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1. Targeted serum proteomics of longitudinal samples from newly diagnosed youth with type 1 diabetes distinguishes markers of disease and C-peptide trajectory

Author

Moulder, Robert, Välikangas, Tommi, Hirvonen, M. Karoliina, Suomi, Tomi, Brorsson, Caroline A., Lietzén, Niina, Bruggraber, Sylvaine F. A., Overbergh, Lut, Dunger, David B., Peakman, Mark, Chmura, Piotr J., Brunak, Soren, Schulte, Anke M., Mathieu, Chantal, Knip, Mikael, Elo, Laura L., and Lahesmaa, Riitta

Published
2023
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2. Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits

Author

Brown, Andrew A., Fernandez-Tajes, Juan J., Hong, Mun-gwan, Brorsson, Caroline A., Koivula, Robert W., Davtian, David, Dupuis, Théo, Sartori, Ambra, Michalettou, Theodora-Dafni, Forgie, Ian M., Adam, Jonathan, Allin, Kristine H., Caiazzo, Robert, Cederberg, Henna, De Masi, Federico, Elders, Petra J. M., Giordano, Giuseppe N., Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison J., Howald, Cédric, Jones, Angus G., Kokkola, Tarja, Laakso, Markku, Mahajan, Anubha, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Mourby, Miranda, Musholt, Petra B., Nilsson, Birgitte, Pattou, Francois, Penet, Deborah, Raverdy, Violeta, Ridderstråle, Martin, Romano, Luciana, Rutters, Femke, Sharma, Sapna, Teare, Harriet, ‘t Hart, Leen, Tsirigos, Konstantinos D., Vangipurapu, Jagadish, Vestergaard, Henrik, Brunak, Søren, Franks, Paul W., Frost, Gary, Grallert, Harald, Jablonka, Bernd, McCarthy, Mark I., Pavo, Imre, Pedersen, Oluf, Ruetten, Hartmut, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., Pearson, Ewan R., Dermitzakis, Emmanouil T., and Viñuela, Ana

Published
2023
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3. Discovery of drug–omics associations in type 2 diabetes with generative deep-learning models

Author

Allesøe, Rosa Lundbye, Lundgaard, Agnete Troen, Hernández Medina, Ricardo, Aguayo-Orozco, Alejandro, Johansen, Joachim, Nissen, Jakob Nybo, Brorsson, Caroline, Mazzoni, Gianluca, Niu, Lili, Biel, Jorge Hernansanz, Leal Rodríguez, Cristina, Brasas, Valentas, Webel, Henry, Benros, Michael Eriksen, Pedersen, Anders Gorm, Chmura, Piotr Jaroslaw, Jacobsen, Ulrik Plesner, Mari, Andrea, Koivula, Robert, Mahajan, Anubha, Vinuela, Ana, Tajes, Juan Fernandez, Sharma, Sapna, Haid, Mark, Hong, Mun-Gwan, Musholt, Petra B., De Masi, Federico, Vogt, Josef, Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Jones, Angus, Kennedy, Gwen, Bell, Jimmy, Thomas, E. Louise, Frost, Gary, Thomsen, Henrik, Hansen, Elizaveta, Hansen, Tue Haldor, Vestergaard, Henrik, Muilwijk, Mirthe, Blom, Marieke T., ‘t Hart, Leen M., Pattou, Francois, Raverdy, Violeta, Brage, Soren, Kokkola, Tarja, Heggie, Alison, McEvoy, Donna, Mourby, Miranda, Kaye, Jane, Hattersley, Andrew, McDonald, Timothy, Ridderstråle, Martin, Walker, Mark, Forgie, Ian, Giordano, Giuseppe N., Pavo, Imre, Ruetten, Hartmut, Pedersen, Oluf, Hansen, Torben, Dermitzakis, Emmanouil, Franks, Paul W., Schwenk, Jochen M., Adamski, Jerzy, McCarthy, Mark I., Pearson, Ewan, Banasik, Karina, Rasmussen, Simon, and Brunak, Søren

Published
2023
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4. Gene expression signature predicts rate of type 1 diabetes progression

Author

Mathieu, Chantal, Gillard, Pieter, Casteels, Kristina, Overbergh, Lutgart, Dunger, David, Wallace, Chris, Evans, Mark, Thankamony, Ajay, Hendriks, Emile, Bruggraber, Sylvaine, Marcoveccchio, Loredana, Peakman, Mark, Tree, Timothy, Morgan, Noel G., Richardson, Sarah, Todd, John A., Wicker, Linda, Mander, Adrian, Dayan, Colin, Alhadj Ali, Mohammad, Pieber, Thomas, Eizirik, Decio L., Cnop, Myriam, Brunak, Søren, Pociot, Flemming, Johannesen, Jesper, Rossing, Peter, Quigley, Cristina Legido, Mallone, Roberto, Scharfmann, Raphael, Boitard, Christian, Knip, Mikael, Otonkoski, Timo, Veijola, Riitta, Lahesmaa, Riitta, Oresic, Matej, Toppari, Jorma, Danne, Thomas, Ziegler, Anette G., Achenbach, Peter, Rodriguez-Calvo, Teresa, Solimena, Michele, Bonifacio, Ezio E., Speier, Stephan, Holl, Reinhard, Dotta, Francesco, Chiarelli, Francesco, Marchetti, Piero, Bosi, Emanuele, Cianfarani, Stefano, Ciampalini, Paolo, De Beaufort, Carine, Dahl-Jørgensen, Knut, Skrivarhaug, Torild, Joner, Geir, Krogvold, Lars, Jarosz-Chobot, Przemka, Battelino, Tadej, Thorens, Bernard, Gotthardt, Martin, Roep, Bart O., Nikolic, Tanja, Zaldumbide, Arnaud, Lernmark, Ake, Lundgren, Marcus, Costacalde, Guillaume, Strube, Thorsten, Schulte, Anke M., Nitsche, Almut, Vela, Jose, Von Herrath, Matthias, Wesley, Johnna, Napolitano-Rosen, Antonella, Thomas, Melissa, Schloot, Nanette, Goldfine, Allison, Waldron-Lynch, Frank, Kompa, Jill, Vedala, Aruna, Hartmann, Nicole, Nicolas, Gwenaelle, van Rampelbergh, Jean, Bovy, Nicolas, Dutta, Sanjoy, Soderberg, Jeannette, Ahmed, Simi, Martin, Frank, Latres, Esther, Agiostratidou, Gina, Koralova, Anne, Willemsen, Ruben, Smith, Anne, Anand, Binu, Datta, Vipan, Puthi, Vijith, Zac-Varghese, Sagen, Dias, Renuka, Sundaram, Premkumar, Vaidya, Bijay, Patterson, Catherine, Owen, Katharine, Piel, Barbara, Heller, Simon, Randell, Tabitha, Gazis, Tasso, Reismen, Elise Bismuth, Carel, Jean-Claude, Riveline, Jean-Pierre, Gautier, Jean-Francoise, Andreelli, Fabrizion, Travert, Florence, Cosson, Emmanuel, Penfornis, Alfred, Petit, Catherine, Feve, Bruno, Lucidarme, Nadine, Beressi, Jean-Paul, Ajzenman, Catherina, Radu, Alina, Greteau-Hamoumou, Stephanie, Bibal, Cecile, Meissner, Thomas, Heidtmann, Bettina, Toni, Sonia, Rami-Merhar, Birgit, Eeckhout, Bart, Peene, Bernard, Vantongerloo, N., Maes, Toon, Gommers, Leen, Suomi, Tomi, Starskaia, Inna, Kalim, Ubaid Ullah, Rasool, Omid, Jaakkola, Maria K., Grönroos, Toni, Välikangas, Tommi, Brorsson, Caroline, Mazzoni, Gianluca, Overbergh, Lut, Chmura, Piotr, and Elo, Laura L.

