Your search keyword '"Popescu, Dorin-Mirel"' showing total 20 results

1. A prenatal skin atlas reveals immune regulation of human skin morphogenesis.

Author

Gopee, Nusayhah, Winheim, Elena, Olabi, Bayanne, Admane, Chloe, Foster, April, Huang, Ni, Botting, Rachel, Torabi, Fereshteh, Sumanaweera, Dinithi, Le, Anh, Kim, Jin, Verger, Luca, Stephenson, Emily, Adão, Diana, Ganier, Clarisse, Gim, Kelly, Serdy, Sara, Deakin, CiCi, Goh, Issac, Steele, Lloyd, Annusver, Karl, Miah, Mohi-Uddin, Tun, Win, Moghimi, Pejvak, Kwakwa, Kwasi, Li, Tong, Basurto Lozada, Daniela, Rumney, Ben, Tudor, Catherine, Roberts, Kenny, Chipampe, Nana-Jane, Sidhpura, Keval, Englebert, Justin, Jardine, Laura, Reynolds, Gary, Rose, Antony, Rowe, Vicky, Pritchard, Sophie, Mulas, Ilaria, Fletcher, James, Popescu, Dorin-Mirel, Poyner, Elizabeth, Dubois, Anna, Guy, Alyson, Filby, Andrew, Lisgo, Steven, Barker, Roger, Glass, Ian, Park, Jong-Eun, Vento-Tormo, Roser, Nikolova, Marina, He, Peng, Lawrence, John, Moore, Josh, Ballereau, Stephane, Hale, Christine, Shanmugiah, Vijaya, Horsfall, David, Rajan, Neil, McGrath, John, OToole, Edel, Treutlein, Barbara, Bayraktar, Omer, Kasper, Maria, Progatzky, Fränze, Mazin, Pavel, Lee, Jiyoon, Gambardella, Laure, Koehler, Karl, Teichmann, Sarah, and Haniffa, Muzlifah

Subjects

Humans, Skin, Morphogenesis, Macrophages, Hair Follicle, Organoids, Induced Pluripotent Stem Cells, Immunity, Innate, Atlases as Topic, Single-Cell Analysis, Endothelial Cells, Female, Neovascularization, Physiologic, Transcriptome, Human Embryonic Stem Cells, Wound Healing, Fetus

Abstract

Human prenatal skin is populated by innate immune cells, including macrophages, but whether they act solely in immunity or have additional functions in morphogenesis is unclear. Here we assembled a comprehensive multi-omics reference atlas of prenatal human skin (7-17 post-conception weeks), combining single-cell and spatial transcriptomics data, to characterize the microanatomical tissue niches of the skin. This atlas revealed that crosstalk between non-immune and immune cells underpins the formation of hair follicles, is implicated in scarless wound healing and is crucial for skin angiogenesis. We systematically compared a hair-bearing skin organoid (SkO) model derived from human embryonic stem cells and induced pluripotent stem cells to prenatal and adult skin1. The SkO model closely recapitulated in vivo skin epidermal and dermal cell types during hair follicle development and expression of genes implicated in the pathogenesis of genetic hair and skin disorders. However, the SkO model lacked immune cells and had markedly reduced endothelial cell heterogeneity and quantity. Our in vivo prenatal skin cell atlas indicated that macrophages and macrophage-derived growth factors have a role in driving endothelial development. Indeed, vascular network remodelling was enhanced following transfer of autologous macrophages derived from induced pluripotent stem cells into SkO cultures. Innate immune cells are therefore key players in skin morphogenesis beyond their conventional role in immunity, a function they achieve through crosstalk with non-immune cells.

Published

2024

2. A prenatal skin atlas reveals immune regulation of human skin morphogenesis

Author

Gopee, Nusayhah Hudaa, Winheim, Elena, Olabi, Bayanne, Admane, Chloe, Foster, April Rose, Huang, Ni, Botting, Rachel A., Torabi, Fereshteh, Sumanaweera, Dinithi, Le, Anh Phuong, Kim, Jin, Verger, Luca, Stephenson, Emily, Adão, Diana, Ganier, Clarisse, Gim, Kelly Y., Serdy, Sara A., Deakin, CiCi, Goh, Issac, Steele, Lloyd, Annusver, Karl, Miah, Mohi-Uddin, Tun, Win Min, Moghimi, Pejvak, Kwakwa, Kwasi Amoako, Li, Tong, Basurto Lozada, Daniela, Rumney, Ben, Tudor, Catherine L., Roberts, Kenny, Chipampe, Nana-Jane, Sidhpura, Keval, Englebert, Justin, Jardine, Laura, Reynolds, Gary, Rose, Antony, Rowe, Vicky, Pritchard, Sophie, Mulas, Ilaria, Fletcher, James, Popescu, Dorin-Mirel, Poyner, Elizabeth, Dubois, Anna, Guy, Alyson, Filby, Andrew, Lisgo, Steven, Barker, Roger A., Glass, Ian A., Park, Jong-Eun, Vento-Tormo, Roser, Nikolova, Marina Tsvetomilova, He, Peng, Lawrence, John E. G., Moore, Josh, Ballereau, Stephane, Hale, Christine B., Shanmugiah, Vijaya, Horsfall, David, Rajan, Neil, McGrath, John A., O’Toole, Edel A., Treutlein, Barbara, Bayraktar, Omer, Kasper, Maria, Progatzky, Fränze, Mazin, Pavel, Lee, Jiyoon, Gambardella, Laure, Koehler, Karl R., Teichmann, Sarah A., and Haniffa, Muzlifah

