Team
Epigenetic Regulations

Dpt: Signaling through Chromatin

Our research activities

Considering the extreme nature of epigenetic regulations operating in maturing male haploid cells, our team has made several major discoveries, shedding new light on the obscure process of sperm epigenome establishment, with conceptual impacts in the field of epigenetics in general. These discoveries concern the biology of bromodomain factors, the biology of histone variants and histone acetyltransferases, and new histone languages based on non-acetylated histone acylations. This has led us more recently to develop a new research axis on the link between metabolism and epigenome in various physio-pathological contexts, including cancer. Our team is also developing EpiMed, an "in silico" epigenetics axis, involving a dedicated group of experts in concept-driven "omics" data analysis. New information on epigenetic regulations is extracted from various “omics” data leading to the discovery of cancer biomarkers, the identification of new therapeutic approaches, and oncogenic mechanisms. In addition, EpiMed also positions us in new research areas such as population epigenetics. The strong and visible activity of our team places us at the center of many international collaborative projects, partly managed by an International Associated Laboratory (LIA) with the Shanghai Institute of Haematology (JiaoTong University). Within this framework, several projects involving computational epigenetics and the metabolism-epigenetics dialogue are under development in various cancer types.

IAB_INFOGRAPHIES-Regulation-Epigenetique2.svg

Saadi KHOCHBIN

Team leader, Platform manager

04 76 54 95 83

Our research axes

We previously discovered the occurrence of unknown structural states that appear during histone-to-protamine (PRM) replacement (2007; 2013; 2017). The objective of this research line is to understand the structural and functional basis of these transient genome organizational states.

We and others have established that a general and physiological hyperacetylation of histone H4 occurs at the time of histone replacement by protamines (PRMs) (2000). The cause of this hyperacetylation and its consequences on the reorganization of the post-meiotic male genome have long remained a mystery. The objective of this particular line of research is to discover the molecular mechanisms at the origin of this massive hyperacetylation of histone H4 (2010; 2018; 2022).

We have previously identified a testis-specific bromodomain-containing factor, BRDT, as an important player in acetylation-dependent chromatin reorganization (2003). The aim of this line of research is to use extensive structural (2009; 2016) and functional (2012; 2016) analyses to decipher the role of BRDT, as well as other testis-specific bromodomain-containing factors such as ATAD2 (2015; 2021), in hyperacetylation-dependent histone eviction.

Our early collaborative work on histone lysine acylations with Prof. Y ZHAO (U. Chicago, USA) showed that histone acylations could be important epigenetic players (2011; 2013; 2014; 2016; 2021). With D. PANNE (U. Leicester, UK), the structural basis for the action of p300 in mediating histone acylations has been established (2017). This work highlights two important paradigm-changing concepts: 1) the metabolically driven competition between histone acetylation and acylation; and 2) its impact on bromodomain factor biology in general (2016; 2021)…

This line of research, which has been developing rapidly in recent years, builds on our recent findings on the role of the bromodomain factor ATAD2 in chromatin dynamics (2010; 2015; 2021), the dynamics of bromodomain factor binding through the acetylation/acylation ratio (2021), and finally, the role of the concurrent metabolic pathways in epigenetic reprogramming.

This research is carried out by the EpiMed members of our team who are experts in concept-driven "omics" data analysis in order to develop innovative approaches, in particular in the discovery of cancer biomarkers (so far, 9 independent cancer types have been considered) and in population epigenetics (environmental epidemiology and physiology). This program also involves all the university hospital members of the team (5 medical/clinical professors and associated staff).

Our major publications

See all publications

Metabolically controlled histone H4K5 acylation/acetylation ratio drives BRD4 genomic distribution

Gao M, Wang J, Rousseaux S, Tan M, Pan L, Peng L, Wang S, Xu…

Cell Rep 2021 Jul 27;36(4):109460.

