Your search keyword '"Tabachnikova, Alexandra"' showing total 38 results

1. SARS-CoV-2 reprograms murine alveolar macrophages to dampen flu

Author

Tabachnikova, Alexandra and Iwasaki, Akiko

Published

2024

2. Distinguishing features of long COVID identified through immune profiling

Author

Klein, Jon, Wood, Jamie, Jaycox, Jillian R., Dhodapkar, Rahul M., Lu, Peiwen, Gehlhausen, Jeff R., Tabachnikova, Alexandra, Greene, Kerrie, Tabacof, Laura, Malik, Amyn A., Silva Monteiro, Valter, Silva, Julio, Kamath, Kathy, Zhang, Minlu, Dhal, Abhilash, Ott, Isabel M., Valle, Gabrielee, Peña-Hernández, Mario, Mao, Tianyang, Bhattacharjee, Bornali, Takahashi, Takehiro, Lucas, Carolina, Song, Eric, McCarthy, Dayna, Breyman, Erica, Tosto-Mancuso, Jenna, Dai, Yile, Perotti, Emily, Akduman, Koray, Tzeng, Tiffany J., Xu, Lan, Geraghty, Anna C., Monje, Michelle, Yildirim, Inci, Shon, John, Medzhitov, Ruslan, Lutchmansingh, Denyse, Possick, Jennifer D., Kaminski, Naftali, Omer, Saad B., Krumholz, Harlan M., Guan, Leying, Dela Cruz, Charles S., van Dijk, David, Ring, Aaron M., Putrino, David, and Iwasaki, Akiko

Published

2023

3. Intratumoral dendritic cell–CD4+ T helper cell niches enable CD8+ T cell differentiation following PD-1 blockade in hepatocellular carcinoma

Author

Magen, Assaf, Hamon, Pauline, Fiaschi, Nathalie, Soong, Brian Y., Park, Matthew D., Mattiuz, Raphaël, Humblin, Etienne, Troncoso, Leanna, D’souza, Darwin, Dawson, Travis, Kim, Joel, Hamel, Steven, Buckup, Mark, Chang, Christie, Tabachnikova, Alexandra, Schwartz, Hara, Malissen, Nausicaa, Lavin, Yonit, Soares-Schanoski, Alessandra, Giotti, Bruno, Hegde, Samarth, Ioannou, Giorgio, Gonzalez-Kozlova, Edgar, Hennequin, Clotilde, Le Berichel, Jessica, Zhao, Zhen, Ward, Stephen C., Fiel, Isabel, Kou, Baijun, Dobosz, Michael, Li, Lianjie, Adler, Christina, Ni, Min, Wei, Yi, Wang, Wei, Atwal, Gurinder S., Kundu, Kunal, Cygan, Kamil J., Tsankov, Alexander M., Rahman, Adeeb, Price, Colles, Fernandez, Nicolas, He, Jiang, Gupta, Namita T., Kim-Schulze, Seunghee, Gnjatic, Sacha, Kenigsberg, Ephraim, Deering, Raquel P., Schwartz, Myron, Marron, Thomas U., Thurston, Gavin, Kamphorst, Alice O., and Merad, Miriam

Published

2023

4. Mild respiratory COVID can cause multi-lineage neural cell and myelin dysregulation

Author

Fernández-Castañeda, Anthony, Lu, Peiwen, Geraghty, Anna C., Song, Eric, Lee, Myoung-Hwa, Wood, Jamie, O’Dea, Michael R., Dutton, Selena, Shamardani, Kiarash, Nwangwu, Kamsi, Mancusi, Rebecca, Yalçın, Belgin, Taylor, Kathryn R., Acosta-Alvarez, Lehi, Malacon, Karen, Keough, Michael B., Ni, Lijun, Woo, Pamelyn J., Contreras-Esquivel, Daniel, Toland, Angus Martin Shaw, Gehlhausen, Jeff R., Klein, Jon, Takahashi, Takehiro, Silva, Julio, Israelow, Benjamin, Lucas, Carolina, Mao, Tianyang, Peña-Hernández, Mario A., Tabachnikova, Alexandra, Homer, Robert J., Tabacof, Laura, Tosto-Mancuso, Jenna, Breyman, Erica, Kontorovich, Amy, McCarthy, Dayna, Quezado, Martha, Vogel, Hannes, Hefti, Marco M., Perl, Daniel P., Liddelow, Shane, Folkerth, Rebecca, Putrino, David, Nath, Avindra, Iwasaki, Akiko, and Monje, Michelle

Published

2022

5. Neoadjuvant cemiplimab for resectable hepatocellular carcinoma: a single-arm, open-label, phase 2 trial

Author

Marron, Thomas U, Fiel, Maria Isabel, Hamon, Pauline, Fiaschi, Nathalie, Kim, Edward, Ward, Stephen C, Zhao, Zhen, Kim, Joel, Kennedy, Paul, Gunasekaran, Ganesh, Tabrizian, Parissa, Doroshow, Deborah, Legg, Meredith, Hammad, Ashley, Magen, Assaf, Kamphorst, Alice O, Shareef, Muhammed, Gupta, Namita T, Deering, Raquel, Wang, Wei, Wang, Fang, Thanigaimani, Pradeep, Mani, Jayakumar, Troncoso, Leanna, Tabachnikova, Alexandra, Chang, Christie, Akturk, Guray, Buckup, Mark, Hamel, Steven, Ioannou, Giorgio, Hennequin, Clotilde, Jamal, Hajra, Brown, Haley, Bonaccorso, Antoinette, Labow, Daniel, Sarpel, Umut, Rosenbloom, Talia, Sung, Max W, Kou, Baijun, Li, Siyu, Jankovic, Vladimir, James, Nicola, Hamon, Sara C, Cheung, Hung Kam, Sims, Jennifer S, Miller, Elizabeth, Bhardwaj, Nina, Thurston, Gavin, Lowy, Israel, Gnjatic, Sacha, Taouli, Bachir, Schwartz, Myron E, and Merad, Miriam

Published

2022

6. Single-cell analysis of human non-small cell lung cancer lesions refines tumor classification and patient stratification

Author

Leader, Andrew M., Grout, John A., Maier, Barbara B., Nabet, Barzin Y., Park, Matthew D., Tabachnikova, Alexandra, Chang, Christie, Walker, Laura, Lansky, Alona, Le Berichel, Jessica, Troncoso, Leanna, Malissen, Nausicaa, Davila, Melanie, Martin, Jerome C., Magri, Giuliana, Tuballes, Kevin, Zhao, Zhen, Petralia, Francesca, Samstein, Robert, D’Amore, Natalie Roy, Thurston, Gavin, Kamphorst, Alice O., Wolf, Andrea, Flores, Raja, Wang, Pei, Müller, Sören, Mellman, Ira, Beasley, Mary Beth, Salmon, Hélène, Rahman, Adeeb H., Marron, Thomas U., Kenigsberg, Ephraim, and Merad, Miriam

Published

2021

7. Impact of circulating SARS-CoV-2 variants on mRNA vaccine-induced immunity

Author

Lucas, Carolina, Vogels, Chantal B. F., Yildirim, Inci, Rothman, Jessica E., Lu, Peiwen, Monteiro, Valter, Gehlhausen, Jeff R., Campbell, Melissa, Silva, Julio, Tabachnikova, Alexandra, Peña-Hernandez, Mario A., Muenker, M. Catherine, Breban, Mallery I., Fauver, Joseph R., Mohanty, Subhasis, Huang, Jiefang, Shaw, Albert C., Ko, Albert I., Omer, Saad B., Grubaugh, Nathan D., and Iwasaki, Akiko

Published

2021

8. Tissue-resident macrophages provide a pro-tumorigenic niche to early NSCLC cells

Author

Casanova-Acebes, María, Dalla, Erica, Leader, Andrew M., LeBerichel, Jessica, Nikolic, Jovan, Morales, Blanca M., Brown, Markus, Chang, Christie, Troncoso, Leanna, Chen, Steven T., Sastre-Perona, Ana, Park, Matthew D., Tabachnikova, Alexandra, Dhainaut, Maxime, Hamon, Pauline, Maier, Barbara, and Sawai, Catherine M.