Published

2024

3. Single-cell atlas of human liver development reveals pathways directing hepatic cell fates

Author

Wesley, Brandon T., Ross, Alexander D. B., Muraro, Daniele, Miao, Zhichao, Saxton, Sarah, Tomaz, Rute A., Morell, Carola M., Ridley, Katherine, Zacharis, Ekaterini D., Petrus-Reurer, Sandra, Kraiczy, Judith, Mahbubani, Krishnaa T., Brown, Stephanie, Garcia-Bernardo, Jose, Alsinet, Clara, Gaffney, Daniel, Horsfall, Dave, Tysoe, Olivia C., Botting, Rachel A., Stephenson, Emily, Popescu, Dorin-Mirel, MacParland, Sonya, Bader, Gary, McGilvray, Ian D., Ortmann, Daniel, Sampaziotis, Fotios, Saeb-Parsy, Kourosh, Haniffa, Muzlifah, Stevens, Kelly R., Zilbauer, Matthias, Teichmann, Sarah A., and Vallier, Ludovic

Published

2022

4. Blood and immune development in human fetal bone marrow and Down syndrome

Author

Jardine, Laura, Webb, Simone, Goh, Issac, Quiroga Londoño, Mariana, Reynolds, Gary, Mather, Michael, Olabi, Bayanne, Stephenson, Emily, Botting, Rachel A., Horsfall, Dave, Engelbert, Justin, Maunder, Daniel, Mende, Nicole, Murnane, Caitlin, Dann, Emma, McGrath, Jim, King, Hamish, Kucinski, Iwo, Queen, Rachel, Carey, Christopher D., Shrubsole, Caroline, Poyner, Elizabeth, Acres, Meghan, Jones, Claire, Ness, Thomas, Coulthard, Rowen, Elliott, Natalina, O’Byrne, Sorcha, Haltalli, Myriam L. R., Lawrence, John E., Lisgo, Steven, Balogh, Petra, Meyer, Kerstin B., Prigmore, Elena, Ambridge, Kirsty, Jain, Mika Sarkin, Efremova, Mirjana, Pickard, Keir, Creasey, Thomas, Bacardit, Jaume, Henderson, Deborah, Coxhead, Jonathan, Filby, Andrew, Hussain, Rafiqul, Dixon, David, McDonald, David, Popescu, Dorin-Mirel, Kowalczyk, Monika S., Li, Bo, Ashenberg, Orr, Tabaka, Marcin, Dionne, Danielle, Tickle, Timothy L., Slyper, Michal, Rozenblatt-Rosen, Orit, Regev, Aviv, Behjati, Sam, Laurenti, Elisa, Wilson, Nicola K., Roy, Anindita, Göttgens, Berthold, Roberts, Irene, Teichmann, Sarah A., and Haniffa, Muzlifah

