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Radiation Induced Lung Injury (RILI) is one of the main limiting factors of thorax irradiation, which can induce acute pneumonitis as well as pulmonary fibrosis, the latter being a life-threatening condition. The order of cellular and molecular events in the progression towards fibrosis is key to the physiopathogenesis of the disease, yet their coordination in space and time remains largely unexplored. Here, we present an interactive murine single cell atlas of the lung response to irradiation, generated from C57BL6/J female mice. This tool opens the door for exploration of the spatio-temporal dynamics of the mechanisms that lead to radiation-induced pulmonary fibrosis. It depicts with unprecedented detail cell type-specific radiation-induced responses associated with either lung regeneration or the failure thereof. A better understanding of the mechanisms leading to lung fibrosis will help finding new therapeutic options that could improve patients’ quality of life. Radiation damages the healthy lung and triggers severe side effects. Here the authors provide a single cell atlas of the lung responses to radiation injury to explore the spatio-temporal dynamics of the mechanisms leading to radio-induced pulmonary fibrosis.

Live-cell imaging has revealed unexpected features of gene expression. Here using improved single-molecule RNA microscopy, we show that synthesis of HIV-1 RNA is achieved by groups of closely spaced polymerases, termed convoys, as opposed to single isolated enzymes. Convoys arise by a Mediator-dependent reinitiation mechanism, which generates a transient but rapid succession of polymerases initiating and escaping the promoter. During elongation, polymerases are spaced by few hundred nucleotides, and physical modelling suggests that DNA torsional stress may maintain polymerase spacing. We additionally observe that the HIV-1 promoter displays stochastic fluctuations on two time scales, which we refer to as multi-scale bursting. Each time scale is regulated independently: Mediator controls minute-scale fluctuation (convoys), while TBP-TATA-box interaction controls sub-hour fluctuations (long permissive/non-permissive periods). A cellular promoter also produces polymerase convoys and displays multi-scale bursting. We propose that slow, TBP-dependent fluctuations are important for phenotypic variability of single cells. HIV-1 viral gene expression stochastically switches between active and inactive states. Here, using improved single molecule RNA microscopy, the authors show that HIV-1 RNA stochastic transcription is achieved by groups of closely spaced polymerases, and is regulated by Mediator and TBP at different time scales.

Telomere dysfunction activates p53-mediated cellular growth arrest, senescence and apoptosis to drive progressive atrophy and functional decline in high-turnover tissues. The broader adverse impact of telomere dysfunction across many tissues including more quiescent systems prompted transcriptomic network analyses to identify common mechanisms operative in haematopoietic stem cells, heart and liver. These unbiased studies revealed profound repression of peroxisome proliferator-activated receptor gamma, coactivator 1 alpha and beta ( PGC-1α and PGC-1β , also known as Ppargc1a and Ppargc1b , respectively) and the downstream network in mice null for either telomerase reverse transcriptase ( Tert ) or telomerase RNA component ( Terc ) genes. Consistent with PGCs as master regulators of mitochondrial physiology and metabolism, telomere dysfunction is associated with impaired mitochondrial biogenesis and function, decreased gluconeogenesis, cardiomyopathy, and increased reactive oxygen species. In the setting of telomere dysfunction, enforced Tert or PGC-1α expression or germline deletion of p53 (also known as Trp53 ) substantially restores PGC network expression, mitochondrial respiration, cardiac function and gluconeogenesis. We demonstrate that telomere dysfunction activates p53 which in turn binds and represses PGC-1α and PGC-1β promoters, thereby forging a direct link between telomere and mitochondrial biology. We propose that this telomere–p53–PGC axis contributes to organ and metabolic failure and to diminishing organismal fitness in the setting of telomere dysfunction. The telomere/mitochondria axis of ageing The recent demonstration of a functional link between mitochondria and telomeres — the protective tips at the ends of chromosomes — raised the possibility that both may be implicated in processes related to ageing. Now an analysis of the transcriptome (the total RNA content) of haematopoietic stem cells from heart and liver tissues of mice points to the existence of a telomere-p53-PGC axis linking telomere dysfunction to compromised organ function and possibly to age-related disorders. In mice with dysfunctional telomeres, p53-mediated cellular growth arrest becomes activated, in turn repressing PGC-1α and PGC-1β, master regulators of metabolic and mitochondrial processes. This results in reduced mitochondrial mass, mitochondrial dysfunction and reduced ATP generation, impaired gluconeogenesis, cardiomyopathy and increased reactive oxygen species. Here it is shown that telomere dysfunction drives metabolic and mitochondrial compromise. Mice with dysfunctional telomeres activate p53, which in turn represses PGC-1α and PGC-1β, master regulators of metabolic and mitochondrial processes. This results in reduced mitochondrial mass, mitochondrial dysfunction and reduced ATP generation, impaired gluconeogenesis, cariomyopathy and increased reactive oxygen species. This telomere–p53–PGC pathway shows how telomere dysfunction may compromise organ function and contribute to age-related disorders.

