Molecular chaperone expression and function in breast cancer and breast cancer stem cells

Sterrenberg, Jason Neville

January 2012

The Cancer Stem Cell (CSC) theory suggests that cancers arise from and are maintained by a subpopulation of cancer cells with stem cell properties. Molecular chaperones are key components of cellular regulation. The overexpression of chaperones has become synonymous with cancer cells with chaperones being recognized as bona fide anti-cancer drug targets. Although chaperone activity has been characterized in cancer cells, very little is known about the cellular functions of chaperones in cancer stem cells. We set out to compare the expression of selected molecular chaperones in non-stem cancer cell and cancer stem cell enriched populations isolated from breast cancer lines, in order to identify chaperones differentially expressed between the two populations for further biological characterization. In order to isolate breast cancer stem cells from the MCF-7 and MDA-MB-231 breast cancer cell lines, three cancer stem cell isolation and identification techniques were utilized based on (1) cell surface marker expression (CD44+/CD24- and CD44+/CD24-/EpCAM+ phenotypes), (2) aldehyde dehydrogenase enzyme activity (ALDHHi) and (3) ability to grow in anchorage-independent conditions. The MDA-MB-231 and MCF-7 breast cancer cell lines displayed CD44+/CD24- cell populations with the MCF-7 cell line additionally displaying a large CD44+/CD24-/EpCAM+ population. Although both cell lines showed similar ALDHHi populations, they differed substantially with respect to anchorage-independent growth. MCF-7 cells were able to form anchorage-independent colonies while the MDA-MB-231 cell line was not. Anchorage-independent MCF-7 cells showed enrichment in CD44+/CD24- and CD44+/CD24-/EpCAM+ cells compared to adherent MCF-7 cells, and were selected for gene expression studies. Gene expression studies identified 22 genes as being down-regulated at the mRNA level in the anchorage-independent MCF-7 cells, while only 2 genes (BAG1 and DNAJC12) were up-regulated. The down-regulation of selected chaperones in anchorage independent MCF-7 cells was confirmed at the protein level for selected chaperones, including DNAJB6, a type II DNAJ protein shown to be involved in the regulation of Wnt signaling. In order to characterize the effect of DNAJB6 expression on BCSCs we developed a pCMV mammalian expression plasmid for both DNAJB6 isoforms (DNAJB6L and DNAJB6S). We successfully constructed mutants of the conserved histidine-proline-aspartic acid (HPD) motif of the J domain of DNAJB6S and DNAJB6L. These constructs will allow the analysis of the role of DNAJB6 in cancer stem cell function. To the best of our knowledge, this is the first report to focus on the comparative expression of molecular chaperones in normal and cancer stem cell enriched breast cancer populations.

Breast -- Cancer

Stem cells

Cancer cells

Directed differentiation of endodermal cells from mouse embryonic stem cells

Kim, Peter Tae Wan

11 1900

Pluripotent embryonic stem cells hold a great promise as an unlimited source of tissue for treatment of chronic diseases such as Type 1 diabetes and chronic liver disease. Various attempts have been made to produce cells that can serve as precursors for pancreas and liver. By using all-trans-retinoic acid, basic fibroblast growth factor, dibutyryl cAMP, and cyclopamine, an attempt has been made to produce definitive endoderm and subsequently cells that can serve as pancreatic and hepatocyte precursors from mouse embryonic stem cells. By using retinoic acid and basic-FGF, in the absence of embryoid body formation, mouse embryonic stem cells were differentiated at different culture periods. Four protocols of varying lengths of culture and reagents and their cells were analyzed by quantitative PCR, immunohistochemistry and static insulin release assay for markers of trilaminar embryo, pancreas and hepatocytes. Inclusion of DBcAMP and extension of culture time resulted in cells that display features of definitive endoderm by expression of Sox 17 and FOXA2 and minimal expression of primitive endoderm and other germ cell layers such as ectoderm and mesoderm. These cells produced insulin and C-peptide and secreted insulin in a glucose responsive manner. However, they seem to lack mature insulin secretion mechanism. There was a production of hepatocyte markers (AFP-2 and transthyretin) but there was insufficient data to assess for convincing production of hepatocytes. In summary, one of the protocols produced cells that displayed characteristics of definitive endoderm and they may serve as pancreatic endocrine precursors. / Surgery, Department of / Medicine, Faculty of / Graduate