Published

2021

5. An investigation of bacterial composition and biofilm structure in mixed-community bioanodes

Author

Popescu, Dorin-Mirel

Subjects

621.31

Abstract

Microbial fuel cells (MFC) are devices that convert chemical energy in soluble organic matter into electrical energy. They can be used for wastewater treatment coupled with energy production as well as for sensing, hydrogen production, electrosynthesis and metal recovery. Implementing these technologies is hindered by low current production. Currently, little is known about anodic communities regarding growth, electrode coverage, bacterial composition, biofilm structure, metabolism and how are they affected by operational factors. Such knowledge is needed to engineer MFCs that can overcome current limitations. The subject of the present study is the mixed-community bioanode. The effects of light, anode-tocathode surface ratio (A/C), substrate composition and anode potential on bioanodes were investigated. Two types of substrates were used: the first was based on sodium acetate and the second was a synthetic wastewater which simulated the chemical composition of real wastewater. First bioanodes were studied in presence and absence of light. A different set of bioanodes were grown at 9 different A/C ratios in single-chamber MFCs. Another set of bioanodes were grown in half-cells at 3 different anode potentials (-400 mV, -200 mV and 0 mV vs Ag/AgCl). The development of anodic biofilms and their long-term dynamics were investigated using a multi-anode reactor which allowed for better replication of running conditions. Geobacter was identified in all bioanodes but its abundance was highly variable and dependent on running conditions. Over time the bacterial composition of bioanodes under constant conditions continuously changed during the first 33 days but stabilised by the 67th day. Bioanodes fed on acetate had higher cell counts, Geobacter percentage, and current output than bioanodes fed on synthetic wastewater. Light exposure decreased coulombic efficiency by almost 14 times and favored growth of Rhodopseudomonas species in the detriment of Geobacter. Abundance of Geobacter increased with anode potential when fed on acetate (from 609.98 106 cells/gram at -400 mV to 5212.38 106 cells/gram at 0 mV) but decreased when fed on synthetic wastewater (from 200.6 106 cells/gram at -400 mV to 49 106 cells/gram at 0 mV). Current density and Geobacter density decreased by an order of magnitude when A/C ratio was varied from 1:12 to 1:1 but remained relatively constant when A/C was increased further to 8:1. Uneven biomass coverage on bioanodes and a decrease of biofilm volume with depth inside bioanodes were observed suggesting that anodes were only partially used by electrigenic bacteria. Results reported here have important implications for future reactor designs, on the use of three-dimensional bioanodes and on long-term applications of Microbial Fuel Cells.

Published

2016

6. A human prenatal skin cell atlas reveals immune cell regulation of skin morphogenesis

Author

Gopee, Nusayhah Hudaa, primary, Huang, Ni, additional, Olabi, Bayanne, additional, Admane, Chloe, additional, Botting, Rachel A, additional, Foster, April Rose, additional, Torabi, Fereshteh, additional, Winheim, Elena, additional, Sumanaweera, Dinithi N, additional, Goh, Issac, additional, Miah, Mohi, additional, Stephenson, Emily, additional, Tun, Win Min, additional, Moghimi, Pejvak, additional, Rumney, Ben, additional, He, Peng, additional, Lawrence, Sid, additional, Roberts, Kenny, additional, Sidhpura, Keval, additional, Englebert, Justin, additional, Jardine, Laura, additional, Reynolds, Gary, additional, Rose, Antony, additional, Ganier, Clarisse, additional, Rowe, Vicky, additional, Pritchard, Sophie, additional, Mulas, Ilaria, additional, Fletcher, James, additional, Popescu, Dorin-Mirel, additional, Poyner, Elizabeth FM, additional, Dubois, Anna, additional, Filby, Andrew, additional, Lisgo, Steven, additional, Barker, Roger A, additional, PARK, JONG-EUN, additional, Vento-Tormo, Roser, additional, Le, Phuong Ahn, additional, Serdy, Sara, additional, Kim, Jin, additional, Deakin, CiCi, additional, Lee, Jiyoon, additional, Nikolova, Marina T, additional, Rajan, Neil, additional, Ballereau, Stephane, additional, Li, Tong, additional, Moore, Josh, additional, Horsfall, David, additional, Basurto Lozada, Daniela, additional, O'Toole, Edel A, additional, Treutlein, Barbara, additional, Bayraktar, Omer, additional, Kasper, Maria, additional, Mazin, Pavel, additional, Gambardella, Laure, additional, Koehler, Karl, additional, Teichmann, Sarah, additional, and Haniffa, Muzlifah, additional

Published

2023

7. Single-cell transcriptomes from human kidneys reveal the cellular identity of renal tumors

Author

Young, Matthew D., Mitchell, Thomas J., Braga, Felipe A. Vieira, Tran, Maxine G. B., Stewart, Benjamin J., Ferdinand, John R., Collord, Grace, Botting, Rachel A., Popescu, Dorin-Mirel, Loudon, Kevin W., Vento-Tormo, Roser, Stephenson, Emily, Cagan, Alex, Farndon, Sarah J., Del Castillo Velasco-Herrera, Martin, Guzzo, Charlotte, Richoz, Nathan, Mamanova, Lira, Aho, Tevita, Armitage, James N., Riddick, Antony C. P., Mushtaq, Imran, Farrell, Stephen, Rampling, Dyanne, Nicholson, James, Filby, Andrew, Burge, Johanna, Lisgo, Steven, Maxwell, Patrick H., Lindsay, Susan, Warren, Anne Y., Stewart, Grant D., Sebire, Neil, Coleman, Nicholas, Haniffa, Muzlifah, Teichmann, Sarah A., Clatworthy, Menna, and Behjati, Sam

Published

2018

8. Decoding human fetal liver haematopoiesis

Author

Popescu, Dorin-Mirel, Botting, Rachel A., Stephenson, Emily, Green, Kile, Webb, Simone, Jardine, Laura, and Calderbank, Emily F.