Mechanical circulatory support (MCS) using left ventricular assist devices (LVAD) have considerably improved the quality of life and survival rate of patients with end-stage heart failure. Despite substantial technological progress, major challenges with regard to VAD-specific and VAD-related infections have hitherto hindered the broader application of this promising therapy approach. Driveline infections (DLI) range among the main adverse events experienced in LVAD patients. However, many centers still apply their own protocol for driveline exit site (DLES) care and an international standard on prevention, reduction and early treatment of DLI after the perioperative period has not yet been defined. In March 2019, VAD coordinators and cardiac surgeons from Germany and Austria met to develop a standard of care procedure (SOP) as well as a new staging approach with recommended actions for treatment of VAD carriers. In this Driveline Expert STagINg and carE (DESTINE) study group we developed a 10-step SOP for DLES care with emphasis on essentials such as clean and save preparation, sterile dressing change and secure driveline immobilization. An advanced wound staging approach was defined with recommended actions for prevention, early detection and stage-related management of DLI. Broad consensus was reached on the fact that an interdisciplinary approach both in DLES care and DLES healing disorder awareness is required to prolong infect-free survival times on MCS as well as to ensure high patient compliance and quality of life. In conclusion, a new detailed SOP for appropriate DLES care and an advanced wound staging approach for prevention and management of DLI were defined on an expert level applicable for VAD clinicians, practitioners and care givers in Central Europe. •Expert consensus meeting defining standards on driveline exit site care in patients with left ventricular assist devices•Development of a detailed standard operating procedure for appropriate driveline exit site wound care•Definition of an advanced wound staging approach with recommended actions for prevention, early detection and management•An interdisciplinary approach is required to prolong infect-free survival times, to ensure high patient compliance and quality of life

The liver plays a central role in metabolism, protein synthesis and detoxification. It possesses unique regenerative capacity upon injury. While many factors regulating cellular proliferation during liver repair have been identified, the mechanisms by which the injured liver maintains vital functions prior to tissue recovery are unknown. Here, we identify a new phase of functional compensation following acute liver injury that occurs prior to cellular proliferation. By coupling single-cell RNA-seq with in situ transcriptional analyses in two independent murine liver injury models, we discover adaptive reprogramming to ensure expression of both injury response and core liver function genes dependent on macrophage-derived WNT/β-catenin signaling. Interestingly, transcriptional compensation is most prominent in non-proliferating cells, clearly delineating two temporally distinct phases of liver recovery. Overall, our work describes a mechanism by which the liver maintains essential physiological functions prior to cellular reconstitution and characterizes macrophage-derived WNT signals required for this compensation. The liver possesses the ability to regenerate following sudden injury. Here, the authors use single-cell RNA-sequencing and in situ transcriptional analyses to identify a new phase of liver regeneration in mice aimed at maintaining essential functions throughout the regenerative process.

