Your search keyword '"Wilbrey-Clark, A"' showing total 7 results

1. Human SARS-CoV-2 challenge uncovers local and systemic response dynamics.

Author

Lindeboom, Rik G. H., Worlock, Kaylee B., Dratva, Lisa M., Yoshida, Masahiro, Scobie, David, Wagstaffe, Helen R., Richardson, Laura, Wilbrey-Clark, Anna, Barnes, Josephine L., Kretschmer, Lorenz, Polanski, Krzysztof, Allen-Hyttinen, Jessica, Mehta, Puja, Sumanaweera, Dinithi, Boccacino, Jacqueline M., Sungnak, Waradon, Elmentaite, Rasa, Huang, Ni, Mamanova, Lira, and Kapuge, Rakesh

Abstract

The COVID-19 pandemic is an ongoing global health threat, yet our understanding of the dynamics of early cellular responses to this disease remains limited1. Here in our SARS-CoV-2 human challenge study, we used single-cell multi-omics profiling of nasopharyngeal swabs and blood to temporally resolve abortive, transient and sustained infections in seronegative individuals challenged with pre-Alpha SARS-CoV-2. Our analyses revealed rapid changes in cell-type proportions and dozens of highly dynamic cellular response states in epithelial and immune cells associated with specific time points and infection status. We observed that the interferon response in blood preceded the nasopharyngeal response. Moreover, nasopharyngeal immune infiltration occurred early in samples from individuals with only transient infection and later in samples from individuals with sustained infection. High expression of HLA-DQA2 before inoculation was associated with preventing sustained infection. Ciliated cells showed multiple immune responses and were most permissive for viral replication, whereas nasopharyngeal T cells and macrophages were infected non-productively. We resolved 54 T cell states, including acutely activated T cells that clonally expanded while carrying convergent SARS-CoV-2 motifs. Our new computational pipeline Cell2TCR identifies activated antigen-responding T cells based on a gene expression signature and clusters these into clonotype groups and motifs. Overall, our detailed time series data can serve as a Rosetta stone for epithelial and immune cell responses and reveals early dynamic responses associated with protection against infection.A human SARS-CoV-2 challenge study in individuals without previous exposure to the virus or vaccines provides detailed profiles of local and systemic epithelial and immune cell response dynamics over time and infection status. [ABSTRACT FROM AUTHOR]