Subjects

Lung cancer, Non-small cell -- Development and progression, Macrophages -- Health aspects, Cancer cells -- Health aspects, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Macrophages have a key role in shaping the tumour microenvironment (TME), tumour immunity and response to immunotherapy, which makes them an important target for cancer treatment.sup.1,2. However, modulating macrophages has proved extremely difficult, as we still lack a complete understanding of the molecular and functional diversity of the tumour macrophage compartment. Macrophages arise from two distinct lineages. Tissue-resident macrophages self-renew locally, independent of adult haematopoiesis.sup.3-5, whereas short-lived monocyte-derived macrophages arise from adult haematopoietic stem cells, and accumulate mostly in inflamed lesions.sup.1. How these macrophage lineages contribute to the TME and cancer progression remains unclear. To explore the diversity of the macrophage compartment in human non-small cell lung carcinoma (NSCLC) lesions, here we performed single-cell RNA sequencing of tumour-associated leukocytes. We identified distinct populations of macrophages that were enriched in human and mouse lung tumours. Using lineage tracing, we discovered that these macrophage populations differ in origin and have a distinct temporal and spatial distribution in the TME. Tissue-resident macrophages accumulate close to tumour cells early during tumour formation to promote epithelial-mesenchymal transition and invasiveness in tumour cells, and they also induce a potent regulatory T cell response that protects tumour cells from adaptive immunity. Depletion of tissue-resident macrophages reduced the numbers and altered the phenotype of regulatory T cells, promoted the accumulation of CD8.sup.+ T cells and reduced tumour invasiveness and growth. During tumour growth, tissue-resident macrophages became redistributed at the periphery of the TME, which becomes dominated by monocyte-derived macrophages in both mouse and human NSCLC. This study identifies the contribution of tissue-resident macrophages to early lung cancer and establishes them as a target for the prevention and treatment of early lung cancer lesions. Single-cell RNA sequencing and imaging of macrophages in human non-small cell lung cancer and in a mouse model of lung adenocarcinoma show that tissue-resident macrophages have a key role in early tumour progression., Author(s): María Casanova-Acebes [sup.1] [sup.2] [sup.3] [sup.19] , Erica Dalla [sup.4] [sup.5] [sup.6] [sup.7] , Andrew M. Leader [sup.1] [sup.2] [sup.3] , Jessica LeBerichel [sup.1] [sup.2] [sup.3] , Jovan Nikolic [...]

Published

2021

9. BRAFV600E-induced senescence drives Langerhans cell histiocytosis pathophysiology

Author

Bigenwald, Camille, Le Berichel, Jessica, Wilk, C. Matthias, Chakraborty, Rikhia, Chen, Steven T., Tabachnikova, Alexandra, Mancusi, Rebecca, Abhyankar, Harshal, Casanova-Acebes, Maria, Laface, Ilaria, Akturk, Guray, Jobson, Jenielle, Karoulia, Zoi, Martin, Jerome C., Grout, John, Rafiei, Anahita, Lin, Howard, Manz, Markus G., Baccarini, Alessia, Poulikakos, Poulikos I., Brown, Brian D., Gnjatic, Sacha, Lujambio, Amaia, McClain, Kenneth L., Picarsic, Jennifer, Allen, Carl E., and Merad, Miriam

Published

2021

10. Sex differences in symptomatology and immune profiles of Long COVID

Author

Silva, Julio, primary, Takahashi, Takehiro, additional, Wood, Jamie, additional, Lu, Peiwen, additional, Tabachnikova, Alexandra, additional, Gehlhausen, Jeff R., additional, Greene, Kerrie, additional, Bhattacharjee, Bornali, additional, Monteiro, Valter Silva, additional, Lucas, Carolina, additional, Dhodapkar, Rahul M., additional, Tabacof, Laura, additional, Peña-Hernandez, Mario, additional, Kamath, Kathy, additional, Mao, Tianyang, additional, Mccarthy, Dayna, additional, Medzhitov, Ruslan, additional, van Dijk, David, additional, Krumholz, Harlan M., additional, Guan, Leying, additional, Putrino, David, additional, and Iwasaki, Akiko, additional

Published

2024

11. Downregulation of exhausted cytotoxic T cells in gene expression networks of multisystem inflammatory syndrome in children

Author

Beckmann, Noam D., Comella, Phillip H., Cheng, Esther, Lepow, Lauren, Beckmann, Aviva G., Tyler, Scott R., Mouskas, Konstantinos, Simons, Nicole W., Hoffman, Gabriel E., Francoeur, Nancy J., Del Valle, Diane Marie, Kang, Gurpawan, Do, Anh, Moya, Emily, Wilkins, Lillian, Le Berichel, Jessica, Chang, Christie, Marvin, Robert, Calorossi, Sharlene, Lansky, Alona, Walker, Laura, Yi, Nancy, Yu, Alex, Chung, Jonathan, Hartnett, Matthew, Eaton, Melody, Hatem, Sandra, Jamal, Hajra, Akyatan, Alara, Tabachnikova, Alexandra, Liharska, Lora E., Cotter, Liam, Fennessy, Brian, Vaid, Akhil, Barturen, Guillermo, Shah, Hardik, Wang, Ying-chih, Sridhar, Shwetha Hara, Soto, Juan, Bose, Swaroop, Madrid, Kent, Ellis, Ethan, Merzier, Elyze, Vlachos, Konstantinos, Fishman, Nataly, Tin, Manying, Smith, Melissa, Xie, Hui, Patel, Manishkumar, Nie, Kai, Argueta, Kimberly, Harris, Jocelyn, Karekar, Neha, Batchelor, Craig, Lacunza, Jose, Yishak, Mahlet, Tuballes, Kevin, Scott, Ieisha, Kumar, Arvind, Jaladanki, Suraj, Agashe, Charuta, Thompson, Ryan, Clark, Evan, Losic, Bojan, Peters, Lauren, Roussos, Panagiotis, Zhu, Jun, Wang, Wenhui, Kasarskis, Andrew, Glicksberg, Benjamin S., Nadkarni, Girish, Bogunovic, Dusan, Elaiho, Cordelia, Gangadharan, Sandeep, Ofori-Amanfo, George, Alesso-Carra, Kasey, Onel, Kenan, Wilson, Karen M., Argmann, Carmen, Bunyavanich, Supinda, Alarcón-Riquelme, Marta E., Marron, Thomas U., Rahman, Adeeb, Kim-Schulze, Seunghee, Gnjatic, Sacha, Gelb, Bruce D., Merad, Miriam, Sebra, Robert, Schadt, Eric E., and Charney, Alexander W.

