Frédéric Lopez
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Figure S6 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S5 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Data from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
Cytidine deaminase (CDA) functions in the pyrimidine salvage pathway for DNA and RNA syntheses and has been shown to protect cancer cells from deoxycytidine-based chemotherapies. In this study, we observed that CDA was overexpressed in pan…
Figure S1 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Supplementary Table from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
Supplemetary table
Figure S4 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Data from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
Cytidine deaminase (CDA) functions in the pyrimidine salvage pathway for DNA and RNA syntheses and has been shown to protect cancer cells from deoxycytidine-based chemotherapies. In this study, we observed that CDA was overexpressed in pan…
Figure S2 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S4 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S5 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S1 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S3 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Supplementary Table from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
Supplemetary table
Figure S2 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S3 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Figure S6 from Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
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Cytidine Deaminase Resolves Replicative Stress and Protects Pancreatic Cancer from DNA-Targeting Drugs Open
Cytidine deaminase (CDA) functions in the pyrimidine salvage pathway for DNA and RNA syntheses and has been shown to protect cancer cells from deoxycytidine-based chemotherapies. In this study, we observed that CDA was overexpressed in pan…
View article: Supplemental Figure 3 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 3 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S3. Podoplanin staining of lymphatic vessels
View article: Supplemental Figure 7 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 7 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S7. Tumor growth after NSAID treatment
View article: Supplemental Figure 1 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 1 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S1. Method to quantify lymphatic vessels diameter
View article: Supplemental Figure 1 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 1 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S1. Method to quantify lymphatic vessels diameter
View article: Supplemental Figure 5 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 5 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S5. VEGF-D 5'UTR mRNA exhibits two structural forms that allow the binding of different proteins
View article: Supplemental Figure 7 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 7 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S7. Tumor growth after NSAID treatment
View article: Supplemental Figure 8 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 8 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S8. Schematic representation of VEGF-D synthesis in tumor cells
View article: Supplemental Figure 4 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 4 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S4. Lymphangiogenesis and tumor gowth are not affected by 4T1 or 67NR lentiviral transduction
View article: Supplemental Figure 6 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 6 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S6. Polysome profiling of 4T1 cells
View article: Supplementary Figure Legend from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplementary Figure Legend from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Supplementary figure legend
View article: Supplemental Figure 2 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 2 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S2. Expression of endogenous VEGF-D in mice tissues
View article: Data from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Data from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
The vascular endothelial growth factor VEGF-D promotes metastasis by inducing lymphangiogenesis and dilatation of the lymphatic vasculature, facilitating tumor cell extravasion. Here we report a novel level of control for VEGF-D expression…
View article: Supplemental Figure 8 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis
Supplemental Figure 8 from Nucleolin Promotes Heat Shock–Associated Translation of VEGF-D to Promote Tumor Lymphangiogenesis Open
Figure S8. Schematic representation of VEGF-D synthesis in tumor cells