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In mammals, both sterile wounding and infection induce inflammation and activate the innate immune system, and the combination of both challenges may lead to severe health defects, revealing the importance of the balance between the intensity and resolution of the inflammatory response for the organism’s fitness. Underlying mechanisms remain however elusive. Using Drosophila, we show that, upon infection with the entomopathogenic bacterium Pseudomonas entomophila (Pe) , a sterile wounding induces a reduced resistance and increased host mortality. To identify the molecular mechanisms underlying the susceptibility of wounded flies to bacterial infection, we analyzed the very first steps of the process by comparing the transcriptome landscape of infected (simple hit flies, SH), wounded and infected (double hit flies, DH) and wounded (control) flies. We observed that overexpressed genes in DH flies compared to SH ones are significantly enriched in genes related to stress, including members of the JNK pathway. We demonstrated that the JNK pathway plays a central role in the DH phenotype by manipulating the Jra/dJun activity. Moreover, the CrebA/Creb3-like transcription factor (TF) and its targets were up-regulated in SH flies and we show that CrebA is required for mounting an appropriate immune response. Drosophila thus appears as a relevant model to investigate interactions between trauma and infection and allows to unravel key pathways involved.

Chromatin organisation and transcriptional regulation are tightly coordinated processes that are essential for maintaining cellular identity and function. ATP-dependent chromatin remodelling proteins play critical roles in control of genome structure and in regulating transcription across eukaryotes. Their essential nature, however, has made it difficult to define exactly how these functions are mediated. The chromatin remodeller CHD4 has been shown to be capable of sliding nucleosomes in vitro, and to regulate chromatin accessibility and gene expression in vivo. Using an inducible depletion system, here we identify a second mechanism of action for CHD4 in actively restricting the residence time of transcription factors on chromatin. Together these activities result in distinct, context-dependent outcomes: at highly accessible regulatory elements, CHD4 limits transcription factor binding to maintain regulatory function, while at low-accessibility euchromatic regions, it prevents transcription factor engagement and sustains chromatin compaction, thereby silencing cryptic enhancers. Collectively, these mechanisms enable CHD4 to reduce transcriptional noise while preserving the responsiveness of active regulatory networks.

As cells exit the pluripotent state and begin to commit to a specific lineage they must activate genes appropriate for that lineage while silencing genes associated with pluripotency and preventing activation of lineage-inappropriate genes. The Nucleosome Remodelling and Deacetylation (NuRD) complex is essential for pluripotent cells to successfully undergo lineage commitment. NuRD controls nucleosome density at regulatory sequences to facilitate transcriptional responses, and also has been shown to prevent unscheduled transcription (transcriptional noise) in undifferentiated pluripotent cells. How these activities combine to ensure cells engage a gene expression program suitable for successful lineage commitment has not been determined. Here we show that while NuRD is not required to silence all genes, its activity is important to restrict expression of genes primed for activation upon exit from the pluripotent state, and that NuRD activity facilitates their subsequent transcriptional activation. We further show that NuRD coordinates gene expression changes, which acts to maintain a barrier between different stable states. Thus NuRD-mediated chromatin remodelling serves multiple functions, including reducing transcriptional noise, priming genes for activation and coordinating the transcriptional response to facilitate lineage commitment.Competing Interest StatementSara-Jane Dunn was an employee at Microsoft Research during this study and is currently employed at DeepMind. Neither Microsoft Research nor DeepMind have directed any aspect of the study nor exerted any commercial rights over the results. The authors declare no conflicts of interest.

Enhancers are genomic DNA sequences that bind transcription factors, chromatin regulators and non-coding transcripts to modulate the expression of target genes. They have been found to act from different locations relative to a gene and to modulate the activity of promoters up to ~1 Mb away. Here we report the first 3D genome structures of single mouse ES cells as they are induced to exit pluripotency, transition through a formative stage and undergo neuroectodermal differentiation. In order to directly study how interactions between enhancers and promoters are reconfigured genome wide we have determined 3D structures of haploid cells using single cell Hi-C, where we can unambiguously map the contacts to particular chromosomes. We find that there is a remarkable reorganisation of 3D genome structure where inter-chromosomal intermingling increases dramatically in the formative state. This intermingling is associated with the formation of a large number of multiway hubs that bring together enhancers and promoters with similar chromatin states from typically 5-8 distant chromosomal sites that are often separated by many Mb from each other. Genes important for pluripotency exit establish contacts with emerging enhancers within multiway chromatin hubs as cells enter the formative state, consistent with these structural changes playing an important role in establishing new cell identities. Furthermore, we find that different multiway chromatin hubs, and thus different enhancer-promoter interactions, are formed in different individual cells. Our results suggest that studying genome structure in single cells will be important to identify key changes in enhancer-promoter interactions that occur as cells undergo developmental transitions.Competing Interest StatementThe authors have declared no competing interest.

Differentiation of mammalian pluripotent cells involves large-scale changes in transcription and, among the molecules that orchestrate these changes, chromatin remodellers are essential to initiate, establish and maintain a new gene regulatory network. The NuRD complex is a highly conserved chromatin remodeller which fine-tunes gene expression in embryonic stem cells. While the function of NuRD in mouse pluripotent cells has been well defined, no study yet has defined NuRD function in human pluripotent cells. We investigated the structure and function of NuRD in human induced pluripotent stem cells (hiPSCs). Using immunoprecipitation followed by mass-spectrometry in hiPSCs and in naive or primed mouse pluripotent stem cells, we find that NuRD structure and biochemical interactors are generally conserved. Using RNA sequencing, we find that, whereas in mouse primed stem cells and in mouse naive ES cells, NuRD is required for an appropriate level of transcriptional response to differentiation signals, hiPSCs require NuRD to initiate these responses. This difference indicates that mouse and human cells interpret and respond to induction of differentiation differently.

Enhancer-promoter dynamics are critical for the spatiotemporal control of gene expression, but it remains unclear how these dynamics are controlled by chromatin regulators, such as the nucleosome remodelling and deacetylase (NuRD) complex. Here, we show that the intact NuRD complex increases CTCF/Cohesin binding and the probability of the interaction of intermediate-range (~1Mb) interactions in Hi-C experiments. To understand how NuRD alters 3D genome structure in this way, we developed a novel approach to segment and extract key biophysical parameters from trajectories of the NuRD complex determined using live-cell 3D single-molecule imaging. Unexpectedly, this revealed that the intact NuRD complex decompacts chromatin structure, makes NuRD-bound sequences move faster, and thus increases the overall volume of the nucleus that they explore. Interestingly, we also uncovered a rare fast-diffusing state of chromatin that exhibits directed motion. The intact NuRD complex reduces the amount of time that enhancers/promoters remain in this fast state, which we propose would otherwise reset enhancer-promoter proximity. Thus, we uncover an intimate connection between a chromatin regulator and the spatial dynamics of the local region of the genome to which it binds.