Published
2023
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6. Author Correction: Discovery of drug–omics associations in type 2 diabetes with generative deep-learning models

Author

Allesøe, Rosa Lundbye, Lundgaard, Agnete Troen, Hernández Medina, Ricardo, Aguayo-Orozco, Alejandro, Johansen, Joachim, Nissen, Jakob Nybo, Brorsson, Caroline, Mazzoni, Gianluca, Niu, Lili, Biel, Jorge Hernansanz, Leal Rodríguez, Cristina, Brasas, Valentas, Webel, Henry, Benros, Michael Eriksen, Pedersen, Anders Gorm, Chmura, Piotr Jaroslaw, Jacobsen, Ulrik Plesner, Mari, Andrea, Koivula, Robert, Mahajan, Anubha, Vinuela, Ana, Tajes, Juan Fernandez, Sharma, Sapna, Haid, Mark, Hong, Mun-Gwan, Musholt, Petra B., De Masi, Federico, Vogt, Josef, Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Jones, Angus, Kennedy, Gwen, Bell, Jimmy, Thomas, E. Louise, Frost, Gary, Thomsen, Henrik, Hansen, Elizaveta, Hansen, Tue Haldor, Vestergaard, Henrik, Muilwijk, Mirthe, Blom, Marieke T., ‘t Hart, Leen M., Pattou, Francois, Raverdy, Violeta, Brage, Soren, Kokkola, Tarja, Heggie, Alison, McEvoy, Donna, Mourby, Miranda, Kaye, Jane, Hattersley, Andrew, McDonald, Timothy, Ridderstråle, Martin, Walker, Mark, Forgie, Ian, Giordano, Giuseppe N., Pavo, Imre, Ruetten, Hartmut, Pedersen, Oluf, Hansen, Torben, Dermitzakis, Emmanouil, Franks, Paul W., Schwenk, Jochen M., Adamski, Jerzy, McCarthy, Mark I., Pearson, Ewan, Banasik, Karina, Rasmussen, Simon, and Brunak, Søren

Published
2023
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7. Dissecting the interplay between ageing, sex and body mass index on a molecular level

Author

Michalettou, Theodora Dafni, Hong, Mun-Gwan, Fernandez, Juan, Sharma, Sapna, Brorsson, Caroline, Koivula, Robert, Adamski, Jerzy, Brunak, Soren, Dermitzakis, Emmanouil, Franks, Paul, McCarthy, Mark, Pearson, Ewan, Schwenk, Jochen M., Walker, Mark, Brown, Andrew, Vinuela, Ana, Michalettou, Theodora Dafni, Hong, Mun-Gwan, Fernandez, Juan, Sharma, Sapna, Brorsson, Caroline, Koivula, Robert, Adamski, Jerzy, Brunak, Soren, Dermitzakis, Emmanouil, Franks, Paul, McCarthy, Mark, Pearson, Ewan, Schwenk, Jochen M., Walker, Mark, Brown, Andrew, and Vinuela, Ana

Abstract

QC 20240301

Published
2024

8. Multi‐omics analysis reveals drivers of loss of β‐cell function after newly diagnosed autoimmune type 1 diabetes: An INNODIA multicenter study.

Author

Armenteros, Jose Juan Almagro, Brorsson, Caroline, Johansen, Christian Holm, Banasik, Karina, Mazzoni, Gianluca, Moulder, Robert, Hirvonen, Karoliina, Suomi, Tomi, Rasool, Omid, Bruggraber, Sylvaine F. A., Marcovecchio, M. Loredana, Hendricks, Emile, Al‐Sari, Naba, Mattila, Ismo, Legido‐Quigley, Cristina, Suvitaival, Tommi, Chmura, Piotr J., Knip, Mikael, Schulte, Anke M., and Lee, Jeong Heon

Subjects
TYPE 1 diabetes, MULTIOMICS, G protein coupled receptors, KILLER cells, GENETIC translation, AUTOIMMUNE diseases
Abstract

Aims: Heterogeneity in the rate of β‐cell loss in newly diagnosed type 1 diabetes patients is poorly understood and creates a barrier to designing and interpreting disease‐modifying clinical trials. Integrative analyses of baseline multi‐omics data obtained after the diagnosis of type 1 diabetes may provide mechanistic insight into the diverse rates of disease progression after type 1 diabetes diagnosis. Methods: We collected samples in a pan‐European consortium that enabled the concerted analysis of five different omics modalities in data from 97 newly diagnosed patients. In this study, we used Multi‐Omics Factor Analysis to identify molecular signatures correlating with post‐diagnosis decline in β‐cell mass measured as fasting C‐peptide. Results: Two molecular signatures were significantly correlated with fasting C‐peptide levels. One signature showed a correlation to neutrophil degranulation, cytokine signalling, lymphoid and non‐lymphoid cell interactions and G‐protein coupled receptor signalling events that were inversely associated with a rapid decline in β‐cell function. The second signature was related to translation and viral infection was inversely associated with change in β‐cell function. In addition, the immunomics data revealed a Natural Killer cell signature associated with rapid β‐cell decline. Conclusions: Features that differ between individuals with slow and rapid decline in β‐cell mass could be valuable in staging and prediction of the rate of disease progression and thus enable smarter (shorter and smaller) trial designs for disease modifying therapies as well as offering biomarkers of therapeutic effect. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Genetic studies of abdominal MRI data identify genes regulating hepcidin as major determinants of liver iron concentration

Author

Jennison, Christopher, Ehrhardt, Beate, Baum, Patrick, Schoelsch, Corinna, Freijer, Jan, Grempler, Rolf, Graefe-Mody, Ulrike, Hennige, Anita, Dings, Christiane, Lehr, Thorsten, Scherer, Nina, Sihinecich, Iryna, Pattou, Francois, Raverdi, Violeta, Caiazzo, Robert, Torres, Fanelly, Verkindt, Helene, Mari, Andrea, Tura, Andrea, Giorgino, Toni, Bizzotto, Roberto, Froguel, Philippe, Bonneford, Amelie, Canouil, Mickael, Dhennin, Veronique, Brorsson, Caroline, Brunak, Soren, De Masi, Federico, Gudmundsdóttir, Valborg, Pedersen, Helle, Banasik, Karina, Thomas, Cecilia, Sackett, Peter, Staerfeldt, Hans-Henrik, Lundgaard, Agnete, Nilsson, Birgitte, Nielsen, Agnes, Mazzoni, Gianluca, Karaderi, Tugce, Rasmussen, Simon, Johansen, Joachim, Allesøe, Rosa, Fritsche, Andreas, Thorand, Barbara, Adamski, Jurek, Grallert, Harald, Haid, Mark, Sharma, Sapna, Troll, Martina, Adam, Jonathan, Ferrer, Jorge, Eriksen, Heather, Frost, Gary, Haussler, Ragna, Hong, Mun-gwan, Schwenk, Jochen, Uhlen, Mathias, Nicolay, Claudia, Pavo, Imre, Steckel-Hamann, Birgit, Thomas, Melissa, Adragni, Kofi, Wu, Han, Hart, Leen't, Roderick, Slieker, van Leeuwen, Nienke, Dekkers, Koen, Frau, Francesca, Gassenhuber, Johann, Jablonka, Bernd, Musholt, Petra, Ruetten, Hartmut, Tillner, Joachim, Baltauss, Tania, Bernard Poenaru, Oana, de Preville, Nathalie, Rodriquez, Marianne, Arumugam, Manimozhiyan, Allin, Kristine, Engelbrechtsen, Line, Hansen, Torben, Hansen, Tue, Forman, Annemette, Jonsson, Anna, Pedersen, Oluf, Dutta, Avirup, Vogt, Josef, Vestergaard, Henrik, Laakso, Markku, Kokkola, Tarja, Kuulasmaa, Teemu, Franks, Paul, Giordano, Nick, Pomares-Millan, Hugo, Fitipaldi, Hugo, Mutie, Pascal, Klintenberg, Maria, Bergstrom, Margit, Groop, Leif, Ridderstrale, Martin, Atabaki Pasdar, Naeimeh, Deshmukh, Harshal, Heggie, Alison, Wake, Dianne, McEvoy, Donna, McVittie, Ian, Walker, Mark, Hattersley, Andrew, Hill, Anita, Jones, Angus, McDonald, Timothy, Perry, Mandy, Nice, Rachel, Hudson, Michelle, Thorne, Claire, Dermitzakis, Emmanouil, Viñuela, Ana, Cabrelli, Louise, Loftus, Heather, Dawed, Adem, Donnelly, Louise, Forgie, Ian, Pearson, Ewan, Palmer, Colin, Brown, Andrew, Koivula, Robert, Wesolowska-Andersen, Agata, Abdalla, Moustafa, McRobert, Nicky, Fernandez, Juan, Jiao, Yunlong, Robertson, Neil, Gough, Stephen, Kaye, Jane, Mourby, Miranda, Mahajan, Anubha, McCarthy, Mark, Shah, Nisha, Teare, Harriet, Holl, Reinhard, Koopman, Anitra, Rutters, Femke, Beulens, Joline, Groeneveld, Lenka, Bell, Jimmy, Thomas, Louise, Whitcher, Brandon, Wilman, Henry R., Parisinos, Constantinos A., Atabaki-Pasdar, Naeimeh, Kelly, Matt, Thomas, E. Louise, Neubauer, Stefan, Hingorani, Aroon D., Patel, Riyaz S., Hemingway, Harry, Franks, Paul W., Bell, Jimmy D., Banerjee, Rajarshi, and Yaghootkar, Hanieh

