Three-dimensional Folding of Eukaryotic Genomes

Hsieh, Tsung-Han S.

15 May 2017

Chromatin packages eukaryotic genomes via a hierarchical series of folding steps, encrypting multiple layers of epigenetic information, which are capable of regulating nuclear transactions in response to complex signals in environment. Besides the 1-dimensinal chromatin landscape such as nucleosome positioning and histone modifications, little is known about the secondary chromatin structures and their functional consequences related to transcriptional regulation and DNA replication. The family of chromosomal conformation capture (3C) assays has revolutionized our understanding of large-scale chromosome folding with the ability to measure relative interaction probability between genomic loci in vivo. However, the suboptimal resolution of the typical 3C techniques leaves the levels of nucleosome interactions or 30 nm structures inaccessible, and also restricts their applicability to study gene level of chromatin folding in small genome organisms such as yeasts, worm, and plants. To uncover the “blind spot” of chromatin organization, I developed an innovative method called Micro-C and an improved protocol, Micro-C XL, which enable to map chromatin structures at all range of scale from single nucleosome to the entire genome. Several fine-scale aspects of chromatin folding in budding and fission yeasts have been identified by Micro-C, including histone tail-mediated tri-/tetra-nucleosome stackings, gene crumples/globules, and chromosomally-interacting domains (CIDs). CIDs are spatially demarcated by the boundaries, which are colocalized with the promoters of actively transcribed genes and histone marks for active transcription or turnover. The levels of chromatin compaction are regulated via transcription-dependent or transcription-independent manner – either the perturbations of transcription or the mutations of chromatin regulators strongly affect the global chromatin folding. Taken together, Micro-C further reveals chromatin folding behaviors below the sub-kilobase scale and opens an avenue to study chromatin organization in many biological systems.

Chromatin

Nucleosome

3D genome

Histone modifications

Biotechnology

Genetics

Genomics

Molecular Biology

The TALE Factors and Nuclear Factor Y Cooperate to Drive Transcription at Zygotic Genome Activation

Stanney, William J., III

06 August 2019

The TALE factors, comprising the pbx and prep/meis gene families, are transcription factors (TFs) vital to the proper formation of anterior anatomical structures during embryonic development. Although best understood as essential cofactors for tissue-specific TFs such as the hox genes during segmentation, the TALE factors also form complexes with nuclear factor Y (NFY) in the early zygote. In zebrafish, Pbx4, Prep1, and NFY are maternally deposited and can access their DNA binding sites in compact chromatin. Our results suggest that TALE/NFY complexes have a unique role in early embryonic development which is distinct from each factor’s independent functions at later stages. To characterize these TALE/NFY complexes, we employed high-throughput transcriptomic and genomic techniques in zebrafish embryos. Using dominant negatives to disrupt the function of each factor, we find that they display similar, but not identical, loss-of-function phenotypes and co-regulate genes involved in transcription regulation and embryonic development. Independently, the TALE factors regulate homeobox genes and NFY governs cilia-related genes. ChIP-seq analysis at zygotic genome activation reveals that the TALE factors occupy DECA sites adjacent to CCAAT boxes near genes expressed early in development and involved with transcription regulation. Finally, DNA elements containing TALE and NFY binding sites drive reporter gene expression in transgenic zebrafish, and disruption of TALE/NFY binding via mutation or dominant negatives eliminates this expression. Taken together, this data suggests that the TALE factors and NFY cooperate to regulate a set of development and transcription control genes in early zygotic development but also have independent roles after gastrulation.

transcription

embryogenesis

maternal

zygotic

enhancer

nucleosome

pioneer factor

epigenetics

TALE

NFY

Biochemistry

Developmental Biology

Molecular Biology

p53 search and recognition dynamics on DNA studied by multi-scale simulations / p53のDNA探索と認識過程のマルチスケールシミュレーションによる研究