Published

2021

12. Supplementary Table from Spatial Positioning and Matrix Programs of Cancer-Associated Fibroblasts Promote T-cell Exclusion in Human Lung Tumors

Author

Grout, John A., primary, Sirven, Philemon, primary, Leader, Andrew M., primary, Maskey, Shrisha, primary, Hector, Eglantine, primary, Puisieux, Isabelle, primary, Steffan, Fiona, primary, Cheng, Evan, primary, Tung, Navpreet, primary, Maurin, Mathieu, primary, Vaineau, Romain, primary, Karpf, Lea, primary, Plaud, Martin, primary, Begue, Anne-Laure, primary, Ganesh, Koushik, primary, Mesple, Jérémy, primary, Casanova-Acebes, Maria, primary, Tabachnikova, Alexandra, primary, Keerthivasan, Shilpa, primary, Lansky, Alona, primary, Berichel, Jessica Le, primary, Walker, Laura, primary, Rahman, Adeeb H., primary, Gnjatic, Sacha, primary, Girard, Nicolas, primary, Lefevre, Marine, primary, Damotte, Diane, primary, Adam, Julien, primary, Martin, Jerome C., primary, Wolf, Andrea, primary, Flores, Raja M., primary, Beasley, Mary Beth, primary, Pradhan, Rachana, primary, Muller, Soren, primary, Marron, Thomas U., primary, Turley, Shannon J., primary, Merad, Miriam, primary, Kenigsberg, Ephraim, primary, and Salmon, Hélène, primary

Published

2023

13. Supplementary Figure from Spatial Positioning and Matrix Programs of Cancer-Associated Fibroblasts Promote T-cell Exclusion in Human Lung Tumors

Author

Grout, John A., primary, Sirven, Philemon, primary, Leader, Andrew M., primary, Maskey, Shrisha, primary, Hector, Eglantine, primary, Puisieux, Isabelle, primary, Steffan, Fiona, primary, Cheng, Evan, primary, Tung, Navpreet, primary, Maurin, Mathieu, primary, Vaineau, Romain, primary, Karpf, Lea, primary, Plaud, Martin, primary, Begue, Anne-Laure, primary, Ganesh, Koushik, primary, Mesple, Jérémy, primary, Casanova-Acebes, Maria, primary, Tabachnikova, Alexandra, primary, Keerthivasan, Shilpa, primary, Lansky, Alona, primary, Berichel, Jessica Le, primary, Walker, Laura, primary, Rahman, Adeeb H., primary, Gnjatic, Sacha, primary, Girard, Nicolas, primary, Lefevre, Marine, primary, Damotte, Diane, primary, Adam, Julien, primary, Martin, Jerome C., primary, Wolf, Andrea, primary, Flores, Raja M., primary, Beasley, Mary Beth, primary, Pradhan, Rachana, primary, Muller, Soren, primary, Marron, Thomas U., primary, Turley, Shannon J., primary, Merad, Miriam, primary, Kenigsberg, Ephraim, primary, and Salmon, Hélène, primary

Published

2023

14. Data from Spatial Positioning and Matrix Programs of Cancer-Associated Fibroblasts Promote T-cell Exclusion in Human Lung Tumors

Author

Grout, John A., primary, Sirven, Philemon, primary, Leader, Andrew M., primary, Maskey, Shrisha, primary, Hector, Eglantine, primary, Puisieux, Isabelle, primary, Steffan, Fiona, primary, Cheng, Evan, primary, Tung, Navpreet, primary, Maurin, Mathieu, primary, Vaineau, Romain, primary, Karpf, Lea, primary, Plaud, Martin, primary, Begue, Anne-Laure, primary, Ganesh, Koushik, primary, Mesple, Jérémy, primary, Casanova-Acebes, Maria, primary, Tabachnikova, Alexandra, primary, Keerthivasan, Shilpa, primary, Lansky, Alona, primary, Berichel, Jessica Le, primary, Walker, Laura, primary, Rahman, Adeeb H., primary, Gnjatic, Sacha, primary, Girard, Nicolas, primary, Lefevre, Marine, primary, Damotte, Diane, primary, Adam, Julien, primary, Martin, Jerome C., primary, Wolf, Andrea, primary, Flores, Raja M., primary, Beasley, Mary Beth, primary, Pradhan, Rachana, primary, Muller, Soren, primary, Marron, Thomas U., primary, Turley, Shannon J., primary, Merad, Miriam, primary, Kenigsberg, Ephraim, primary, and Salmon, Hélène, primary

Published

2023

15. Roles for eosinophils and basophils in COVID-19?

Author

Tabachnikova, Alexandra and Chen, Steven T.

Published

2020

16. 543 Response to checkpoint blockade in HCC is associated with IgG1 skewing

Author

Sweeney, Robert, primary, Gonzalez-Kozlova, Edgar, additional, Tabachnikova, Alexandra, additional, Chang, Christie, additional, Walker, Laura, additional, Magen, Assaf, additional, Schwartz, Myron, additional, Marron, Thomas, additional, Merad, Miriam, additional, and Gnjatic, Sacha, additional

Published

2022

17. Spatial Positioning and Matrix Programs of Cancer-Associated Fibroblasts Promote T-cell Exclusion in Human Lung Tumors

Author

Grout, John A., primary, Sirven, Philemon, additional, Leader, Andrew M., additional, Maskey, Shrisha, additional, Hector, Eglantine, additional, Puisieux, Isabelle, additional, Steffan, Fiona, additional, Cheng, Evan, additional, Tung, Navpreet, additional, Maurin, Mathieu, additional, Vaineau, Romain, additional, Karpf, Lea, additional, Plaud, Martin, additional, Begue, Anne-Laure, additional, Ganesh, Koushik, additional, Mesple, Jérémy, additional, Casanova-Acebes, Maria, additional, Tabachnikova, Alexandra, additional, Keerthivasan, Shilpa, additional, Lansky, Alona, additional, Berichel, Jessica Le, additional, Walker, Laura, additional, Rahman, Adeeb H., additional, Gnjatic, Sacha, additional, Girard, Nicolas, additional, Lefevre, Marine, additional, Damotte, Diane, additional, Adam, Julien, additional, Martin, Jerome C., additional, Wolf, Andrea, additional, Flores, Raja M., additional, Beasley, Mary Beth, additional, Pradhan, Rachana, additional, Muller, Soren, additional, Marron, Thomas U., additional, Turley, Shannon J., additional, Merad, Miriam, additional, Kenigsberg, Ephraim, additional, and Salmon, Hélène, additional

Published

2022

18. Distinguishing features of Long COVID identified through immune profiling

Author

Klein, Jon, primary, Wood, Jamie, additional, Jaycox, Jillian, additional, Lu, Peiwen, additional, Dhodapkar, Rahul M., additional, Gehlhausen, Jeff R., additional, Tabachnikova, Alexandra, additional, Tabacof, Laura, additional, Malik, Amyn A., additional, Kamath, Kathy, additional, Greene, Kerrie, additional, Monteiro, Valter Silva, additional, Peña-Hernandez, Mario, additional, Mao, Tianyang, additional, Bhattacharjee, Bornali, additional, Takahashi, Takehiro, additional, Lucas, Carolina, additional, Silva, Julio, additional, Mccarthy, Dayna, additional, Breyman, Erica, additional, Tosto-Mancuso, Jenna, additional, Dai, Yile, additional, Perotti, Emily, additional, Akduman, Koray, additional, Tzeng, Tiffany J., additional, Xu, Lan, additional, Yildirim, Inci, additional, Krumholz, Harlan M., additional, Shon, John, additional, Medzhitov, Ruslan, additional, Omer, Saad B., additional, van Dijk, David, additional, Ring, Aaron M., additional, Putrino, David, additional, and Iwasaki, Akiko, additional