Subjects

Liver cells -- Identification and classification, Hematopoiesis -- Methods, Fetal tissues -- Identification and classification -- Genetic aspects, DNA testing -- Methods, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Definitive haematopoiesis in the fetal liver supports self-renewal and differentiation of haematopoietic stem cells and multipotent progenitors (HSC/MPPs) but remains poorly defined in humans. Here, using single-cell transcriptome profiling of approximately 140,000 liver and 74,000 skin, kidney and yolk sac cells, we identify the repertoire of human blood and immune cells during development. We infer differentiation trajectories from HSC/MPPs and evaluate the influence of the tissue microenvironment on blood and immune cell development. We reveal physiological erythropoiesis in fetal skin and the presence of mast cells, natural killer and innate lymphoid cell precursors in the yolk sac. We demonstrate a shift in the haemopoietic composition of fetal liver during gestation away from being predominantly erythroid, accompanied by a parallel change in differentiation potential of HSC/MPPs, which we functionally validate. Our integrated map of fetal liver haematopoiesis provides a blueprint for the study of paediatric blood and immune disorders, and a reference for harnessing the therapeutic potential of HSC/MPPs. Single-cell transcriptomic profiling of fetal liver, skin, kidney and yolk sac reveals the differentiation trajectories of human haematopoietic stem cells and multipotent progenitors, which are validated to produce an integrated map of fetal liver haematopoiesis., Author(s): Dorin-Mirel Popescu [sup.1] , Rachel A. Botting [sup.1] , Emily Stephenson [sup.1] , Kile Green [sup.1] , Simone Webb [sup.1] , Laura Jardine [sup.1] , Emily F. Calderbank [sup.2] [...]

Published

2019

9. Yolk sac cell atlas reveals multiorgan functions during human early development

Author

Goh, Issac, primary, Botting, Rachel A., additional, Rose, Antony, additional, Webb, Simone, additional, Engelbert, Justin, additional, Gitton, Yorick, additional, Stephenson, Emily, additional, Quiroga Londoño, Mariana, additional, Mather, Michael, additional, Mende, Nicole, additional, Imaz-Rosshandler, Ivan, additional, Yang, Lu, additional, Horsfall, Dave, additional, Basurto-Lozada, Daniela, additional, Chipampe, Nana-Jane, additional, Rook, Victoria, additional, Lee, Jimmy Tsz Hang, additional, Ton, Mai-Linh, additional, Keitley, Daniel, additional, Mazin, Pavel, additional, Vijayabaskar, M. S., additional, Hannah, Rebecca, additional, Gambardella, Laure, additional, Green, Kile, additional, Ballereau, Stephane, additional, Inoue, Megumi, additional, Tuck, Elizabeth, additional, Lorenzi, Valentina, additional, Kwakwa, Kwasi, additional, Alsinet, Clara, additional, Olabi, Bayanne, additional, Miah, Mohi, additional, Admane, Chloe, additional, Popescu, Dorin-Mirel, additional, Acres, Meghan, additional, Dixon, David, additional, Ness, Thomas, additional, Coulthard, Rowen, additional, Lisgo, Steven, additional, Henderson, Deborah J., additional, Dann, Emma, additional, Suo, Chenqu, additional, Kinston, Sarah J., additional, Park, Jong-eun, additional, Polanski, Krzysztof, additional, Marioni, John, additional, van Dongen, Stijn, additional, Meyer, Kerstin B., additional, de Bruijn, Marella, additional, Palis, James, additional, Behjati, Sam, additional, Laurenti, Elisa, additional, Wilson, Nicola K., additional, Vento-Tormo, Roser, additional, Chédotal, Alain, additional, Bayraktar, Omer, additional, Roberts, Irene, additional, Jardine, Laura, additional, Göttgens, Berthold, additional, Teichmann, Sarah A., additional, and Haniffa, Muzlifah, additional

