Talks

Presenting Author

Sheema Khan

Presentation Type

Oral Presentation

Discipline Track

Biomedical Science

Abstract Type

Research/Clinical

Abstract

Introduction: Cellular stress is known to function in synergistic cooperation with oncogenic mutations during tumorigenesis to drive cancer progression. Oncogenic RAS is a strong inducer of a variety of pro-tumorigenic cellular stresses, and also enhances the ability of cells to tolerate these stresses through multiple mechanisms that leads to resistance to chemotherapy and to therapies that target the RAS pathway. Pancreatic Ductal Adenocarcinoma (PDAC) patients exhibit extremely poor prognosis. KRAS mutation on codon-12 is present in 70–95% of PDAC cases and it drives stress-adaptive mechanisms, PDAC growth and progression. Galectin-1 (Gal-1) is present in both PDAC and stromal cells, being involved in tumor microenvironment, immune cell activation and metastasis. Therefore, this study discusses the efficiency of combined inhibition of mutated KRASG12D and Gal-1 inhibition to effectively suppress PDAC growth and progression. For this we have delivered KRASG12D inhibiting siRNA (siKRASG12D) using a superparamagnetic iron oxide nanoparticle (SPION) and a galectin inhibitor.

Methods: SPION nano-formulation was used to deliver siKRASG12D and investigate in conjunction with Gal-1 inhibitor for its anticancer efficacy. Particles were investigated for size, physico-chemical characterization (Dynamic light scattering), hemocompatibility (hemolysis assay) and the complexation of siKRAS (gel retardation assay). Cellular internalization and uptake of the particles were investigated. Anti-cancer efficacy was determined using in vitro functional assays for cell viability (MTT), migration (Boyden chambers), invasion (Matrigel), clonogenicity, tumor spheroid formation, and in a KrasG12D;LSL-Trp53R172H syngeneic mouse model.

Results: Our results demonstrate that SP-siKRAS efficiently internalized in PDAC cells and suppressed KRASG12D as well as its downstream targets, YAP and PDL-1. Combined targeting of siKRAS and Gal-1 inhibited cell proliferation, clonogenicity, migration, and invasion of PDAC cells and tumor spheroid growth in 3D cell models, which recapitulate the heterogeneity and pathophysiology of PDAC. We have used -KrasG12D;LSL-Trp53R172H syngeneic mouse model of PDAC for investigating efficacy of combined SP-siKRAS formulation and galectin-1 inhibitor. Our results showed that the combination treatment inhibited the fibrotic tumor growth and increased survival rate. The combined treatment increased infiltration of total T cell population and CD8+T cells, reduced the population of myeloid-derived suppressor cells (MDSCs) by 50% (CD45+, CD3-, CD11b+, Ly6C high, Ly6G-) and T-Regulatory cells (Treg) by 57% (FoxP3+CD25+CD45+CD3+) and increased memory T cells by 34% in mice.

Conclusion: This gene therapy targeting KRAS G12D mutation with a Gal-1 inhibition has a potential to modulate the oncogenic network, stress-adaptive mechanisms and tumor microenvironment resulting in the repression of growth, metastasis, chemoresistance, and improvement in patient survival. This study will develop a novel sustainable therapeutic approach to target PDAC growth and improve patient survivability.

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Targeted Treatment for KRAS12D For PDAC Treatment

Introduction: Cellular stress is known to function in synergistic cooperation with oncogenic mutations during tumorigenesis to drive cancer progression. Oncogenic RAS is a strong inducer of a variety of pro-tumorigenic cellular stresses, and also enhances the ability of cells to tolerate these stresses through multiple mechanisms that leads to resistance to chemotherapy and to therapies that target the RAS pathway. Pancreatic Ductal Adenocarcinoma (PDAC) patients exhibit extremely poor prognosis. KRAS mutation on codon-12 is present in 70–95% of PDAC cases and it drives stress-adaptive mechanisms, PDAC growth and progression. Galectin-1 (Gal-1) is present in both PDAC and stromal cells, being involved in tumor microenvironment, immune cell activation and metastasis. Therefore, this study discusses the efficiency of combined inhibition of mutated KRASG12D and Gal-1 inhibition to effectively suppress PDAC growth and progression. For this we have delivered KRASG12D inhibiting siRNA (siKRASG12D) using a superparamagnetic iron oxide nanoparticle (SPION) and a galectin inhibitor.

Methods: SPION nano-formulation was used to deliver siKRASG12D and investigate in conjunction with Gal-1 inhibitor for its anticancer efficacy. Particles were investigated for size, physico-chemical characterization (Dynamic light scattering), hemocompatibility (hemolysis assay) and the complexation of siKRAS (gel retardation assay). Cellular internalization and uptake of the particles were investigated. Anti-cancer efficacy was determined using in vitro functional assays for cell viability (MTT), migration (Boyden chambers), invasion (Matrigel), clonogenicity, tumor spheroid formation, and in a KrasG12D;LSL-Trp53R172H syngeneic mouse model.

Results: Our results demonstrate that SP-siKRAS efficiently internalized in PDAC cells and suppressed KRASG12D as well as its downstream targets, YAP and PDL-1. Combined targeting of siKRAS and Gal-1 inhibited cell proliferation, clonogenicity, migration, and invasion of PDAC cells and tumor spheroid growth in 3D cell models, which recapitulate the heterogeneity and pathophysiology of PDAC. We have used -KrasG12D;LSL-Trp53R172H syngeneic mouse model of PDAC for investigating efficacy of combined SP-siKRAS formulation and galectin-1 inhibitor. Our results showed that the combination treatment inhibited the fibrotic tumor growth and increased survival rate. The combined treatment increased infiltration of total T cell population and CD8+T cells, reduced the population of myeloid-derived suppressor cells (MDSCs) by 50% (CD45+, CD3-, CD11b+, Ly6C high, Ly6G-) and T-Regulatory cells (Treg) by 57% (FoxP3+CD25+CD45+CD3+) and increased memory T cells by 34% in mice.

Conclusion: This gene therapy targeting KRAS G12D mutation with a Gal-1 inhibition has a potential to modulate the oncogenic network, stress-adaptive mechanisms and tumor microenvironment resulting in the repression of growth, metastasis, chemoresistance, and improvement in patient survival. This study will develop a novel sustainable therapeutic approach to target PDAC growth and improve patient survivability.

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