Your search keyword '"Tahra K. Luther"' showing total 4 results

1. Co-transfer of tumor-specific effector and memory CD8+ T cells enhances the efficacy of adoptive melanoma immunotherapy in a mouse model

Author

Amanda Contreras, Megan V. Beems, Andrew J. Tatar, Siddhartha Sen, Prakrithi Srinand, M. Suresh, Tahra K. Luther, and Clifford S. Cho

Subjects

Adoptive transfer, Immunotherapy, T cell, Memory, Effector, Melanoma, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Adoptive cell transfer (ACT) is a promising cancer immunotherapeutic strategy that remains ineffective for a large subset of patients. ACT with memory CD8+ T cells (Tmem) has been shown to have superior efficacy compared to traditional ACT with effector CD8+ T cells (Teff). Teff and Tmem have complementary physiological advantages for immunotherapy, but previous publications have not examined ACT using a combination of Teff and Tmem. Methods Splenocytes harvested from Ly5.1+/C57BL/6 mice during and after infection with lymphocytic choriomeningitis virus (LCMV) were used to generate bona fide effector and memory CD8+ T cells specific for the LCMV epitope peptide GP33. Congenic Ly5.2+/C57BL/6 mice were inoculated with B16F10 melanoma cells transfected to express very low levels of GP33, then treated with ACT 7 days later with GP33-specific Teff, Tmem, or a combination of Teff + Tmem. Results Inhibition of melanoma growth was strongest in mice receiving combinatorial ACT. Although combinatorial ACT and memory ACT resulted in maximal intratumoral infiltration of CD8+ T cells, combinatorial ACT induced stronger infiltration of endogenous CD8+ T cells than Tmem ACT and a stronger systemic T cell responsiveness to tumor antigen. In vitro assays revealed rapid but transient melanoma inhibition with Teff and gradual but prolonged melanoma inhibition with Tmem; the addition of Tmem enhanced the ability of Teff to inhibit melanoma in a manner that could be reproduced using conditioned media from activated Tmem and blocked by the addition of anti-IL-2 blocking antibody. Conclusions These findings suggest that a novel combinatorial approach that takes advantage of the unique and complementary strengths of tumor-specific Teff and Tmem may be a way to optimize the efficacy of adoptive immunotherapy.

Published

2018

2. Supplementary Figures from RAD51 Mediates Resistance of Cancer Stem Cells to PARP Inhibition in Triple-Negative Breast Cancer

Author

Suling Liu, Max S. Wicha, Zhi-ming Shao, Shawn G. Clouthier, Justin Colacino, Trenton L. Baker, April Davis, Tahra K. Luther, Alex Fox, Li Shang, Michael D. Brooks, Ramdane Harouaka, Shoumin Bai, Joey Guy, Rachel Martin-Trevino, Monika L. Burness, and Yajing Liu

Abstract

Supplementary Figure S1. BRCA1 mutation confirmation and RAD51 gene expression in SUM149 cells. Supplementary Figure S2. RAD51 foci is associated with CSC population of BRCA1-mutant TNBC cells and effect of long-term PARP inhibition on RAD51. Supplementary Figure S3: Knockdown of RAD51 prevents foci formation in SUM149 and SUM159 cells. Supplementary Figure S4. The effect of RAD51 KD on TNBC viable cell count, CSCs, and cell cycle. Supplementary Figure S5. RAD51 KD sensitizes TNBC CSCs to PARPi. Supplementary Figure S6. Efficiency of RAD51 shRNA knockdown with additional shRNA vectors. Supplementary Figure S7. Knocking down RAD51 with two additional shRNA vectors also sensitizes CSCs to PARPi. Supplementary Figure S8. "Physiologic" RAD51 knockdown decreases cancer stem cells in SUM149 cells.

Published

2023

3. Supplementary figure legends from RAD51 Mediates Resistance of Cancer Stem Cells to PARP Inhibition in Triple-Negative Breast Cancer

Author

Suling Liu, Max S. Wicha, Zhi-ming Shao, Shawn G. Clouthier, Justin Colacino, Trenton L. Baker, April Davis, Tahra K. Luther, Alex Fox, Li Shang, Michael D. Brooks, Ramdane Harouaka, Shoumin Bai, Joey Guy, Rachel Martin-Trevino, Monika L. Burness, and Yajing Liu

Abstract

Supplementary figures 1-8 legends

Published

2023

4. Supplementary Methods, Figures 1 - 7 from HER2 Drives Luminal Breast Cancer Stem Cells in the Absence of HER2 Amplification: Implications for Efficacy of Adjuvant Trastuzumab

Author

Max S. Wicha, Hasan Korkaya, Daniel F. Hayes, Dafydd G. Thomas, Celina G. Kleer, Mark L. Day, Whitney A. Chadwick, Shawn G. Clouthier, Tahra K. Luther, Nader Tawakkol, Amber N. Heath, Nallasivam Palanisamy, Christopher L. Hall, April Davis, Stephanie Daignault, Kathleen Woods Ignatoski, Ahmed A. Quraishi, Tom F. Bersano-Begey, Scott J. Dawsey, Qin Zen, Fayaz Malik, Kathleen C. Day, and Suthinee Ithimakin

Abstract

PDF file - 491K, Supplementary Figure 3. Effect of trastazumab on stem cell marker expression. Supplementary Figure 2. Trastuzumab inhibits tertiary tumorsphere formation in luminal cell lines. Supplementary Figure 1. Representative FACS analysis demonstrating an overlap between HER2 expression and ALDH activity. Supplementary Figure 4. Trastuzumab treatment or HER2 gene knockdown reduces tumorsphere formation of MCF7 cells. Supplementary Figure 5. Rank mediated upreglation of HER2 expression in MCF7 cells. Supplementary Figure 6. Elevated HER2 expression in bone metastasis compared to matched primary luminal tumors is not due to HER2 gene amplification. Supplemental Figure 7. No significant differences in HER2 protein expression were found in matched primary tumors and bone metastasis in women with HER-positive breast cancer.

Published

2023