Remco Loos
Remco Loos
Celgene Institute for Translational Research
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Cited by
Cited by
Resetting transcription factor control circuitry toward ground-state pluripotency in human
Y Takashima, G Guo, R Loos, J Nichols, G Ficz, F Krueger, D Oxley, ...
Cell 158 (6), 1254-1269, 2014
The ability of inner-cell-mass cells to self-renew as embryonic stem cells is acquired following epiblast specification
T Boroviak, R Loos, P Bertone, A Smith, J Nichols
Nature cell biology 16 (6), 513-525, 2014
Lineage-specific profiling delineates the emergence and progression of naive pluripotency in mammalian embryogenesis
T Boroviak, R Loos, P Lombard, J Okahara, R Behr, E Sasaki, J Nichols, ...
Developmental cell 35 (3), 366-382, 2015
Citrullination regulates pluripotency and histone H1 binding to chromatin
MA Christophorou, G Castelo-Branco, RP Halley-Stott, CS Oliveira, ...
Nature 507 (7490), 104-108, 2014
Transcriptional diversity during lineage commitment of human blood progenitors
L Chen, M Kostadima, JHA Martens, G Canu, SP Garcia, E Turro, ...
Science 345 (6204), 1251033, 2014
NuRD suppresses pluripotency gene expression to promote transcriptional heterogeneity and lineage commitment
N Reynolds, P Latos, A Hynes-Allen, R Loos, D Leaford, ...
Cell stem cell 10 (5), 583-594, 2012
Nuclear architecture organized by Rif1 underpins the replication-timing program
R Foti, S Gnan, D Cornacchia, V Dileep, A Bulut-Karslioglu, S Diehl, ...
Molecular cell 61 (2), 260-273, 2016
The nucleosome remodeling and deacetylation complex modulates chromatin structure at sites of active transcription to fine-tune gene expression
S Bornelöv, N Reynolds, M Xenophontos, S Gharbi, E Johnstone, R Floyd, ...
Molecular Cell 71 (1), 56-72. e4, 2018
Sall4 controls differentiation of pluripotent cells independently of the Nucleosome Remodelling and Deacetylation (NuRD) complex
A Miller, M Ralser, SL Kloet, R Loos, R Nishinakamura, P Bertone, ...
Development 143 (17), 3074-3084, 2016
Comparison of RNA-seq and microarray platforms for splice event detection using a cross-platform algorithm
JP Romero, M Ortiz-Estévez, A Muniategui, S Carrancio, FJ de Miguel, ...
BMC genomics 19, 1-14, 2018
Small universal accepting hybrid networks of evolutionary processors
R Loos, F Manea, V Mitrana
Acta Informatica 47 (2), 133-146, 2010
Next-generation sequencing: a challenge to meet the increasing demand for training workshops in Australia
NS Watson-Haigh, CA Shang, M Haimel, M Kostadima, R Loos, ...
Briefings in bioinformatics 14 (5), 563-574, 2013
On small, reduced, and fast universal accepting networks of splicing processors
R Loos, F Manea, V Mitrana
Theoretical computer science 410 (4-5), 406-416, 2009
Descriptional complexity of splicing systems
R Loos, A Malcher, D Wotschke
International Journal of Foundations of Computer Science 19 (04), 813-826, 2008
Solving SAT and HPP with accepting splicing systems
R Loos, C Martín-Vide, V Mitrana
International Conference on Parallel Problem Solving from Nature, 771-777, 2006
DECO: decompose heterogeneous population cohorts for patient stratification and discovery of sample biomarkers using omic data profiling
FJ Campos-Laborie, A Risueńo, M Ortiz-Estévez, B Rosón-Burgo, ...
Bioinformatics 35 (19), 3651-3662, 2019
An alternative definition of splicing
R Loos
Theoretical computer science 358 (1), 75-87, 2006
The Fascinating World of Phosphanylphosphonates: From Acetylenic Phosphaalkenes to Reductive Aldehyde Couplings
J Mai, S Ott
Synlett 30 (16), 1867-1885, 2019
Complexity theory for splicing systems
R Loos, M Ogihara
Theoretical computer science 386 (1-2), 132-150, 2007
Small universal accepting networks of evolutionary processors with filtered connections
R Loos, F Manea, V Mitrana
arXiv preprint arXiv:0907.5130, 2009
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