Published
2019
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10. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes: descriptive characteristics of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W., Forgie, Ian M., Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N., Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D. M., Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A., Dawed, Adem Y., De Masi, Federico, Groves, Christopher J., Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H., Rauh, Simone P., Ridderstråle, Martin, Teare, Harriet J. A., Thomas, E. Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline W., Brunak, Søren, Dermitzakis, Emmanouil T., Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J., Pedersen, Oluf, Schwenk, Jochen M., Pavo, Imre, Mari, Andrea, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul W., and for the IMI DIRECT Consortium

Published
2019
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11. Whole blood co-expression modules associate with metabolic traits and type 2 diabetes: an IMI-DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Mazzoni, Gianluca, Allin, Kristine H., Artati, Anna, Beulens, Joline W., Banasik, Karina, Brorsson, Caroline, Cederberg, Henna, Chabanova, Elizaveta, De Masi, Federico, Elders, Petra J., Forgie, Ian, Giordano, Giuseppe N., Grallert, Harald, Gupta, Ramneek, Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison, Hong, Mun-Gwan, Jones, Angus G., Koivula, Robert, Kokkola, Tarja, Laakso, Markku, Løngreen, Peter, Mahajan, Anubha, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Musholt, Petra B., Pavo, Imre, Prehn, Cornelia, Ruetten, Hartmut, Ridderstråle, Martin, Rutters, Femke, Sharma, Sapna, Slieker, Roderick C., Syed, Ali, Tajes, Juan Fernandez, Thomas, Cecilia Engel, Thomsen, Henrik S., Vangipurapu, Jagadish, Vestergaard, Henrik, Viñuela, Ana, Wesolowska-Andersen, Agata, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., McCarthy, Mark I., Pearson, Ewan, Dermitzakis, Emmanouil, Franks, Paul W., Pedersen, Oluf, and Brunak, Søren

Published
2020
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12. Gene expression signature predicts rate of type 1 diabetes progression

Author

Suomi, Tomi, primary, Starskaia, Inna, additional, Kalim, Ubaid Ullah, additional, Rasool, Omid, additional, Jaakkola, Maria K., additional, Grönroos, Toni, additional, Välikangas, Tommi, additional, Brorsson, Caroline, additional, Mazzoni, Gianluca, additional, Bruggraber, Sylvaine, additional, Overbergh, Lut, additional, Dunger, David, additional, Peakman, Mark, additional, Chmura, Piotr, additional, Brunak, Søren, additional, Schulte, Anke M., additional, Mathieu, Chantal, additional, Knip, Mikael, additional, Lahesmaa, Riitta, additional, Elo, Laura L., additional, Gillard, Pieter, additional, Casteels, Kristina, additional, Overbergh, Lutgart, additional, Wallace, Chris, additional, Evans, Mark, additional, Thankamony, Ajay, additional, Hendriks, Emile, additional, Marcoveccchio, Loredana, additional, Tree, Timothy, additional, Morgan, Noel G., additional, Richardson, Sarah, additional, Todd, John A., additional, Wicker, Linda, additional, Mander, Adrian, additional, Dayan, Colin, additional, Alhadj Ali, Mohammad, additional, Pieber, Thomas, additional, Eizirik, Decio L., additional, Cnop, Myriam, additional, Pociot, Flemming, additional, Johannesen, Jesper, additional, Rossing, Peter, additional, Quigley, Cristina Legido, additional, Mallone, Roberto, additional, Scharfmann, Raphael, additional, Boitard, Christian, additional, Otonkoski, Timo, additional, Veijola, Riitta, additional, Oresic, Matej, additional, Toppari, Jorma, additional, Danne, Thomas, additional, Ziegler, Anette G., additional, Achenbach, Peter, additional, Rodriguez-Calvo, Teresa, additional, Solimena, Michele, additional, Bonifacio, Ezio E., additional, Speier, Stephan, additional, Holl, Reinhard, additional, Dotta, Francesco, additional, Chiarelli, Francesco, additional, Marchetti, Piero, additional, Bosi, Emanuele, additional, Cianfarani, Stefano, additional, Ciampalini, Paolo, additional, De Beaufort, Carine, additional, Dahl-Jørgensen, Knut, additional, Skrivarhaug, Torild, additional, Joner, Geir, additional, Krogvold, Lars, additional, Jarosz-Chobot, Przemka, additional, Battelino, Tadej, additional, Thorens, Bernard, additional, Gotthardt, Martin, additional, Roep, Bart O., additional, Nikolic, Tanja, additional, Zaldumbide, Arnaud, additional, Lernmark, Ake, additional, Lundgren, Marcus, additional, Costacalde, Guillaume, additional, Strube, Thorsten, additional, Nitsche, Almut, additional, Vela, Jose, additional, Von Herrath, Matthias, additional, Wesley, Johnna, additional, Napolitano-Rosen, Antonella, additional, Thomas, Melissa, additional, Schloot, Nanette, additional, Goldfine, Allison, additional, Waldron-Lynch, Frank, additional, Kompa, Jill, additional, Vedala, Aruna, additional, Hartmann, Nicole, additional, Nicolas, Gwenaelle, additional, van Rampelbergh, Jean, additional, Bovy, Nicolas, additional, Dutta, Sanjoy, additional, Soderberg, Jeannette, additional, Ahmed, Simi, additional, Martin, Frank, additional, Latres, Esther, additional, Agiostratidou, Gina, additional, Koralova, Anne, additional, Willemsen, Ruben, additional, Smith, Anne, additional, Anand, Binu, additional, Datta, Vipan, additional, Puthi, Vijith, additional, Zac-Varghese, Sagen, additional, Dias, Renuka, additional, Sundaram, Premkumar, additional, Vaidya, Bijay, additional, Patterson, Catherine, additional, Owen, Katharine, additional, Piel, Barbara, additional, Heller, Simon, additional, Randell, Tabitha, additional, Gazis, Tasso, additional, Reismen, Elise Bismuth, additional, Carel, Jean-Claude, additional, Riveline, Jean-Pierre, additional, Gautier, Jean-Francoise, additional, Andreelli, Fabrizion, additional, Travert, Florence, additional, Cosson, Emmanuel, additional, Penfornis, Alfred, additional, Petit, Catherine, additional, Feve, Bruno, additional, Lucidarme, Nadine, additional, Beressi, Jean-Paul, additional, Ajzenman, Catherina, additional, Radu, Alina, additional, Greteau-Hamoumou, Stephanie, additional, Bibal, Cecile, additional, Meissner, Thomas, additional, Heidtmann, Bettina, additional, Toni, Sonia, additional, Rami-Merhar, Birgit, additional, Eeckhout, Bart, additional, Peene, Bernard, additional, Vantongerloo, N., additional, Maes, Toon, additional, and Gommers, Leen, additional

Published
2023
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13. Identification of shared molecular signatures of ageing and metabolic diseases using multi-omic data

Author

Michalettou, Theodora Dafni, Hong, Mun-Gwan, Fernandez, Juan, Sharma, Sapna, Brorsson, Caroline Anna, Koivula, Robert, Adamski, Jerzy, Brunak, Soren, Dermitzakis, Emmanouil, Franks, Paul, McCarthy, Mark, Pearson, Ewan, Schwenk, Jochen, Walker, Mark, Brown, Andrew, Vinuela, Ana, Michalettou, Theodora Dafni, Hong, Mun-Gwan, Fernandez, Juan, Sharma, Sapna, Brorsson, Caroline Anna, Koivula, Robert, Adamski, Jerzy, Brunak, Soren, Dermitzakis, Emmanouil, Franks, Paul, McCarthy, Mark, Pearson, Ewan, Schwenk, Jochen, Walker, Mark, Brown, Andrew, and Vinuela, Ana

