Project description:It is well-known that embryonic stem cells (ESC) are much more sensitive to replication-induced stress than differentiated cells but the underpinning mechanisms are largely unknown. H2A.X, a minor variant of H2A, constitutes only 1-10% of the mammalian genome. H2A.X plays a well-known for role in the DNA damage response and maintaining stability in the genome, including the regions frequently experiencing replication stress, such as the fragile sites. Intriguingly, several recent studies have reported that H2A.X function is elevated in ESC; and others reported that H2A.X function is provoked during cellular reprogramming (in induced pluripotent stem cells, iPSC), indicating that increased proliferation during iPS may trigger replication stress and the H2A.X DNA damage response. However, several studies of genomic instability in iPSC led to different conclusions on this important issue. For example, frequent copy number variants (CNV) were reported at the genomic regions sensitive to replication stress, such as the fragile sites. On the other hand, another study reported the lack of genomic instability in mouse iPS clones that are able to generate “all-iPS” animals in tetraploid complementation assays (4N+ iPSC), indicative of a potential link between pluripotency and genome integrity. However, whether if high level genomic instability occurs in the 4N- iPSC iPSC clones at replication stress sensitive regions is unknown. Moreover, due to the lack of mechanistic insights on genome integrity maintenance, how pluripotency and genome integrity are connected remains elusive. Here we show that H2A.X plays unexpected roles in maintaining pluripotency and genome integrity in ESC and iPSC. In ESC, it is specially enriched at genomic regions sensitive to replication stress so that it protects genome integrity thereat. Faithful H2A.X deposition is critical for genome integrity and pluripotency in iPSC. H2A.X depositions in 4N+ iPSC clones faithfully recapitulate the ESC pattern and therefore, prevent genome instability. On the other hand, insufficient H2A.X depositions in 4N- iPSC clones at such regions lead to genome instability and defects in replication stress response and DNA repair, reminiscent of the H2A.X deficient ESC. Detect and compare different H2A.X deposition patterns in ES cells and iPS cells, with Illumina HiSeq 2000 and Illumina Genome Analyzer IIx

Project description:Induced pluripotent stem cells (iPSCs) are commonly generated by transduction of Oct4, Sox2, Klf4 and Myc (OSKM) into somatic cells. Though iPSCs are pluripotent, they frequently exhibit high variation in their quality as measured by chimera contribution and tetraploid (4n) complementation. Thus, improving the quality of iPSCs is an indispensable prerequisite for future iPSC-based therapy. Here we show that one major determinant for iPSCs quality is the selection of the reprogramming factors combination. Ectopic expression of Sall4, Nanog, Esrrb and Lin28 (SNEL) in MEFs efficiently generated high quality iPSCs as compared to other combinations of factors. SNEL-iPSCs produced approximately 5 times more efficiently “all-iPSC” mice compared to OSKM-iPSCs. While differentially methylated regions, transcript number of master regulators, establishment of ESC-specific super enhancers, and global aneuploidy were comparable between the lines, aberrant expression of 1,765 genes, trisomy of chromosome 8 and abnormal H2A.X deposition were frequently observed in poor quality OSKM-iPSCs. For high-quality iPSCs, H2A.X pattern of SNEL is most similar to that of ESC, OSK and OSKM have more devoid regions than SNEL iPSCs. Compare H2A.X deposition pattern of the OSKM 4-factor iPS cell lines (4N-), SNEL 4-factor iPS cell lines (4N+) with ChIP-Seq. The same background ES cell line as the control line.

Project description:Here we demonstrate the generation of stable induced trophoblast stem cells (iTSCs) from fibroblasts by the transient expression of Gata3, Eomes and Tfap2c. Transcriptome and methylome analyses and functional assays such as hemorrhagic lesion formation and placenta contribution suggested a high degree of conversion. Careful examination of the reprogramming process indicated that the cells did not go through a transient pluripotent state. Detect and compare different H2A.X deposition patterns in ES cells,MEFs and iTSC and TS cells, with Illumina HiSeq 2000

Project description:With the advent of the induced pluripotent stem cell (iPSC) technology, how to distinguish the developmental potentials of the iPSC clones with molecular approaches becomes an imperative issue. Herein, we demonstrated that histone variant H2A.X plays an unexpected role in distinguishing the developmental potentials of iPSC. We showed that H2A.X is specifically targeted to and negatively regulates extra-embryonic lineage gene expression in embryonic stem cell (ESCs) and therefore, it prevents trophectoderm (TE) lineage differentiation under inductive conditions. ESC-specific H2A.X deposition and functions are faithfully recapitulated in the iPSC lines that support the development of “all-iPS” animals. In iPSC lines that fail to support embryonic development, aberrant H2A.X depositions result in upregulation of extra-embryonic lineage genes and predisposition to extra-embryonic tissue differentiation. In summary, our work has revealed novel epigenetic mechanisms for maintaining cell lineage commitment, which can be used to distinguish the quality of the iPSC lines.