Published

2024

2. An integrated cell atlas of the lung in health and disease

Author

Sikkema, Lisa, Ramírez-Suástegui, Ciro, Strobl, Daniel C., Gillett, Tessa E., Zappia, Luke, Madissoon, Elo, Markov, Nikolay S., Zaragosi, Laure Emmanuelle, Ji, Yuge, Ansari, Meshal, Arguel, Marie Jeanne, Apperloo, Leonie, Banchero, Martin, Bécavin, Christophe, Berg, Marijn, Chichelnitskiy, Evgeny, Chung, Mei i., Collin, Antoine, Gay, Aurore C.A., Gote-Schniering, Janine, Hooshiar Kashani, Baharak, Inecik, Kemal, Jain, Manu, Kapellos, Theodore S., Kole, Tessa M., Leroy, Sylvie, Mayr, Christoph H., Oliver, Amanda J., von Papen, Michael, Peter, Lance, Taylor, Chase J., Walzthoeni, Thomas, Xu, Chuan, Bui, Linh T., De Donno, Carlo, Dony, Leander, Faiz, Alen, Guo, Minzhe, Gutierrez, Austin J., Heumos, Lukas, Huang, Ni, Ibarra, Ignacio L., Jackson, Nathan D., Kadur Lakshminarasimha Murthy, Preetish, Lotfollahi, Mohammad, Tabib, Tracy, Talavera-López, Carlos, Travaglini, Kyle J., Wilbrey-Clark, Anna, Worlock, Kaylee B., Yoshida, Masahiro, Chen, Yuexin, Hagood, James S., Agami, Ahmed, Horvath, Peter, Lundeberg, Joakim, Marquette, Charles Hugo, Pryhuber, Gloria, Samakovlis, Chistos, Sun, Xin, Ware, Lorraine B., Zhang, Kun, van den Berge, Maarten, Bossé, Yohan, Desai, Tushar J., Eickelberg, Oliver, Kaminski, Naftali, Krasnow, Mark A., Lafyatis, Robert, Nikolic, Marko Z., Powell, Joseph E., Rajagopal, Jayaraj, Rojas, Mauricio, Rozenblatt-Rosen, Orit, Seibold, Max A., Sheppard, Dean, Shepherd, Douglas P., Sin, Don D., Timens, Wim, Tsankov, Alexander M., Whitsett, Jeffrey, Xu, Yan, Banovich, Nicholas E., Barbry, Pascal, Duong, Thu Elizabeth, Falk, Christine S., Meyer, Kerstin B., Kropski, Jonathan A., Pe’er, Dana, Schiller, Herbert B., Tata, Purushothama Rao, Schultze, Joachim L., Teichmann, Sara A., Misharin, Alexander V., Nawijn, Martijn C., Luecken, Malte D., Theis, Fabian J., Sikkema, Lisa, Ramírez-Suástegui, Ciro, Strobl, Daniel C., Gillett, Tessa E., Zappia, Luke, Madissoon, Elo, Markov, Nikolay S., Zaragosi, Laure Emmanuelle, Ji, Yuge, Ansari, Meshal, Arguel, Marie Jeanne, Apperloo, Leonie, Banchero, Martin, Bécavin, Christophe, Berg, Marijn, Chichelnitskiy, Evgeny, Chung, Mei i., Collin, Antoine, Gay, Aurore C.A., Gote-Schniering, Janine, Hooshiar Kashani, Baharak, Inecik, Kemal, Jain, Manu, Kapellos, Theodore S., Kole, Tessa M., Leroy, Sylvie, Mayr, Christoph H., Oliver, Amanda J., von Papen, Michael, Peter, Lance, Taylor, Chase J., Walzthoeni, Thomas, Xu, Chuan, Bui, Linh T., De Donno, Carlo, Dony, Leander, Faiz, Alen, Guo, Minzhe, Gutierrez, Austin J., Heumos, Lukas, Huang, Ni, Ibarra, Ignacio L., Jackson, Nathan D., Kadur Lakshminarasimha Murthy, Preetish, Lotfollahi, Mohammad, Tabib, Tracy, Talavera-López, Carlos, Travaglini, Kyle J., Wilbrey-Clark, Anna, Worlock, Kaylee B., Yoshida, Masahiro, Chen, Yuexin, Hagood, James S., Agami, Ahmed, Horvath, Peter, Lundeberg, Joakim, Marquette, Charles Hugo, Pryhuber, Gloria, Samakovlis, Chistos, Sun, Xin, Ware, Lorraine B., Zhang, Kun, van den Berge, Maarten, Bossé, Yohan, Desai, Tushar J., Eickelberg, Oliver, Kaminski, Naftali, Krasnow, Mark A., Lafyatis, Robert, Nikolic, Marko Z., Powell, Joseph E., Rajagopal, Jayaraj, Rojas, Mauricio, Rozenblatt-Rosen, Orit, Seibold, Max A., Sheppard, Dean, Shepherd, Douglas P., Sin, Don D., Timens, Wim, Tsankov, Alexander M., Whitsett, Jeffrey, Xu, Yan, Banovich, Nicholas E., Barbry, Pascal, Duong, Thu Elizabeth, Falk, Christine S., Meyer, Kerstin B., Kropski, Jonathan A., Pe’er, Dana, Schiller, Herbert B., Tata, Purushothama Rao, Schultze, Joachim L., Teichmann, Sara A., Misharin, Alexander V., Nawijn, Martijn C., Luecken, Malte D., and Theis, Fabian J.