Published

2023

10. Multi-organ functions of yolk sac during human early development

Author

Botting, Rachel A, primary, Goh, Issac, additional, Rose, Antony, additional, Webb, Simone, additional, Engelbert, Justin, additional, Gitton, Yorick, additional, Stephenson, Emily, additional, Quiroga Londoño, Mariana, additional, Mather, Michael, additional, Mende, Nicole, additional, Imaz-Rosshandler, Ivan, additional, Horsfall, Dave, additional, Basurto-Lozada, Daniela, additional, Chipampe, Nana-Jane, additional, Rook, Victoria, additional, Mazin, Pavel, additional, Vijayabaskar, MS, additional, Hannah, Rebecca, additional, Gambardella, Laure, additional, Green, Kile, additional, Ballereau, Stephane, additional, Inoue, Megumi, additional, Tuck, Liz, additional, Lorenzi, Valentina, additional, Kwakwa, Kwasi, additional, Alsinet, Clara, additional, Olabi, Bayanne, additional, Miah, Mohi, additional, Admane, Chloe, additional, Popescu, Dorin-Mirel, additional, Acres, Meghan, additional, Dixon, David, additional, Coulthard, Rowen, additional, Lisgo, Steven, additional, Henderson, Deborah J, additional, Dann, Emma, additional, Suo, Chenqu, additional, Kinston, Sarah J, additional, Park, Jong-eun, additional, Polanski, Krzysztof, additional, Van Dongen, Stijn, additional, Meyer, Kerstin B, additional, de Bruijn, Marella, additional, Palis, James, additional, Behjati, Sam, additional, Laurenti, Elisa, additional, Wilson, Nicola K, additional, Vento-Tormo, Roser, additional, Chédotal, Alain, additional, Bayraktar, Omer, additional, Roberts, Irene, additional, Jardine, Laura, additional, Göttgens, Berthold, additional, Teichmann, Sarah A, additional, and Haniffa, Muzlifah, additional

Published

2022

11. Single-cell atlas of human liver development reveals pathways directing hepatic cell fates

Author

Wesley, Brandon T., primary, Ross, Alexander D. B., additional, Muraro, Daniele, additional, Miao, Zhichao, additional, Saxton, Sarah, additional, Tomaz, Rute A., additional, Morell, Carola M., additional, Ridley, Katherine, additional, Zacharis, Ekaterini D., additional, Petrus-Reurer, Sandra, additional, Kraiczy, Judith, additional, Mahbubani, Krishnaa T., additional, Brown, Stephanie, additional, Garcia-Bernardo, Jose, additional, Alsinet, Clara, additional, Gaffney, Daniel, additional, Tysoe, Olivia C., additional, Botting, Rachel A., additional, Stephenson, Emily, additional, Popescu, Dorin-Mirel, additional, MacParland, Sonya, additional, Bader, Gary, additional, McGilvray, Ian D., additional, Ortmann, Daniel, additional, Sampaziotis, Fotios, additional, Saeb-Parsy, Kourosh, additional, Haniffa, Muzlifah, additional, Stevens, Kelly R., additional, Zilbauer, Matthias, additional, Teichmann, Sarah A., additional, and Vallier, Ludovic, additional

Published

2022

12. Intrinsic and extrinsic regulation of human fetal bone marrow haematopoiesis and perturbations in Down syndrome

Author

Jardine, Laura, primary, Webb, Simone, additional, Goh, Issac, additional, Londoño, Mariana Quiroga, additional, Reynolds, Gary, additional, Mather, Michael, additional, Olabi, Bayanne, additional, Stephenson, Emily, additional, Botting, Rachel A., additional, Horsfall, Dave, additional, Engelbert, Justin, additional, Maunder, Daniel, additional, Mende, Nicole, additional, Murnane, Caitlin, additional, Dann, Emma, additional, McGrath, Jim, additional, King, Hamish, additional, Kucinski, Iwo, additional, Queen, Rachel, additional, Carey, Christopher D, additional, Shrubsole, Caroline, additional, Poyner, Elizabeth, additional, Acres, Meghan, additional, Jones, Claire, additional, Ness, Thomas, additional, Coulthard, Rowan, additional, Elliott, Natalina, additional, O’Byrne, Sorcha, additional, Haltalli, Myriam L. R., additional, Lawrence, John E, additional, Lisgo, Steven, additional, Balogh, Petra, additional, Meyer, Kerstin B, additional, Prigmore, Elena, additional, Ambridge, Kirsty, additional, Jain, Mika Sarkin, additional, Efremova, Mirjana, additional, Pickard, Keir, additional, Creasey, Thomas, additional, Bacardit, Jaume, additional, Henderson, Deborah, additional, Coxhead, Jonathan, additional, Filby, Andrew, additional, Hussain, Rafiqul, additional, Dixon, David, additional, McDonald, David, additional, Popescu, Dorin-Mirel, additional, Kowalczyk, Monika S., additional, Li, Bo, additional, Ashenberg, Orr, additional, Tabaka, Marcin, additional, Dionne, Danielle, additional, Tickle, Timothy L., additional, Slyper, Michal, additional, Rozenblatt-Rosen, Orit, additional, Regev, Aviv, additional, Behjati, Sam, additional, Laurenti, Elisa, additional, Wilson, Nicola K., additional, Roy, Anindita, additional, Göttgens, Berthold, additional, Roberts, Irene, additional, Teichmann, Sarah A., additional, and Haniffa, Muzlifah, additional

