Project description:Re-induction of endogenous proliferation is a promising regeneration strategy for post-mitotic organs. For heart regeneration, we recently discovered that dual inhibition of both GSK3 and MST1 is required for proliferation in mature human cardiac organoids1. However, the mechanisms of action are not yet understood. Here, we de-convolute the mitogenic response using proteomics and report that GSK3 inhibition activates a cell cycle network whereas MST1 inhibition drives the mevalonate pathway. Screening of an additional 105 compounds identified a p38 inhibitor, which activated a cell cycle network, as well as an inhibitor of TGFBR, which activated the mevalonate pathway; combinatorial treatment with these two inhibitors also resulted in synergistic cell cycle activation. The mevalonate pathway which was consistently activated under the most robust proliferative conditions, is down-regulated during in vivo maturation when cardiomyocyte regenerative capacity ceases and inhibition of the mevalonate pathway abolished the myocyte proliferative response to mitogens. Taken together, our findings suggest that the mevalonate pathway synergises with mitogenic agents to enable mature cardiomyocytes to re-enter the cell cycle. These findings have important ramifications for development of cardiac regenerative therapeutics.

Project description:Background: Zebrafish can faithfully regenerate injured fins through the formation of a blastema, a mass of proliferative cells that can grow and develop into the lost body part. After amputation, various cell types contribute to blastema formation, where each cell type retains fate restriction and exclusively contributes to regeneration of its own lineage. Epigenetic changes that are associated with lineage restriction during regeneration remain underexplored. Results: We produce epigenome maps, including DNA methylation and chromatin accessibility, as well as transcriptomes, of osteoblasts and other cells in uninjured and regenerating fins. This effort reveals regeneration as a process of highly dynamic and orchestrated transcriptomic and chromatin accessibility changes, coupled with stably maintained lineage-specific DNA methylation. The epigenetic signatures also reveal many novel regeneration-specific enhancers, which are experimentally validated. Regulatory networks important for regeneration are constructed through integrative analysis of the epigenome map, and a knockout of a predicted upstream regulator disrupts normal regeneration, validating our prediction. Conclusion: Our study shows that lineage-specific DNA methylation signatures are stably maintained during regeneration, and regeneration enhancers are preset as hypomethylated before injury. In contrast, chromatin accessibility is dynamically changed during regeneration. Many enhancers driving regeneration gene expression as well as upstream regulators of regeneration are identified and validated through integrative epigenome analysis.

Project description:Background: Zebrafish can faithfully regenerate injured fins through the formation of a blastema, a mass of proliferative cells that can grow and develop into the lost body part. After amputation, various cell types contribute to blastema formation, where each cell type retains fate restriction and exclusively contributes to regeneration of its own lineage. Epigenetic changes that are associated with lineage restriction during regeneration remain underexplored. Results: We produce epigenome maps, including DNA methylation and chromatin accessibility, as well as transcriptomes, of osteoblasts and other cells in uninjured and regenerating fins. This effort reveals regeneration as a process of highly dynamic and orchestrated transcriptomic and chromatin accessibility changes, coupled with stably maintained lineage-specific DNA methylation. The epigenetic signatures also reveal many novel regeneration-specific enhancers, which are experimentally validated. Regulatory networks important for regeneration are constructed through integrative analysis of the epigenome map, and a knockout of a predicted upstream regulator disrupts normal regeneration, validating our prediction. Conclusion: Our study shows that lineage-specific DNA methylation signatures are stably maintained during regeneration, and regeneration enhancers are preset as hypomethylated before injury. In contrast, chromatin accessibility is dynamically changed during regeneration. Many enhancers driving regeneration gene expression as well as upstream regulators of regeneration are identified and validated through integrative epigenome analysis.

Project description:Background: Zebrafish can faithfully regenerate injured fins through the formation of a blastema, a mass of proliferative cells that can grow and develop into the lost body part. After amputation, various cell types contribute to blastema formation, where each cell type retains fate restriction and exclusively contributes to regeneration of its own lineage. Epigenetic changes that are associated with lineage restriction during regeneration remain underexplored. Results: We produce epigenome maps, including DNA methylation and chromatin accessibility, as well as transcriptomes, of osteoblasts and other cells in uninjured and regenerating fins. This effort reveals regeneration as a process of highly dynamic and orchestrated transcriptomic and chromatin accessibility changes, coupled with stably maintained lineage-specific DNA methylation. The epigenetic signatures also reveal many novel regeneration-specific enhancers, which are experimentally validated. Regulatory networks important for regeneration are constructed through integrative analysis of the epigenome map, and a knockout of a predicted upstream regulator disrupts normal regeneration, validating our prediction. Conclusion: Our study shows that lineage-specific DNA methylation signatures are stably maintained during regeneration, and regeneration enhancers are preset as hypomethylated before injury. In contrast, chromatin accessibility is dynamically changed during regeneration. Many enhancers driving regeneration gene expression as well as upstream regulators of regeneration are identified and validated through integrative epigenome analysis.

