Citrullination of HP1γ chromodomain affects association with chromatin.

BACKGROUND: Stem cell differentiation involves major chromatin reorganisation, heterochromatin formation and genomic relocalisation of structural proteins, including heterochromatin protein 1 gamma (HP1γ). As the principal reader of the repressive histone marks H3K9me2/3, HP1 plays a key role in numerous processes including heterochromatin formation and maintenance. RESULTS: We find that HP1γ is citrullinated in mouse embryonic stem cells (mESCs) and this diminishes when cells differentiate, indicating that it is a dynamically regulated post-translational modification during stem cell differentiation. Peptidylarginine deiminase 4, a known regulator of pluripotency, citrullinates HP1γ in vitro. This requires R38 and R39 within the HP1γ chromodomain, and the catalytic activity is enhanced by trimethylated H3K9 (H3K9me3) peptides. Mutation of R38 and R39, designed to mimic citrullination, affects HP1γ binding to H3K9me3-containing peptides. Using live-cell single-particle tracking, we demonstrate that R38 and R39 are important for HP1γ binding to chromatin in vivo. Furthermore, their mutation reduces the residence time of HP1γ on chromatin in differentiating mESCs. CONCLUSION: Citrullination is a novel post-translational modification of the structural heterochromatin protein HP1γ in mESCs that is dynamically regulated during mESC differentiation. The citrullinated residues lie within the HP1γ chromodomain and are important for H3K9me3 binding in vitro and chromatin association in vivo.Cancer Research UK (grant reference RG17001) Wellcome Trust (Core Grant reference WT203144) Cancer Research UK (grant reference C6946/A24843). Wellcome Trust (206291/Z/17/Z) Medical Research Council (MR/P019471/1 and MR/M010082/1). Royal Society Professorship (RP150066) Medical Research Council (MR/K015850/1

Terminology and Classification of Muscle Injuries in Sport: The Munich Consensus Statement

Objective: To provide a clear terminology and classification of muscle injuries in order to facilitate effective communication among medical practitioners and development of systematic treatment strategies. Methods: Thirty native English-speaking scientists and team doctors of national and first division professional sports teams were asked to complete a questionnaire on muscle injuries to evaluate the currently used terminology of athletic muscle injury. In addition, a consensus meeting of international sports medicine experts was established to develop practical and scientific definitions of muscle injuries as well as a new and comprehensive classification system. Results: The response rate of the survey was 63%. The responses confirmed the marked variability in the use of the terminology relating to muscle injury, with the most obvious inconsistencies for the term strain. In the consensus meeting, practical and systematic terms were defined and established. In addition, a new comprehensive classification system was developed, which differentiates between four types: functional muscle disorders (type 1: overexertion-related and type 2: neuromuscular muscle disorders) describing disorders without macroscopic evidence of fibre tear and structural muscle injuries (type 3: partial tears and type 4: (sub)total tears/tendinous avulsions) with macroscopic evidence of fibre tear, that is, structural damage. Subclassifications are presented for each type. Conclusions: A consistent English terminology as well as a comprehensive classification system for athletic muscle injuries which is proven in the daily practice are presented. This will help to improve clarity of communication for diagnostic and therapeutic purposes and can serve as the basis for future comparative studies to address the continued lack of systematic information on muscle injuries in the literature. What are the new things: Consensus definitions of the terminology which is used in the field of muscle injuries as well as a new comprehensive classification system which clearly defines types of athletic muscle injuries

FRET-enhanced photostability allows improved single-molecule tracking of proteins and protein complexes in live mammalian cells.

A major challenge in single-molecule imaging is tracking the dynamics of proteins or complexes for long periods of time in the dense environments found in living cells. Here, we introduce the concept of using FRET to enhance the photophysical properties of photo-modulatable (PM) fluorophores commonly used in such studies. By developing novel single-molecule FRET pairs, consisting of a PM donor fluorophore (either mEos3.2 or PA-JF549) next to a photostable acceptor dye JF646, we demonstrate that FRET competes with normal photobleaching kinetic pathways to increase the photostability of both donor fluorophores. This effect was further enhanced using a triplet-state quencher. Our approach allows us to significantly improve single-molecule tracking of chromatin-binding proteins in live mammalian cells. In addition, it provides a novel way to track the localization and dynamics of protein complexes by labeling one protein with the PM donor and its interaction partner with the acceptor dye

