Your search keyword '"Kier, Melanie"' showing total 5 results

1. CTLA4 blockade abrogates KEAP1/STK11-related resistance to PD-(L)1 inhibitors

Author

Skoulidis, Ferdinandos, Araujo, Haniel A., Do, Minh Truong, Qian, Yu, Sun, Xin, Cobo, Ana Galan, Le, John T., Montesion, Meagan, Palmer, Rachael, Jahchan, Nadine, Juan, Joseph M., Min, Chengyin, Yu, Yi, Pan, Xuewen, Arbour, Kathryn C., Vokes, Natalie, Schmidt, Stephanie T., Molkentine, David, Owen, Dwight H., Memmott, Regan, Patil, Pradnya D., Marmarelis, Melina E., Awad, Mark M., Murray, Joseph C., Hellyer, Jessica A., Gainor, Justin F., Dimou, Anastasios, Bestvina, Christine M., Shu, Catherine A., Riess, Jonathan W., Blakely, Collin M., Pecot, Chad V., Mezquita, Laura, Tabbó, Fabrizio, Scheffler, Matthias, Digumarthy, Subba, Mooradian, Meghan J., Sacher, Adrian G., Lau, Sally C. M., Saltos, Andreas N., Rotow, Julia, Johnson, Rocio Perez, Liu, Corinne, Stewart, Tyler, Goldberg, Sarah B., Killam, Jonathan, Walther, Zenta, Schalper, Kurt, Davies, Kurtis D., Woodcock, Mark G., Anagnostou, Valsamo, Marrone, Kristen A., Forde, Patrick M., Ricciuti, Biagio, Venkatraman, Deepti, Van Allen, Eliezer M., Cummings, Amy L., Goldman, Jonathan W., Shaish, Hiram, Kier, Melanie, Katz, Sharyn, Aggarwal, Charu, Ni, Ying, Azok, Joseph T., Segal, Jeremy, Ritterhouse, Lauren, Neal, Joel W., Lacroix, Ludovic, Elamin, Yasir Y., Negrao, Marcelo V., Le, Xiuning, Lam, Vincent K., Lewis, Whitney E., Kemp, Haley N., Carter, Brett, Roth, Jack A., Swisher, Stephen, Lee, Richard, Zhou, Teng, Poteete, Alissa, Kong, Yifan, Takehara, Tomohiro, Paula, Alvaro Guimaraes, Parra Cuentas, Edwin R., Behrens, Carmen, Wistuba, Ignacio I., Zhang, Jianjun, Blumenschein, George R., Gay, Carl, Byers, Lauren A., Gibbons, Don L., Tsao, Anne, Lee, J. Jack, Bivona, Trever G., Camidge, D. Ross, Gray, Jhannelle E., Lieghl, Natasha, Levy, Benjamin, Brahmer, Julie R., Garassino, Marina C., Gandara, David R., Garon, Edward B., Rizvi, Naiyer A., Scagliotti, Giorgio Vittorio, Wolf, Jürgen, Planchard, David, Besse, Benjamin, Herbst, Roy S., Wakelee, Heather A., Pennell, Nathan A., Shaw, Alice T., Jänne, Pasi A., Carbone, David P., Hellmann, Matthew D., Rudin, Charles M., Albacker, Lee, Mann, Helen, Zhu, Zhou, Lai, Zhongwu, Stewart, Ross, Peters, Solange, Johnson, Melissa L., Wong, Kwok K., Huang, Alan, Winslow, Monte M., Rosen, Michael J., Winters, Ian P., Papadimitrakopoulou, Vassiliki A., Cascone, Tina, Jewsbury, Philip, and Heymach, John V.

Abstract

For patients with advanced non-small-cell lung cancer (NSCLC), dual immune checkpoint blockade (ICB) with CTLA4 inhibitors and PD-1 or PD-L1 inhibitors (hereafter, PD-(L)1 inhibitors) is associated with higher rates of anti-tumour activity and immune-related toxicities, when compared with treatment with PD-(L)1 inhibitors alone. However, there are currently no validated biomarkers to identify which patients will benefit from dual ICB1,2. Here we show that patients with NSCLC who have mutations in the STK11and/or KEAP1tumour suppressor genes derived clinical benefit from dual ICB with the PD-L1 inhibitor durvalumab and the CTLA4 inhibitor tremelimumab, but not from durvalumab alone, when added to chemotherapy in the randomized phase III POSEIDON trial3. Unbiased genetic screens identified loss of both of these tumour suppressor genes as independent drivers of resistance to PD-(L)1 inhibition, and showed that loss of Keap1was the strongest genomic predictor of dual ICB efficacy—a finding that was confirmed in several mouse models of Kras-driven NSCLC. In both mouse models and patients, KEAP1and STK11alterations were associated with an adverse tumour microenvironment, which was characterized by a preponderance of suppressive myeloid cells and the depletion of CD8+cytotoxic T cells, but relative sparing of CD4+effector subsets. Dual ICB potently engaged CD4+effector cells and reprogrammed the tumour myeloid cell compartment towards inducible nitric oxide synthase (iNOS)-expressing tumoricidal phenotypes that—together with CD4+and CD8+T cells—contributed to anti-tumour efficacy. These data support the use of chemo-immunotherapy with dual ICB to mitigate resistance to PD-(L)1 inhibition in patients with NSCLC who have STK11and/or KEAP1alterations.