Published

2022

19. Intratumoral mregDC and CXCL13 T helper niches enable local differentiation of CD8 T cells following PD-1 blockade

Author

Magen, Assaf, primary, Hamon, Pauline, additional, Fiaschi, Nathalie, additional, Troncoso, Leanna, additional, Humblin, Etienne, additional, D’souza, Darwin, additional, Dawson, Travis, additional, Park, Matthew D., additional, Kim, Joel, additional, Hamel, Steven, additional, Buckup, Mark, additional, Chang, Christie, additional, Tabachnikova, Alexandra, additional, Schwartz, Hara, additional, Malissen, Nausicaa, additional, Lavin, Yonit, additional, Soares-Schanoski, Alessandra, additional, Giotti, Bruno, additional, Hegde, Samarth, additional, Mattiuz, Raphaël, additional, Hennequin, Clotilde, additional, Berichel, Jessica Le, additional, Zhao, Zhen, additional, Ward, Stephen, additional, Fiel, Isabel, additional, Price, Colles, additional, Fernandez, Nicolas, additional, He, Jiang, additional, Kou, Baijun, additional, Dobosz, Michael, additional, Li, Lianjie, additional, Adler, Christina, additional, Ni, Min, additional, Wei, Yi, additional, Wang, Wei, additional, Gupta, Namita T., additional, Kundu, Kunal, additional, Cygan, Kamil, additional, Deering, Raquel P., additional, Tsankov, Alex, additional, Kim-Schulze, Seunghee, additional, Gnjatic, Sacha, additional, Kenigsberg, Ephraim, additional, Schwartz, Myron, additional, Marron, Thomas U., additional, Thurston, Gavin, additional, Kamphorst, Alice O., additional, and Merad, Miriam, additional

Published

2022

20. No evidence of fetal defects or anti-syncytin-1 antibody induction following COVID-19 mRNA vaccination

Author

Lu-Culligan, Alice, primary, Tabachnikova, Alexandra, additional, Pérez-Then, Eddy, additional, Tokuyama, Maria, additional, Lee, Hannah J., additional, Lucas, Carolina, additional, Silva Monteiro, Valter, additional, Miric, Marija, additional, Brache, Vivian, additional, Cochon, Leila, additional, Muenker, M. Catherine, additional, Mohanty, Subhasis, additional, Huang, Jiefang, additional, Kang, Insoo, additional, Dela Cruz, Charles, additional, Farhadian, Shelli, additional, Campbell, Melissa, additional, Yildirim, Inci, additional, Shaw, Albert C., additional, Ma, Shuangge, additional, Vermund, Sten H., additional, Ko, Albert I., additional, Omer, Saad B., additional, and Iwasaki, Akiko, additional

Published

2022

21. Shift of lung macrophage composition is associated with COVID-19 disease severity and recovery

Author

Chen, Steven T., Park, Matthew D., Del Valle, Diane Marie, Buckup, Mark, Tabachnikova, Alexandra, Simons, Nicole W., Mouskas, Konstantinos, Lee, Brian, Geanon, Daniel, D’Souza, Darwin, Dawson, Travis, Marvin, Robert, Nie, Kai, Thompson, Ryan C., Zhao, Zhen, LeBerichel, Jessica, Chang, Christie, Jamal, Hajra, Chaddha, Udit, Mathews, Kusum, Acquah, Samuel, Brown, Stacey-Ann, Reiss, Michelle, Harkin, Timothy, Feldmann, Marc, Powell, Charles A., Hook, Jaime L., Kim-Schulze, Seunghee, Rahman, Adeeb H., Brown, Brian D., Beckmann, Noam D., Gnjatic, Sacha, Kenigsberg, Ephraim, Charney, Alexander W., and Merad, Miriam

Subjects

Macrophages, Macrophages, Alveolar, COVID-19, Humans, Lung, Article, Monocytes

Abstract

Although it has been more than 2 years since the start of the coronavirus disease 2019 (COVID-19) pandemic, COVID-19 continues to be a worldwide health crisis. Despite the development of preventive vaccines, therapies to treat COVID-19 and other inflammatory diseases remain a major unmet need in medicine. Our study sought to identify drivers of disease severity and mortality to develop tailored immunotherapy strategies to halt disease progression. We assembled the Mount Sinai COVID-19 Biobank, which was composed of almost 600 hospitalized patients followed longitudinally through the peak of the pandemic in 2020. Moderate disease and survival were associated with a stronger antigen presentation and effector T cell signature. In contrast, severe disease and death were associated with an altered antigen presentation signature, increased numbers of inflammatory immature myeloid cells, and extrafollicular activated B cells that have been previously associated with autoantibody formation. In severely ill patients with COVID-19, lung tissue-resident alveolar macrophages not only were drastically depleted but also had an altered antigen presentation signature, which coincided with an influx of inflammatory monocytes and monocyte-derived macrophages. In addition, we found that the size of the alveolar macrophage pool correlated with patient outcome and that alveolar macrophage numbers and functionality were restored to homeostasis in patients who recovered from COVID-19. These data suggest that local and systemic myeloid cell dysregulation are drivers of COVID-19 severity and modulation of alveolar macrophage numbers and activity in the lung may be a viable therapeutic strategy for the treatment of critical inflammatory lung diseases.

Published

2022

22. Mild respiratory SARS-CoV-2 infection can cause multi-lineage cellular dysregulation and myelin loss in the brain

Author

Fernández-Castañeda, Anthony, primary, Lu, Peiwen, additional, Geraghty, Anna C., additional, Song, Eric, additional, Lee, Myoung-Hwa, additional, Wood, Jamie, additional, Yalçın, Belgin, additional, Taylor, Kathryn R., additional, Dutton, Selena, additional, Acosta-Alvarez, Lehi, additional, Ni, Lijun, additional, Contreras-Esquivel, Daniel, additional, Gehlhausen, Jeff R., additional, Klein, Jon, additional, Lucas, Carolina, additional, Mao, Tianyang, additional, Silva, Julio, additional, Peña-Hernández, Mario A., additional, Tabachnikova, Alexandra, additional, Takahashi, Takehiro, additional, Tabacof, Laura, additional, Tosto-Mancuso, Jenna, additional, Breyman, Erica, additional, Kontorovich, Amy, additional, McCarthy, Dayna, additional, Quezado, Martha, additional, Hefti, Marco, additional, Perl, Daniel, additional, Folkerth, Rebecca, additional, Putrino, David, additional, Nath, Avi, additional, Iwasaki, Akiko, additional, and Monje, Michelle, additional

Published

2022

23. No evidence of fetal defects or anti-syncytin-1 antibody induction following COVID-19 mRNA vaccination

Author

Lu-Culligan, Alice, primary, Tabachnikova, Alexandra, additional, Tokuyama, Maria, additional, Lee, Hannah J, additional, Lucas, Carolina, additional, Silva Monteiro, Valter, additional, Muenker, M. Catherine, additional, Mohanty, Subhasis, additional, Huang, Jiefang, additional, Kang, Insoo, additional, Dela Cruz, Charles, additional, Farhadian, Shelli, additional, Campbell, Melissa, additional, Yildirim, Inci, additional, Shaw, Albert, additional, Ko, Albert, additional, Omer, Saad, additional, and Iwasaki, Akiko, additional

Published

2021

24. 685 Characterization of molecular and spatial diversity of macrophages in hepatocellular carcinoma

