumor growth, maintenance, progression and metastasis. While expression of CD133 in cancer has been heavily characterized, little is currently known about its function. One such avenue to understand its mechanism of action in cancer, and more particularly GBM, is to define its interactions with other proteins. Protein-protein interactions play a pivotal part as the backbone of signalling pathways that drive tumor development and growth. Therefore, defining and mapping the CD133 interaction network may help us understand how this protein governs regulation of GSCs, and ultimately, GBM progression. While the biology of CD133 has yet to be elucidated, targeting CD133 on GSCs has presented a promising therapeutic strategy for patients with GBM. Previously in the Singh Lab, we developed an engineered T-cell therapy, known as a CAR-T, that can recognize CD133 to induce tumor cell death. While this showed success in our animal models of human GBM, other considerations must be addressed on its path to clinical development. As of current, CAR-T therapies are generated from T-cells taken from cancer patients. This hosts a myriad of concerns including the quality of patient T-cells, the time and cost to manufacture, and its availability for patients with rapidly progressing disease. To circumvent this issue, donor-derived CAR-T cells can be genetically engineered for safe usage in GBM patients as a readily available, “off-the-shelf” therapy. To define the function of CD133, we have attempted to use a technique known as BioID, which tags the protein of interest with a smaller biotin ligase. This biotin ligase can subsequently tag proteins that come within the vicinity of CD133, that may later be identified by sequencing as potential interactors. As current use of BioID may not reliably mimic the interaction of CD133, we sought to genetically engineer human GBM lines with the BioID protein to more closely resemble tumor-relevant behaviours of CD133. To develop a donor-derived CAR-T therapy, we similarly used genetic engineering of T-cells to ensure specific targeting of tumor cells with CD133, while sparing healthy tissues. By using CD133 as a centralizing concept in this thesis, we ultimately hope to develop our biological understanding of CD133, while testing the therapeutic development of a donor-derived CAR-T therapy.

Cancer

Glioblastoma

BioID

Proteins

CAR-T

Immunotherapy

Allogeneic

T-cell

CD133

Brain tumor initiating cells

Cancer stem cells

MODELING COLORECTAL CANCER DRUG RESISTANCE USING THREE-DIMENSIONAL TUMOR MODELS

Lamichhane, Astha

02 August 2023

No description available.

Biomedical Engineering

Oncology

Defining immunophenotypic signatures of stem cells

Sukhdeo, Kumar

23 August 2013

No description available.

Biology

Biomedical Research

Cellular Biology

Pathology

Lgr5, stem cells

cancer stem cells

colon cancer

retina, amacrine cells

liver

progenitor cells

NOTCH SIGNALING REGULATES STEMNESS AND METABOLISM OF LIPOSARCOMA CELLS

Pei Chieh Tien (14232620)

09 December 2022

<p>Liposarcoma (LPS) arises from adipocytes and is a rare malignancy among all cancer types, but represents the most common form of soft tissue sarcoma, with approximately 2,000 new cases reported annually. Clinically, liposarcomas are classified into four subtypes based on histological analysis: well-differentiated liposarcoma (WDLPS), dedifferentiated liposarcoma (DDLPS), myxoid/round cell liposarcoma, and pleomorphic liposarcoma. Although histological analysis provides useful information for identifying various liposarcoma subtypes, treatment options rely on a fundamental understanding of driver mutations and molecular mechanisms underlying tumorigenesis. This thesis focuses on elucidating important driver mutations and therapeutic targets to eradicate DDLPS. Notch signaling is an evolutionarily conserved signaling pathway essential for organ development and stem cell function. Aberrant Notch signaling underlies the tumorigenesis of many cancers including LPS. However, the specific role of Notch signaling in development of LPS remains elusive. In Chapter 2, I provide evidence demonstrating that Notch signaling plays a key role in cancer stem cells (CSCs), also referred to as tumor-initiating cells (TICs), that drive aggressive DDLPS. I used serial transplantation to enrich and generate a murine DDLPS cell line with constitutively activated Notch signaling (NICDOE). My analyses revealed that NICDOE DDLPS cells are heterogeneous and contain TICs that express cancer stem cell markers. Chapter 3 elucidates how Notch signaling regulates CSCs of LPS. I analyzed human LPS samples to establish a strong correlation between Notch signaling activation and tumor marker expression and prognosis. I further performed gene expression and metabolic analyses of NICDOE DDLPS cells. These assays revealed that NICDOE reduced mitochondrial respiration in DDLPS cells, which was associated with diminished expression of peroxisome proliferator-activated receptor gamma coactivator 1α (PGC-1α), a master regulator of mitochondrial biogenesis. CRISPR/CAS9-mediated deletion of the NICDOE cassette rescued the expression of PGC-1α and mitochondrial respiration in DDLPS cells. Similarly, overexpression of PGC-1α was sufficient to rescue mitochondrial biogenesis in DDLPS cells. Together, these data demonstrate that Notch signaling regulates CSCs, at least partially by controlling PGC-1α mediated mitochondria biogenesis.</p>