Computational Methods for Integrating Microscopy with Chromatin Structures

The genome is more than a linear sequence of bases; its spatial organisation is a key part of its function. In humans, three billion base pairs, or approximately two metres of DNA are packaged into a nucleus a few micrometres in diameter. The genome must also be organised so that it can be replicated and partitioned into daughter cells, and so that regulatory elements are positioned to affect their targets. Until recently, little was known about the organisation of the genome at the scale of single genes. The packaging of DNA onto nucleosomes, and the segregation of chromosomes into chromosome territories was well understood, but the development of chromatin conformation capture (3C) techniques has enabled the first thorough study of intermediate scales. These methods provide information about the distances between pairs of genomic loci, which gives indirect information about their positions. By applying these techniques to single cells, it has become possible to calculate a structure from the observed distance restraints. Through the prior constraints placed on the model, such as the existence of a continuous backbone, these structures provide additional information about the conformation of DNA. To overcome the limitations of 3C, it is useful to integrate additional sources of information. I present several methods for the validation and improvement of Hi-C structures by adding data from microscopy, and for characterising dyes used in single-molecule light microscopy. It is found that single-cell Hi-C structures agree with fluorescence microscopy when observing the distance of genes from the edge of the nucleus, and that centromeres are not a suitable label for direct validation. Adding absolute positional restraints from images is shown to be useful in better determining chromatin structure in synthetic tests. Finally, the presence of a FRET acceptor near a fluorescent protein is shown to improve its photophysical properties.Funded by the 4D CellFate projec

Citrullination of HP1γ chromodomain affects association with chromatin.

BACKGROUND: Stem cell differentiation involves major chromatin reorganisation, heterochromatin formation and genomic relocalisation of structural proteins, including heterochromatin protein 1 gamma (HP1γ). As the principal reader of the repressive histone marks H3K9me2/3, HP1 plays a key role in numerous processes including heterochromatin formation and maintenance. RESULTS: We find that HP1γ is citrullinated in mouse embryonic stem cells (mESCs) and this diminishes when cells differentiate, indicating that it is a dynamically regulated post-translational modification during stem cell differentiation. Peptidylarginine deiminase 4, a known regulator of pluripotency, citrullinates HP1γ in vitro. This requires R38 and R39 within the HP1γ chromodomain, and the catalytic activity is enhanced by trimethylated H3K9 (H3K9me3) peptides. Mutation of R38 and R39, designed to mimic citrullination, affects HP1γ binding to H3K9me3-containing peptides. Using live-cell single-particle tracking, we demonstrate that R38 and R39 are important for HP1γ binding to chromatin in vivo. Furthermore, their mutation reduces the residence time of HP1γ on chromatin in differentiating mESCs. CONCLUSION: Citrullination is a novel post-translational modification of the structural heterochromatin protein HP1γ in mESCs that is dynamically regulated during mESC differentiation. The citrullinated residues lie within the HP1γ chromodomain and are important for H3K9me3 binding in vitro and chromatin association in vivo.Cancer Research UK (grant reference RG17001) Wellcome Trust (Core Grant reference WT203144) Cancer Research UK (grant reference C6946/A24843). Wellcome Trust (206291/Z/17/Z) Medical Research Council (MR/P019471/1 and MR/M010082/1). Royal Society Professorship (RP150066) Medical Research Council (MR/K015850/1

Research data supporting "A microfluidic platform for trapping, releasing and super-resolution imaging of single cells"

Particles and cells were trapped and released using a microfluidic device. The device enabled the trapping of single particles with a trapping efficiency of greater than 95%, and allowed for single particles and cells to be trapped, released and manipulated by simply controlling corresponding valves. Stable immobilisation of large numbers of single cells could be achieved in a few minutes. Proof-of-concept super-resolution imaging experiments with mouse embryonic stem cells (mESCs) were conducted by exploiting super-resolution photoactivated localisation microscopy (PALM). Cells and nuclei were stably trapped and imaged. Centromeres of ∼200 nm size could be identified with a localisation precision of <15 nm.BBSRC [BB/K013726/1