Abstract

QC 20231128

Published
2023

14. Mellan hopp och förtvivlan : En predikoanalys efter attentatet på Drottninggatan 2017

Author

Brorsson, Caroline and Brorsson, Caroline

Abstract

A sermon after a crisis or traumatic event requires great pastoral care. How do we put what happened into words? When things are so devastating that words are not enough? How do we speak about hope and despair in the midst of a crisis? This thesis aims to analyze sermons in the Church of Sweden after the attack on Drottninggatan, Stockholm, Sweden in 2017. Nine sermons held in the weeks following the attack have been analyzed. The theoretical background and theme of the analysis has been psychotraumatology and trauma-informed theology. The thesis’ process has been an inductive approach, as it begins in the material and then compares these against the selected aspects. The questions asked in the thesis are: “What qualities can be found in these sermons after the terrorist attack at Drottninggatan?“ As well as two sub-questions about the respective perspectives: “Which psychotraumatological perspectives were found in the sermons?” and “What perspectives of trauma-informed theology were found in the sermons?” The analysis of sermons and the answer to the first question resulted in five common themes: Responsibility and humanity, The terrorist attack and evil, The Bible and God, Despair and Hope. Based on this, both theoretical aspects have been used to analyze the results.

Published
2023

15. Gene expression signature predicts rate of type 1 diabetes progression.

Author

Suomi, Tomi, Starskaia, Inna, Kalim, Ubaid Ullah, Rasool, Omid, Jaakkola, Maria K, Grönroos, Toni, Välikangas, Tommi, Brorsson, Caroline, Mazzoni, Gianluca, Bruggraber, Sylvaine, Overbergh, Lut, Dunger, David B, Peakman, Mark, Chmura, Piotr, Brunak, Søren, Cnop, Miriam, Schulte, Anke M, Mathieu, Chantal, Knip, Mikael, Lahesmaa, Riitta, Elo, Laura L, INNODIA Consortium, Suomi, Tomi, Starskaia, Inna, Kalim, Ubaid Ullah, Rasool, Omid, Jaakkola, Maria K, Grönroos, Toni, Välikangas, Tommi, Brorsson, Caroline, Mazzoni, Gianluca, Bruggraber, Sylvaine, Overbergh, Lut, Dunger, David B, Peakman, Mark, Chmura, Piotr, Brunak, Søren, Cnop, Miriam, Schulte, Anke M, Mathieu, Chantal, Knip, Mikael, Lahesmaa, Riitta, Elo, Laura L, and INNODIA Consortium

Abstract

Type 1 diabetes is a complex heterogenous autoimmune disease without therapeutic interventions available to prevent or reverse the disease. This study aimed to identify transcriptional changes associated with the disease progression in patients with recent-onset type 1 diabetes., 0, Miriam Cnop is in the author list as part of the INNODIA Consortium, info:eu-repo/semantics/published

Published
2023

16. Discovery of drug-omics associations in type 2 diabetes with generative deep-learning models:[with Author Correction]

Author

Allesøe, Rosa Lundbye, Lundgaard, Agnete Troen, Hernández Medina, Ricardo, Aguayo-Orozco, Alejandro, Johansen, Joachim, Nissen, Jakob Nybo, Brorsson, Caroline, Mazzoni, Gianluca, Niu, Lili, Biel, Jorge Hernansanz, Brasas, Valentas, Webel, Henry, Benros, Michael Eriksen, Pedersen, Anders Gorm, Chmura, Piotr Jaroslaw, Jacobsen, Ulrik Plesner, Mari, Andrea, Koivula, Robert, Mahajan, Anubha, Vinuela, Ana, Tajes, Juan Fernandez, Sharma, Sapna, Haid, Mark, Hong, Mun-Gwan, Musholt, Petra B, De Masi, Federico, Vogt, Josef, Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Jones, Angus, Kennedy, Gwen, Bell, Jimmy, Thomas, E Louise, Frost, Gary, Thomsen, Henrik, Hansen, Elizaveta, Hansen, Tue Haldor, Vestergaard, Henrik, Muilwijk, Mirthe, Blom, Marieke T, 't Hart, Leen M, Pattou, Francois, Raverdy, Violeta, Brage, Soren, Ridderstråle, Martin, Pedersen, Oluf, Hansen, Torben, Banasik, Karina, Rasmussen, Simon, Brunak, Søren, Allesøe, Rosa Lundbye, Lundgaard, Agnete Troen, Hernández Medina, Ricardo, Aguayo-Orozco, Alejandro, Johansen, Joachim, Nissen, Jakob Nybo, Brorsson, Caroline, Mazzoni, Gianluca, Niu, Lili, Biel, Jorge Hernansanz, Brasas, Valentas, Webel, Henry, Benros, Michael Eriksen, Pedersen, Anders Gorm, Chmura, Piotr Jaroslaw, Jacobsen, Ulrik Plesner, Mari, Andrea, Koivula, Robert, Mahajan, Anubha, Vinuela, Ana, Tajes, Juan Fernandez, Sharma, Sapna, Haid, Mark, Hong, Mun-Gwan, Musholt, Petra B, De Masi, Federico, Vogt, Josef, Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Jones, Angus, Kennedy, Gwen, Bell, Jimmy, Thomas, E Louise, Frost, Gary, Thomsen, Henrik, Hansen, Elizaveta, Hansen, Tue Haldor, Vestergaard, Henrik, Muilwijk, Mirthe, Blom, Marieke T, 't Hart, Leen M, Pattou, Francois, Raverdy, Violeta, Brage, Soren, Ridderstråle, Martin, Pedersen, Oluf, Hansen, Torben, Banasik, Karina, Rasmussen, Simon, and Brunak, Søren

Abstract

The application of multiple omics technologies in biomedical cohorts has the potential to reveal patient-level disease characteristics and individualized response to treatment. However, the scale and heterogeneous nature of multi-modal data makes integration and inference a non-trivial task. We developed a deep-learning-based framework, multi-omics variational autoencoders (MOVE), to integrate such data and applied it to a cohort of 789 people with newly diagnosed type 2 diabetes with deep multi-omics phenotyping from the DIRECT consortium. Using in silico perturbations, we identified drug-omics associations across the multi-modal datasets for the 20 most prevalent drugs given to people with type 2 diabetes with substantially higher sensitivity than univariate statistical tests. From these, we among others, identified novel associations between metformin and the gut microbiota as well as opposite molecular responses for the two statins, simvastatin and atorvastatin. We used the associations to quantify drug-drug similarities, assess the degree of polypharmacy and conclude that drug effects are distributed across the multi-omics modalities.

Published
2023

18. Multi-omics analysis reveals drivers of loss of β-cell function after newly diagnosed autoimmune type 1 diabetes: An INNODIA‡multicenter study

Author

Armenteros, Jose Juan Almagro, primary, Brorsson, Caroline, additional, Johansen, Christian Holm, additional, Banasik, Karina, additional, Mazzoni, Gianluca, additional, Moulder, Robert, additional, Hirvonen, Karoliina, additional, Suomi, Tomi, additional, Rasool, Omid, additional, Bruggraber, Sylvaine FA, additional, Marcovecchio, M Loredana, additional, Hendricks, Emile, additional, Al-Sari, Naba, additional, Mattila, Ismo, additional, Legido-Quigley, Cristina, additional, Suvitaival, Tommi, additional, Chmura, Piotr J, additional, Knip, Mikael, additional, Schulte, Anke M, additional, Lee, Jeong Heon, additional, Sebastiani, Guido, additional, Grieco, Giuseppina Emanuela, additional, Elo, Laura L, additional, Kaur, Simranjeet, additional, Pociot, Flemming, additional, Dotta, Francesco, additional, Tree, Tim, additional, Lahesmaa, Riitta, additional, Overbergh, Lut, additional, Mathieu, Chantal, additional, Peakman, Mark, additional, and Brunak, Søren, additional

Published
2023
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19. CTSH regulates β-cell function and disease progression in newly diagnosed type 1 diabetes patients