Transcription factor networks, together with histone modifications and signalling pathways, underlie the establishment and maintenance of gene regulatory architectures associated with the molecular identity of each cell type. However, how master transcription factors individually impact the epigenomic landscape and orchestrate the behaviour of regulatory networks under different environmental constraints is only partially understood. Here, we show that the transcription factor Nanog deploys multiple distinct mechanisms to enhance embryonic stem cell self-renewal. In the presence of LIF, which fosters self-renewal, Nanog rewires the pluripotency network by promoting chromatin accessibility and binding of other pluripotency factors to thousands of enhancers. In the absence of LIF, Nanog blocks differentiation by sustaining H3K27me3, a repressive histone mark, at developmental regulators. Among those, we show that the repression of Otx2 plays a preponderant role. Our results underscore the versatility of master transcription factors, such as Nanog, to globally influence gene regulation during developmental processes. Transcription factor (TF) networks are essential for the molecular identity of each cell type. Here, the authors show that TF Nanog utilises multiple molecular strategies to enhance embryonic stem cell self-renewal, which include regulation of chromatin accessibility in the presence of LIF or maintenance of H3K27me3 at developmental regulators in its absence.

Pluripotent mouse embryonic stem cells maintain their identity throughout virtually infinite cell divisions. This phenomenon, referred to as self-renewal, depends on a network of sequence-specific transcription factors (TFs) and requires daughter cells to accurately reproduce the gene expression pattern of the mother. However, dramatic chromosomal changes take place in mitosis, generally leading to the eviction of TFs from chromatin. Here, we report that Esrrb, a major pluripotency TF, remains bound to key regulatory regions during mitosis. We show that mitotic Esrrb binding is highly dynamic, driven by specific recognition of its DNA-binding motif and is associated with early transcriptional activation of target genes after completion of mitosis. These results indicate that Esrrb may act as a mitotic bookmarking factor, opening another perspective to molecularly understand the role of sequence-specific TFs in the epigenetic control of self-renewal, pluripotency and genome reprogramming. Festuccia et al. show that the pluripotency regulator Esrrb is retained on mitotic chromosomes, both in embryonic stem cells and during early embryogenesis, and epigenetically marks key regulatory regions during mitosis.

The cell cycle is a series of regulated stages during which a cell grows, replicates its DNA, and divides. It consists of four phases – two growth phases (G1 and G2), a replication phase (S), and a division phase (M) – each characterized by distinct transcriptional programs and impacting most other cellular processes. In imaging assays, the cell cycle phase can be identified using specific cell-cycle markers. However, the use of dedicated cell-cycle markers can be impractical or even prohibitive, as they occupy fluorescent channels that may be needed for other reporters. To address this limitation we propose a method to infer the cell cycle phase from a widely used fluorescent reporter: SiR-DNA, thereby bypassing the need for phase-specific markers while leveraging information already present in common experimental setups. Our method is based on a Variational Auto-Encoder (VAE), enhanced with two auxiliary tasks: predicting the average intensity of phase-specific markers and enforcing temporal consistency through latent space regularization. The reconstruction task ensures that the latent space captures cell cycle–relevant features, while the temporal constraint promotes biological plausibility. The resulting model, CC-VAE, classifies cell cycle phases with high accuracy from widely used DNA markers and can thus be applied to high-content screening datasets not specifically designed for cell cycle analysis. CC-VAE is freely available, along with a new, publicly released dataset comprising over 600,000 labeled HeLa Kyoto nuclear images to support further development and benchmarking in the community.

Local translation allows for a spatial control of gene expression. Here, we use high-throughput smFISH to screen centrosomal protein-coding genes, and we describe 8 human mRNAs accumulating at centrosomes. These mRNAs localize at different stages during cell cycle with a remarkable choreography, indicating a finely regulated translational program at centrosomes. Interestingly, drug treatments and reporter analyses reveal a common translation-dependent localization mechanism requiring the nascent protein. Using ASPM and NUMA1 as models, single mRNA and polysome imaging reveals active movements of endogenous polysomes towards the centrosome at the onset of mitosis, when these mRNAs start localizing. ASPM polysomes associate with microtubules and localize by either motor-driven transport or microtubule pulling. Remarkably, the Drosophila orthologs of the human centrosomal mRNAs also localize to centrosomes and also require translation. These data identify a conserved family of centrosomal mRNAs that localize by active polysome transport mediated by nascent proteins. Centrosomes function as microtubule organizing centers where several mRNAs accumulate. By employing high-throughput single molecule FISH screening, the authors discover that 8 human mRNAs localize to centrosomes with unique cell cycle dependent patterns using an active polysome targeting mechanism.