Published

2021

13. Developmental cell programs are co-opted in inflammatory skin disease

Author

Reynolds, Gary, primary, Vegh, Peter, additional, Fletcher, James, additional, Poyner, Elizabeth F. M., additional, Stephenson, Emily, additional, Goh, Issac, additional, Botting, Rachel A., additional, Huang, Ni, additional, Olabi, Bayanne, additional, Dubois, Anna, additional, Dixon, David, additional, Green, Kile, additional, Maunder, Daniel, additional, Engelbert, Justin, additional, Efremova, Mirjana, additional, Polański, Krzysztof, additional, Jardine, Laura, additional, Jones, Claire, additional, Ness, Thomas, additional, Horsfall, Dave, additional, McGrath, Jim, additional, Carey, Christopher, additional, Popescu, Dorin-Mirel, additional, Webb, Simone, additional, Wang, Xiao-nong, additional, Sayer, Ben, additional, Park, Jong-Eun, additional, Negri, Victor A., additional, Belokhvostova, Daria, additional, Lynch, Magnus D., additional, McDonald, David, additional, Filby, Andrew, additional, Hagai, Tzachi, additional, Meyer, Kerstin B., additional, Husain, Akhtar, additional, Coxhead, Jonathan, additional, Vento-Tormo, Roser, additional, Behjati, Sam, additional, Lisgo, Steven, additional, Villani, Alexandra-Chloé, additional, Bacardit, Jaume, additional, Jones, Philip H., additional, O’Toole, Edel A., additional, Ogg, Graham S., additional, Rajan, Neil, additional, Reynolds, Nick J., additional, Teichmann, Sarah A., additional, Watt, Fiona M., additional, and Haniffa, Muzlifah, additional

Published

2021

14. Poised cell circuits in human skin are activated in disease

Author

Reynolds, Gary, primary, Vegh, Peter, additional, Fletcher, James, additional, Poyner, Elizabeth F.M., additional, Stephenson, Emily, additional, Goh, Issac, additional, Botting, Rachel A., additional, Huang, Ni, additional, Olabi, Bayanne, additional, Dubois, Anna, additional, Dixon, David, additional, Green, Kile, additional, Maunder, Daniel, additional, Engelbert, Justin, additional, Efremova, Mirjana, additional, Polański, Krzysztof, additional, Jardine, Laura, additional, Jones, Claire, additional, Ness, Thomas, additional, Horsfall, Dave, additional, McGrath, Jim, additional, Carey, Christopher, additional, Popescu, Dorin-Mirel, additional, Webb, Simone, additional, Wang, Xiao-nong, additional, Sayer, Ben, additional, Park, Jong-Eun, additional, Negri, Victor A., additional, Belokhvostova, Daria, additional, Lynch, Magnus, additional, McDonald, David, additional, Filby, Andrew, additional, Hagai, Tzachi, additional, Meyer, Kerstin B., additional, Husain, Akhtar, additional, Coxhead, Jonathan, additional, Vento-Tormo, Roser, additional, Behjati, Sam, additional, Lisgo, Steven, additional, Villani, Alexandra-Chloé, additional, Bacardit, Jaume, additional, Jones, Phil, additional, O’Toole, Edel A., additional, Ogg, Graham S., additional, Rajan, Neil, additional, Reynolds, Nick J., additional, Teichmann, Sarah A., additional, Watt, Fiona, additional, and Haniffa, Muzlifah, additional

Published

2020

15. A cell atlas of human thymic development defines T cell repertoire formation

Author

Park, Jong-Eun, primary, Botting, Rachel A., additional, Domínguez Conde, Cecilia, additional, Popescu, Dorin-Mirel, additional, Lavaert, Marieke, additional, Kunz, Daniel J., additional, Goh, Issac, additional, Stephenson, Emily, additional, Ragazzini, Roberta, additional, Tuck, Elizabeth, additional, Wilbrey-Clark, Anna, additional, Roberts, Kenny, additional, Kedlian, Veronika R., additional, Ferdinand, John R., additional, He, Xiaoling, additional, Webb, Simone, additional, Maunder, Daniel, additional, Vandamme, Niels, additional, Mahbubani, Krishnaa T., additional, Polanski, Krzysztof, additional, Mamanova, Lira, additional, Bolt, Liam, additional, Crossland, David, additional, de Rita, Fabrizio, additional, Fuller, Andrew, additional, Filby, Andrew, additional, Reynolds, Gary, additional, Dixon, David, additional, Saeb-Parsy, Kourosh, additional, Lisgo, Steven, additional, Henderson, Deborah, additional, Vento-Tormo, Roser, additional, Bayraktar, Omer A., additional, Barker, Roger A., additional, Meyer, Kerstin B., additional, Saeys, Yvan, additional, Bonfanti, Paola, additional, Behjati, Sam, additional, Clatworthy, Menna R., additional, Taghon, Tom, additional, Haniffa, Muzlifah, additional, and Teichmann, Sarah A., additional