Embrynoic stem cells

Diabetes

Definitive endoderm

Development of embryonic stem cells expressing endogenous levels of a fluorescent protein fused to the telomere binding protein TRF1

Miller, Shelley Bonnie

11 1900

Telomeres are the repetitive DNA sequence and associated proteins found at the ends of linear chromosomes. They have a role in biological processes including meiosis and aging as well as implications in a number of genomic instability disorders and cancers. Telomeres maintain genomic stability by protecting chromosome ends from terminal fusions and misidentification as DNA damage sites. Their wide range of functions has resulted in an increased interest in developing tools to study the dynamics of telomeres in live cells. To do this, current studies use the ubiquitously expressed protein Telomere Repeat Factor 1 (TRF1) tagged with a fluorescent protein. TRF1 is a negative regulator of telomere length that binds exclusively to telomere repeats. Over-expression of the fluorescent protein fused to TRF1 has been a useful tool to track telomere movement. The foci formed by the tagged TRF1 protein accurately represent the number of telomeres expected in the cells and the localization is maintained throughout the cell cycle. A caveat with this system is that over-expression of TRF1 leads to accelerated telomere shortening, as well as replication defects that can stall telomere replication. These caveats make it difficult to draw conclusions about telomere dynamics based solely on observations of cells over-expressing fluorescently tagged TRF1. To eliminate problems associated with protein over-expression, I have tried to develop knock-in embryonic stem (ES) cells expressing fluorescently tagged TRF1 from the endogenous Trf1 promoter. To do this, I have used a recombineering technique using Bacterial Artificial Chromosomes (BACs). BAC recombineering allows for the direct knock-in of a fluorescent tag into the mouse Trf1gene locus. Genetic constructs with the correct sequence inserts have been obtained and have been used for transfection of ES cells. While no correctly targeted ES cells have been identified so far, the expectation is that ES cell lines with correctly targeted fluorescently tagged TRF1 will be obtained in the near future. Such lines will be used to study telomere dynamics in ES cells, differentiated cells generated from ES cells, as well as to generate mice. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Telomeres

TRF1

Embryonic stem cells

Recombineering

Stochasticity and order : studies of keratinocyte proliferation

Roshan, Amit

January 2014

A central tenet of stem cell biology has been that proliferating tissues are maintained through a cellular hierarchy comprising of self-renewing stem cells at the apex, multiple lineage-restricted short-lived progenitor cells, and post-mitotic differentiated cells. The wide range of colony sizes in cultured human keratinocytes has been taken to support this hypothesis. Contrary to this model, researchers using genetic lineage tracing in mouse epidermis have inferred a single progenitor population for homeostasis, and a quiescent stem cell population activated upon wounding or genetic mutation. To study the proliferative behaviour of human keratinocytes, I used live imaging in vitro at single cell resolution. This shows two modes of proliferation: Type 1 cell division is stochastic with equal odds of generating dividing or non-dividing progeny, while Type 2 cell division predominantly produces two dividing daughters. These two modes are sufficient to explain the entire range of colony sizes seen after 7-12 days of culture and does not require a spectrum of proliferative ability. This insight provides a simple way to study the effects of external factors on cell fate. To exemplify this, I observed the effects of epidermal growth factor (EGF) and the Wnt agonist R-spondin on proliferation. Here I find proliferation in type 2 colonies changes by changing the proportion of cells dividing. This has implications for the limited success of EGF therapies in clinical trials following burns. To examine clonal contributions to wound repair, I used the mouse oesophageal epithelium which is exclusively composed of, and maintained by, a single progenitor population. I developed a micro-endoscopic wounding technique that produced localised superficial wounds. Here, I found that these wounds healed by uniform contribution from surrounding keratinocytes, demonstrating that reserve stem cells are not obligatory for wound repair. In summary, my work shows that human keratinocytes in vitro have two, and only two, modes of proliferation: a stochastic mode that is insensitive to external EGF signalling, and a EGF-sensitive exponential mode. Additionally, proliferation during wound repair can occur with stochastically dividing progenitors, and does not obligate stem cell recruitment in vivo.