Author

Fløyel, Tina, Brorsson, Caroline, Nielsen, Lotte B., Miani, Michela, Bang-Berthelsen, Claus Heiner, Friedrichsen, Martin, Overgaard, Anne Julie, Berchtold, Lukas A., Wiberg, Anna, Poulsen, Pernille, Hansen, Lars, Rosinger, Silke, Boehm, Bernhard O., Ram, Ramesh, Nguyen, Quang, Mehta, Munish, Morahan, Grant, Concannon, Patrick, Bergholdt, Regine, Nielsen, Jens H., Reinheckel, Thomas, von Herrath, Matthias, Vaag, Allan, Eizirik, Decio Laks, Mortensen, Henrik B., Størling, Joachim, and Pociot, Flemming

Published
2014

22. Four groups of type 2 diabetes contribute to the etiological and clinical heterogeneity in newly diagnosed individuals: An IMI DIRECT study

Author

Wesolowska-Andersen, Agata, primary, Brorsson, Caroline A., additional, Bizzotto, Roberto, additional, Mari, Andrea, additional, Tura, Andrea, additional, Koivula, Robert, additional, Mahajan, Anubha, additional, Vinuela, Ana, additional, Tajes, Juan Fernandez, additional, Sharma, Sapna, additional, Haid, Mark, additional, Prehn, Cornelia, additional, Artati, Anna, additional, Hong, Mun-Gwan, additional, Musholt, Petra B., additional, Kurbasic, Azra, additional, De Masi, Federico, additional, Tsirigos, Kostas, additional, Pedersen, Helle Krogh, additional, Gudmundsdottir, Valborg, additional, Thomas, Cecilia Engel, additional, Banasik, Karina, additional, Jennison, Chrisopher, additional, Jones, Angus, additional, Kennedy, Gwen, additional, Bell, Jimmy, additional, Thomas, Louise, additional, Frost, Gary, additional, Thomsen, Henrik, additional, Allin, Kristine, additional, Hansen, Tue Haldor, additional, Vestergaard, Henrik, additional, Hansen, Torben, additional, Rutters, Femke, additional, Elders, Petra, additional, t’Hart, Leen, additional, Bonnefond, Amelie, additional, Canouil, Mickaël, additional, Brage, Soren, additional, Kokkola, Tarja, additional, Heggie, Alison, additional, McEvoy, Donna, additional, Hattersley, Andrew, additional, McDonald, Timothy, additional, Teare, Harriet, additional, Ridderstrale, Martin, additional, Walker, Mark, additional, Forgie, Ian, additional, Giordano, Giuseppe N., additional, Froguel, Philippe, additional, Pavo, Imre, additional, Ruetten, Hartmut, additional, Pedersen, Oluf, additional, Dermitzakis, Emmanouil, additional, Franks, Paul W., additional, Schwenk, Jochen M., additional, Adamski, Jerzy, additional, Pearson, Ewan, additional, McCarthy, Mark I., additional, and Brunak, Søren, additional

Published
2022
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27. Telling the truth about God : A Study about non-masculine words about God in sermons in the Church of Sweden

Author

Brorsson, Caroline

Subjects
Queer theology, Homiletics, Könsneutralt, Gud, Religionsvetenskap, Feminism, Religious Studies, Pronomen, Feminist theology, God, Könsbalanserat, Gender neutral language, Gender balanced language, Queer, Teologi
Abstract

God is not a he, yet “he” is by far the most common pronoun for God. This qualitative study looks at how some priests from the Church of Sweden preach about God in a non-masculine way. The study was done through interviews and analysis of sermons from four priests who all work with non-masculine language concerning God. Question: How can a non-masculine language about God look like, in sermons and in the preparations of sermons, in the Swedish church today? Sub-questions: What types of words, pronouns and imagery of God are used in the sermons that were studied?What were the reflections of the priests in the study regarding non-masculine language in the preparation of sermons? From the interviews and sermons, a list has been compiled with words about God that are gender neutral and gender balanced. Although the importance of theological anchoring in the Bible is important there are also forgotten traditions and the congregations of the living folk church to anchor into.

Published
2021

28. Tala sant om Gud! : En undersökning om icke maskulina ord i predikningar i Svenska kyrkan

Author

Brorsson, Caroline and Brorsson, Caroline

Abstract

God is not a he, yet “he” is by far the most common pronoun for God. This qualitative study looks at how some priests from the Church of Sweden preach about God in a non-masculine way. The study was done through interviews and analysis of sermons from four priests who all work with non-masculine language concerning God. Question: How can a non-masculine language about God look like, in sermons and in the preparations of sermons, in the Swedish church today? Sub-questions: What types of words, pronouns and imagery of God are used in the sermons that were studied?What were the reflections of the priests in the study regarding non-masculine language in the preparation of sermons? From the interviews and sermons, a list has been compiled with words about God that are gender neutral and gender balanced. Although the importance of theological anchoring in the Bible is important there are also forgotten traditions and the congregations of the living folk church to anchor into.

Published
2021

31. Additional file 1 of Whole blood co-expression modules associate with metabolic traits and type 2 diabetes: an IMI-DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Mazzoni, Gianluca, Allin, Kristine H., Artati, Anna, Beulens, Joline W., Banasik, Karina, Brorsson, Caroline, Cederberg, Henna, Chabanova, Elizaveta, Masi, Federico De, Elders, Petra J., Forgie, Ian, Giordano, Giuseppe N., Grallert, Harald, Ramneek Gupta, Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison, Mun-Gwan Hong, Jones, Angus G., Koivula, Robert, Kokkola, Tarja, Laakso, Markku, Løngreen, Peter, Anubha Mahajan, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Musholt, Petra B., Pavo, Imre, Prehn, Cornelia, Ruetten, Hartmut, Ridderstråle, Martin, Rutters, Femke, Sharma, Sapna, Slieker, Roderick C., Syed, Ali, Tajes, Juan Fernandez, Thomas, Cecilia Engel, Thomsen, Henrik S., Jagadish Vangipurapu, Vestergaard, Henrik, Viñuela, Ana, Wesolowska-Andersen, Agata, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., McCarthy, Mark I., Pearson, Ewan, Dermitzakis, Emmanouil, Franks, Paul W., Pedersen, Oluf, and Brunak, Søren

Abstract

Additional file 1. Supplementary Figures. This file contains Fig. S1 – S13.

Published
2020
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32. Additional file 2 of Whole blood co-expression modules associate with metabolic traits and type 2 diabetes: an IMI-DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Mazzoni, Gianluca, Allin, Kristine H., Artati, Anna, Beulens, Joline W., Banasik, Karina, Brorsson, Caroline, Cederberg, Henna, Chabanova, Elizaveta, Masi, Federico De, Elders, Petra J., Forgie, Ian, Giordano, Giuseppe N., Grallert, Harald, Ramneek Gupta, Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison, Mun-Gwan Hong, Jones, Angus G., Koivula, Robert, Kokkola, Tarja, Laakso, Markku, Løngreen, Peter, Anubha Mahajan, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Musholt, Petra B., Pavo, Imre, Prehn, Cornelia, Ruetten, Hartmut, Ridderstråle, Martin, Rutters, Femke, Sharma, Sapna, Slieker, Roderick C., Syed, Ali, Tajes, Juan Fernandez, Thomas, Cecilia Engel, Thomsen, Henrik S., Jagadish Vangipurapu, Vestergaard, Henrik, Viñuela, Ana, Wesolowska-Andersen, Agata, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., McCarthy, Mark I., Pearson, Ewan, Dermitzakis, Emmanouil, Franks, Paul W., Pedersen, Oluf, and Brunak, Søren

Subjects
Data_FILES
Abstract

Additional file 2. Supplementary Methods. This file contains methods descriptions for omics data generation and preprocessing.

