TY - JOUR
T1 - Impact of infection on proteome-wide glycosylation revealed by distinct signatures for bacterial and viral pathogens
AU - PERFORM Consortium
AU - Willems, Esther
AU - Gloerich, Jolein
AU - Suppers, Anouk
AU - van der Flier, Michiel
AU - van den Heuvel, Lambert P.
AU - van de Kar, Nicole
AU - Philipsen, Ria H.L.A.
AU - van Dael, Maurice
AU - Kaforou, Myrsini
AU - Wright, Victoria J.
AU - Herberg, Jethro A.
AU - Torres, Federico Martinon
AU - Levin, Michael
AU - de Groot, Ronald
AU - van Gool, Alain J.
AU - Lefeber, Dirk J.
AU - Wessels, Hans J.C.T.
AU - de Jonge, Marien I.
AU - Abdulla, Amina
AU - Aebi, Christoph
AU - van Aerde, Koen
AU - Agbeko, Rachel
AU - Agyeman, Philipp
AU - D'alessandro, Umberto
AU - Ali, Ladan
AU - Alkema, Wynand
AU - Allen, Karen
AU - González, Fernando Álvez
AU - Anderson, Suzanne
AU - Ansari, Imran
AU - Araf, Tasnim
AU - Avramoska, Tanja
AU - Baas, Bryan
AU - Bahovec, Natalija
AU - Farto, Cristina Balo
AU - Balode, Anda
AU - Barendregt, A. M.
AU - Barral-Arca, Ruth
AU - Castro, María Barreiro
AU - Bārzdiņa, Arta
AU - Bath, David
AU - Bauchinger, Sebastian
AU - Baumard, Lucas
AU - Baumgart, Hinrich
AU - Baxter, Frances
AU - Bell, Ashley
AU - Bell, Kathryn
AU - Bello, Xabier
AU - Shen, Ching Fen
AU - Wang, Shih Min
N1 - Publisher Copyright:
© 2023 The Author(s)
PY - 2023/8/18
Y1 - 2023/8/18
N2 - Mechanisms of infection and pathogenesis have predominantly been studied based on differential gene or protein expression. Less is known about posttranslational modifications, which are essential for protein functional diversity. We applied an innovative glycoproteomics method to study the systemic proteome-wide glycosylation in response to infection. The protein site-specific glycosylation was characterized in plasma derived from well-defined controls and patients. We found 3862 unique features, of which we identified 463 distinct intact glycopeptides, that could be mapped to more than 30 different proteins. Statistical analyses were used to derive a glycopeptide signature that enabled significant differentiation between patients with a bacterial or viral infection. Furthermore, supported by a machine learning algorithm, we demonstrated the ability to identify the causative pathogens based on the distinctive host blood plasma glycopeptide signatures. These results illustrate that glycoproteomics holds enormous potential as an innovative approach to improve the interpretation of relevant biological changes in response to infection.
AB - Mechanisms of infection and pathogenesis have predominantly been studied based on differential gene or protein expression. Less is known about posttranslational modifications, which are essential for protein functional diversity. We applied an innovative glycoproteomics method to study the systemic proteome-wide glycosylation in response to infection. The protein site-specific glycosylation was characterized in plasma derived from well-defined controls and patients. We found 3862 unique features, of which we identified 463 distinct intact glycopeptides, that could be mapped to more than 30 different proteins. Statistical analyses were used to derive a glycopeptide signature that enabled significant differentiation between patients with a bacterial or viral infection. Furthermore, supported by a machine learning algorithm, we demonstrated the ability to identify the causative pathogens based on the distinctive host blood plasma glycopeptide signatures. These results illustrate that glycoproteomics holds enormous potential as an innovative approach to improve the interpretation of relevant biological changes in response to infection.
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U2 - 10.1016/j.isci.2023.107257
DO - 10.1016/j.isci.2023.107257
M3 - Article
AN - SCOPUS:85165028111
SN - 2589-0042
VL - 26
JO - iScience
JF - iScience
IS - 8
M1 - 107257
ER -