, 2008 — From Molecules to Organisms: Towards Multiscale Integrated Models of Biological Systems. Theoretical Biology Insights vol. 1, , dir. {Libertas Academica Ltd} p. 13-22
, 2019 — « La formulation en cuisine : entre chimie et alchimie ou la maitrise des molécules » in Les métamorphoses de l’aliment.. , ,
, juin 2011 — Linker Histones Incorporation Maintains Chromatin Fiber Plasticity. Biophysical Journal vol. 100, n° 11, dir. {Biophysical Society} p. 2726-2735
, octobre 2011 — Nucleosome-remodelling machines and other molecular motors observed at the single-molecule level. FEBS Journal vol. 278, n° 19, dir. {Wiley} p. 3596-3607
, 2019 — « Cuisiner/pâtisser avec le chocolat : jeux de textures » in Les goûts du chocolat dans le monde.. , ,
, 2009 — The Yeast Pif1 Helicase Prevents Genomic Instability Caused by G-Quadruplex-Forming CEB1 Sequences In Vivo. PLoS Genetics vol. 5, n° 5, dir. {Public Library of Science} e1000475
, janvier 2020 — Identification of hemicatenane-specific binding proteins by fractionation of Hela nuclei extracts. Biochemical Journal vol. 477, n° 2, dir. {Portland Press} p. 509-524
, mars 2016 — G-quadruplexes and helicases. Nucleic Acids Research vol. 44, n° 5, dir. {Oxford University Press} p. 1989-2006
, 2015 — A fluorescence-based helicase assay: application to the screening of G-quadruplex ligands. Nucleic Acids Research vol. 43, n° 11, dir. {Oxford University Press} e71
, 2016 — Yeast cells reveal the misfolding and the cellular mislocalisation of the human BRCA1 protein. Journal of Cell Science , , dir. {Company of Biologists}
, 2006 — Structural plasticity of single chromatin fibers revealed by torsional manipulation.. Nature Structural and Molecular Biology vol. 13, , dir. {Nature Publishing Group} p. 444-450
, 2021 — Identifying G-Quadruplex-DNA-Disrupting Small Molecules. Journal of the American Chemical Society vol. 143, n° 32, dir. {American Chemical Society} p. 12567-12577
, septembre 2021 — Multiple hPOT1–TPP1 cooperatively unfold contiguous telomeric G-quadruplexes proceeding from 3’ toward 5’, a feature due to a 3’-end binding preference and to structuring of telomeric DNA. Nucleic Acids Research vol. 49, , dir. {Oxford University Press} p. 10735-10746
, juin 2021 — Fermentation: A Short Scientific and Culinary Overview of Kefir. , ,
, octobre 2015 — Use of double-stranded DNA mini-circles to characterize the covalent topoisomerase-DNA complex. Scientific Reports vol. 5, n° 1, dir. {Nature Publishing Group}
, 2011 — 5’CAG and 5’CTG Repeats Create Differential Impediment to the Progression of a Minimal Reconstituted T4 Replisome Depending on the Concentration of dNTPs.. Mol Biol Int vol. 2011, , p. 213824
, novembre 2008 — Rad51 Polymerization Reveals a New Chromatin Remodeling Mechanism. PLoS ONE vol. 3, n° 11, dir. {Public Library of Science} e3643
, septembre 2007 — Chromatin polymorphism and the nucleosome superfamily: a genealogy.. Cell Cycle vol. 6, n° 17, dir. {Taylor \\& Francis} p. 2113-9
, octobre 2014 — Auto-assembly as a new regulatory mechanism of noncoding RNA. Cell Cycle vol. 8, n° 6, dir. {Taylor \\& Francis} p. 952-954
, février 2020 — « RNA Nanostructure Molecular Imaging » in RNA Spectroscopy.. , , p. 319-327