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Modulation of the tumor microenvironment by the CXCR4 antagonist AMD3100 in pancreatic and colorectal adenocarcinomaSmoragiewicz, Martin January 2019 (has links)
No description available.
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A characterisation of the tumour microenvironment in murine pancreatic cancer as a target for combination immunotherapyWells, Richard John Beringer January 2015 (has links)
No description available.
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Harnessing Oncolytic Virus-mediated Anti-tumour ImmunityLemay, Chantal 25 September 2012 (has links)
Treatment of permissive tumours with the oncolytic virus (OV) VSV-Δ51 leads to a robust anti-tumour T cell response, which contributes to efficacy; however, many tumours are not permissive to in vivo treatment with VSV-Δ51. In an attempt to channel the immune stimulatory properties of VSV-Δ51 and broaden the scope of tumours that can be treated by an OV, a potent oncolytic vaccine platform was developed, consisting of tumour cells infected with VSV-Δ51. I demonstrate that prophylactic immunization with this infected cell vaccine (ICV) protected mice from subsequent tumour challenge, and expression of GM-CSF by the virus (VSVgm-ICV) increased efficacy. Immunization with VSVgm-ICV in the VSV-resistant B16-F10 model induced maturation of dendritic cells, natural killer (NK) cells, and T cells. I demonstrate that this approach is robust enough to control the growth of established and spontaneous tumours. This strategy is broadly applicable because of VSV’s extremely broad tropism, allowing nearly all cell types to be infected at high MOIs in vitro, where the virus replication kinetics outpace the cellular IFN response. It is also personalized to the unique tumour antigen(s) displayed by the cancer cell. Histone deacetylase inhibitors (HDIs) can augment viral replication, making them particularly interesting complements to OV therapy. However, the impact of HDIs on the generation and re-stimulation of immune responses remains to be clearly elucidated. Along with my collaborators at McMaster University, I demonstrate that MS-275, but not SAHA, selectively depletes naïve and regulatory lymphocytes. Memory lymphocytes that are being boosted remain unscathed and even have enhanced cytokine production, potentially as a consequence of the depleted lymphocyte compartment. This leads to a delay in anti-VSV neutralizing antibodies and T cell responses. Interestingly, HDI treatment of B16-F10 cells appears to inhibit VSV replication but allows for a longer persistence within the tumour. When used in an oncolytic prime/boost vaccination model, MS-275 potently enhanced survival. Though the anti-tumour immune response is enhanced, a near complete reduction in autoimmune vitiligo is observed with MS-275 administration. Therefore, this HDI uniquely modulates the immune response to enhance anti-tumour immunity and decrease the anti-viral response, while also decreasing autoimmune sequelae.
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Improving the biological activity of CpG ODN by linking it to carbon nanotubesTomporowski, Jason Scott 19 January 2010 (has links)
Preventative immunotherapeutic treatments have been an area of great interest to combat infectious disease because of the ability to stimulate the hosts immune system which prepares the host to fight pathogenic microbes. The immunotherapeutic approach requires the use of an immune stimulating molecule that is able to boost the hosts immune response. A major problem exists that these immune stimulating molecules are often very expensive and require a large dose to be effective. To reduce the cost of using these molecules, a delivery system can be used which is able to lower the effective dose of the immune stimulant while not causing any toxic effects towards the hosts health. In this study, the immune stimulating molecules synthetic unmethylated cytidine-phosphate-guanosine oligodeoxynucleotides were attached non-covalently to multi-walled carbon nanotubes. The use of carbon nanotubes as a delivery mechanism could result in a lower effective dose able to stimulate a protective immune response in a chicken model. In this study, we first assessed which of the non-covalant linkages was ideal for linking the immune stimulant to the carbon nanotubes. This was conducted by looking at which method of linkage would allow the best cellular proliferation and transcriptional activation of selected innate immune genes. Once an appropriate linkage method had been selected, cellular uptake studies were conducted to establish that cytidine-phosphate-guanosine oligodeoxynucleotides were delivered to intracellular target receptors. After cellular uptake was demonstrated, it was important that the carbon nanotubes linked to the immune stimulant do not cause toxicity towards the host. To measure toxicity, in vitro studies were conducted to observe cell viability post treatment with carbon nanotube linked immune stimulant. Further studies were conducted on any alterations to the immune stimulants ability to activate immune cells by studying the pathway of macrophage activation. The protective ability of the molecules was then measured by the ability to protect chickens from a lethal challenge with S. typhimurium. Once the protective nature of the molecules was established, the mechanism of immune stimulation was examined by in vivo cell recruitment and in vitro cytokine production. These studies indicate that linking cytidine-phosphate-guanosine oligodeoxynucleotides to carbon nanotubes can lower the effective dose of the immune stimulant without altering the biological function of the molecule.