611

Spatial organisation of proto-oncogenes in human haematopoietic progenitor cells

Ewels, Philip Andrew

January 2013

The eukaryotic cell nucleus is a highly organised organelle, with distinct specialised sub- compartments responsible for specific nuclear functions. Within the context of this functional framework, the genome is organised, allowing contact between specific genomic regions and sub-compartments. Previous work has shown that genes in both cis and trans can make specific contacts with each other. I hypothesise that such a preferred juxtaposition may impact the propensity for specific cancerinitiating chromosomal translocations to occur. In this thesis, I describe how I have extended and developed a ligation based proximity assay known as enriched 4C. I have coupled this technique with high throughput sequencing to determine genomic regions that spatially co-associate with the proto-oncogenes MLL, ABL1 and BCR. In addition to further developing the laboratory protocol, I have created bioinformatics tools used in the analysis of the sequencing data. I find that the association profiles of the three genes show strong correlation to the binding profile of RNA polymerase II and other active marks, suggesting that transcribed genes have a propensity to associate with other transcribed regions of the genome. Each gene also exhibits a unique repertoire of preferred associations with specific regions of the genome. Significantly, I find that the most frequent trans association of BCR is telomeric chromosome 9, encompassing its recurrent translocation partner gene ABL1. Interestingly, ABL1 is not at the maximum point of interaction. I use DNA-fluorescence in-situ hybridisation to validate the e4C association. My data supports a hypothesis that gene transcription has a direct role on genome organisation. I suggest that preferred co-associations of genes at transcription factories may promote the occurrence of specific chromosomal translocations.

572.8

Transcriptional functions of the corepressor Sin3A in skin

Cox, Claire

January 2013

Upon activation in epidermal stem cells, the proto-oncogene c-Myc triggers their exit from the stem cell compartment resulting in an increase in progenitor cell proliferation and an induction in terminal differentiation. Whether c-Myc plays a direct transcriptional role in epidermal stem cell differentiation was unknown. The exploration of c-Myc's transcriptional roles at the epidermal differentiation complex (EDC), a locus essential for skin maturation demonstrated that binding of c-Myc to the EDC can simultaneously recruit and displace specific sets of differentiation-specific transcriptional regulators to EDC genes. Among these factors, Sin3A acts as a transcriptional co-repressor and was initially discovered via its direct interaction with Mxi1 and Mxd1, which are antagonists of the Myc family network. As such, I concentrated on the role of Sin3A as a potential opposing factor to c-Myc activity in the epidermis. To analyse the role of Sin3A in regulating epidermal stem cell fate in vivo, I generated a number of transgenic mouse models. To determine whether Sin3A functions in hair follicle stem cells, I inducibly deleted Sin3A in the hair follicle bulge, where quiescent stem cells reside. However, lack of Sin3A in the hair bulge did not cause any aberrant phenotype and I concluded that Sin3A is dispensable for hair follicle homeostasis. I next analysed a mouse model in which Sin3A is inducibly deleted in the basal layer of the epidermis. Deletion of Sin3A resulted in a severe disruption of epidermal homeostasis-namely due to increases in proliferation and differentiation. Further investigation demonstrated that this phenotype is driven by enhanced genomic recruitment of c-Myc to the epidermal differentiation complex and reactivation of c-Myc target genes involved in cellular proliferation. I found that Sin3A causes de-acetylation of the c-Myc protein to directly repress c-Myc’s transcriptional activity and is antagonistic to c-Myc in the interfollicular epidermis. I hypothesised that simultaneous deletion of Sin3A and c-Myc might return the skin to normality. Indeed, when Sin3A and Myc are concurrently deleted, proliferation and differentiation levels returned to normal. These results demonstrate how levels of Sin3A and c-Myc must be carefully balanced for epidermal homeostasis to be maintained. Decreased expression of Sin3A has been linked to tumour susceptibility in other tissues for example in non-small cell lung carcinoma making Sin3A a candidate tumour suppressor gene. I therefore considered that loss of Sin3A may lead to increased susceptibility to skin cancer. To investigate this I performed pilot experiments using UVB irradiation of skin that has one copy of Sin3A deleted in the basal layer of the epidermis. Under normal conditions, these mice have no identifiable phenotype, but pilot experiments demonstrated that after short term and long term UVB irradiation, they exhibit increased epidermal thickness and proliferation relative to controls. This recapitulated the phenotype observed when Sin3A is inducibly deleted in the interfollicular epidermis and further demonstrates the role of SinA as an inhibitor of proliferation in this tissue. Overall, these results demonstrate that an interplay between the opposing functions of Sin3A and c-Myc are necessary to ensure that there is balanced homeostasis in the interfollicular epidermis.