Author

Hamon, Pauline, primary, Magen, Assaf, additional, Kim, Joel, additional, Buckup, Mark, additional, Troncoso, Leanna, additional, Hamel, Steven, additional, Berichel, Jessica Le, additional, Barboy, Oren, additional, David, Eyal, additional, Tabachnikova, Alexandra, additional, Chang, Christie, additional, Zhao, Zhen, additional, Cohen, Merav, additional, Giladi, Amir, additional, Malissen, Nausicaa, additional, Desland, Fiona, additional, Amit, Ido, additional, Kenigsberg, Ephraim, additional, Schwartz, Myron, additional, Marron, Thomas, additional, and Merad, Miriam, additional

Published

2021

25. BRAF V600E-induced senescence drives Langerhans cell histiocytosis pathophysiology

Author

Bigenwald, Camille, Le Berichel, Jessica, Wilk, C Matthias, Chakraborty, Rikhia, Chen, Steven T, Tabachnikova, Alexandra, Mancusi, Rebecca, Abhyankar, Harshal, Casanova-Acebes, Maria, Laface, Ilaria, Akturk, Guray, Jobson, Jenielle, Karoulia, Zoi, Martin, Jerome C, Grout, John, Rafiei, Anahita, Lin, Howard, Manz, Markus G, Baccarini, Alessia, Poulikakos, Poulikos I, Brown, Brian D, Gnjatic, Sacha, Lujambio, Amaia, McClain, Kenneth L, Picarsic, Jennifer, Allen, Carl E, Merad, Miriam, University of Zurich, and Merad, Miriam

Subjects

1300 General Biochemistry, Genetics and Molecular Biology, 10032 Clinic for Oncology and Hematology, 610 Medicine & health

Published

2021

26. Abstract 64: Characterization of molecular and spatial diversity of macrophages in hepatocellular carcinoma

Author

Hamon, Pauline, primary, Magen, Assaf, additional, Cohen, Merav, additional, Tabachnikova, Alexandra, additional, Chang, Christie, additional, Buckup, Mark, additional, Troncoso, Leanna, additional, Zhao, Zhen, additional, Kim, Joel, additional, Giladi, Amir, additional, Malissen, Nausicaa, additional, Desland, Fiona, additional, Berichel, Jessica Le, additional, Amit, Ido, additional, Kenigsberg, Ephraim, additional, Schwartz, Myron, additional, Marron, Thomas, additional, and Merad, Miriam, additional

Published

2021

27. A shift in lung macrophage composition is associated with COVID-19 severity and recovery.

Author

Chen, Steven T., Park, Matthew D., Del Valle, Diane Marie, Buckup, Mark, Tabachnikova, Alexandra, Thompson, Ryan C., Simons, Nicole W., Mouskas, Konstantinos, Lee, Brian, Geanon, Daniel, D'Souza, Darwin, Dawson, Travis, Marvin, Robert, Nie, Kai, Zhao, Zhen, LeBerichel, Jessica, Chang, Christie, Jamal, Hajra, Akturk, Guray, and Chaddha, Udit

Subjects

COVID-19, ALVEOLAR macrophages, MYELOID cells, ANTIGEN presentation, AUTOANTIBODIES, COVID-19 pandemic, B cells, MACROPHAGES

Abstract

Although it has been more than 2 years since the start of the coronavirus disease 2019 (COVID-19) pandemic, COVID-19 continues to be a worldwide health crisis. Despite the development of preventive vaccines, therapies to treat COVID-19 and other inflammatory diseases remain a major unmet need in medicine. Our study sought to identify drivers of disease severity and mortality to develop tailored immunotherapy strategies to halt disease progression. We assembled the Mount Sinai COVID-19 Biobank, which was composed of almost 600 hospitalized patients followed longitudinally through the peak of the pandemic in 2020. Moderate disease and survival were associated with a stronger antigen presentation and effector T cell signature. In contrast, severe disease and death were associated with an altered antigen presentation signature, increased numbers of inflammatory immature myeloid cells, and extrafollicular activated B cells that have been previously associated with autoantibody formation. In severely ill patients with COVID-19, lung tissue–resident alveolar macrophages not only were drastically depleted but also had an altered antigen presentation signature, which coincided with an influx of inflammatory monocytes and monocyte-derived macrophages. In addition, we found that the size of the alveolar macrophage pool correlated with patient outcome and that alveolar macrophage numbers and functionality were restored to homeostasis in patients who recovered from COVID-19. These data suggest that local and systemic myeloid cell dysregulation are drivers of COVID-19 severity and modulation of alveolar macrophage numbers and activity in the lung may be a viable therapeutic strategy for the treatment of critical inflammatory lung diseases. Modulation of macrophages: Understanding why some individuals develop severe disease after SARS-CoV-2 infection remains a high priority. Here, Chen et al. evaluated factors associated with disease severity and survival in samples from 600 individuals hospitalized with COVID-19 during 2020. The authors found that severe disease and death were associated with altered antigen presentation signatures, as well as a distinct macrophage profile in the peripheral blood. They also studied lung macrophages, finding that those with severe COVID-19 had increased inflammatory monocytes and monocyte-derived macrophage infiltration, with a corresponding decrease in the alveolar macrophage population. Together, these data suggest that restoring macrophage homeostasis may be a strategy for treating COVID-19. [ABSTRACT FROM AUTHOR]

Published

2022

28. Intratumoral dendritic cell–CD4+T helper cell niches enable CD8+T cell differentiation following PD-1 blockade in hepatocellular carcinoma

Author

Magen, Assaf, Hamon, Pauline, Fiaschi, Nathalie, Soong, Brian Y., Park, Matthew D., Mattiuz, Raphaël, Humblin, Etienne, Troncoso, Leanna, D’souza, Darwin, Dawson, Travis, Kim, Joel, Hamel, Steven, Buckup, Mark, Chang, Christie, Tabachnikova, Alexandra, Schwartz, Hara, Malissen, Nausicaa, Lavin, Yonit, Soares-Schanoski, Alessandra, Giotti, Bruno, Hegde, Samarth, Ioannou, Giorgio, Gonzalez-Kozlova, Edgar, Hennequin, Clotilde, Le Berichel, Jessica, Zhao, Zhen, Ward, Stephen C., Fiel, Isabel, Kou, Baijun, Dobosz, Michael, Li, Lianjie, Adler, Christina, Ni, Min, Wei, Yi, Wang, Wei, Atwal, Gurinder S., Kundu, Kunal, Cygan, Kamil J., Tsankov, Alexander M., Rahman, Adeeb, Price, Colles, Fernandez, Nicolas, He, Jiang, Gupta, Namita T., Kim-Schulze, Seunghee, Gnjatic, Sacha, Kenigsberg, Ephraim, Deering, Raquel P., Schwartz, Myron, Marron, Thomas U., Thurston, Gavin, Kamphorst, Alice O., and Merad, Miriam

Abstract

Despite no apparent defects in T cell priming and recruitment to tumors, a large subset of T cell rich tumors fail to respond to immune checkpoint blockade (ICB). We leveraged a neoadjuvant anti-PD-1 trial in patients with hepatocellular carcinoma (HCC), as well as additional samples collected from patients treated off-label, to explore correlates of response to ICB within T cell-rich tumors. We show that ICB response correlated with the clonal expansion of intratumoral CXCL13+CH25H+IL-21+PD-1+CD4+T helper cells (“CXCL13+TH”) and Granzyme K+PD-1+effector-like CD8+T cells, whereas terminally exhausted CD39hiTOXhiPD-1hiCD8+T cells dominated in nonresponders. CD4+and CD8+T cell clones that expanded post-treatment were found in pretreatment biopsies. Notably, PD-1+TCF-1+(Progenitor-exhausted) CD8+T cells shared clones mainly with effector-like cells in responders or terminally exhausted cells in nonresponders, suggesting that local CD8+T cell differentiation occurs upon ICB. We found that these Progenitor CD8+T cells interact with CXCL13+THwithin cellular triads around dendritic cells enriched in maturation and regulatory molecules, or “mregDC”. These results suggest that discrete intratumoral niches that include mregDC and CXCL13+THcontrol the differentiation of tumor-specific Progenitor exhasuted CD8+T cells following ICB.

