Project description:We report a reprogrammable mouse system in which reprogramming factor expression in vivo can be controlled temporally by treatment with doxycycline (Dox). Transient expression of reprogramming factors in vivo results in tumor development in various tissues, consisting of undifferentiated dysplastic cells. We analyzed the kidney tumors developed in reprogrammable mice for global gene expressions and DNA methylations.

Project description:We report a reprogrammable mouse system in which reprogramming factor expression in vivo can be controlled temporally by treatment with doxycycline (Dox). Transient expression of reprogramming factors in vivo results in tumor development in various tissues, consisting of undifferentiated dysplastic cells. We analyzed the kidney tumors developed in reprogrammable mice for global gene expressions and DNA methylations.

Project description:Cellular reprogramming of somatic cells towards induced pluripotency is a multistep stochastic process mediated by the transcription factors Oct4, Sox2, Klf4 and c-Myc (OSKM), which orchestrate global epigenetic and transcriptional changes. We performed a large-scale analysis of integrated ChIP-seq, ATAC-seq and RNA-seq data and revealed the spatiotemporal highly dynamic pattern of OSKM DNA binding during reprogramming. We found that OSKM show distinct temporal patterns of binding to different classes of pluripotency-related enhancers. Genes involved in reprogramming are regulated by the coordinated activity of multiple enhancers, which are sequentially bound by OSKM for strict transcriptional control. Based on these findings, we developed an unbiased approach to identify Reprogramming-Inducible Enhancers (RIEs), constructed enhancer-traps and isolated cells undergoing reprogramming in real time. We used a representative RIE taken from the Upp1 gene fused to GFP and isolated cells at different time-points during reprogramming and found that they have unique developmental capacities as they are reprogrammed with high efficiency due to their distinct molecular signatures. In conclusion, our experiments have led to the development of an unbiased method to identify and isolate reprogrammable cells in real time by exploiting the functional dynamics of OSKM, which can be used as efficient reprogramming biomarkers.

Project description:Cellular reprogramming of somatic cells towards induced pluripotency is a multistep stochastic process mediated by the transcription factors Oct4, Sox2, Klf4 and c-Myc (OSKM), which orchestrate global epigenetic and transcriptional changes. We performed a large-scale analysis of integrated ChIP-seq, ATAC-seq and RNA-seq data and revealed the spatiotemporal highly dynamic pattern of OSKM DNA binding during reprogramming. We found that OSKM show distinct temporal patterns of binding to different classes of pluripotency-related enhancers. Genes involved in reprogramming are regulated by the coordinated activity of multiple enhancers, which are sequentially bound by OSKM for strict transcriptional control. Based on these findings, we developed an unbiased approach to identify Reprogramming-Inducible Enhancers (RIEs), constructed enhancer-traps and isolated cells undergoing reprogramming in real time. We used a representative RIE taken from the Upp1 gene fused to GFP and isolated cells at different time-points during reprogramming and found that they have unique developmental capacities as they are reprogrammed with high efficiency due to their distinct molecular signatures. In conclusion, our experiments have led to the development of an unbiased method to identify and isolate reprogrammable cells in real time by exploiting the functional dynamics of OSKM, which can be used as efficient reprogramming biomarkers.

Project description:Cellular reprogramming of somatic cells towards induced pluripotency is a multistep stochastic process mediated by the transcription factors Oct4, Sox2, Klf4 and c-Myc (OSKM), which orchestrate global epigenetic and transcriptional changes. We performed a large-scale analysis of integrated ChIP-seq, ATAC-seq and RNA-seq data and revealed the spatiotemporal highly dynamic pattern of OSKM DNA binding during reprogramming. We found that OSKM show distinct temporal patterns of binding to different classes of pluripotency-related enhancers. Genes involved in reprogramming are regulated by the coordinated activity of multiple enhancers, which are sequentially bound by OSKM for strict transcriptional control. Based on these findings, we developed an unbiased approach to identify Reprogramming-Inducible Enhancers (RIEs), constructed enhancer-traps and isolated cells undergoing reprogramming in real time. We used a representative RIE taken from the Upp1 gene fused to GFP and isolated cells at different time-points during reprogramming and found that they have unique developmental capacities as they are reprogrammed with high efficiency due to their distinct molecular signatures. In conclusion, our experiments have led to the development of an unbiased method to identify and isolate reprogrammable cells in real time by exploiting the functional dynamics of OSKM, which can be used as efficient reprogramming biomarkers.