Project description:Herein, we demonstrated that the cell lineage commitment is unexpectedly regulated by the novel functions of H2A.X, a histone variant which was only well-known for its role in genome integrity maintenance previously. Surprisingly, only in ESCs but not differentiated cells, H2A.X is specifically targeted to genomic regions encoding early embryonic and extra-embryonic lineage genes to repress their expression. In addition, H2A.X is also enriched at genomic regions sensitive to replication stress and maintains genomic stability thereat. Most interestingly, faithful H2A.X deposition plays critical roles in maintaining both cell lineage commitment and genome integrity in iPSC. In iPSC lines which support the development of "all-iPS" animals, H2A.X deposition faithfully recapitulates the ESC pattern and therefore, the genome stability and cell lineage commitment are maintained. In iPSC lines that fail to support embryonic development, defective H2A.X depositions result in aberrant upregulation of early embryonic and extra-embryonic lineage genes and H2A.X-dependent genome instability. mRNA-Seq of WT ESC and H2A.X KO ESC; and 4N+, 4N- iPSC.

Project description:Herein, we demonstrated that the cell lineage commitment is unexpectedly regulated by the novel functions of H2A.X, a histone variant which was only well-known for its role in genome integrity maintenance previously. Surprisingly, only in ESCs but not differentiated cells, H2A.X is specifically targeted to genomic regions encoding early embryonic and extra-embryonic lineage genes to repress their expression. In addition, H2A.X is also enriched at genomic regions sensitive to replication stress and maintains genomic stability thereat. Most interestingly, faithful H2A.X deposition plays critical roles in maintaining both cell lineage commitment and genome integrity in iPSC. In iPSC lines which support the development of "all-iPS" animals, H2A.X deposition faithfully recapitulates the ESC pattern and therefore, the genome stability and cell lineage commitment are maintained. In iPSC lines that fail to support embryonic development, defective H2A.X depositions result in aberrant upregulation of early embryonic and extra-embryonic lineage genes and H2A.X-dependent genome instability.

Project description:The epithelial-mesenchymal transition (EMT), considered essential for metastatic cancer, has been a focus of much research, but important questions remain. Here, we show that silencing or removing H2A.X, a histone H2A variant involved in cellular DNA repair and robust growth, induced mesenchymal-like characteristics including activation of EMT transcription factors, Slug and ZEB1, in HCT116 human colon cancer cells. Ectopic H2A.X re-expression partially reversed these changes; as did silencing Slug and ZEB1. In an experimental metastasis model, the HCT116 parental and H2A.X-null cells exhibited similar metastases levels, but the cells with re-expressed H2A.X exhibited substantially elevated levels. We surmise that H2A.X re-expression led to partial EMT reversal and increased robustness in the HCT116 cells, permitting them to both form tumors and to metastasize. In a human adenocarcinoma panel, H2A.X levels correlated inversely with Slug and ZEB1 levels. Together, these results point to H2A.X as a novel regulator of EMT. 9 samples in total including 4 replicates of control shRNA and 5 replicates of shH2A.X.

Project description:It is well-known that embryonic stem cells (ESC) are much more sensitive to replication-induced stress than differentiated cells but the underpinning mechanisms are largely unknown. H2A.X, a minor variant of H2A, constitutes only 1-10% of the mammalian genome. H2A.X plays a well-known for role in the DNA damage response and maintaining stability in the genome, including the regions frequently experiencing replication stress, such as the fragile sites. Intriguingly, several recent studies have reported that H2A.X function is elevated in ESC; and others reported that H2A.X function is provoked during cellular reprogramming (in induced pluripotent stem cells, iPSC), indicating that increased proliferation during iPS may trigger replication stress and the H2A.X DNA damage response. However, several studies of genomic instability in iPSC led to different conclusions on this important issue. For example, frequent copy number variants (CNV) were reported at the genomic regions sensitive to replication stress, such as the fragile sites. On the other hand, another study reported the lack of genomic instability in mouse iPS clones that are able to generate “all-iPS” animals in tetraploid complementation assays (4N+ iPSC), indicative of a potential link between pluripotency and genome integrity. However, whether if high level genomic instability occurs in the 4N- iPSC iPSC clones at replication stress sensitive regions is unknown. Moreover, due to the lack of mechanistic insights on genome integrity maintenance, how pluripotency and genome integrity are connected remains elusive. Here we show that H2A.X plays unexpected roles in maintaining pluripotency and genome integrity in ESC and iPSC. In ESC, it is specially enriched at genomic regions sensitive to replication stress so that it protects genome integrity thereat. Faithful H2A.X deposition is critical for genome integrity and pluripotency in iPSC. H2A.X depositions in 4N+ iPSC clones faithfully recapitulate the ESC pattern and therefore, prevent genome instability. On the other hand, insufficient H2A.X depositions in 4N- iPSC clones at such regions lead to genome instability and defects in replication stress response and DNA repair, reminiscent of the H2A.X deficient ESC. In this study, male 129sv/C57 ES cell genomic DNA was used as reference control, to identify CNV sites in iPS cell lines. And also detect H2A.X (-/-) ES cell (129/Sv) CNVs, with the H2A.X(f/f) ES cell DNA (129/Sv) as control. DNA samples were compared on NimbleGen Mouse CGH 3x720K Whole-Genome Tiling Array (Build MM9).