Published

2020

16. Spatiotemporal immune zonation of the human kidney

Author

Stewart, Benjamin J., primary, Ferdinand, John R., additional, Young, Matthew D., additional, Mitchell, Thomas J., additional, Loudon, Kevin W., additional, Riding, Alexandra M., additional, Richoz, Nathan, additional, Frazer, Gordon L., additional, Staniforth, Joy U. L., additional, Vieira Braga, Felipe A., additional, Botting, Rachel A., additional, Popescu, Dorin-Mirel, additional, Vento-Tormo, Roser, additional, Stephenson, Emily, additional, Cagan, Alex, additional, Farndon, Sarah J., additional, Polanski, Krzysztof, additional, Efremova, Mirjana, additional, Green, Kile, additional, Del Castillo Velasco-Herrera, Martin, additional, Guzzo, Charlotte, additional, Collord, Grace, additional, Mamanova, Lira, additional, Aho, Tevita, additional, Armitage, James N., additional, Riddick, Antony C. P., additional, Mushtaq, Imran, additional, Farrell, Stephen, additional, Rampling, Dyanne, additional, Nicholson, James, additional, Filby, Andrew, additional, Burge, Johanna, additional, Lisgo, Steven, additional, Lindsay, Susan, additional, Bajenoff, Marc, additional, Warren, Anne Y., additional, Stewart, Grant D., additional, Sebire, Neil, additional, Coleman, Nicholas, additional, Haniffa, Muzlifah, additional, Teichmann, Sarah A., additional, Behjati, Sam, additional, and Clatworthy, Menna R., additional

Published

2019

17. Decoding the development of the blood and immune systems during human fetal liver haematopoiesis

Author

Popescu, Dorin-Mirel, primary, Botting, Rachel A., additional, Stephenson, Emily, additional, Green, Kile, additional, Jardine, Laura, additional, Calderbank, Emily F., additional, Efremova, Mirjana, additional, Acres, Meghan, additional, Maunder, Daniel, additional, Vegh, Peter, additional, Goh, Issac, additional, Gitton, Yorick, additional, Park, Jongeun, additional, Polanski, Krzysztof, additional, Vento-Tormo, Roser, additional, Miao, Zhichao, additional, Rowell, Rachel, additional, McDonald, David, additional, Fletcher, James, additional, Dixon, David, additional, Poyner, Elizabeth, additional, Reynolds, Gary, additional, Mather, Michael, additional, Moldovan, Corina, additional, Mamanova, Lira, additional, Greig, Frankie, additional, Young, Matthew, additional, Meyer, Kerstin, additional, Lisgo, Steven, additional, Bacardit, Jaume, additional, Fuller, Andrew, additional, Millar, Ben, additional, Innes, Barbara, additional, Lindsay, Susan, additional, Stubbington, Michael J. T., additional, Kowalczyk, Monika S., additional, Li, Bo, additional, Ashenbrg, Orr, additional, Tabaka, Marcin, additional, Dionne, Danielle, additional, Tickle, Timothy L., additional, Slyper, Michal, additional, Rozenblatt-Rosen, Orit, additional, Filby, Andrew, additional, Villani, Alexandra-Chloe, additional, Roy, Anindita, additional, Regev, Aviv, additional, Chedotal, Alain, additional, Roberts, Irene, additional, Göttgens, Berthold, additional, Laurenti, Elisa, additional, Behjati, Sam, additional, Teichmann, Sarah A., additional, and Haniffa, Muzlifah, additional

Published

2019

18. A cell atlas of human thymic development defines T cell repertoire formation.

Author

Jong-Eun Park, Botting, Rachel A., Domínguez Conde, Cecilia, Popescu, Dorin-Mirel, Lavaert, Marieke, Kunz, Daniel J., Goh, Issac, Stephenson, Emily, Ragazzini, Roberta, Tuck, Elizabeth, Wilbrey-Clark, Anna, Roberts, Kenny, Kedlian, Veronika R., Ferdinand, John R., Xiaoling He, Webb, Simone, Maunder, Daniel, Vandamme, Niels, Mahbubani, Krishnaa T., and Polanski, Krzysztof

Published

2020

19. Decoding human fetal liver haematopoiesis

Author

Popescu, Dorin-Mirel, Botting, Rachel A, Stephenson, Emily, Green, Kile, Webb, Simone, Jardine, Laura, Calderbank, Emily F, Polanski, Krzysztof, Goh, Issac, Efremova, Mirjana, Acres, Meghan, Maunder, Daniel, Vegh, Peter, Gitton, Yorick, Park, Jong-Eun, Vento-Tormo, Roser, Miao, Zhichao, Dixon, David, Rowell, Rachel, McDonald, David, Fletcher, James, Poyner, Elizabeth, Reynolds, Gary, Mather, Michael, Moldovan, Corina, Mamanova, Lira, Greig, Frankie, Young, Matthew D, Meyer, Kerstin B, Lisgo, Steven, Bacardit, Jaume, Fuller, Andrew, Millar, Ben, Innes, Barbara, Lindsay, Susan, Stubbington, Michael JT, Kowalczyk, Monika S, Li, Bo, Ashenberg, Orr, Tabaka, Marcin, Dionne, Danielle, Tickle, Timothy L, Slyper, Michal, Rozenblatt-Rosen, Orit, Filby, Andrew, Carey, Peter, Villani, Alexandra-Chloé, Roy, Anindita, Regev, Aviv, Chédotal, Alain, Roberts, Irene, Göttgens, Berthold, Behjati, Sam, Laurenti, Elisa, Teichmann, Sarah A, and Haniffa, Muzlifah