Project description:We report a reprogrammable mouse system in which reprogramming factor expression in vivo can be controlled temporally by treatment with doxycycline (Dox). Transient expression of reprogramming factors in vivo results in tumor development in various tissues, consisting of undifferentiated dysplastic cells. We analyzed the kidney tumors developed in reprogrammable mice for global gene expressions and DNA methylations. Reprogrammable mice at 4 weeks of age were treated with Dox for 7 days followed by the withdrawal.  Seven days after the withdrawal, kidney tumors were analyzed for gene expressions and DNA methylations with microarray and RRBS method, respectively.  Normal kidney tissue at the same age and ES cells were analyzed as controls.  To examine the early changes of gene expressions, transgene-expressing kidney cells were FACS sorted and they are utilized for microarray analysis.  Primary liver tumors in reprogrammable mice and transplanted secondary kidney tumors in the subcutaneous tissues of immnodeficient mice were also analyzed for gene expressions.

Project description:We report a reprogrammable mouse system in which reprogramming factor expression in vivo can be controlled temporally by treatment with doxycycline (Dox). Transient expression of reprogramming factors in vivo results in tumor development in various tissues, consisting of undifferentiated dysplastic cells. We analyzed the kidney tumors developed in reprogrammable mice for global gene expressions and DNA methylations. Reprogrammable mice at 4 weeks of age were treated with Dox for 7 days followed by the withdrawal. Seven days after the withdrawal, kidney tumors were analyzed for gene expressions and DNA methylations with microarray and RRBS method, respectively. Normal kidney tissue at the same age and ES cells were analyzed as controls. To examine the early changes of gene expressions, transgene-expressing kidney cells were FACS sorted and they are utilized for microarray analysis. Primary liver tumors in reprogrammable mice and transplanted secondary kidney tumors in the subcutaneous tissues of immnodeficient mice were also analyzed for gene expressions.

Project description:Unlike aging somatic cells, which exhibit a decline in molecular fidelity and eventually reach a state of replicative senescence, pluripotent stem cells can indefinitely replenish themselves while retaining full homeostatic capacity. The conferment of beneficial -pluripotency related traits via in vivo partial cellular reprogramming (IVPR) significantly extends lifespan and restores aging phenotypes in mouse models. Although the phases of cellular reprogramming are well characterized, details of the rejuvenation processes are poorly defined. Here we created the first reprogrammable accelerated aging mouse model with a DNA damage repair defect to better understand the effects of reprogramming on a key driver of aging. Using enhanced partial reprogramming by combining small molecules with the Yamanaka factors, we observed potent reversion of DNA damage, significant upregulation of multiple DNA damage repair processes, and restoration of the epigenetic clock is observed. In addition, we present evidence that TGFb inhibition of the ALK5 or ALK2 receptor is able to phenocopy some benefits including epigenetic clock restoration suggesting a role in the mechanism of rejuvenation during partial reprogramming.

Project description:The expression of the pluripotency factors OCT4, SOX2, KLF4 and MYC (OSKM) can transform somatic differentiated cells into pluripotent stem cells in a process known as reprogramming. Transient OSKM expression perturbs cellular homeostasis in a reversible manner and cycles of such incomplete reprogramming rejuvenate features of aging in cells and progeroid mice. However, little is known about the mechanisms involved. Here, we have studied changes in the DNA methylome, transcriptome and metabolome in naturally aged mice subject to a single period of transient OSKM expression in all tissues. We found that this manipulation is sufficient to rejuvenate a substantial fraction of the DNA methylation changes in gene regulatory elements that occur upon aging in the pancreas, liver and spleen. Similarly, we observed rejuvenation at the transcriptomic level, especially regarding biological processes known to change during aging. Finally, a subset of serum metabolites normally altered with aging were restored to young levels upon reprogramming. These observations indicate that a single period of OSKM expression can drive epigenetic, transcriptomic and metabolomic changes towards a younger configuration in multiple tissues and in the serum.

Project description:We have generated “reprogrammable” transgenic mice that ubiquitously express the four Yamanaka factors in an inducible manner. Transitory induction of the transgene results in multiple teratomas emerging from a variety of organs, thus indicating that full reprogramming into iPSCs can occur in vivo. By performing bone marrow transplant experiments, we demonstrate that both hematopoietic cells, as well as non-hematopoietic cells can be reprogrammed in vivo. Remarkably, reprogrammable mice also present circulating iPSCs in the bloodstream (in vivo-iPSCs) with all the expected properties of bona fide iPSCs. Moreover, in contrast to in vitro-iPSCs or embryonic stem cells (ESCs), in vivo-iPSCs have an increased capacity to undergo trophectoderm lineage differentiation, which suggests that in vivo-iPSCs are more plastic or primitive than in vitro-generated iPSCs or ESCs.