Terakawa, Tsuyoshi

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18117号 / 理博第3995号 / 新制||理||1576(附属図書館) / 30975 / 京都大学大学院理学研究科生物科学専攻 / (主査)教授 高田 彰二, 教授 大野 睦人, 准教授 土井 知子 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

transcription factor

p53

DNA

nucleosome

400

STRUCTURAL AND FUNCTIONAL ANALYSIS OF THE ISW2 CHROMATIN REMODELING COMPLEX

Hota, Swetansu Kumar

01 December 2011

Chromatin remodelers utilize the energy derived from ATP hydrolysis to mobilize nucleosomes. ISWI remodelers mobilize and evenly space nucleosomes to regulate gene expression. ISW2, an ISWI remodeler in yeast, has been shown to reposition nucleosome near promoter regions and represses both mRNA and antisense non coding RNA transcription. ISW2 is composed of four subunits and the catalytic Isw2 subunit consists of several conserved domains. The highly conserved ATPase domain is present at the N-terminus whereas the conserved HAND, SANT and SLIDE domain are towards the carboxyl terminal end of Isw2. Nucleosome mobilization by ISW2 requires both extranucleosomal DNA and the N-terminal tail of histone H4. DNA crosslinking and peptide mapping revealed that the ATPase domain contacts nucleosome two helical turns away (SHL2) from dyad to a site close to the H4 tail, whereas the HAND, SANT and SLIDE domain contact a 30bp stretch of DNA comprising the edge of nucleosome and ~20bp of extranucleosomal DNA. The ATPase domain and the C-terminal domains were investigated for their role in regulation of ISW2 activity both in-vitro and in-vivo. It appears that there are distinct modes of ISW2 regulation by these domains. Mutation of a patch of five acidic amino acids on the region of ATPase domain that contact SHL2 was found to be crucial for both ISW2 remodeling and nucleosome stimulated ATPase activity. Acidic patch mutant ISW2 was unable to mobilize nucleosome or hydrolyze ATP in absence of H4 tail. This indicates that the region of ATPase domain contacting nucleosome at SHL2 and H4 tail act in two separate and independent pathways to regulate ISW2 remodeling. Both HAND and SLIDE domain were shown to crosslink entry/exit site and linker DNA respectively. The roles of C-terminal domains were investigated either by deletion of the individual domain or mutation of conserved basic residues on the surface of these domains that are suspected to interact extranucleosomal with DNA. Deletion of HAND domain had minimal effect on in vitro ISW2 activity, however whole genome transcription analysis revealed one key role of this domain in ISW2 regulation. In absence of HAND domain, ISW2 had minimal role on repression of genes that were RPD3 (co-factor) dependent, however significantly derepressed genes that were RPD3 independent. At these loci, nucleosome positions were altered and ISW2 recruitment was reduced in absence of a functional HAND domain. Thus the HAND domain regulates recruitment and remodeling of ISW2 at those genes where ISW2 acts independent of other cofactors. The SANT domain, C-terminal to HAND domain, appears to control the "step size" of nucleosome remodeling and was found to be required for processive nucleosome remodeling by ISW2. Both H4 tail and SANT domain appear to control two distinct stages of ISW2 remodeling. A long alpha helical spacer separates SANT domain from SLIDE domain. SLIDE domain was found to be the protein-protein interaction domain that interacts with accessory Itc1 subunit to maintain ISW2 complex integrity. The two ways by which SLIDE domain regulate ISW2 is by binding or recruitment of ISW2 to promoter regions and additionally by binding independent regulation of both ATPase and remodeling activity. The remodeling mechanism of ISW2 was further compared with another ISWI type remodeler in yeast, Isw1a; using time resolved nucleosome remodeling combined with high resolution site specific histone DNA crosslinking at six different nucleosomal positions to track the movement of the nucleosomes. Nucleosome remodeled by the same remodeler showed discontinuous nucleosome movement between two tracking points indicating formation of small "bulges". One key difference in remodeling mechanism was that although both ISW2 and Isw1a moved nucleosomes towards longer linker DNA, only Isw1a remodeled nucleosomes "backtracked" ~11bp during remodeling. Backtracking of remodeling was prominently observed at nucleosomal regions in close proximity to translocase binding sites suggesting the potentially different mechanisms shared by similar remodeling complexes.