616.02

Molecular Mechanisms of Myogenesis in Stem Cells

Ryan, Tammy

January 2011

Embryonic stem cells (ESCs) represent a promising source of cells for cell replacement therapy in the context of muscle diseases; however, before ESC-based cell therapy can be translated to the clinic, we must learn to modulate cell-fate decisions in order to maximize the yield of myocytes from this systems. In order to gain a better understanding of the myogenic cell fate, we sought to define the molecular mechanisms underlying the specification and differentiation of ESCs into cardiac and skeletal muscle. More specifically, the central hypothesis of the thesis is that myogenic signalling cascades modulate cell fate via regulation of transcription factors. Retinoic acid (RA) is known to promote skeletal myogenesis, however the molecular basis for this remains unknown. We showed that RA expands the premyogenic progenitor population in mouse stem cells by directly activating pro-myogenic transcription factors such as Pax3 and Meox1. RA also acts indirectly by activating the pro-myogenic Wnt signalling cascade while simultaneously inhibiting the anti-myogenic influence of BMP4. This ultimately resulted in a significant enhancement of skeletal myogenesis. Furthermore, we showed that this effect was conserved in human embryonic stem cells, with implications for directed differentiation and cell therapy. The regulation of cardiomyogenesis by the Wnt pathway was also investigated. We identified a novel interaction between the cardiomyogenic transcription factor Nkx2.5 and the myosin phosphatase (MP) enzyme complex. Interaction with MP resulted in exclusion of Nkx2.5 from the nucleus and inhibition of its transcriptional activity. Finally, we showed that this interaction was modulated by phosphorylation of the Mypt1 subunit of MP by ROCK, downstream of Wnt3a. Treatment of differentiating mouse ESCs with Wnt3a resulted in exclusion of Nkx2.5 from the nucleus and a subsequent failure to undergo terminal differentiation into cardiomyocytes. This likely represents part of the molecular basis for Wnt-mediated inhibition of terminal differentiation of cardiomyocytes. Taken together, our results provide novel insight into the relationship between myogenic signalling cascades and downstream transcription factors and into how they function together to orchestrate the myogenic cell fate in stem cells.

embryonic stem cells

myogenesis

transcription factor

"Role of SRY-related HMG box (SOX)-7 in Skeletal Muscle Development" and "Effect of an extracellular matrix on skeletal and cardiac muscle development"

Ebadi, Diba

January 2011

A complex network of transcription factors, which are regulated by signalling molecules, is responsible in coordinating the formation of differentiated skeletal and cardiac myocytes from undifferentiated stem cells. The present study aims to understand and compare the transcriptional regulation of skeletal and/or cardiac muscle development in the absence of Sox7 or in the presence of a collagen-based matrix in P19 embyonal carcinoma (EC) and mouse embryonic stem (ES) cells. First, knock-down of Sox7 , by shRNA, in muscle inducing conditions (+DMSO) and in the absence of RA (-RA), decreased muscle progenitor transcription factor and myogenic regulatory factor (MRF) levels, suggesting that Sox7 is necessary for myogenesis. However, knock-down of Sox7 in the presence of RA (+RA) and DMSO increased expression of muscle progenitor markers and MRFs, suggesting that Sox7 is inhibitory for myogenesis +RA. Furthermore, Sox7 overexpression enhanced myogenesis -RA, but inhibited myogenesis and enhanced neurogenesis +RA. These results suggest an important interplay between RA signalling and Sox7 function during P19 differentiation. Second, Q-PCR analysis showed that compared to the mouse ES cells differentiated on the regular TC plates, differentiation on the collagen matrices had a higher expression of skeletal and cardiac precursors, MRFs and terminal differentiation markers. Collagen alone enhanced myotube formation. The enhanced collagen matrix, containing the oligosaccharide sialyl LewisX (sLeX), specifically enhanced cardiomyogenesis. These studies have added to our understanding of the transcriptional regulation of premyogenic mesoderm factors and the role of Sox7 in this process. In addition these studies provide a vision for possible use of biomaterials in directed differentiation of stem cells for the purpose of cell therapy.