See the publication

Nut Directs p300-Dependent, Genome-Wide H4 Hyperacetylation in Male Germ Cells

Shiota H, Barral S, Buchou T, Tan M, Couté Y, Charbonnier G, Reynoird N, Boussouar…

Cell Rep 2018 24:3477-3487.e6.

See the publication

Transcription factor dimerization activates the p300 acetyltransferase

Ortega E, Rengachari S, Ibrahim Z, Hoghoughi N, Gaucher J, Holehouse AS, Khochbin S, Panne D.

Nature 2018 562: 538-544

See the publication

Histone Variant H2A.L.2 Guides Transition Protein-Dependent Protamine Assembly in Male Germ Cells

Barral S, Morozumi Y, Tanaka H, Montellier E, Govin J, de Dieuleveult M, Charbonnier G,…

Molecular Cel 2017 66: 89-101.e8.

See the publication

Dynamic Competing Histone H4 K5K8 Acetylation and Butyrylation Are Hallmarks of Highly Active Gene Promoters

Goudarzi A, Zhang D, Huang H, Barral S, Kwon OK, Qi S, Tang Z, Buchou…

Molecular Cell 2016 62:169-180.

See the publication

Lysine 2-hydroxyisobutyrylation is a widely distributed active histone mark

Dai L, Peng C, Montellier E, Lu Z, Chen Y, Ishii H, Debernardi A, Buchou…

Nature Chem Biol 2014 10: 365-70.

See the publication

Chromatin-to-nucleoprotamine transition is controlled by the histone H2B variant TH2B

Montellier E, Boussouar F, Rousseaux S, Zhang K, Buchou T, Fenaille F, Shiota H, Debernardi…

Genes Dev 2013 Aug 1;27(15):1680-92.

See the publication

Ectopic activation of germline and placental genes identifies aggressive metastasis-prone lung cancers

Rousseaux S, Debernardi A, Jacquiau B, Vitte AL, Vesin A, Nagy-Mignotte H, Moro-Sibilot D, Brichon…

Science Transl Med 2013 May 22;5(186):186ra66.

See the publication

Bromodomain-dependent stage-specific male genome programming by Brdt

Gaucher J, Boussouar F, Montellier E, Curtet S, Buchou T, Bertrand S, Hery P, Jounier…

EMBO J 2012 Oct 3;31(19):3809-20.

See the publication

Oncogenesis by sequestration of CBP/p300 in transcriptionally inactive hyperacetylated chromatin domains

Reynoird N, Schwartz BE, Delvecchio M, Sadoul K, Meyers D, Mukherjee C, Caron C, Kimura…

EMBO J 2010 Sep 1;29(17):2943-52.

See the publication

Our activities in pictures

142022-27062023-regul-photo1.jpg
142022-27062023-regul-photo2.jpg
142028-27062023-covercellrep_shiota.jpg
142028-27062023-covermolcell_barral.jpg
142028-27062023-covermolcell_goudarzi.jpg

Our collaborations

  • Pr. Daniel Panne, Leicester Institute of Structural and Chemical Biology (University of Leicester). Structural basis of p300 activation and p300-mediated histone acylation (6 published research articles).
  • Pr. Yingming Zhao, University of Chicago. Functional studies of histone acylations (9 published research articles and 1 review).
  • Dr. Carlo Petosa, Institut de Biologie Structurale, bromodomain/histone structure/function (6 published research articles and 1 review).
  • Pr. Mi/Wang, Loboratoire International Associé (Grenoble-Shanghai) (10 published articles, and 3 reviews).
  • Pr. Minoru Yoshida, Riken/Tokyo University. Acetylation biology (11 published articles, and 2 reviews)
  • In addition to these examples, we are coordinating important international networks of world-class leaders. Most of our high impact publications in fact involve between 5 to 10 international laboratories from Asia (China and Japan), Europe, and USA.

Our technologies

  • All the cutting-edge molecular/chromatin biology laboratory technics
  • Development of various mouse models (post-meiotic spermatogenesis, lung and liver cancers, etc…)
  • All the bioinformatics/biostatistics/artificial intelligence approaches