Cell metabolism

NOTCH 1 Intracellular Domain Indicate

liposarcoma-associated

Cancer metabolism

Cancer Stem Cells Cells

Targeting Cancer Stem-LIike Cells in Human Esophageal Squamous Carcinoma Cell Lines by Curcumin

Almanaa, Taghreed N.

16 December 2013

No description available.

Biology

Molecular Biology

Cellular Biology

Esophageal cancer

Curcumin

Cancer stem cells

Tumorsphere

ALDH1A1

CD44

NF-kappaB

Aldefluor

Adherent Cells

ROLE OF NON-MUSCLE MYOSIN IIB IN BREAST CANCER INVASION

Thomas, Dustin G.

27 January 2016

No description available.

Biology

Cellular Biology

Molecular Biology

Myosin

Invasion

Metastasis

Breast Cancer

myh10

Cancer Stem Cells

Epithelial to Mesenchymal Transition

EMT

Neoplastic Human Embryonic Stem Cells as a Model of Radiation Resistance of Human Cancer Stem Cells

Dingwall, Steven

10 1900

<p>Recent studies have implicated that a small sub population of cells within a tumour, termed cancer stem cells (CSCs), have an enhanced capacity for tumour formation in multiple cancers and may be responsible for recurrence of the disease after treatment. Further work has suggest that CSCs are radioresistant relative to other cell types composing tumours, in several solid cancers. The genetic and phenotypic heterogeneity of malignant CSCs, as well as the difficulty associated with culturing these cells in vitro, limits the capacity to study the response of CSCs to ionizing radiation. Further, the absence of normal known counterparts for many CSCs has made it difficult to compare the radiation responses of CSCs with the normal stem cells required for post radiotherapy tissue regeneration. Here we have shown that transformed human embryonic stem cells (t-hESCs), showing features of neoplastic progression, produce tumours resistant to radiation relative to their normal counterpart. We further show that t-hESCs have a reduced capacity for radiation induced cell death via apoptosis and exhibit altered cell cycle arrest in vitro, relative to hESCs. We found that decreased levels of p53ser15, following DNA double strand break induction, is associated with this radiation resistance.</p> / Master of Science (MSc)

radiation resistance

cancer stem cells

embryonic stem cells

radiation

Medical Biophysics

Medical Sciences

Medicine and Health Sciences

Medical Biophysics

USING GENE EXPRESSION ANALYSIS TO GUIDE AND IDENTIFY TREATMENTS FOR BREAST CANCER PATIENTS

Hallett, Robin M.

10 1900

<p>Based on breast cancer clinical trial data accumulated over the last several decades it is obvious that standard breast cancer therapeutics extend survival in breast cancer patients. However, only a minority of patients within these trials derive benefit from treatment. In a population of breast cancer patients treated with adjuvant therapy after surgery, many patients are over-treated, as they would never experience relapse even without receiving adjuvant therapies. Among the remaining patients, some achieve durable remission from therapy, whereas others relapse despite therapy. Hence, there is an obvious need to develop biomarkers that can serve to identify these three populations of patients, such that only patients who are likely to benefit from available therapies are treated with these therapies, as well as to develop new therapies for the treatment of patients who aren’t afforded durable remission by approved treatments. Here, we present the identification of biomarkers to identify low risk breast cancer patients who experience excellent long-term survival even without adjuvant therapy. Conversely, high risk patients represent those patients most likely to benefit from intervention with aggressive treatment regimens. We also report on the identification of biomarkers which can predict the likelihood of response to approved chemotherapy regimens, which could be used to further stratify high risk patients into responders and non-responders. Finally, for high risk patients unlikely to be afforded durable remission from available therapies, we report on the identification of agents that target breast tumor-initiating cells, and may be effective for the treatment of these patients.</p> / Doctor of Philosophy (PhD)

Breast cancer

gene expression profiling

cancer stem cells

tumor-initating cells

biomarkers

Bioinformatics

Computational Biology

Genomics

Molecular Biology

Bioinformatics

Targeted Oncolytic Virotherapy Using Newcastle Disease Virus Against Prostate Cancer