Stem cells

Biomaterials

Transcription factors

Myogenesis

Paracrine Engineering of Human Cardiac Stem Cells with Insulin-Like Growth Factor 1 Promotes Cell Survival to Enhance Myocardial Repair

Jackson, Robyn

January 2014

Insulin-like growth factor (IGF-1) is a potent pro-survival cytokine that is not robustly expressed by human cardiac stem cells (CSCs). Here, we explore the mechanism underlying IGF-1 enhanced cardiac repair by CSCs. Human CSCs underwent lentiviral- mediated somatic gene transfer of IGF-1 to boost cytokine secretion without adversely blunting the overall cytokine signature of CSCs. In vitro studies demonstrated that IGF-1 provided paracrine and autocrine support that reduced apoptosis by CSCs and cardiomyoctes. In vivo experiments demonstrated that IGF-1 increased CSC-mediated cardiac repair by enhancing salvage of reversibly damaged myocardium and transplanted cell survival.

Stem cells

Cardiac repair

Cytokine

Apoptosis

Definition of the human embryonic stem cell niche in vitro

Soteriou, Despina

January 2012

The unique pluripotent character of human embryonic stem cells (hESCs) places them in the forefront of scientific research, especially as they hold great promise for application in regenerative medicine, as well as drug discovery and toxicity analyses. Conventionally hESCs are cultured on mitotically inactivated mouse embryonic fibroblasts (MEFs) that are derived from E13.5 mouse embryos. One of the biggest challenges in the hESC field is the development of a reproducible and defined hESC culture system that would eliminate batch-to-batch variability of the MEFs as well as exposure to feeder cells that makes hESCs less applicable for clinical use. Previous studies have shown that maintenance of pluripotency can be achieved using Matrigel, a mixture of ECM components, or ECM derived from MEFs or human fibroblasts (Xu, et al., 2001, Klimanskaya, et al., 2005). Other groups have succeeded in culturing feeder-free hESCs by using extracellular matrix (ECM) proteins, such as fibronectin, vitronectin or laminin, as substrates for hESC culture in the absence of feeders, confirming that ECM plays a key role in maintaining hESC growth (Amit, et al., 2004, Braam, et al., 2008, Baxter, et al., 2009, Rodin, et al., 2010).The aim of this work was to investigate the ECM deposited by MEF feeder cells and to isolate and identify proteins in the ECM that support undifferentiated growth of hESCs in the absence of feeders. We have investigated whether matrices derived from different passage feeders differ in their ability to support pluripotency. I also assessed the integrin receptor profile of hESCs in order to define the mechanisms of ECM engagement. ECM was extracted from two strains of feeder cells, CD1 x CD1 and MF1 x CD1, at passages 4 (early passage), 9 and 14 (late passage), and assessed for its ability to support hESC self-renewal over at least 3 passages. Tandem mass spectrometry was used to analyse the ECM composition of each MEF line, thereby allowing a comparison between different passages and different cell lines. More than 100 proteins were identified for each sample, the majority of which were ECM proteins and shared between different passage feeders. As predicted, fibronectin, which is known to support hESC self-renewal was the most prevalent species in all MEF-derived matrices. Furthermore a proteomic analysis of matrix derived from hESCs cultured in feeder-free conditions on fibronectin coating substratum revealed a number of proteins shared between supportive MEF populations and hESC, suggesting other potential candidates that may either assist or interfere with the maintenance of pluripotent hESCs. Of the proteins identified fibrillin-1, perlecan, fibulin-2 were tested as substrates for culturing hESCs in the absence of feeders, with the prospect of developing an optimised feeder-free culturing system that uses a combination defined animal-free substrates. Finally this study sought to dissect the interaction between ECM and growth factors and how these extrinsic factors may affect self-renewal and maintenance of pluripotency-associated gene expression. Interruption of hESC attachment, as well as removal of growth factors appeared to affect transcript levels of pluripotency genes, OCT4 and NANOG, suggesting that the microenvironment can influence hESC fate.

616.02774