Surgery (RMH) - Theses

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Type: PhD thesis × Subject: Cancer × Subject: Glioblastoma × Subject: Invasion ×

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    Deconstructing the brain tumour microenvironment using multimodal analysis
    Dinevska, Marija ( 2023-06)
    Gliomas are a type of astrocytoma and are the most prevalent type of primary brain cancer, with the most aggressive form being glioblastoma (GBM), with a median survival of only 15 months. Rapid tumour cell invasion and progression is a significant challenge for patients and their oncologists and neurosurgeons, reducing treatment efficacy and inevitably leading to tumour recurrence. Cancer cells thrive by responding and adapting to cellular and non-cellular cues in the tumour microenvironment, including the extracellular matrix (ECM). However, little is known about ECM composition in brain tumours and how the ECM evolves during disease progression, and the impact of the ECM on immune cell localisation, cancer cell signalling and the functional activity of tumour cells. The PI3K and MAPK signalling pathways are typically dysregulated in GBM, and can activate the downstream transcription factor, CREB, which has been reported to regulate GBM malignancy. By integrating multiplex immunohistochemistry, histopathological staining, and spatial tissue analysis, as well as in vitro 3D GBM models, I investigated ECM composition in low- and high-grade glioma, and the spatial relationship between neoplastic cells, immune cells and the ECM in GBM tissue. My results demonstrated a grade-dependent increase in ECM deposition and an upregulation of type I and type IV collagen mRNA expression, which is associated with poor survival in patients with GBM. GBM cells and vascular cells were identified as key contributors of ECM protein deposition in GBM. Spatial analysis demonstrated that T-cells were predominantly located in perivascular niches in ECM-rich regions, while macrophages exhibited more efficient infiltration into tumour cell-rich regions. Extensive tissue remodelling contributes to cellular compartmentalisation in the tumour microenvironment and this compartmentalisation correlates with PI3K, MAPK and CREB activity, and histopathological hallmarks, including angiogenesis, tumour cell density and cell invasion. Inhibiting the PI3K and MAPK signalling pathways reduced 3D cell invasion and also facilitated a shift in the ECM composition, from a more fibrotic to a less fibrotic state. Taken together, the results suggest that the accumulation of ECM plays an important role in GBM progression, affecting both immune cell distribution and cancer cell signalling. These findings suggest that targeting the PI3K and MAPK pathways to ‘normalise’ the ECM could serve to enhance the efficacy of existing and novel therapies for GBM.
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    Evaluating the role of invadopodia in glioma invasion and response to therapeutics
    Whitehead, Clarissa Anne ( 2021)
    Glioblastoma (GBM) is the most prevalent and aggressive form of glioma, and is associated with an extremely poor prognosis, with a low median patient survival time of just 15 months post-diagnosis with the current therapeutic approach known as the Stupp protocol, consisting of surgical resection, followed by radiotherapy (RT) and concomitant chemotherapy with temozolomide (TMZ). A significant contributing factor that impacts the survival of GBM patients is the highly infiltrative nature of GBM cells, which prevents complete tumour resection and also limits the capacity of targeted therapies to effectively reach the infiltrating tumour cells. Consequently, these tumours can exhibit high rates of recurrence, appearing within months following the completion of the first round of treatment and can also demonstrate minimal response to further rounds of RT/TMZ treatment. Evidence suggests that the efficacy of current therapeutic approach may be compromised by an enhanced invasive phenotype that is displayed by the GBM cells that survive the current treatment protocol (Wild-Bode, Weller et al. 2001, Cordes, Hansmeier et al. 2003, Hegedus, Zach et al. 2004, Trog, Fountoulakis et al. 2006, Trog, Yeghiazaryan et al. 2006, Steinle, Palme et al. 2011). The targeting of the enhanced invasive abilities exhibited by RT/TMZ treated GBM cells could provide a potential therapeutic approach for improving patient outcome, however the mechanisms utilised by invasive GBM cells following the current treatment are not well understood. As GBM cells have been shown to form actin-rich membrane protrusions known as invadopodia that can facilitate invasion by degrading the surrounding ECM via highly localised proteolytic activity (Stylli, Kaye et al. 2008, Mao, Whitehead et al. 2017, Petropoulos, Guichet et al. 2018), it is possible that the enhanced invasive capabilities of GBM cells post- RT/TMZ treatment may be mediated by invadopodia. In this thesis, the role of invadopodia in GBM cell invasion and response to RT/TMZ treatment was investigated. Using clinically relevant doses of RT and TMZ, it was demonstrated that the enhanced invasive capabilities of GBM cells post-RT/TMZ treatment may be attributed to an increase in invadopodia formation and activity. The role of intracellular communication between GBM cells via small extracellular vesicles (sEVs) was also investigated, highlighting the ability of GBM cell line secreted sEVs to transfer a pro-invadopodia phenotype to recipient GBM cells, as well as their potential to facilitate an enhanced pro-invadopodia phenotype following RT/TMZ treatment. Demonstrating the potential to dualistically target invadopodia activity and sEV secretion to overcome RT/TMZ-induced GBM invasion, the addition of the microtubule-targeting agent Vinorelbine Tartrate (VT) alongside RT/TMZ reduced the enhanced secretion of sEVs, in accordance with previous data from our laboratory showing VT also reduces invadopodia activity in GBM cells surviving RT/TMZ (Whitehead, Nguyen et al. 2018). Lastly, GBM cell lines and their corresponding secreted sEVs were subjected to comprehensive proteomic profiling to identify proteins that may facilitate invadopodia formation and activity following exposure to RT/TMZ treatment, thereby contributing to enhanced GBM invasion. Collectively, this work highlights the contributing role of invadopodia and sEVs to the pro-invasive abilities of GBM cells, and provides insight into the dysregulated proteomic landscape of GBM cells and sEVs following exposure to RT/TMZ treatment that may contribute to enhanced invasive capacity, which may ultimately assist in the development of novel adjuvant therapeutic strategies to improve the clinical efficacy of RT and TMZ treatment.