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Harnessing Oncolytic Virus-mediated Anti-tumour ImmunityLemay, Chantal 25 September 2012 (has links)
Treatment of permissive tumours with the oncolytic virus (OV) VSV-Δ51 leads to a robust anti-tumour T cell response, which contributes to efficacy; however, many tumours are not permissive to in vivo treatment with VSV-Δ51. In an attempt to channel the immune stimulatory properties of VSV-Δ51 and broaden the scope of tumours that can be treated by an OV, a potent oncolytic vaccine platform was developed, consisting of tumour cells infected with VSV-Δ51. I demonstrate that prophylactic immunization with this infected cell vaccine (ICV) protected mice from subsequent tumour challenge, and expression of GM-CSF by the virus (VSVgm-ICV) increased efficacy. Immunization with VSVgm-ICV in the VSV-resistant B16-F10 model induced maturation of dendritic cells, natural killer (NK) cells, and T cells. I demonstrate that this approach is robust enough to control the growth of established and spontaneous tumours. This strategy is broadly applicable because of VSV’s extremely broad tropism, allowing nearly all cell types to be infected at high MOIs in vitro, where the virus replication kinetics outpace the cellular IFN response. It is also personalized to the unique tumour antigen(s) displayed by the cancer cell. Histone deacetylase inhibitors (HDIs) can augment viral replication, making them particularly interesting complements to OV therapy. However, the impact of HDIs on the generation and re-stimulation of immune responses remains to be clearly elucidated. Along with my collaborators at McMaster University, I demonstrate that MS-275, but not SAHA, selectively depletes naïve and regulatory lymphocytes. Memory lymphocytes that are being boosted remain unscathed and even have enhanced cytokine production, potentially as a consequence of the depleted lymphocyte compartment. This leads to a delay in anti-VSV neutralizing antibodies and T cell responses. Interestingly, HDI treatment of B16-F10 cells appears to inhibit VSV replication but allows for a longer persistence within the tumour. When used in an oncolytic prime/boost vaccination model, MS-275 potently enhanced survival. Though the anti-tumour immune response is enhanced, a near complete reduction in autoimmune vitiligo is observed with MS-275 administration. Therefore, this HDI uniquely modulates the immune response to enhance anti-tumour immunity and decrease the anti-viral response, while also decreasing autoimmune sequelae.
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The isolation and identification of MHC-bound CTL peptide epitopes expressed by tumour cellsHill, Seran Catherine January 2000 (has links)
No description available.
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CD200: A Novel Therapeutic Target for Chronic Lymphocytic LeukemiaWong, Karrie 08 January 2013 (has links)
The ability of cancer cells to escape anti-tumor immune responses is acknowledged as one of the hallmarks of cancer. Overexpression of immunoregulatory molecules is one mechanism responsible for the immunsuppressive network that is characteristic of the tumor microenvironment.
In this thesis, we investigated the role of CD200, a potent immunoregulatory molecule, in Chronic Lymphocytic Leukemia. We showed that functional blockade of CD200 on lymphoma cells or primary CLL cells, both of which express CD200 at high levels, augmented cytotoxic killing of these cells by effector CD8+ T cells in vitro. We also identified and characterized a previously unrecognized soluble form of CD200, sCD200, present in elevated levels in CLL plasma when compared to plasma from controls.
The data reported show that patients with high sCD200 levels have more aggressive disease, inferring that sCD200 may be a novel prognostic marker for CLL. The in vivo function of sCD200 was investigated for its ability to support engraftment of CLL splenocytes in NOD.SCID mice. Infusion of sCD200hi CLL plasma, but not sCD200lo normal plasma, enhanced engraftment of CLL-splenocytes in vivo, an effect which was abrogated by depletion of sCD200 from CLL plasma. The prolonged engraftment of CLL cells seen in this model (>6 months) suggests these mice represent a useful pre-clinical model for drug screening. The effect of CD200 blockade was tested in this model, and was found to be as effective in eliminating engrafted CLL cells as rituximab. Investigation of the mechanisms leading to the release of sCD200 from CLL cells showed that sCD200 was produced following ectodomain shedding by ADAM proteases and MMPs.
Results from studies reported in this thesis support the hypothesis that CD200 plays a major role in CLL biology, and suggests it may represent a novel therapeutic target for CLL.
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CD200: A Novel Therapeutic Target for Chronic Lymphocytic LeukemiaWong, Karrie 08 January 2013 (has links)
The ability of cancer cells to escape anti-tumor immune responses is acknowledged as one of the hallmarks of cancer. Overexpression of immunoregulatory molecules is one mechanism responsible for the immunsuppressive network that is characteristic of the tumor microenvironment.
In this thesis, we investigated the role of CD200, a potent immunoregulatory molecule, in Chronic Lymphocytic Leukemia. We showed that functional blockade of CD200 on lymphoma cells or primary CLL cells, both of which express CD200 at high levels, augmented cytotoxic killing of these cells by effector CD8+ T cells in vitro. We also identified and characterized a previously unrecognized soluble form of CD200, sCD200, present in elevated levels in CLL plasma when compared to plasma from controls.
The data reported show that patients with high sCD200 levels have more aggressive disease, inferring that sCD200 may be a novel prognostic marker for CLL. The in vivo function of sCD200 was investigated for its ability to support engraftment of CLL splenocytes in NOD.SCID mice. Infusion of sCD200hi CLL plasma, but not sCD200lo normal plasma, enhanced engraftment of CLL-splenocytes in vivo, an effect which was abrogated by depletion of sCD200 from CLL plasma. The prolonged engraftment of CLL cells seen in this model (>6 months) suggests these mice represent a useful pre-clinical model for drug screening. The effect of CD200 blockade was tested in this model, and was found to be as effective in eliminating engrafted CLL cells as rituximab. Investigation of the mechanisms leading to the release of sCD200 from CLL cells showed that sCD200 was produced following ectodomain shedding by ADAM proteases and MMPs.
Results from studies reported in this thesis support the hypothesis that CD200 plays a major role in CLL biology, and suggests it may represent a novel therapeutic target for CLL.
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Host-tumour interactions in Myeloma :Brown, Ross Duncan. Unknown Date (has links)
Thesis (PhD)--University of South Australia, 2002.
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Immunomodulating properties of iscoms /Johansson, Margaretha, January 1900 (has links) (PDF)
Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniv. / Härtill 4 uppsatser.
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