Published
2020
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33. Whole blood co-expression modules associate with metabolic traits and type 2 diabetes:an IMI-DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Mazzoni, Gianluca, Allin, Kristine H., Artati, Anna, Beulens, Joline W., Banasik, Karina, Brorsson, Caroline, Cederberg, Henna, Chabanova, Elizaveta, De Masi, Federico, Elders, Petra J., Forgie, Ian, Giordano, Giuseppe N., Grallert, Harald, Gupta, Ramneek, Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison, Hong, Mun Gwan, Jones, Angus G., Koivula, Robert, Kokkola, Tarja, Laakso, Markku, Løngreen, Peter, Mahajan, Anubha, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Musholt, Petra B., Pavo, Imre, Prehn, Cornelia, Ruetten, Hartmut, Ridderstråle, Martin, Rutters, Femke, Sharma, Sapna, Slieker, Roderick C., Syed, Ali, Tajes, Juan Fernandez, Thomas, Cecilia Engel, Thomsen, Henrik S., Vangipurapu, Jagadish, Vestergaard, Henrik, Viñuela, Ana, Wesolowska-Andersen, Agata, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., McCarthy, Mark I., Pearson, Ewan, Dermitzakis, Emmanouil, Franks, Paul W., Pedersen, Oluf, Brunak, Søren, Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Mazzoni, Gianluca, Allin, Kristine H., Artati, Anna, Beulens, Joline W., Banasik, Karina, Brorsson, Caroline, Cederberg, Henna, Chabanova, Elizaveta, De Masi, Federico, Elders, Petra J., Forgie, Ian, Giordano, Giuseppe N., Grallert, Harald, Gupta, Ramneek, Haid, Mark, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew T., Heggie, Alison, Hong, Mun Gwan, Jones, Angus G., Koivula, Robert, Kokkola, Tarja, Laakso, Markku, Løngreen, Peter, Mahajan, Anubha, Mari, Andrea, McDonald, Timothy J., McEvoy, Donna, Musholt, Petra B., Pavo, Imre, Prehn, Cornelia, Ruetten, Hartmut, Ridderstråle, Martin, Rutters, Femke, Sharma, Sapna, Slieker, Roderick C., Syed, Ali, Tajes, Juan Fernandez, Thomas, Cecilia Engel, Thomsen, Henrik S., Vangipurapu, Jagadish, Vestergaard, Henrik, Viñuela, Ana, Wesolowska-Andersen, Agata, Walker, Mark, Adamski, Jerzy, Schwenk, Jochen M., McCarthy, Mark I., Pearson, Ewan, Dermitzakis, Emmanouil, Franks, Paul W., Pedersen, Oluf, and Brunak, Søren

Abstract

Background: The rising prevalence of type 2 diabetes (T2D) poses a major global challenge. It remains unresolved to what extent transcriptomic signatures of metabolic dysregulation and T2D can be observed in easily accessible tissues such as blood. Additionally, large-scale human studies are required to further our understanding of the putative inflammatory component of insulin resistance and T2D. Here we used transcriptomics data from individuals with (n = 789) and without (n = 2127) T2D from the IMI-DIRECT cohorts to describe the co-expression structure of whole blood that mainly reflects processes and cell types of the immune system, and how it relates to metabolically relevant clinical traits and T2D. Methods: Clusters of co-expressed genes were identified in the non-diabetic IMI-DIRECT cohort and evaluated with regard to stability, as well as preservation and rewiring in the cohort of individuals with T2D. We performed functional and immune cell signature enrichment analyses, and a genome-wide association study to describe the genetic regulation of the modules. Phenotypic and trans-omics associations of the transcriptomic modules were investigated across both IMI-DIRECT cohorts. Results: We identified 55 whole blood co-expression modules, some of which clustered in larger super-modules. We identified a large number of associations between these transcriptomic modules and measures of insulin action and glucose tolerance. Some of the metabolically linked modules reflect neutrophil-lymphocyte ratio in blood while others are independent of white blood cell estimates, including a module of genes encoding neutrophil granule proteins with antibacterial properties for which the strongest associations with clinical traits and T2D status were observed. Through the integration of genetic and multi-omics data, we provide a holistic view of the regulation and molecular context of whole blood transcriptomic modules. We furthermore identified an overlap between genetic sig

Published
2020

37. Residual [beta]-cell function 3-6 years after onset of type 1 diabetes reduces risk of severe hypoglycemia in children and adolescents

Author

Sorensen, Jesper S., Johannesen, Jesper, Pociot, Flemming, Kristensen, Kurt, Thomsen, Jane, Hertel, N. Thomas, Kjaersgaard, Per, Brorsson, Caroline, and Birkebaek, Niels H.

Subjects
Diabetes therapy, Type 1 diabetes -- Risk factors, Pancreatic beta cells, Peptides, Health
Abstract

OBJECTIVE--To determine the prevalence of residual [beta]-cell function (RBF) in children after 3-6 years of type 1 diabetes, and to examine the association between RBF and incidence of severe hypoglycemia, [...]

Published
2013
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39. Genetic studies of abdominal MRI data identify genes regulating hepcidin as major determinants of liver iron concentration

Author

Wilman, Henry R., Parisinos, Constantinos A., Atabaki-Pasdar, Naeimeh, Kelly, Matt, Thomas, E. Louise, Neubauer, Stefan, Jennison, Christopher, Ehrhardt, Beate, Baum, Patrick, Schoelsch, Corinna, Freijer, Jan, Grempler, Rolf, Graefe-Mody, Ulrike, Hennige, Anita, Dings, Christiane, Lehr, Thorsten, Scherer, Nina, Sihinecich, Iryna, Pattou, Francois, Raverdi, Violeta, Caiazzo, Robert, Torres, Fanelly, Verkindt, Helene, Mari, Andrea, Tura, Andrea, Giorgino, Toni, Bizzotto, Froguel, Philippe, Bonneford, Amelie, Canouil, Mickael, Dhennin, Veronique, Brorsson, Caroline, Brunak, Soren, de Masi, Federico, Gudmundsdóttir, Valborg, Pedersen, Helle, Banasik, Karina, Thomas, Cecilia, Sackett, Peter, Staerfeldt, Hans-Henrik, Lundgaard, Agnete, Koopman, Anitra, Rutters, Femke, Beulens, Joline, Groeneveld, Lenka, Thomas, Louise, Whitcher, Brandon, Mahajan, Anubha, Hingorani, Aroon D., Patel, Riyaz S., Hemingway, Harry, Franks, Paul W., Bell, Jimmy D., Banerjee, Rajarshi, Yaghootkar, Hanieh, Epidemiology and Data Science, APH - Health Behaviors & Chronic Diseases, ACS - Diabetes & metabolism, ACS - Heart failure & arrhythmias, and APH - Aging & Later Life

Abstract

Background & Aims: Excess liver iron content is common and is linked to the risk of hepatic and extrahepatic diseases. We aimed to identify genetic variants influencing liver iron content and use genetics to understand its link to other traits and diseases. Methods: First, we performed a genome-wide association study (GWAS) in 8,289 individuals from UK Biobank, whose liver iron level had been quantified by magnetic resonance imaging, before validating our findings in an independent cohort (n = 1,513 from IMI DIRECT). Second, we used Mendelian randomisation to test the causal effects of 25 predominantly metabolic traits on liver iron content. Third, we tested phenome-wide associations between liver iron variants and 770 traits and disease outcomes. Results: We identified 3 independent genetic variants (rs1800562 [C282Y] and rs1799945 [H63D] in HFE and rs855791 [V736A] in TMPRSS6) associated with liver iron content that reached the GWAS significance threshold (p

Published
2019
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40. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes:descriptive characteristics of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W, Forgie, Ian M, Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N, Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D M, Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A, Dawed, Adem Y, De Masi, Federico, Groves, Christopher J, Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H, Rauh, Simone P, Ridderstråle, Martin, Teare, Harriet J A, Thomas, E Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline W, Brunak, Søren, Dermitzakis, Emmanouil T, Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J, Pedersen, Oluf, Schwenk, Jochen M, Pavo, Imre, Mari, Andrea, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul W, Koivula, Robert W, Forgie, Ian M, Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N, Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D M, Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A, Dawed, Adem Y, De Masi, Federico, Groves, Christopher J, Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H, Rauh, Simone P, Ridderstråle, Martin, Teare, Harriet J A, Thomas, E Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline W, Brunak, Søren, Dermitzakis, Emmanouil T, Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J, Pedersen, Oluf, Schwenk, Jochen M, Pavo, Imre, Mari, Andrea, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, and Franks, Paul W