Abstract

Single-cell technologies have transformed our understanding of human tissues. Yet, studies typically capture only a limited number of donors and disagree on cell type definitions. Integrating many single-cell datasets can address these limitations of individual studies and capture the variability present in the population. Here we present the integrated Human Lung Cell Atlas (HLCA), combining 49 datasets of the human respiratory system into a single atlas spanning over 2.4 million cells from 486 individuals. The HLCA presents a consensus cell type re-annotation with matching marker genes, including annotations of rare and previously undescribed cell types. Leveraging the number and diversity of individuals in the HLCA, we identify gene modules that are associated with demographic covariates such as age, sex and body mass index, as well as gene modules changing expression along the proximal-to-distal axis of the bronchial tree. Mapping new data to the HLCA enables rapid data annotation and interpretation. Using the HLCA as a reference for the study of disease, we identify shared cell states across multiple lung diseases, including SPP1 + profibrotic monocyte-derived macrophages in COVID-19, pulmonary fibrosis and lung carcinoma. Overall, the HLCA serves as an example for the development and use of large-scale, cross-dataset organ atlases within the Human Cell Atlas., QC 20230710

Published

2023

3. An integrated cell atlas of the lung in health and disease.

Author

Sikkema, L, Ramírez-Suástegui, C, Strobl, DC, Gillett, TE, Zappia, L, Madissoon, E, Markov, NS, Zaragosi, L-E, Ji, Y, Ansari, M, Arguel, M-J, Apperloo, L, Banchero, M, Bécavin, C, Berg, M, Chichelnitskiy, E, Chung, M-I, Collin, A, Gay, ACA, Gote-Schniering, J, Hooshiar Kashani, B, Inecik, K, Jain, M, Kapellos, TS, Kole, TM, Leroy, S, Mayr, CH, Oliver, AJ, von Papen, M, Peter, L, Taylor, CJ, Walzthoeni, T, Xu, C, Bui, LT, De Donno, C, Dony, L, Faiz, A, Guo, M, Gutierrez, AJ, Heumos, L, Huang, N, Ibarra, IL, Jackson, ND, Kadur Lakshminarasimha Murthy, P, Lotfollahi, M, Tabib, T, Talavera-López, C, Travaglini, KJ, Wilbrey-Clark, A, Worlock, KB, Yoshida, M, Lung Biological Network Consortium, van den Berge, M, Bossé, Y, Desai, TJ, Eickelberg, O, Kaminski, N, Krasnow, MA, Lafyatis, R, Nikolic, MZ, Powell, JE, Rajagopal, J, Rojas, M, Rozenblatt-Rosen, O, Seibold, MA, Sheppard, D, Shepherd, DP, Sin, DD, Timens, W, Tsankov, AM, Whitsett, J, Xu, Y, Banovich, NE, Barbry, P, Duong, TE, Falk, CS, Meyer, KB, Kropski, JA, Pe'er, D, Schiller, HB, Tata, PR, Schultze, JL, Teichmann, SA, Misharin, AV, Nawijn, MC, Luecken, MD, Theis, FJ, Sikkema, L, Ramírez-Suástegui, C, Strobl, DC, Gillett, TE, Zappia, L, Madissoon, E, Markov, NS, Zaragosi, L-E, Ji, Y, Ansari, M, Arguel, M-J, Apperloo, L, Banchero, M, Bécavin, C, Berg, M, Chichelnitskiy, E, Chung, M-I, Collin, A, Gay, ACA, Gote-Schniering, J, Hooshiar Kashani, B, Inecik, K, Jain, M, Kapellos, TS, Kole, TM, Leroy, S, Mayr, CH, Oliver, AJ, von Papen, M, Peter, L, Taylor, CJ, Walzthoeni, T, Xu, C, Bui, LT, De Donno, C, Dony, L, Faiz, A, Guo, M, Gutierrez, AJ, Heumos, L, Huang, N, Ibarra, IL, Jackson, ND, Kadur Lakshminarasimha Murthy, P, Lotfollahi, M, Tabib, T, Talavera-López, C, Travaglini, KJ, Wilbrey-Clark, A, Worlock, KB, Yoshida, M, Lung Biological Network Consortium, van den Berge, M, Bossé, Y, Desai, TJ, Eickelberg, O, Kaminski, N, Krasnow, MA, Lafyatis, R, Nikolic, MZ, Powell, JE, Rajagopal, J, Rojas, M, Rozenblatt-Rosen, O, Seibold, MA, Sheppard, D, Shepherd, DP, Sin, DD, Timens, W, Tsankov, AM, Whitsett, J, Xu, Y, Banovich, NE, Barbry, P, Duong, TE, Falk, CS, Meyer, KB, Kropski, JA, Pe'er, D, Schiller, HB, Tata, PR, Schultze, JL, Teichmann, SA, Misharin, AV, Nawijn, MC, Luecken, MD, and Theis, FJ