Published

2023

29. CITEseq analysis of non-small-cell lung cancer lesions reveals an axis of immune cell activation associated with tumor antigen load and TP53 mutations

Author

Leader, Andrew M., primary, Grout, John A., additional, Chang, Christie, additional, Maier, Barbara, additional, Tabachnikova, Alexandra, additional, Walker, Laura, additional, Lansky, Alona, additional, LeBerichel, Jessica, additional, Malissen, Naussica, additional, Davila, Melanie, additional, Martin, Jerome, additional, Magri, Giuliana, additional, Tuballes, Kevin, additional, Zhao, Zhen, additional, Petralia, Francesca, additional, Samstein, Robert, additional, D’Amore, Natalie Roy, additional, Thurston, Gavin, additional, Kamphorst, Alice, additional, Wolf, Andrea, additional, Flores, Raja, additional, Wang, Pei, additional, Beasley, Mary Beth, additional, Salmon, Helene, additional, Rahman, Adeeb H., additional, Marron, Thomas U., additional, Kenigsberg, Ephraim, additional, and Merad, Miriam, additional

Published

2020

30. Sampling the host response to SARS-CoV-2 in hospitals under siege

Author

Charney, Alexander W., Simons, Nicole W., Mouskas, Konstantinos, Lepow, Lauren, Cheng, Esther, Le Berichel, Jessica, Chang, Christie, Marvin, Robert, Del Valle, Diane Marie, Calorossi, Sharlene, Lansky, Alona, Walker, Laura, Patel, Manishkumar, Xie, Hui, Yi, Nancy, Yu, Alex, Kang, Gurpawan, Mendoza, Anthony, Liharska, Lora E., Moya, Emily, Hartnett, Matthew, Hatem, Sandra, Wilkins, Lillian, Eaton, Melody, Jamal, Hajra, Tuballes, Kevin, Chen, Steven T., Tabachnikova, Alexandra, Chung, Jonathan, Harris, Jocelyn, Batchelor, Craig, Lacunza, Jose, Yishak, Mahlet, Argueta, Kimberly, Karekar, Neha, Lee, Brian, Kelly, Geoffrey, Geanon, Daniel, Handler, Diana, Leech, John, Stefanos, Hiyab, Dawson, Travis, Scott, Ieisha, Francoeur, Nancy, Johnson, Jessica S., Vaid, Akhil, Glicksberg, Benjamin S., Nadkarni, Girish N., Schadt, Eric E., Gelb, Bruce D., Rahman, Adeeb, Sebra, Robert, Martin, Glenn, Agashe, Charuta, Agrawal, Priyal, Akyatan, Alara, Alesso-Carra, Kasey, Alibo, Eziwoma, Alvarez, Kelvin, Amabile, Angelo, Ascolillo, Steven, Bailey, Rasheed, Begani, Priya, Correra, Paloma Bravo, Brown, Stacey-Ann, Buckup, Mark, Burka, Larissa, Cambron, Lena, Carrara, Gina, Chang, Serena, Chien, Jonathan, Chowdhury, Mashkura, Bozkus, Cansu Cimen, Comella, Phillip, Cosgrove, Dana, Cossarini, Francesca, Cotter, Liam, Dave, Arpit, Dayal, Bheesham, Dhainaut, Maxime, Dornfeld, Rebecca, Dul, Katie, Eber, Nissan, Elaiho, Cordelia, Fabris, Frank, Faith, Jeremiah, Falci, Dominique, Feng, Susie, Fennessy, Brian, Fernandes, Marie, Gangadharan, Sandeep, Grabowska, Joanna, Gyimesi, Gavin, Hamdani, Maha, Herbinet, Manon, Herrera, Elva, Hochman, Arielle, Hoffman, Gabriel E., Hook, Jaime, Horta, Laila, Humblin, Etienne, Karim, Subha, Kim, Jessica, Lebovitch, Dannielle, Lee, Grace, Lee, Gyu Ho, Lee, Jacky, Leventhal, Mike, Lindblad, Katherine, Livanos, Alexandra, Machado, Rosalie, Mahmood, Zafar, Mar, Kelcey, Maskey, Shrisha, Matthews, Paul, Meckel, Katherine, Mehandru, Saurabh, Mercedes, Cynthia, Meyer, Dara, Mollaoglu, Gurkan, Morris, Sarah, Nie, Kai, Nisenholtz, Marjorie, Ofori-Amanfo, George, Onel, Kenan, Ounadjela, Merouane, Patel, Vishwendra, Pruitt, Cassandra, Rathi, Shivani, Redes, Jamie, Reyes-Torres, Ivan, Rodrigues, Alcina, Rodriguez, Alfonso, Roudko, Vladimir, Ruiz, Evelyn, Scalzo, Pearl, Silva, Pedro, Schanoski, Alessandra Soares, Straw, Meghan, Tabachnikova, Sasha, Teague, Collin, Upadhyaya, Bhaskar, Van Der Heide, Verena, Vaninov, Natalie, Wacker, Daniel, Walsh, Hadley, Wilk, C. Matthias, Wilson, Jessica, Wilson, Karen M., Xue, Li, Yeboah, Naa-akomaah, Young, Sabina, Zaks, Nina, Zha, Renyuan, Marron, Thomas, Beckmann, Noam, Kim-Schulze, Seunghee, Gnjatic, Sacha, and Merad, Miriam

Subjects

Siege, 2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), biology, business.industry, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Host response, Sampling (statistics), General Medicine, biology.organism_classification, Virology, General Biochemistry, Genetics and Molecular Biology, Pandemic, Medicine, business, Betacoronavirus

Published

2020

31. Dynamic changes in the immune infiltrate within hepatocellular carcinoma tumor correlate with response to PD-1 blockade.

Author

Marron, Thomas Urban, primary, Desland, Fiona, additional, Lavin, Yonit, additional, Schwartz, Myron E., additional, Tabrizian, Parissa, additional, Fernandez, Nicholas, additional, Kim, Joel, additional, Tabachnikova, Alexandra, additional, Kamphorst, Alice O., additional, Schanoski, Alessandra Soares, additional, Brown, Brian, additional, Kenigsberg, Effi, additional, Sung, Max W., additional, Taouli, Bachir, additional, Rahman, Adeeb, additional, and Merad, Miriam, additional

Published

2019

32. Author Correction: Sampling the host response to SARS-CoV-2 in hospitals under siege

Author

Charney, Alexander W., Simons, Nicole W., Mouskas, Konstantinos, Lepow, Lauren, Cheng, Esther, Le Berichel, Jessica, Chang, Christie, Marvin, Robert, Del Valle, Diane Marie, Calorossi, Sharlene, Lansky, Alona, Walker, Laura, Patel, Manishkumar, Xie, Hui, Yi, Nancy, Yu, Alex, Kang, Gurpawan, Mendoza, Anthony, Liharska, Lora E., Moya, Emily, Hartnett, Matthew, Hatem, Sandra, Wilkins, Lillian, Eaton, Melody, Jamal, Hajra, Tuballes, Kevin, Chen, Steven T., Tabachnikova, Alexandra, Chung, Jonathan, Harris, Jocelyn, Batchelor, Craig, Lacunza, Jose, Yishak, Mahlet, Argueta, Kimberly, Karekar, Neha, Lee, Brian, Kelly, Geoffrey, Geanon, Daniel, Handler, Diana, Leech, John, Stefanos, Hiyab, Dawson, Travis, Scott, Ieisha, Francoeur, Nancy, Johnson, Jessica S., Vaid, Akhil, Glicksberg, Benjamin S., Nadkarni, Girish N., Schadt, Eric E., Gelb, Bruce D., Rahman, Adeeb, Sebra, Robert, Martin, Glenn, Marron, Thomas, Beckmann, Noam, Kim-Schulze, Seunghee, Gnjatic, Sacha, and Merad, Miriam

Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s41591-021-01247-3.