Project description:It is well-known that embryonic stem cells (ESC) are much more sensitive to replication-induced stress than differentiated cells but the underpinning mechanisms are largely unknown. H2A.X, a minor variant of H2A, constitutes only 1-10% of the mammalian genome. H2A.X plays a well-known for role in the DNA damage response and maintaining stability in the genome, including the regions frequently experiencing replication stress, such as the fragile sites. Intriguingly, several recent studies have reported that H2A.X function is elevated in ESC; and others reported that H2A.X function is provoked during cellular reprogramming (in induced pluripotent stem cells, iPSC), indicating that increased proliferation during iPS may trigger replication stress and the H2A.X DNA damage response. However, several studies of genomic instability in iPSC led to different conclusions on this important issue. For example, frequent copy number variants (CNV) were reported at the genomic regions sensitive to replication stress, such as the fragile sites. On the other hand, another study reported the lack of genomic instability in mouse iPS clones that are able to generate “all-iPS” animals in tetraploid complementation assays (4N+ iPSC), indicative of a potential link between pluripotency and genome integrity. However, whether if high level genomic instability occurs in the 4N- iPSC iPSC clones at replication stress sensitive regions is unknown. Moreover, due to the lack of mechanistic insights on genome integrity maintenance, how pluripotency and genome integrity are connected remains elusive. Here we show that H2A.X plays unexpected roles in maintaining pluripotency and genome integrity in ESC and iPSC. In ESC, it is specially enriched at genomic regions sensitive to replication stress so that it protects genome integrity thereat. Faithful H2A.X deposition is critical for genome integrity and pluripotency in iPSC. H2A.X depositions in 4N+ iPSC clones faithfully recapitulate the ESC pattern and therefore, prevent genome instability. On the other hand, insufficient H2A.X depositions in 4N- iPSC clones at such regions lead to genome instability and defects in replication stress response and DNA repair, reminiscent of the H2A.X deficient ESC.

Project description:It is well-known that embryonic stem cells (ESC) are much more sensitive to replication-induced stress than differentiated cells but the underpinning mechanisms are largely unknown. H2A.X, a minor variant of H2A, constitutes only 1-10% of the mammalian genome. H2A.X plays a well-known for role in the DNA damage response and maintaining stability in the genome, including the regions frequently experiencing replication stress, such as the fragile sites. Intriguingly, several recent studies have reported that H2A.X function is elevated in ESC; and others reported that H2A.X function is provoked during cellular reprogramming (in induced pluripotent stem cells, iPSC), indicating that increased proliferation during iPS may trigger replication stress and the H2A.X DNA damage response. However, several studies of genomic instability in iPSC led to different conclusions on this important issue. For example, frequent copy number variants (CNV) were reported at the genomic regions sensitive to replication stress, such as the fragile sites. On the other hand, another study reported the lack of genomic instability in mouse iPS clones that are able to generate “all-iPS” animals in tetraploid complementation assays (4N+ iPSC), indicative of a potential link between pluripotency and genome integrity. However, whether if high level genomic instability occurs in the 4N- iPSC iPSC clones at replication stress sensitive regions is unknown. Moreover, due to the lack of mechanistic insights on genome integrity maintenance, how pluripotency and genome integrity are connected remains elusive. Here we show that H2A.X plays unexpected roles in maintaining pluripotency and genome integrity in ESC and iPSC. In ESC, it is specially enriched at genomic regions sensitive to replication stress so that it protects genome integrity thereat. Faithful H2A.X deposition is critical for genome integrity and pluripotency in iPSC. H2A.X depositions in 4N+ iPSC clones faithfully recapitulate the ESC pattern and therefore, prevent genome instability. On the other hand, insufficient H2A.X depositions in 4N- iPSC clones at such regions lead to genome instability and defects in replication stress response and DNA repair, reminiscent of the H2A.X deficient ESC.