Project description:The abundancy of intracellular amino acid (AA) levels is precisely sensed by complex machineries to regulate various signaling pathways and control cell functions. Insufficient intracellular AAs may block the release of tRNA molecules from the general control non-derepressible 2 (GCN2), and consequently activate GCN2-ATF4 pathways, which is an indirect mechanism for sensing general AAs levels. Additionally, the intracellular levels of some AAs can be sensed by direct binding to specific sensors. Nowadays, the sensors of arginine and leucine levels are most well-characterized, including CASTor1/2, SLC38A9, Sestrin2 and SAR1B, which regulate the mechanistic target of rapamycin complex 1 (mTORC1) pathway, and couple AA availability to cell growth and metabolism. However, it is still unclear whether and how other types of amino acids are directly sensed to regulate cellular functions except tRNA synthetases. Moreover, epigenetics is known to be regulated by the metabolism of amino acids, but it is incompletely understood how AA abundancy regulates the epigenetics, especially DNA methylation. The long-sought sensor of amino acids for epigenetic regulation has thus far been unknown. Here, we present evidence that valine sensor regulated DNA demethylation.

Project description:The structure of broken DNA ends is a critical determinant of the pathway used for DNA double strand break (DSB) repair. Here, we develop an approach, hairpin capture of DNA end structures (HCoDES), which elucidates chromosomal DNA end structures at single nucleotide resolution. HCoDES defines structures of physiologic DSBs generated by the RAG endonuclease, as well as those generated by nucleases widely used for genome editing. Analysis of G1-phase cells deficient in H2AX or 53BP1 reveals DNA ends that are frequently resected to form long single-stranded overhangs that can be repaired by mutagenic pathways. In addition to 3’ overhangs, many of these DNA ends unexpectedly form long 5’ single-stranded overhangs. The divergence in DNA end structures resolved by HCoDES suggests that H2AX and 53BP1 may have distinct activities in end protection. Thus, the high-resolution end structures obtained by HCoDES identify new features of DNA end processing during DSB repair. Single stranded DNA ligation of genomic DNA isolated from G1 arrested LigaseIV-/-, LigaseIV-/- 53BP1-/- and LigaseIV-/- H2AX-/- Abelson pre-B cells harboring site specific DSBs generated by the RAG recombinase, Cas9 endonuclease or Zinc Finger Endonuclease.

Project description:The structure of broken DNA ends is a critical determinant of the pathway used for DNA double-strand break (DSB) repair. Here, we develop an approach involving the hairpin capture of DNA end structures (HCoDES), which elucidates chromosomal DNA end structures at single-nucleotide resolution. HCoDES defines structures of physiologic DSBs generated by the RAG endonuclease, as well as those generated by nucleases widely used for genome editing. Analysis of G1 phase cells deficient in H2AX or 53BP1 reveals DNA ends that are frequently resected to form long single-stranded overhangs that can be repaired by mutagenic pathways. In addition to 3' overhangs, many of these DNA ends unexpectedly form long 5' single-stranded overhangs. The divergence in DNA end structures resolved by HCoDES suggests that H2AX and 53BP1 may have distinct activities in end protection. Thus, the high-resolution end structures obtained by HCoDES identify features of DNA end processing during DSB repair.

Project description:The structure of broken DNA ends is a critical determinant of the pathway used for DNA double strand break (DSB) repair. Here, we develop an approach, hairpin capture of DNA end structures (HCoDES), which elucidates chromosomal DNA end structures at single nucleotide resolution. HCoDES defines structures of physiologic DSBs generated by the RAG endonuclease, as well as those generated by nucleases widely used for genome editing. Analysis of G1-phase cells deficient in H2AX or 53BP1 reveals DNA ends that are frequently resected to form long single-stranded overhangs that can be repaired by mutagenic pathways. In addition to 3’ overhangs, many of these DNA ends unexpectedly form long 5’ single-stranded overhangs. The divergence in DNA end structures resolved by HCoDES suggests that H2AX and 53BP1 may have distinct activities in end protection. Thus, the high-resolution end structures obtained by HCoDES identify new features of DNA end processing during DSB repair.