Published

2021

33. Dendritic cells type 1 control the formation, maintenance, and function of tertiary lymphoid structures in cancer.

Author

Mattiuz R, Boumelha J, Hamon P, Le Berichel J, Vaidya A, Soong BY, Halasz L, Radkevich E, Kim HM, Park MD, Donne R, Troncoso L, D'Souza D, Kaiza ME, MacFawn IP, Belabed M, Mestrallet G, Humblin E, Merand R, Hennequin C, Ioannou G, Ozbey S, Figueiredo I, Hegde S, Tepper A, Merarda H, Nemeth E, Goldstein S, Reid AM, Noureddine M, Tabachnikova A, Ahmed J, Polydorides AD, Bhardwaj N, Lujambio A, Chen Z, Gonzalez Kozlova E, Kim-Schulze S, Brody JD, Schotsaert M, Moussion C, Gnjatic S, Sautès-Fridman C, Fridman WH, Roudko V, Brown BD, Marron TU, Cyster JG, Salmon H, Bruno TC, Joshi NS, Kamphorst AO, and Merad M

Abstract

Tertiary lymphoid structures (TLS) are organized immune cell aggregates that arise in chronic inflammatory conditions. In cancer, TLS are associated with better prognosis and enhanced response to immunotherapy, making these structures attractive therapeutic targets. However, the mechanisms regulating TLS formation and maintenance in cancer are incompletely understood. Using spatial transcriptomics and multiplex imaging across various human tumors, we found an enrichment of mature dendritic cells (DC) expressing high levels of CCR7 in TLS, prompting us to investigate the role of DC in the formation and maintenance of TLS in solid tumors. To address this, we developed a novel murine model of non-small cell lung cancer (NSCLC) that forms mature TLS, containing B cell follicles with germinal centers and T cell zones with T follicular helper cells (T FH ) and TCF1 + PD-1 + progenitor exhausted CD8 + T cells (Tpex). Here we show that, during the early stages of tumor development, TLS formation relies on IFNγ-driven maturation of the conventional DC type 1 (cDC1) subset, their migration to tumor-draining lymph nodes (tdLN), and recruitment of activated T cells to the tumor site. As tumors progress, TLS maintenance becomes independent of T cell egress from tdLN, coinciding with a significant reduction of cDC1 migration to tdLN. Instead, mature cDC1 accumulate within intratumoral CCR7 ligand-enriched stromal hubs. Notably, timed depletion of cDC1 or disruption of their migration to these stromal hubs after TLS are formed alters TLS maintenance. Importantly, we found that cDC1-mediated antigen presentation to both CD4 + and CD8 + T cells and intact CD40 signaling, is critical for the maintenance of TLS, the preservation of the T FH cell pool, the formation of germinal center and the production of tumor-specific IgG antibodies. These findings underscore the key role of mature cDC1 in establishing and maintaining functional TLS within tumor lesions and highlight the potential for cDC1-targeting therapies as a promising strategy to enhance TLS function and improve anti-tumor immunity in patients with cancer.

Published

2024

34. Sex differences in symptomatology and immune profiles of Long COVID.

Author

Silva J, Takahashi T, Wood J, Lu P, Tabachnikova A, Gehlhausen JR, Greene K, Bhattacharjee B, Monteiro VS, Lucas C, Dhodapkar RM, Tabacof L, Peña-Hernandez M, Kamath K, Mao T, Mccarthy D, Medzhitov R, van Dijk D, Krumholz HM, Guan L, Putrino D, and Iwasaki A

Abstract

Strong sex differences in the frequencies and manifestations of Long COVID (LC) have been reported with females significantly more likely than males to present with LC after acute SARS-CoV-2 infection 1-7 . However, whether immunological traits underlying LC differ between sexes, and whether such differences explain the differential manifestations of LC symptomology is currently unknown. Here, we performed sex-based multi-dimensional immune-endocrine profiling of 165 individuals 8 with and without LC in an exploratory, cross-sectional study to identify key immunological traits underlying biological sex differences in LC. We found that female and male participants with LC experienced different sets of symptoms, and distinct patterns of organ system involvement, with female participants suffering from a higher symptom burden. Machine learning approaches identified differential sets of immune features that characterized LC in females and males. Males with LC had decreased frequencies of monocyte and DC populations, elevated NK cells, and plasma cytokines including IL-8 and TGF-β-family members. Females with LC had increased frequencies of exhausted T cells, cytokine-secreting T cells, higher antibody reactivity to latent herpes viruses including EBV, HSV-2, and CMV, and lower testosterone levels than their control female counterparts. Testosterone levels were significantly associated with lower symptom burden in LC participants over sex designation. These findings suggest distinct immunological processes of LC in females and males and illuminate the crucial role of immune-endocrine dysregulation in sex-specific pathology.

Published

2024

35. Impact of COVID-19 vaccination on symptoms and immune phenotypes in vaccine-naïve individuals with Long COVID.

Author

Grady CB, Bhattacharjee B, Silva J, Jaycox J, Lee LW, Monteiro VS, Sawano M, Massey D, Caraballo C, Gehlhausen JR, Tabachnikova A, Mao T, Lucas C, Peña-Hernandez MA, Xu L, Tzeng TJ, Takahashi T, Herrin J, Güthe DB, Akrami A, Assaf G, Davis H, Harris K, McCorkell L, Schulz WL, Grffin D, Wei H, Ring AM, Guan L, Cruz CD, Iwasaki A, and Krumholz HM

Abstract

Background: Long COVID contributes to the global burden of disease. Proposed root cause hypotheses include the persistence of SARS-CoV-2 viral reservoir, autoimmunity, and reactivation of latent herpesviruses. Patients have reported various changes in Long COVID symptoms after COVID-19 vaccinations, leaving uncertainty about whether vaccine-induced immune responses may alleviate or worsen disease pathology., Methods: In this prospective study, we evaluated changes in symptoms and immune responses after COVID-19 vaccination in 16 vaccine-naïve individuals with Long COVID. Surveys were administered before vaccination and then at 2, 6, and 12 weeks after receiving the first vaccine dose of the primary series. Simultaneously, SARS-CoV-2-reactive TCR enrichment, SARS-CoV-2-specific antibody responses, antibody responses to other viral and self-antigens, and circulating cytokines were quantified before vaccination and at 6 and 12 weeks after vaccination., Results: Self-report at 12 weeks post-vaccination indicated 10 out of 16 participants had improved health, 3 had no change, 1 had worse health, and 2 reported marginal changes. Significant elevation in SARS-CoV-2-specific TCRs and Spike protein-specific IgG were observed 6 and 12 weeks after vaccination. No changes in reactivities were observed against herpes viruses and self-antigens. Within this dataset, higher baseline sIL-6R was associated with symptom improvement, and the two top features associated with non-improvement were high IFN-β and CNTF, among soluble analytes., Conclusions: Our study showed that in this small sample, vaccination improved the health or resulted in no change to the health of most participants, though few experienced worsening. Vaccination was associated with increased SARS-CoV-2 Spike protein-specific IgG and T cell expansion in most individuals with Long COVID. Symptom improvement was observed in those with baseline elevated sIL-6R, while elevated interferon and neuropeptide levels were associated with a lack of improvement.