Abstract

Single-cell technologies have transformed our understanding of human tissues. Yet, studies typically capture only a limited number of donors and disagree on cell type definitions. Integrating many single-cell datasets can address these limitations of individual studies and capture the variability present in the population. Here we present the integrated Human Lung Cell Atlas (HLCA), combining 49 datasets of the human respiratory system into a single atlas spanning over 2.4 million cells from 486 individuals. The HLCA presents a consensus cell type re-annotation with matching marker genes, including annotations of rare and previously undescribed cell types. Leveraging the number and diversity of individuals in the HLCA, we identify gene modules that are associated with demographic covariates such as age, sex and body mass index, as well as gene modules changing expression along the proximal-to-distal axis of the bronchial tree. Mapping new data to the HLCA enables rapid data annotation and interpretation. Using the HLCA as a reference for the study of disease, we identify shared cell states across multiple lung diseases, including SPP1+ profibrotic monocyte-derived macrophages in COVID-19, pulmonary fibrosis and lung carcinoma. Overall, the HLCA serves as an example for the development and use of large-scale, cross-dataset organ atlases within the Human Cell Atlas.

Published

2023

4. Spatially resolved multiomics of human cardiac niches.

Author

Kanemaru, Kazumasa, Cranley, James, Muraro, Daniele, Miranda, Antonio M. A., Ho, Siew Yen, Wilbrey-Clark, Anna, Patrick Pett, Jan, Polanski, Krzysztof, Richardson, Laura, Litvinukova, Monika, Kumasaka, Natsuhiko, Qin, Yue, Jablonska, Zuzanna, Semprich, Claudia I., Mach, Lukas, Dabrowska, Monika, Richoz, Nathan, Bolt, Liam, Mamanova, Lira, and Kapuge, Rakeshlal

Abstract

The function of a cell is defined by its intrinsic characteristics and its niche: the tissue microenvironment in which it dwells. Here we combine single-cell and spatial transcriptomics data to discover cellular niches within eight regions of the human heart. We map cells to microanatomical locations and integrate knowledge-based and unsupervised structural annotations. We also profile the cells of the human cardiac conduction system1. The results revealed their distinctive repertoire of ion channels, G-protein-coupled receptors (GPCRs) and regulatory networks, and implicated FOXP2 in the pacemaker phenotype. We show that the sinoatrial node is compartmentalized, with a core of pacemaker cells, fibroblasts and glial cells supporting glutamatergic signalling. Using a custom CellPhoneDB.org module, we identify trans-synaptic pacemaker cell interactions with glia. We introduce a druggable target prediction tool, drug2cell, which leverages single-cell profiles and drug–target interactions to provide mechanistic insights into the chronotropic effects of drugs, including GLP-1 analogues. In the epicardium, we show enrichment of both IgG+ and IgA+ plasma cells forming immune niches that may contribute to infection defence. Overall, we provide new clarity to cardiac electro-anatomy and immunology, and our suite of computational approaches can be applied to other tissues and organs.Single-cell and spatial transcriptomic analysis of eight human heart tissues reveals the cellular profiles and tissue architecture of niches including the cardiac conduction system, and a new tool, drug2cell, identifies drug target expression. [ABSTRACT FROM AUTHOR]

Published

2023

5. Author Correction: Human SARS-CoV-2 challenge uncovers local and systemic response dynamics.

Author

Lindeboom, Rik G. H., Worlock, Kaylee B., Dratva, Lisa M., Yoshida, Masahiro, Scobie, David, Wagstaffe, Helen R., Richardson, Laura, Wilbrey-Clark, Anna, Barnes, Josephine L., Kretschmer, Lorenz, Polanski, Krzysztof, Allen-Hyttinen, Jessica, Mehta, Puja, Sumanaweera, Dinithi, Boccacino, Jacqueline M., Sungnak, Waradon, Elmentaite, Rasa, Huang, Ni, Mamanova, Lira, and Kapuge, Rakesh