Project description:The abundancy of intracellular amino acid (AA) levels is precisely sensed by complex machineries to regulate various signaling pathways and control cell functions. Insufficient intracellular AAs may block the release of tRNA molecules from the general control non-derepressible 2 (GCN2), and consequently activate GCN2-ATF4 pathways, which is an indirect mechanism for sensing general AAs levels. Additionally, the intracellular levels of some AAs can be sensed by direct binding to specific sensors. Nowadays, the sensors of arginine and leucine levels are most well-characterized, including CASTor1/2, SLC38A9, Sestrin2 and SAR1B, which regulate the mechanistic target of rapamycin complex 1 (mTORC1) pathway, and couple AA availability to cell growth and metabolism. However, it is still unclear whether and how other types of amino acids are directly sensed to regulate cellular functions except tRNA synthetases. Moreover, epigenetics is known to be regulated by the metabolism of amino acids, but it is incompletely understood how AA abundancy regulates the epigenetics, especially DNA methylation. The long-sought sensor of amino acids for epigenetic regulation has thus far been unknown. Here, we present evidence that valine sensor regulated DNA demethylation.

Project description:Numerous indirect, genetic approaches in various experimental systems have implicated dynamic alternative non-B DNA structures in human physiology and disease. Nevertheless, direct detection of dynamic DNA structures in vivo remains a challenge. To address this problem, we developed a new methods to visualize ssDNA containing alternative DNA structures. We described an uncharted landscape of dynamic alternative DNA structures formed by DNA cruciform and DNA triplexes (H-DNA) that contribute to genome instability.

Project description:DNA in cells is predominantly B-form double helix. Though certain DNA sequences in vitro may fold into other structures, such as triplex, left-handed Z form, or quadruplex DNA, the stability and prevalence of these structures in vivo are not known. Here, using computational analysis of sequence motifs, RNA polymerase II binding data, and genome-wide potassium permanganate-dependent nuclease footprinting data, we map thousands of putative non-B DNA sites at high resolution in mouse B cells. Computational analysis associates these non-B DNAs with particular structures and indicates that they form at locations compatible with an involvement in gene regulation. Further analyses support the notion that non-B DNA structure formation influences the occupancy and positioning of nucleosomes in chromatin. These results suggest that non-B DNAs contribute to the control of a variety of critical cellular and organismal processes.

Project description:DNA N6-methyladenine (N6-mA) is an emerging epigenetic mark in the mammalian genome. Levels of N6-mA undergo drastic fluctuation during early embryogenesis, indicative of active regulation. Here we demonstrate that the 2-oxoglurarate oxygenase ALKBH1 functions as a nuclear eraser of N6-mA in unpairing regions (e.g. SIDD, Stress Induced DNA Double Helix Destabilization regions). Enzymatic profiling studies revealed that ALKBH1 displays demethylation activity towards N6-mA on DNA substrates that share a common unpairing feature, e.g. bubbled, bulged or single-stranded DNA oligos. Furthermore, ssDNA-seq and DIP-seq analyses revealed significant genome-wide co-occurrence of base unpairing regions with N6-mA in mouse embryonic stem cells, especially during cell fate transition. Collectively, our biochemical, structural and genomic studies demonstrate that ALKBH1 is an important DNA demethylase that regulates genome N6-mA turnover in unpairing regions associated with dynamic chromatin regulation in early development. This series contains data from ssDNA-seq experiments on mouse ES cells. We used the S1 nuclease and biotin end-labeling to enrich for DNA at ssDNA regions followed by HiSeq4000 sequencing and data analysis.

Project description:Valine-restricted diet regulates DNA methylation [END-Seq, ddC S1-END-Seq]

Project description:The 5' and 3' termini of RNA play important roles in many cellular processes. Using Förster resonance energy transfer (FRET), we show that mRNAs and lncRNAs have an intrinsic propensity to fold in the absence of proteins into structures in which the 5' end and 3' end are ≤7 nm apart irrespective of mRNA length. Computational estimates suggest that the inherent proximity of the ends is a universal property of most mRNA and lncRNA sequences. Only guanosine-depleted RNA sequences with low sequence complexity are unstructured and exhibit end-to-end distances expected for the random coil conformation of RNA. While the biological implications remain to be explored, short end-to-end distances could facilitate the binding of protein factors that regulate translation initiation by bridging mRNA 5' and 3' ends. Furthermore, our studies provide the basis for measuring, computing and manipulating end-to-end distances and secondary structure in RNA in research and biotechnology.