Project description:The salamander limb regenerates only the missing portion. Each limb segment can only form segments equivalent to- or more distal to their own identity, relying on a property termed “positional information”. How positional information is encoded in limb cells has been unknown. By cell-type-specific chromatin profiling of upper arm, lower arm, and hand, we found segment-specific levels of histone H3K27me3 at limb homeoprotein gene loci but not their upstream regulators, constituting an intrinsic segment information code. During regeneration, regeneration-specific regulatory elements became active prior to the re-appearance of developmental regulatory elements. This means that, in the hand segment, the permissive chromatin state of the hand homeoprotein gene HoxA13 engages with regeneration regulatory elements, bypassing the upper limb program. We performed Differential Gene expression analysis using data obtained from RNA-seq of two mature limb segments (mature arm vs hand). Therefore, we performed libraries from the mature arm and 5, 9, 13 dpa regenerating arm blastema.

Project description:Joint pain, either traumatic or degenerative, is a common cause of morbidity. Triamcinolone acetonide (TA), a common glucocorticoid, has been used as symptomatic treatment for joint pain for decades. However, besides its relatively short-lived therapeutic effects, TA may have potentially devastating effects by altering the normal healing process to restore and maintain the cellular entities that contribute to tissue regeneration of the synovial joint. Mesenchymal stem cells (MSCs) have been shown to hold great potential in tissue regeneration due to their multipotency in regenerating osteoblasts, chondrocytes and adipocytes and their immunomodulatory properties. So far, it remains largely unclear how TA treatment affects MSC activities.

Project description:Malnutrition is a frequent symptom of various malignant diseases and is frequently observed in patients with gastrointestinal tumors. Eicosapentanoic acid (EPA) has been introduced as specific and anticatabolic acting substrate in cancer patients. Only few randomized trials are available which investigated the effect of EPA in form of an EPA-enriched, protein- and energy-dense oral nutritional supplement mostly in patients with pancreatic carcinoma. Therefore, the effect of an EPA-rich oral nutritional supplement for two months on functional state and quality of life in patients with other gastroenterological tumors and weight loss is investigated in this randomized prospective trial.

Project description:Mitochondria are pivotal for cellular metabolism, serving as sources and targets of nutrient intermediates from converging metabolic pathways. Here, we demonstrate that insulin resistance leads to a marked alteration in the mitochondrial proteome of adipocytes. Analysis across multiple insulin resistance models revealed a consistent decrease in the level of the mitochondrial processing peptidase miPEP, suggesting a potential role for miPEP in the aetiology of insulin resistance. Adipocyte specific miPEP knockout mice demonstrated a strong phenotype marked by a browning-independent increment in energy expenditure, enhanced insulin sensitivity, and reduced adiposity, despite normal food intake and physical activity. These phenotypes vanished when mice were housed at thermoneutrality suggesting that miPEP deletion triggers a compensatory enhancement in thermogenesis protecting against metabolic dysfunction. Tissue specific analysis of miPEP deficient mice revealed a selective increment in muscle metabolism evidenced by increased basal and insulin induced glucose uptake and upregulation of the protein Fbp2, involved in energy wasting via futile cycling. These findings suggest that miPEP deletion initiates a compensatory increase in thermogenesis, acting as a protective mechanism against diet-induced insulin resistance.

Project description:B-RAF activation in mature corticospinal neurons upregulated a discrete set of transcription factors overlapping with a set induced early in axotomized zebrafish retina ganglion cells which can fully regenerate their axons. Conditional genetic activation of B-RAF promoted robust regeneration and sprouting of corticospinal tract axons after experimental spinal cord injury. Newly sprouting axon collaterals formed synaptic connections, correlating with recovery of skilled motor function. We also found that non-invasive suprathreshold high-frequency repetitive transcranial magnetic stimulation activates the RAF effector MEK and promotes regeneration and sprouting of corticospinal tract axons, dependent on MEK signaling. Our findings demonstrate a central role of neuron-intrinsic RAF–MEK signaling in enhancing the growth capacity of mature corticospinal neurons and propose transcranial magnetic stimulation as a potential therapy for spinal cord injury.

Project description:Peripheral nerve regeneration after injury is a complex process involving a large number of transcriptional changes. How these changes impact the regenerative outcome is though, poorly understood. Here, we take advantage of the genetically based differences in the peripheral and central regenerative capacity of CAST/Ei and C57BL/6j inbred mice to better understand the molecular bases driving superior regeneration in the CAST/Ei mouse strain. Single cell RNA sequencing highlighted the existence of three populations of cells, one of which expressed genes enriched for mature neuronal function, another one had a gene expression profile enriched for an immature dedifferentiated state while the third one showed an intermediate profile between these two extremes. The immature expression state was observed after injury in both strains but a larger proportion of the CAST/Ei neurons retained an expression pattern consistent with neuronal identity whereas a larger proportion of C57BL/6 neurons acquired an immature gene expression state accompanied by expression of stress markers. This finding suggests that unexpectedly, maintenance of a mature differentiated state in injured neurons increased regenerative success.