ATPase domain

ATP dependent chromatin remodeler

HAND

SANT and SLIDE domain

ISWI

nucleosome

SWI/SNF

Thermodynamic Characterization of Linker Histone Binding Interactions with ds-DNA

Machha, Venkata Ramana

17 May 2014

Linker histones (H1) are the basic proteins in higher eukaryotes that are responsible for the final condensation of chromatin. H1 also plays an important role in regulating gene expression. H1 has been described as a transcriptional repressor as it limits the access of transcriptional factors to DNA. Linker histone binds to DNA that enters or exits the nucleosome. Several crystal structures have been published for the nucleosome (histone core/DNA complex), and the interactions of the core histone proteins with DNA are well understood. In contrast the location of the linker histone and its interactions with ds-DNA are poorly understood. In this study we have used isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC), and CD spectropolarimetry to determine the thermodynamic signatures and structural changes that accompany H1 binding to ds-DNA. The thermodynamic parameters for the binding of intact linker histones (H1.1, H1.4, and H10) to highly polymerized calf-thymus DNA and to short double stranded DNA oligomers have been determined. We have also determined the thermodynamics for binding of H10 C-terminal tail (H10-C) and globular domain (H10-G) to calf-thymus DNA. The real surprise in the energetics is that the enthalpy change for formation of the H1/DNA complex is very unfavorable and that H1/DNA complex formation is driven by very large positive changes in entropy. The binding site sizes for H1.1, H1.4, and H10 were determined to be 36bp, 32bp, and 36bp respectively. CD results indicate that CT-DNA is restructured upon complexation with either the full length H1 protein (H10) or its C-terminal domain (H10-C). In contrast, the structure of H10 is largely unchanged in the DNA complex. Temperature dependence of enthalpy change, osmotic stress and ionic strength dependence of Ka were tested using ITC. These results indicate that the entropy driven H1/DNA complexes are a result primarily from the expulsion of bound water molecules from the binding interface. This study provides new insights into the binding of linker Histone H1 to DNA. A better understanding of the functional properties of H1 and its interactions with DNA could provide new insights in understanding the role H1 in DNA condensation and transcriptional regulation.

Histone

H1.1

H1.4

H10

H10-C

H10-G

CT-DNA

chromatin

chromosome

nucleosome

ITC

CD

DSC

Investigation of FRET System and Fluorine-Containing Nucleic Acids by Artificial Nucleobases / 人工核酸塩基を活用したFRETシステムと含フッ素核酸の研究

Hirashima, Shingo

23 March 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24442号 / 理博第4941号 / 新制||理||1706(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)准教授 板東 俊和, 教授 深井 周也, 教授 秋山 芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Fluorescent nucleic acid

Fluorescent nucleobase

FRET

Nucleosome

Fluorinated nucleobase

2-Fluoroadenine

400

XPRIME-EM: Eliciting Expert Prior Information for Motif Exploration Using the Expectation-Maximization Algorithm

Zhou, Wei

22 June 2012

Understanding the possible mechanisms of gene transcription regulation is a primary challenge for current molecular biologists. Identifying transcription factor binding sites (TFBSs), also called DNA motifs, is an important step in understanding these mechanisms. Furthermore, many human diseases are attributed to mutations in TFBSs, which makes identifying those DNA motifs significant for disease treatment. Uncertainty and variations in specific nucleotides of TFBSs present difficulties for DNA motif searching. In this project, we present an algorithm, XPRIME-EM (Eliciting EXpert PRior Information for Motif Exploration using the Expectation-Maximization Algorithm), which can discover known and de novo (unknown) DNA motifs simultaneously from a collection of DNA sequences using a modified EM algorithm and describe the variation nature of DNA motifs using position specific weight matrix (PWM). XPRIME improves the efficiency of locating and describing motifs by prevent the overlap of multiple motifs, a phenomenon termed a phase shift, and generates stronger motifs by considering the correlations between nucleotides at different positions within each motif. Moreover, a Bayesian formulation of the XPRIME algorithm allows for the elicitation of prior information for motifs of interest from literature and experiments into motif searching. We are the first research team to incorporate human genome-wide nucleosome occupancy information into the PWM based DNA motif searching.

