Positioning Europe for the EPITRANSCRIPTOMICS challenge

Michael F. Jantsch; Alessandro Quattrone; Mary O'Connell; Mark Helm; Michaela Frye; Manuel Macias-Gonzales; Marie Ohman; Stefan Ameres; Luc Willems; Francois Fuks; Anastasis Oulas; Stepanka Vanacova; Henrik Nielsen; Cecile Bousquet-Antonelli; Yuri Motorin; Jean Yves Roignant; Nikolaos Balatsos; Andras Dinnyes; Pavel Baranov; Vincent Kelly; Ayelet Lamm; Gideon Rechavi; Mattia Pelizzola; Janis Liepins; Irina Holodnuka Kholodnyuk; Vanessa Zammit; Duncan Ayers; Finn Drablos; John Arne Dahl; Janusz Bujnicki; Carmen Jeronimo; Raquel Almeida; Monica Neagu; Marieta Costache; Jasna Bankovic; Bojana Banovic; Jan Kyselovic; Luis Miguel Valor; Stefan Selbert; Pinar Pir; Turan Demircan; Victoria Cowling; Matthias Schäfer; Walter Rossmanith; Denis Lafontaine; Alexandre David; Clement Carre; Frank Lyko; Raffael Schaffrath; Schraga Schwartz; Andre Verdel; Arne Klungland; Elzbieta Purta; Gordana Timotijevic; Fernando Cardona; Alberto Davalos; Ester Ballana; Donal O'Carroll; Jernej Ule; Rupert Fray

doi:10.1080/15476286.2018.1460996

Positioning Europe for the EPITRANSCRIPTOMICS challenge

Michael F. Jantsch
, Alessandro Quattrone
, Mary O'Connell
, Mark Helm
, Michaela Frye
, Manuel Macias-Gonzales
, Marie Ohman
, Stefan Ameres
, Luc Willems
, Francois Fuks
, Anastasis Oulas
, Stepanka Vanacova
, Henrik Nielsen
, Cecile Bousquet-Antonelli
, Yuri Motorin
, Jean Yves Roignant
, Nikolaos Balatsos
, Andras Dinnyes
, Pavel Baranov
, Vincent Kelly

Ayelet Lamm, Gideon Rechavi, Mattia Pelizzola, Janis Liepins, Irina Holodnuka Kholodnyuk, Vanessa Zammit, Duncan Ayers, Finn Drablos, John Arne Dahl, Janusz Bujnicki, Carmen Jeronimo, Raquel Almeida, Monica Neagu, Marieta Costache, Jasna Bankovic, Bojana Banovic, Jan Kyselovic, Luis Miguel Valor, Stefan Selbert, Pinar Pir, Turan Demircan, Victoria Cowling, Matthias Schäfer, Walter Rossmanith, Denis Lafontaine, Alexandre David, Clement Carre, Frank Lyko, Raffael Schaffrath, Schraga Schwartz, Andre Verdel, Arne Klungland, Elzbieta Purta, Gordana Timotijevic, Fernando Cardona, Alberto Davalos, Ester Ballana, Donal O'Carroll, Jernej Ule, Rupert Fray

School of Biochemistry and Cell Biology

Medical University of Vienna
University of Trento
Masaryk University
Johannes Gutenberg University Mainz
University of Cambridge
Hospital Complex of Malaga (Virgen de la Victoria)
Stockholm University
Institute of Molecular Biotechnology
University of Liege
Université libre de Bruxelles
Cyprus Institute of Neurology and Genetics
University of Copenhagen
Université de Perpignan
Université de Lorraine
Institute of Molecular Biology
University of Thessaly
BioTalentum
Trinity College Dublin
Technion-Israel Institute of Technology
Tel Aviv University
Italian Institute of Technology
University of Latvia
Riga Stradins University
St. Luke's Hospital Malta
University of Malta
Norwegian University of Science and Technology
University of Oslo
International Institute of Molecular and Cell Biology in Warsaw
Instituto Português de Oncologia do Porto Francisco Gentil E.P.E.
University of Porto
Victor Babes National Institute
University of Bucharest
University of Belgrade
Comenius University
Fundacion para la Gestion de la Investigacion Biomedica de Cadiz
Polygene AG
Gebze Technical University
Istanbul Medipol University
University of Dundee
Institut de Genomique Fonctionnelle
Sorbonne Université
German Cancer Research Center
University of Kassel
Weizmann Institute of Science
Institute for Advanced Bioscience
IMDEA Food Institute
Germans Trias i Pujol Research Institute (IGTP)
University of Edinburgh
The Francis Crick Institute
University of Nottingham