Abstract

AIMS/HYPOTHESIS: Here, we describe the characteristics of the Innovative Medicines Initiative (IMI) Diabetes Research on Patient Stratification (DIRECT) epidemiological cohorts at baseline and follow-up examinations (18, 36 and 48 months of follow-up).METHODS: From a sampling frame of 24,682 adults of European ancestry enrolled in population-based cohorts across Europe, participants at varying risk of glycaemic deterioration were identified using a risk prediction algorithm (based on age, BMI, waist circumference, use of antihypertensive medication, smoking status and parental history of type 2 diabetes) and enrolled into a prospective cohort study (n = 2127) (cohort 1, prediabetes risk). We also recruited people from clinical registries with type 2 diabetes diagnosed 6-24 months previously (n = 789) into a second cohort study (cohort 2, diabetes). Follow-up examinations took place at ~18 months (both cohorts) and at ~48 months (cohort 1) or ~36 months (cohort 2) after baseline examinations. The cohorts were studied in parallel using matched protocols across seven clinical centres in northern Europe.RESULTS: Using ADA 2011 glycaemic categories, 33% (n = 693) of cohort 1 (prediabetes risk) had normal glucose regulation and 67% (n = 1419) had impaired glucose regulation. Seventy-six per cent of participants in cohort 1 was male. Cohort 1 participants had the following characteristics (mean ± SD) at baseline: age 62 (6.2) years; BMI 27.9 (4.0) kg/m2; fasting glucose 5.7 (0.6) mmol/l; 2 h glucose 5.9 (1.6) mmol/l. At the final follow-up examination the participants' clinical characteristics were as follows: fasting glucose 6.0 (0.6) mmol/l; 2 h OGTT glucose 6.5 (2.0) mmol/l. In cohort 2 (diabetes), 66% (n = 517) were treated by lifestyle modification and 34% (n = 272) were treated with metformin plus lifestyle modification at enrolment. Fifty-eight per cent of participants in cohort 2 was male. Cohort 2 participants had the following characteristics at

Published
2019

42. Integrative network analysis highlights biological processes underlying GLP-1 stimulated insulin secretion:A DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Allebrandt, Karla Viviani, Brorsson, Caroline Anna, van Leeuwen, Nienke, Banasik, Karina, Mahajan, Anubha, Groves, Christopher J, van de Bunt, Martijn, Dawed, Adem Y, Fritsche, Andreas, Staiger, Harald, Simonis-Bik, Annemarie M C, Deelen, Joris, Kramer, Mark H H, Dietrich, Axel, Hübschle, Thomas, Willemsen, Gonneke, Häring, Hans-Ulrich, de Geus, Eco J C, Boomsma, Dorret I, Eekhoff, Elisabeth M W, Ferrer, Jorge, McCarthy, Mark I, Pearson, Ewan R, Gupta, Ramneek, Brunak, Søren, 't Hart, Leen M, Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Allebrandt, Karla Viviani, Brorsson, Caroline Anna, van Leeuwen, Nienke, Banasik, Karina, Mahajan, Anubha, Groves, Christopher J, van de Bunt, Martijn, Dawed, Adem Y, Fritsche, Andreas, Staiger, Harald, Simonis-Bik, Annemarie M C, Deelen, Joris, Kramer, Mark H H, Dietrich, Axel, Hübschle, Thomas, Willemsen, Gonneke, Häring, Hans-Ulrich, de Geus, Eco J C, Boomsma, Dorret I, Eekhoff, Elisabeth M W, Ferrer, Jorge, McCarthy, Mark I, Pearson, Ewan R, Gupta, Ramneek, Brunak, Søren, and 't Hart, Leen M

Abstract

Glucagon-like peptide 1 (GLP-1) stimulated insulin secretion has a considerable heritable component as estimated from twin studies, yet few genetic variants influencing this phenotype have been identified. We performed the first genome-wide association study (GWAS) of GLP-1 stimulated insulin secretion in non-diabetic individuals from the Netherlands Twin register (n = 126). This GWAS was enhanced using a tissue-specific protein-protein interaction network approach. We identified a beta-cell protein-protein interaction module that was significantly enriched for low gene scores based on the GWAS P-values and found support at the network level in an independent cohort from Tübingen, Germany (n = 100). Additionally, a polygenic risk score based on SNPs prioritized from the network was associated (P < 0.05) with glucose-stimulated insulin secretion phenotypes in up to 5,318 individuals in MAGIC cohorts. The network contains both known and novel genes in the context of insulin secretion and is enriched for members of the focal adhesion, extracellular-matrix receptor interaction, actin cytoskeleton regulation, Rap1 and PI3K-Akt signaling pathways. Adipose tissue is, like the beta-cell, one of the target tissues of GLP-1 and we thus hypothesized that similar networks might be functional in both tissues. In order to verify peripheral effects of GLP-1 stimulation, we compared the transcriptome profiling of ob/ob mice treated with liraglutide, a clinically used GLP-1 receptor agonist, versus baseline controls. Some of the upstream regulators of differentially expressed genes in the white adipose tissue of ob/ob mice were also detected in the human beta-cell network of genes associated with GLP-1 stimulated insulin secretion. The findings provide biological insight into the mechanisms through which the effects of GLP-1 may be modulated and highlight a potential role of the beta-cell expressed genes RYR2, GDI2, KIAA0232, COL4A1 and COL4A2 in GLP-1 stimulated insulin secre

Published
2018

43. Integrative network analysis highlights biological processes underlying GLP-1 stimulated insulin secretion: A DIRECT study

Author

Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Allebrandt, Karla Viviani, Brorsson, Caroline Anna, van Leeuwen, Nienke, Banasik, Karina, Mahajan, Anubha, Groves, Christopher J, van de Bunt, Martijn, Dawed, Adem Y, Fritsche, Andreas, Staiger, Harald, Simonis-Bik, Annemarie M C, Deelen, Joris, Kramer, Mark H H, Dietrich, Axel, Hübschle, Thomas, Willemsen, Gonneke, Häring, Hans-Ulrich, de Geus, Eco J C, Boomsma, Dorret I, Eekhoff, Elisabeth M W, Ferrer, Jorge, McCarthy, Mark I, Pearson, Ewan R, Gupta, Ramneek, Brunak, Søren, 't Hart, Leen M, Gudmundsdottir, Valborg, Pedersen, Helle Krogh, Allebrandt, Karla Viviani, Brorsson, Caroline Anna, van Leeuwen, Nienke, Banasik, Karina, Mahajan, Anubha, Groves, Christopher J, van de Bunt, Martijn, Dawed, Adem Y, Fritsche, Andreas, Staiger, Harald, Simonis-Bik, Annemarie M C, Deelen, Joris, Kramer, Mark H H, Dietrich, Axel, Hübschle, Thomas, Willemsen, Gonneke, Häring, Hans-Ulrich, de Geus, Eco J C, Boomsma, Dorret I, Eekhoff, Elisabeth M W, Ferrer, Jorge, McCarthy, Mark I, Pearson, Ewan R, Gupta, Ramneek, Brunak, Søren, and 't Hart, Leen M

Abstract

Glucagon-like peptide 1 (GLP-1) stimulated insulin secretion has a considerable heritable component as estimated from twin studies, yet few genetic variants influencing this phenotype have been identified. We performed the first genome-wide association study (GWAS) of GLP-1 stimulated insulin secretion in non-diabetic individuals from the Netherlands Twin register (n = 126). This GWAS was enhanced using a tissue-specific protein-protein interaction network approach. We identified a beta-cell protein-protein interaction module that was significantly enriched for low gene scores based on the GWAS P-values and found support at the network level in an independent cohort from Tübingen, Germany (n = 100). Additionally, a polygenic risk score based on SNPs prioritized from the network was associated (P <0.05) with glucose-stimulated insulin secretion phenotypes in up to 5,318 individuals in MAGIC cohorts. The network contains both known and novel genes in the context of insulin secretion and is enriched for members of the focal adhesion, extracellular-matrix receptor interaction, actin cytoskeleton regulation, Rap1 and PI3K-Akt signaling pathways. Adipose tissue is, like the beta-cell, one of the target tissues of GLP-1 and we thus hypothesized that similar networks might be functional in both tissues. In order to verify peripheral effects of GLP-1 stimulation, we compared the transcriptome profiling of ob/ob mice treated with liraglutide, a clinically used GLP-1 receptor agonist, versus baseline controls. Some of the upstream regulators of differentially expressed genes in the white adipose tissue of ob/ob mice were also detected in the human beta-cell network of genes associated with GLP-1 stimulated insulin secretion. The findings provide biological insight into the mechanisms through which the effects of GLP-1 may be modulated and highlight a potential role of the beta-cell expressed genes RYR2, GDI2, KIAA0232, COL4A1 and COL4A2 in GLP-1 stimulated insulin secretion