Published

2024

6. Local and systemic responses to SARS-CoV-2 infection in children and adults.

Author

Yoshida, Masahiro, Worlock, Kaylee B., Huang, Ni, Lindeboom, Rik G. H., Butler, Colin R., Kumasaka, Natsuhiko, Dominguez Conde, Cecilia, Mamanova, Lira, Bolt, Liam, Richardson, Laura, Polanski, Krzysztof, Madissoon, Elo, Barnes, Josephine L., Allen-Hyttinen, Jessica, Kilich, Eliz, Jones, Brendan C., de Wilton, Angus, Wilbrey-Clark, Anna, Sungnak, Waradon, and Pett, J. Patrick

Abstract

It is not fully understood why COVID-19 is typically milder in children1–3. Here, to examine the differences between children and adults in their response to SARS-CoV-2 infection, we analysed paediatric and adult patients with COVID-19 as well as healthy control individuals (total n = 93) using single-cell multi-omic profiling of matched nasal, tracheal, bronchial and blood samples. In the airways of healthy paediatric individuals, we observed cells that were already in an interferon-activated state, which after SARS-CoV-2 infection was further induced especially in airway immune cells. We postulate that higher paediatric innate interferon responses restrict viral replication and disease progression. The systemic response in children was characterized by increases in naive lymphocytes and a depletion of natural killer cells, whereas, in adults, cytotoxic T cells and interferon-stimulated subpopulations were significantly increased. We provide evidence that dendritic cells initiate interferon signalling in early infection, and identify epithelial cell states associated with COVID-19 and age. Our matching nasal and blood data show a strong interferon response in the airways with the induction of systemic interferon-stimulated populations, which were substantially reduced in paediatric patients. Together, we provide several mechanisms that explain the milder clinical syndrome observed in children.Mechanisms explaining the milder clinical syndrome that is observed in children with SARS-CoV-2 infection. [ABSTRACT FROM AUTHOR]

Published

2022

7. Single-cell reconstruction of the early maternal-fetal interface in humans.

Author

Vento-Tormo, Roser, Efremova, Mirjana, Botting, Rachel A., Turco, Margherita Y., Vento-Tormo, Miquel, Meyer, Kerstin B., Park, Jong-Eun, Stephenson, Emily, Polański, Krzysztof, Goncalves, Angela, Gardner, Lucy, Holmqvist, Staffan, Henriksson, Johan, Zou, Angela, Sharkey, Andrew M., Millar, Ben, Innes, Barbara, Wood, Laura, Wilbrey-Clark, Anna, and Payne, Rebecca P.

Abstract

During early human pregnancy the uterine mucosa transforms into the decidua, into which the fetal placenta implants and where placental trophoblast cells intermingle and communicate with maternal cells. Trophoblast-decidual interactions underlie common diseases of pregnancy, including pre-eclampsia and stillbirth. Here we profile the transcriptomes of about 70,000 single cells from first-trimester placentas with matched maternal blood and decidual cells. The cellular composition of human decidua reveals subsets of perivascular and stromal cells that are located in distinct decidual layers. There are three major subsets of decidual natural killer cells that have distinctive immunomodulatory and chemokine profiles. We develop a repository of ligand-receptor complexes and a statistical tool to predict the cell-type specificity of cell-cell communication via these molecular interactions. Our data identify many regulatory interactions that prevent harmful innate or adaptive immune responses in this environment. Our single-cell atlas of the maternal-fetal interface reveals the cellular organization of the decidua and placenta, and the interactions that are critical for placentation and reproductive success. Transcriptomes of about 70,000 single cells from first-trimester deciduas and placentas reveal subsets of perivascular, stromal and natural killer cells in the decidua, with distinct immunomodulatory profiles that regulate the environment necessary for successful placentation. [ABSTRACT FROM AUTHOR]

Published

2018