Raghunath, Shobana

27 November 2012

Prostate cancer (CaP) is the second leading cause of cancer related deaths in men in the United States. Currently, androgen depletion is an essential strategy for CaP combined with surgery, chemotherapy and radiation. Hormone independent cancer stem cells escaping conventional therapy present a major therapeutic challenge. The available treatment regimens for hormone resistant CaP are only palliative and marginally increase survival. Therefore, novel strategies to eradicate CaP including stem cells are imperative. Oncolytic virus (OV) therapy is a novel approach that overcomes the limitations posed by radiation and chemotherapy. Oncolytic virotherapy of cancer is based on the use of replication competent, tumor selective viruses with limited toxicity. Newcastle Disease Virus (NDV), an avian paramyxovirus, is a safe and promising OV successfully used in many clinical trials. NDV is inherently tumor selective and cytotoxic but replication restricted in normal cells. But, systemically delivered NDV fails to reach solid tumors in therapeutic concentrations and also spreads poorly within the tumors due to barriers including complement, innate immunity and extracellular matrix. Overcoming these hurdles is paramount to realize the exceptional oncolytic efficacy of NDV. Therefore, we engineered the fusion (F) glycoprotein of NDV and generated a recombinant NDV (rNDV) cleavable exclusively by prostate specific antigen (PSA). The rNDV replicated efficiently and specifically only in prostate cancer (CaP) cells but failed to replicate in the absence of PSA. Further, PSA-cleavable rNDV caused specific lysis of androgen independent and dependent/responsive CaP cells with a mean effective concentration (EC50) ranging from 0.01 to 0.1 multiplicity of infection (MOI). PSA retargeted rNDV efficiently lysed three-dimensional prostaspheres, suggesting efficacy in vivo. Also, PSA-cleavable NDV failed to replicate in chicken embryos, indicating absence of pathogenicity to its natural host, chickens. Prostaspheres generated from DU-145 CaP cell line derived xenografts showed self-renewal, proliferative and clonogenic potential in vitro, and exhibited increased tumorigenicity in vivo. Embryonic stem and progenitor cell markers like Nanog, Nestin and CD44 were overexpressed in spheres as compared to the cell line suggesting prostaspheres comprise tumor-initiating cells from CaP. Xenograft and cell line derived prostaspheres were permissive for rNDV replication, when the fusion protein was activated by exogenous PSA. The EC50 against tumor initiating cells was 0.11-0.14 MOI, suggesting an excellent therapeutic margin for in vivo studies. PSA retargeting is likely to enhance the therapeutic index of rNDV owing to tumor restricted replication and enhanced fusogenicity. Our results suggest PSA retargeted rNDV selectively replicates and lyse PSA producing CaP cells including tumor-initiating cells and is a promising candidate for immediate Phase I/II clinical trials. / Ph. D.

Tumor initiating cells

Prostate cancer stem cells

Oncolytic virotherapy

Newcastle disease virus

Re targeting

Prostate specific antigen

Patterns of cancer cell sphere formation in primary cultures of human oral tongue squamous cell carcinoma and neck nodes

Saleem, Saira, Jamshed, A., Faisal, S., Hussain, R., Tahseen, M., Loya, A., Sutton, Chris W.

12 April 2014

Yes / Recently a sub-population of cells with stem cell characteristics, reported to be associated with initiation, growth, spread and recurrence, has been identified in several solid tumors including oral tongue squamous cell carcinoma (OTSCC). The aim of our pilot study was to isolate CD44+ cancer stem cells from primary cultures of OTSCC and neck node Level I (node-I) biopsies, grow cell spheres and observe their characteristics in primary cultures. Parallel cultures of hyperplastic lesions of tongue (non-cancer) were set up as a control. Immunohistochemistry was used to detect CD44/CD24 expression and magnetic activated cell sorting to isolate CD44+ cell populations followed by primary cell culturing. Both OTSCC and node-I biopsies produced floating spheres in suspension, however those grown in hyperplastic and node-I primary cultures did not exhibit self-renewal properties. Lymph node metastatic OTSCC, express higher CD44/CD24 levels, produce cancer cell spheres in larger number and rapidly (24 hours) compared to node negative OTSCC (1 week) and non-cancer specimens (3 weeks). In addition, metastatic OTSCC have the capacity for proliferation for up to three generations in primary culture. This in vitro system will be used to study cancer stem cell behavior, therapeutic drug screening and optimization of radiation dose for elimination of resistant cancer cells. / SKMCH&RC, Yorkshire Cancer Research

Oral tongue squamous cell carcinoma

Lymph node metastasis

Primary culture

Cancel cell sphere

Cancer stem cells

In vitro assay