Published
2018

45. Integrative network analysis highlights biological processes underlying GLP-1 stimulated insulin secretion: A DIRECT study

Author

Gudmundsdottir, Valborg, primary, Pedersen, Helle Krogh, additional, Allebrandt, Karla Viviani, additional, Brorsson, Caroline, additional, van Leeuwen, Nienke, additional, Banasik, Karina, additional, Mahajan, Anubha, additional, Groves, Christopher J., additional, van de Bunt, Martijn, additional, Dawed, Adem Y., additional, Fritsche, Andreas, additional, Staiger, Harald, additional, Simonis-Bik, Annemarie M. C., additional, Deelen, Joris, additional, Kramer, Mark H. H., additional, Dietrich, Axel, additional, Hübschle, Thomas, additional, Willemsen, Gonneke, additional, Häring, Hans-Ulrich, additional, de Geus, Eco J. C., additional, Boomsma, Dorret I., additional, Eekhoff, Elisabeth M. W., additional, Ferrer, Jorge, additional, McCarthy, Mark I., additional, Pearson, Ewan R., additional, Gupta, Ramneek, additional, Brunak, Søren, additional, and ‘t Hart, Leen M., additional

Published
2018
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46. JNK1 Deficient Insulin-Producing Cells Are Protected against Interleukin-1 beta-Induced Apoptosis Associated with Abrogated Myc Expression

Author

Prause, Michala, Mayer, Christopher Michael, Brorsson, Caroline, Frederiksen, Klaus Stensgaard, Billestrup, Nils, Storling, Joachim, Mandrup-Poulsen, Thomas, Prause, Michala, Mayer, Christopher Michael, Brorsson, Caroline, Frederiksen, Klaus Stensgaard, Billestrup, Nils, Storling, Joachim, and Mandrup-Poulsen, Thomas

Abstract

The relative contributions of the JNK subtypes in inflammatory β-cell failure and apoptosis are unclear. The JNK protein family consists of JNK1, JNK2, and JNK3 subtypes, encompassing many different isoforms. INS-1 cells express JNK1α1, JNK1α2, JNK1β1, JNK1β2, JNK2α1, JNK2α2, JNK3α1, and JNK3α2 mRNA isoform transcripts translating into 46 and 54 kDa isoform JNK proteins. Utilizing Lentiviral mediated expression of shRNAs against JNK1, JNK2, or JNK3 in insulin-producing INS-1 cells, we investigated the role of individual JNK subtypes in IL-1β-induced β-cell apoptosis. JNK1 knockdown prevented IL-1β-induced INS-1 cell apoptosis associated with decreased 46 kDa isoform JNK protein phosphorylation and attenuated Myc expression. Transient knockdown of Myc also prevented IL-1β-induced apoptosis as well as caspase 3 cleavage. JNK2 shRNA potentiated IL-1β-induced apoptosis and caspase 3 cleavage, whereas JNK3 shRNA did not affect IL-1β-induced β-cell death compared to nonsense shRNA expressing INS-1 cells. In conclusion, JNK1 mediates INS-1 cell death associated with increased Myc expression. These findings underline the importance of differentiated targeting of JNK subtypes in the development of inflammatory β-cell failure and destruction.

Published
2016

47. Genetic Risk Score Modelling for Disease Progression in New-Onset Type 1 Diabetes Patients:Increased Genetic Load of Islet-Expressed and Cytokine-Regulated Candidate Genes Predicts Poorer Glycemic Control

Author

Brorsson, Caroline A, Nielsen, Lotte B, Andersen, Marie-Louise, Kaur, Simranjeet, Bergholdt, Regine, Hansen, Lars, Mortensen, Henrik B., Pociot, Flemming, Størling, Joachim, Brorsson, Caroline A, Nielsen, Lotte B, Andersen, Marie-Louise, Kaur, Simranjeet, Bergholdt, Regine, Hansen, Lars, Mortensen, Henrik B., Pociot, Flemming, and Størling, Joachim

Abstract

Genome-wide association studies (GWAS) have identified over 40 type 1 diabetes risk loci. The clinical impact of these loci on β-cell function during disease progression is unknown. We aimed at testing whether a genetic risk score could predict glycemic control and residual β-cell function in type 1 diabetes (T1D). As gene expression may represent an intermediate phenotype between genetic variation and disease, we hypothesized that genes within T1D loci which are expressed in islets and transcriptionally regulated by proinflammatory cytokines would be the best predictors of disease progression. Two-thirds of 46 GWAS candidate genes examined were expressed in human islets, and 11 of these significantly changed expression levels following exposure to proinflammatory cytokines (IL-1β + IFNγ + TNFα) for 48 h. Using the GWAS single nucleotide polymorphisms (SNPs) from each locus, we constructed a genetic risk score based on the cumulative number of risk alleles carried in children with newly diagnosed T1D. With each additional risk allele carried, HbA1c levels increased significantly within first year after diagnosis. Network and gene ontology (GO) analyses revealed that several of the 11 candidate genes have overlapping biological functions and interact in a common network. Our results may help predict disease progression in newly diagnosed children with T1D which can be exploited for optimizing treatment.

Published
2016

48. Ranking factors involved in diabetes remission after bariatric surgery using machine-learning integrating clinical and genomic biomarkers

Author

Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Pedersen, Mette Krogh, Brorsson, Caroline, Brunak, Søren, Gupta, Ramneek, Pedersen, Helle Krogh, Gudmundsdottir, Valborg, Pedersen, Mette Krogh, Brorsson, Caroline, Brunak, Søren, and Gupta, Ramneek

Abstract

As weight-loss surgery is an effective treatment for the glycaemic control of type 2 diabetes in obese patients, yet not all patients benefit, it is valuable to find predictive factors for this diabetic remission. This will help elucidating possible mechanistic insights and form the basis for prioritising obese patients with dysregulated diabetes for surgery where diabetes remission is of interest. In this study, we combine both clinical and genomic factors using heuristic methods, informed by prior biological knowledge in order to rank factors that would have a role in predicting diabetes remission, and indeed in identifying patients who may have low likelihood in responding to bariatric surgery for improved glycaemic control. Genetic variants from the Illumina CardioMetaboChip were prioritised through single-association tests and then seeded a larger selection from protein-protein interaction networks. Artificial neural networks allowing nonlinear correlations were trained to discriminate patients with and without surgery-induced diabetes remission, and the importance of each clinical and genetic parameter was evaluated. The approach highlighted insulin treatment, baseline HbA1c levels, use of insulin-sensitising agents and baseline serum insulin levels, as the most informative variables with a decent internal validation performance (74% accuracy, area under the curve (AUC) 0.81). Adding information for the eight top-ranked single nucleotide polymorphisms (SNPs) significantly boosted classification performance to 84% accuracy (AUC 0.92). The eight SNPs mapped to eight genes - ABCA1, ARHGEF12, CTNNBL1, GLI3, PROK2, RYBP, SMUG1 and STXBP5 - three of which are known to have a role in insulin secretion, insulin sensitivity or obesity, but have not been indicated for diabetes remission after bariatric surgery before.

Published
2016

49. Identification of a SIRT1 Mutation in a Family with Type 1 Diabetes

Author

Biason-Lauber, Anna, Böni-Schnetzler, Marianne, Hubbard, Basil P., Bouzakri, Karim, Brunner, Andrea, Cavelti-Weder, Claudia, Keller, Cornelia, Meyer-Böni, Monika, Meier, Daniel T., Brorsson, Caroline, Timper, Katharina, Leibowitz, Gil, Patrignani, Andrea, Bruggmann, Remy, Boily, Gino, Zulewski, Henryk, Geier, Andreas, Cermak, Jennifer M., Elliott, Peter, Ellis, James L., Westphal, Christoph, Knobel, Urs, Eloranta, Jyrki J., Kerr-Conte, Julie, Pattou, François, Konrad, Daniel, Matter, Christian M., Fontana, Adriano, Rogler, Gerhard, Schlapbach, Ralph, Regairaz, Camille, Carballido, José M., Glaser, Benjamin, McBurney, Michael W., Pociot, Flemming, Sinclair, David A., and Donath, Marc Y.

Published
2013
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