Research output: Contribution to journal › Comment/Debate

Abstract

The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the ~150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.

Original language	English
Pages (from-to)	829-831
Number of pages	3
Journal	RNA Biology
Volume	15
Issue number	6
DOIs	https://doi.org/10.1080/15476286.2018.1460996
Publication status	Published - 3 Jun 2018

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

database of Modification
detection of RNA modification
epitranscriptomics
European funding
model systems

Access to Document

10.1080/15476286.2018.1460996

Cite this

Jantsch, M. F., Quattrone, A., O'Connell, M., Helm, M., Frye, M., Macias-Gonzales, M., Ohman, M., Ameres, S., Willems, L., Fuks, F., Oulas, A., Vanacova, S., Nielsen, H., Bousquet-Antonelli, C., Motorin, Y., Roignant, J. Y., Balatsos, N., Dinnyes, A., Baranov, P., ... Fray, R. (2018). Positioning Europe for the EPITRANSCRIPTOMICS challenge. RNA Biology, 15(6), 829-831. https://doi.org/10.1080/15476286.2018.1460996

@article{1b7a3f651fde491fb5bfcb86659bc7e6,

title = "Positioning Europe for the EPITRANSCRIPTOMICS challenge",

abstract = "The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the \textasciitilde{}150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.",

keywords = "database of Modification, detection of RNA modification, epitranscriptomics, European funding, model systems",

author = "Jantsch, \{Michael F.\} and Alessandro Quattrone and Mary O'Connell and Mark Helm and Michaela Frye and Manuel Macias-Gonzales and Marie Ohman and Stefan Ameres and Luc Willems and Francois Fuks and Anastasis Oulas and Stepanka Vanacova and Henrik Nielsen and Cecile Bousquet-Antonelli and Yuri Motorin and Roignant, \{Jean Yves\} and Nikolaos Balatsos and Andras Dinnyes and Pavel Baranov and Vincent Kelly and Ayelet Lamm and Gideon Rechavi and Mattia Pelizzola and Janis Liepins and \{Holodnuka Kholodnyuk\}, Irina and Vanessa Zammit and Duncan Ayers and Finn Drablos and Dahl, \{John Arne\} and Janusz Bujnicki and Carmen Jeronimo and Raquel Almeida and Monica Neagu and Marieta Costache and Jasna Bankovic and Bojana Banovic and Jan Kyselovic and Valor, \{Luis Miguel\} and Stefan Selbert and Pinar Pir and Turan Demircan and Victoria Cowling and Matthias Sch{\"a}fer and Walter Rossmanith and Denis Lafontaine and Alexandre David and Clement Carre and Frank Lyko and Raffael Schaffrath and Schraga Schwartz and Andre Verdel and Arne Klungland and Elzbieta Purta and Gordana Timotijevic and Fernando Cardona and Alberto Davalos and Ester Ballana and Donal O'Carroll and Jernej Ule and Rupert Fray",

note = "Publisher Copyright: {\textcopyright} 2018, {\textcopyright} 2018 Informa UK Limited, trading as Taylor \& Francis Group.",