DNA motif

modified EM algorithm

human nucleosome occupancy information

Statistics and Probability

Genome-wide nucleosome map and cytosine methylation levels of an ancient human genome.

Pedersen, J.S., Valen, E., Velazquez, A.M.V., Parker, B.J., Lindgreen, S., Lilje, B., Tobin, Desmond J., Kelly, T.K., Vang, S., Andersson, R., Jones, P.A., Hoover, C.A., Prokhortchouk, E., Rubin, E.M., Sandelin, A., Gilbert, M.T.P., Krogh, A., Willerslev, E.

January 2014

yes / Epigenetic information is available from contemporary organisms, but is difficult to track back in evolutionary time. Here, we show that genome-wide epigenetic information can be gathered directly from next-generation sequence reads of DNA isolated from ancient remains. Using the genome sequence data generated from hair shafts of a 4000-yr-old Paleo- Eskimo belonging to the Saqqaq culture, we generate the first ancient nucleosome map coupled with a genome-wide survey of cytosine methylation levels. The validity of both nucleosome map and methylation levels were confirmed by the recovery of the expected signals at promoter regions, exon/intron boundaries, and CTCF sites. The top-scoring nucleosome calls revealed distinct DNA positioning biases, attesting to nucleotide-level accuracy. The ancient methylation levels exhibited high conservation over time, clustering closely with modern hair tissues. Using ancient methylation information, we estimated the age at death of the Saqqaq individual and illustrate how epigenetic information can be used to infer ancient gene expression. Similar epigenetic signatures were found in other fossil material, such as 110,000- to 130,000-yr-old bones, supporting the contention that ancient epigenomic information can be reconstructed from a deep past. Our findings lay the foundation for extracting epigenomic information from ancient samples, allowing shifts in epialleles to be tracked through evolutionary time, as well as providing an original window into modern epigenomics.

Understanding biological motions with improved resolution and accuracy by NMR

Kharchenko, Vladlena

12 1900

Biological motion constitutes a key and indispensable element of all biomolecules, as dynamics tightly link spatial architecture with function. Several computational and experimental techniques have been developed to study biomolecular dynamics. Nevertheless, few label-free and atomic or sub-atomic resolution techniques are able to capture biological motions at close to native conditions. Indeed, the only label-free technique giving atomic level access to dynamics from picoseconds down to seconds is nuclear magnetic resonance (NMR) spectroscopy. In this dissertation, I identify the imperfections and inaccuracies accompanying the routine and well-accepted methods of probing protein dynamics via 15N spin relaxation NMR measurements. Subsequently, I propose and develop solutions and experimental approaches to overcome the limitations and eliminate artefacts. The routine procedures applying heavy water as an internal locking standard lead to artifacts in every type of relaxation rate of 15N amides due to reaction with exchangeable deuterons. The deviations from correct values are most pronounced for highly dynamic and exposed protein fragments. I introduce a novel set of directly detected 15N spin relaxation experiments yielding an unprecedent resolution resolving the signal overlap, although of lower sensitivity. I propose a more accurate. Finally, I present how the 15N spin relaxation techniques and improved routines can be applied to understand biological processes that cannot be described without monitoring molecular motions. Using the example of human BTB domains, which are directly linked to human cancer, I demonstrate the ability to detect cryptic binding sites on the surfaces of proteins. The cryptic binding site was verified by a comprehensive NMR-monitored fragment-based screening that revealed a hit-rate only for MIZ1BTB, which was the only protein displaying slow segmental motions. I also managed to track subtle and biologically-relevant dynamic modulations of an exposed H3 histone tail affected by H1 histones or other histone variants. Enhancement of H3 tail dynamics led to increased H3K36 methylation, while restriction of motions resulted in the opposite effect. These observed correlations unequivocally support the essential role of molecular mobility in biological functions.

NMR

protein dynamics

fragment-based screening

pulse programming

nucleosome

biological motions

Applications of statistical mechanics to nucleic acids

Forties, Robert A.

13 September 2011

No description available.

Biophysics

DNA bending

nucleosome fluctuations