Subjects

Blood Cells, Lymphoid Tissue, Gene Expression Profiling, Stem Cells, Flow Cytometry, 3. Good health, Hematopoiesis, Fetus, Cellular Microenvironment, Liver, embryonic structures, Humans, Female, Single-Cell Analysis

Abstract

Definitive haematopoiesis in the fetal liver supports self-renewal and differentiation of haematopoietic stem cells and multipotent progenitors (HSC/MPPs) but remains poorly defined in humans. Here, using single-cell transcriptome profiling of approximately 140,000 liver and 74,000 skin, kidney and yolk sac cells, we identify the repertoire of human blood and immune cells during development. We infer differentiation trajectories from HSC/MPPs and evaluate the influence of the tissue microenvironment on blood and immune cell development. We reveal physiological erythropoiesis in fetal skin and the presence of mast cells, natural killer and innate lymphoid cell precursors in the yolk sac. We demonstrate a shift in the haemopoietic composition of fetal liver during gestation away from being predominantly erythroid, accompanied by a parallel change in differentiation potential of HSC/MPPs, which we functionally validate. Our integrated map of fetal liver haematopoiesis provides a blueprint for the study of paediatric blood and immune disorders, and a reference for harnessing the therapeutic potential of HSC/MPPs., We acknowledge funding from the Wellcome Human Cell Atlas Strategic Science Support (WT211276/Z/18/Z); M.H. is funded by Wellcome (WT107931/Z/15/Z), The Lister Institute for Preventive Medicine and NIHR and Newcastle-Biomedical Research Centre; S.A.T. is funded by Wellcome (WT206194), ERC Consolidator and EU MRG-Grammar awards and; S.B. is funded by Wellcome (WT110104/Z/15/Z) and St. Baldrick’s Foundation; E.L. is funded by a Wellcome Sir Henry Dale and Royal Society Fellowships, European Haematology Association, Wellcome and MRC to the Wellcome-MRC Cambridge Stem Cell Institute and BBSRC.

20. Single-cell transcriptomes from human kidneys reveal the cellular identity of renal tumors

Author

Young, Matthew D, Mitchell, Thomas J, Vieira Braga, Felipe A, Tran, Maxine GB, Stewart, Benjamin J, Ferdinand, John R, Collord, Grace, Botting, Rachel A, Popescu, Dorin-Mirel, Loudon, Kevin W, Vento-Tormo, Roser, Stephenson, Emily, Cagan, Alex, Farndon, Sarah J, Del Castillo Velasco-Herrera, Martin, Guzzo, Charlotte, Richoz, Nathan, Mamanova, Lira, Aho, Tevita, Armitage, James N, Riddick, Antony CP, Mushtaq, Imran, Farrell, Stephen, Rampling, Dyanne, Nicholson, James, Filby, Andrew, Burge, Johanna, Lisgo, Steven, Maxwell, Patrick H, Lindsay, Susan, Warren, Anne Y, Stewart, Grant D, Sebire, Neil, Coleman, Nicholas, Haniffa, Muzlifah, Teichmann, Sarah A, Clatworthy, Menna, and Behjati, Sam

Subjects

Adult, Genetic Variation, Humans, Single-Cell Analysis, Child, Kidney, Transcriptome, Carcinoma, Renal Cell, Wilms Tumor, Kidney Neoplasms, 3. Good health

Abstract

Messenger RNA encodes cellular function and phenotype. In the context of human cancer, it defines the identities of malignant cells and the diversity of tumor tissue. We studied 72,501 single-cell transcriptomes of human renal tumors and normal tissue from fetal, pediatric, and adult kidneys. We matched childhood Wilms tumor with specific fetal cell types, thus providing evidence for the hypothesis that Wilms tumor cells are aberrant fetal cells. In adult renal cell carcinoma, we identified a canonical cancer transcriptome that matched a little-known subtype of proximal convoluted tubular cell. Analyses of the tumor composition defined cancer-associated normal cells and delineated a complex vascular endothelial growth factor (VEGF) signaling circuit. Our findings reveal the precise cellular identities and compositions of human kidney tumors.