year = "2018",

month = jun,

day = "3",

doi = "10.1080/15476286.2018.1460996",

language = "English",

volume = "15",

pages = "829--831",

journal = "RNA Biology",

issn = "1547-6286",

publisher = "Taylor and Francis Ltd.",

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Jantsch, MF, Quattrone, A, O'Connell, M, Helm, M, Frye, M, Macias-Gonzales, M, Ohman, M, Ameres, S, Willems, L, Fuks, F, Oulas, A, Vanacova, S, Nielsen, H, Bousquet-Antonelli, C, Motorin, Y, Roignant, JY, Balatsos, N, Dinnyes, A, Baranov, P, Kelly, V, Lamm, A, Rechavi, G, Pelizzola, M, Liepins, J, Holodnuka Kholodnyuk, I, Zammit, V, Ayers, D, Drablos, F, Dahl, JA, Bujnicki, J, Jeronimo, C, Almeida, R, Neagu, M, Costache, M, Bankovic, J, Banovic, B, Kyselovic, J, Valor, LM, Selbert, S, Pir, P, Demircan, T, Cowling, V, Schäfer, M, Rossmanith, W, Lafontaine, D, David, A, Carre, C, Lyko, F, Schaffrath, R, Schwartz, S, Verdel, A, Klungland, A, Purta, E, Timotijevic, G, Cardona, F, Davalos, A, Ballana, E, O'Carroll, D, Ule, J & Fray, R 2018, 'Positioning Europe for the EPITRANSCRIPTOMICS challenge', RNA Biology, vol. 15, no. 6, pp. 829-831. https://doi.org/10.1080/15476286.2018.1460996

TY - JOUR

T1 - Positioning Europe for the EPITRANSCRIPTOMICS challenge

AU - Jantsch, Michael F.

AU - Quattrone, Alessandro

AU - O'Connell, Mary

AU - Helm, Mark

AU - Frye, Michaela

AU - Macias-Gonzales, Manuel

AU - Ohman, Marie

AU - Ameres, Stefan

AU - Willems, Luc

AU - Fuks, Francois

AU - Oulas, Anastasis

AU - Vanacova, Stepanka

AU - Nielsen, Henrik

AU - Bousquet-Antonelli, Cecile

AU - Motorin, Yuri

AU - Roignant, Jean Yves

AU - Balatsos, Nikolaos

AU - Dinnyes, Andras

AU - Baranov, Pavel

AU - Kelly, Vincent

AU - Lamm, Ayelet

AU - Rechavi, Gideon

AU - Pelizzola, Mattia

AU - Liepins, Janis

AU - Holodnuka Kholodnyuk, Irina

AU - Zammit, Vanessa

AU - Ayers, Duncan

AU - Drablos, Finn

AU - Dahl, John Arne

AU - Bujnicki, Janusz

AU - Jeronimo, Carmen

AU - Almeida, Raquel

AU - Neagu, Monica

AU - Costache, Marieta

AU - Bankovic, Jasna

AU - Banovic, Bojana

AU - Kyselovic, Jan

AU - Valor, Luis Miguel

AU - Selbert, Stefan

AU - Pir, Pinar

AU - Demircan, Turan

AU - Cowling, Victoria

AU - Schäfer, Matthias

AU - Rossmanith, Walter

AU - Lafontaine, Denis

AU - David, Alexandre

AU - Carre, Clement

AU - Lyko, Frank

AU - Schaffrath, Raffael

AU - Schwartz, Schraga

AU - Verdel, Andre

AU - Klungland, Arne

AU - Purta, Elzbieta

AU - Timotijevic, Gordana

AU - Cardona, Fernando

AU - Davalos, Alberto

AU - Ballana, Ester

AU - O'Carroll, Donal

AU - Ule, Jernej

AU - Fray, Rupert

PY - 2018/6/3

Y1 - 2018/6/3

N2 - The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the ~150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.

AB - The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the ~150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.

KW - database of Modification

KW - detection of RNA modification

KW - epitranscriptomics

KW - European funding

KW - model systems

UR - https://www.scopus.com/pages/publications/85046696156

U2 - 10.1080/15476286.2018.1460996

DO - 10.1080/15476286.2018.1460996

M3 - Comment/Debate

C2 - 29671387

AN - SCOPUS:85046696156

SN - 1547-6286

VL - 15

SP - 829

EP - 831

JO - RNA Biology

JF - RNA Biology

IS - 6

ER -

Positioning Europe for the EPITRANSCRIPTOMICS challenge

Abstract

UN SDGs

Keywords

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