Published

2024

36. Distinguishing features of Long COVID identified through immune profiling.

Author

Klein J, Wood J, Jaycox J, Lu P, Dhodapkar RM, Gehlhausen JR, Tabachnikova A, Tabacof L, Malik AA, Kamath K, Greene K, Monteiro VS, Peña-Hernandez M, Mao T, Bhattacharjee B, Takahashi T, Lucas C, Silva J, Mccarthy D, Breyman E, Tosto-Mancuso J, Dai Y, Perotti E, Akduman K, Tzeng TJ, Xu L, Yildirim I, Krumholz HM, Shon J, Medzhitov R, Omer SB, van Dijk D, Ring AM, Putrino D, and Iwasaki A

Abstract

SARS-CoV-2 infection can result in the development of a constellation of persistent sequelae following acute disease called post-acute sequelae of COVID-19 (PASC) or Long COVID 1-3 . Individuals diagnosed with Long COVID frequently report unremitting fatigue, post-exertional malaise, and a variety of cognitive and autonomic dysfunctions 1-3 ; however, the basic biological mechanisms responsible for these debilitating symptoms are unclear. Here, 215 individuals were included in an exploratory, cross-sectional study to perform multi-dimensional immune phenotyping in conjunction with machine learning methods to identify key immunological features distinguishing Long COVID. Marked differences were noted in specific circulating myeloid and lymphocyte populations relative to matched control groups, as well as evidence of elevated humoral responses directed against SARS-CoV-2 among participants with Long COVID. Further, unexpected increases were observed in antibody responses directed against non-SARS-CoV-2 viral pathogens, particularly Epstein-Barr virus. Analysis of circulating immune mediators and various hormones also revealed pronounced differences, with levels of cortisol being uniformly lower among participants with Long COVID relative to matched control groups. Integration of immune phenotyping data into unbiased machine learning models identified significant distinguishing features critical in accurate classification of Long COVID, with decreased levels of cortisol being the most significant individual predictor. These findings will help guide additional studies into the pathobiology of Long COVID and may aid in the future development of objective biomarkers for Long COVID.

Published

2022

37. Mild respiratory SARS-CoV-2 infection can cause multi-lineage cellular dysregulation and myelin loss in the brain.

Author

Fernández-Castañeda A, Lu P, Geraghty AC, Song E, Lee MH, Wood J, Yalçın B, Taylor KR, Dutton S, Acosta-Alvarez L, Ni L, Contreras-Esquivel D, Gehlhausen JR, Klein J, Lucas C, Mao T, Silva J, Peña-Hernández MA, Tabachnikova A, Takahashi T, Tabacof L, Tosto-Mancuso J, Breyman E, Kontorovich A, McCarthy D, Quezado M, Hefti M, Perl D, Folkerth R, Putrino D, Nath A, Iwasaki A, and Monje M

Abstract

Survivors of Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) infection frequently experience lingering neurological symptoms, including impairment in attention, concentration, speed of information processing and memory. This long-COVID cognitive syndrome shares many features with the syndrome of cancer therapy-related cognitive impairment (CRCI). Neuroinflammation, particularly microglial reactivity and consequent dysregulation of hippocampal neurogenesis and oligodendrocyte lineage cells, is central to CRCI. We hypothesized that similar cellular mechanisms may contribute to the persistent neurological symptoms associated with even mild SARS-CoV-2 respiratory infection. Here, we explored neuroinflammation caused by mild respiratory SARS-CoV-2 infection - without neuroinvasion - and effects on hippocampal neurogenesis and the oligodendroglial lineage. Using a mouse model of mild respiratory SARS-CoV-2 infection induced by intranasal SARS-CoV-2 delivery, we found white matter-selective microglial reactivity, a pattern observed in CRCI. Human brain tissue from 9 individuals with COVID-19 or SARS-CoV-2 infection exhibits the same pattern of prominent white matter-selective microglial reactivity. In mice, pro-inflammatory CSF cytokines/chemokines were elevated for at least 7-weeks post-infection; among the chemokines demonstrating persistent elevation is CCL11, which is associated with impairments in neurogenesis and cognitive function. Humans experiencing long-COVID with cognitive symptoms (48 subjects) similarly demonstrate elevated CCL11 levels compared to those with long-COVID who lack cognitive symptoms (15 subjects). Impaired hippocampal neurogenesis, decreased oligodendrocytes and myelin loss in subcortical white matter were evident at 1 week, and persisted until at least 7 weeks, following mild respiratory SARS-CoV-2 infection in mice. Taken together, the findings presented here illustrate striking similarities between neuropathophysiology after cancer therapy and after SARS-CoV-2 infection, and elucidate cellular deficits that may contribute to lasting neurological symptoms following even mild SARS-CoV-2 infection.

Published

2022

38. Cytotoxic lymphocytes are dysregulated in multisystem inflammatory syndrome in children.

Author

Beckmann ND, Comella PH, Cheng E, Lepow L, Beckmann AG, Mouskas K, Simons NW, Hoffman GE, Francoeur NJ, Del Valle DM, Kang G, Moya E, Wilkins L, Le Berichel J, Chang C, Marvin R, Calorossi S, Lansky A, Walker L, Yi N, Yu A, Hartnett M, Eaton M, Hatem S, Jamal H, Akyatan A, Tabachnikova A, Liharska LE, Cotter L, Fennessey B, Vaid A, Barturen G, Tyler SR, Shah H, Wang YC, Sridhar SH, Soto J, Bose S, Madrid K, Ellis E, Merzier E, Vlachos K, Fishman N, Tin M, Smith M, Xie H, Patel M, Argueta K, Harris J, Karekar N, Batchelor C, Lacunza J, Yishak M, Tuballes K, Scott L, Kumar A, Jaladanki S, Thompson R, Clark E, Losic B, Zhu J, Wang W, Kasarskis A, Glicksberg BS, Nadkarni G, Bogunovic D, Elaiho C, Gangadharan S, Ofori-Amanfo G, Alesso-Carra K, Onel K, Wilson KM, Argmann C, Alarcón-Riquelme ME, Marron TU, Rahman A, Kim-Schulze S, Gnjatic S, Gelb BD, Merad M, Sebra R, Schadt EE, and Charney AW

Abstract

Multisystem inflammatory syndrome in children (MIS-C) presents with fever, inflammation and multiple organ involvement in individuals under 21 years following severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. To identify genes, pathways and cell types driving MIS-C, we sequenced the blood transcriptomes of MIS-C cases, pediatric cases of coronavirus disease 2019, and healthy controls. We define a MIS-C transcriptional signature partially shared with the transcriptional response to SARS-CoV-2 infection and with the signature of Kawasaki disease, a clinically similar condition. By projecting the MIS-C signature onto a co-expression network, we identified disease gene modules and found genes downregulated in MIS-C clustered in a module enriched for the transcriptional signatures of exhausted CD8 + T-cells and CD56 dim CD57 + NK cells. Bayesian network analyses revealed nine key regulators of this module, including TBX21 , a central coordinator of exhausted CD8 + T-cell differentiation. Together, these findings suggest dysregulated cytotoxic lymphocyte response to SARS-Cov-2 infection in MIS-C.

Published

2020