Published

2024

2. A single dose of neoadjuvant PD-1 blockade predicts clinical outcomes in resectable melanoma

Author

Huang, Alexander C., Orlowski, Robert J., Xu, Xiaowei, Mick, Rosemarie, George, Sangeeth M., Yan, Patrick K., Manne, Sasikanth, Kraya, Adam A., Wubbenhorst, Bradley, Dorfman, Liza, D’Andrea, Kurt, Wenz, Brandon M., Liu, Shujing, Chilukuri, Lakshmi, Kozlov, Andrew, Carberry, Mary, Giles, Lydia, Kier, Melanie W., Quagliarello, Felix, McGettigan, Suzanne, Kreider, Kristin, Annamalai, Lakshmanan, Zhao, Qing, Mogg, Robin, Xu, Wei, Blumenschein, Wendy M., Yearley, Jennifer H., Linette, Gerald P., Amaravadi, Ravi K., Schuchter, Lynn M., Herati, Ramin S., Bengsch, Bertram, Nathanson, Katherine L., Farwell, Michael D., Karakousis, Giorgos C., Wherry, E. John, and Mitchell, Tara C.

Abstract

Immunologic responses to anti-PD-1 therapy in melanoma patients occur rapidly with pharmacodynamic T cell responses detectable in blood by 3 weeks. It is unclear, however, whether these early blood-based observations translate to the tumor microenvironment. We conducted a study of neoadjuvant/adjuvant anti-PD-1 therapy in stage III/IV melanoma. We hypothesized that immune reinvigoration in the tumor would be detectable at 3 weeks and that this response would correlate with disease-free survival. We identified a rapid and potent anti-tumor response, with 8 of 27 patients experiencing a complete or major pathological response after a single dose of anti-PD-1, all of whom remain disease free. These rapid pathologic and clinical responses were associated with accumulation of exhausted CD8 T cells in the tumor at 3 weeks, with reinvigoration in the blood observed as early as 1 week. Transcriptional analysis demonstrated a pretreatment immune signature (neoadjuvant response signature) that was associated with clinical benefit. In contrast, patients with disease recurrence displayed mechanisms of resistance including immune suppression, mutational escape, and/or tumor evolution. Neoadjuvant anti-PD-1 treatment is effective in high-risk resectable stage III/IV melanoma. Pathological response and immunological analyses after a single neoadjuvant dose can be used to predict clinical outcome and to dissect underlying mechanisms in checkpoint blockade.

Published

2019

3. The Inpatient Immunotherapy Outcomes study: A multicenter retrospective study of patients treated with immune checkpoint inhibitors in the inpatient setting.

Author

Riaz, Fauzia, Zhu, Huili, Cheng, Wei, Brongiel, Samantha, Baldwin, Elena, Kier, Melanie Wain, Zaemes, Jacob, Hearn, Caleb, Abdelghany, Osama, Parikh, Ravi Bharat, Reuss, Joshua E., Prsic, Elizabeth Horn, and Doroshow, Deborah Blythe

Published

2022

4. Financial toxicity in patients with advanced solid malignancies participating in early-phase clinical trials.

Author

Blanter, Julia, Werner, Michael, Kier, Melanie Wain, Hapanowicz, Olivia, Itani, Muhieddine, Ahmad, Maham, DeMerchant, Mandy, Eder, Joseph Paul, Galsky, Matt D., Hammad, Ashley, King, Paula, Lachowicz, Michael, Lucas, Natalie, Marron, Thomas Urban, Shelton, Gary, Wu, Kathy, Xu, Suzanne, LoRusso, Patricia, Hofstatter, Erin Wysong, and Doroshow, Deborah Blythe

Published

2022

5. Hospital at Home in an oncology setting: Updated analysis.

Author

Kier, Melanie Wain, Lubetsky, Sara, Schiller, Gabrielle, Siu, Albert L., Ornstein, Katherine A., and Smith, Cardinale B.

Published

2022