Toward an understanding of the relation between gene regulation and 3D genome organization

AbstractThe development and usage of chromosome conformation capture technologies have provided great details on 3D genome organization and provide great opportunities to understand how gene regulation is affected by the 3D chromatin structure. Previously, we identified two types of sequence domains, CGI forest and CGI prairie, which tend to segregate spatially, but to different extent in different tissues/cell states. To further quantify the association of domain segregation with gene regulation and differentiation, we analyzed in this study the distribution of genes of different tissue specificities along the linear genome, and found that the distribution patterns are distinctly different in forests and prairies. The tissue-specific genes (TSGs) are significantly enriched in the latter but not in the former and genes of similar expression profiles among different cell types (co-activation/repression) also tend to cluster in specific prairies. We then analyzed the correlation between gene expression and the spatial contact revealed in Hi-C measurement. Tissue-specific forest-prairie contact formation was found to correlate with the regulation of the TSGs, in particular those in the prairie domains, pointing to the important role gene positioning, in the linear DNA sequence as well as in 3D chromatin structure, plays in gene regulatory network formation.

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HP1 drives de novo 3D genome reorganization in early Drosophila embryos

Nature ◽

10.1038/s41586-021-03460-z ◽

2021 ◽

Author(s):

Fides Zenk ◽

Yinxiu Zhan ◽

Pavel Kos ◽

Eva Löser ◽

Nazerke Atinbayeva ◽

...

Keyword(s):

Genome Organization ◽

Molecular Mechanisms ◽

High Throughput Sequencing ◽

De Novo ◽

Early Embryo ◽

Heterochromatin Protein ◽

Chromosome Conformation ◽

3D Genome ◽

Genome Reorganization

AbstractFundamental features of 3D genome organization are established de novo in the early embryo, including clustering of pericentromeric regions, the folding of chromosome arms and the segregation of chromosomes into active (A-) and inactive (B-) compartments. However, the molecular mechanisms that drive de novo organization remain unknown1,2. Here, by combining chromosome conformation capture (Hi-C), chromatin immunoprecipitation with high-throughput sequencing (ChIP–seq), 3D DNA fluorescence in situ hybridization (3D DNA FISH) and polymer simulations, we show that heterochromatin protein 1a (HP1a) is essential for de novo 3D genome organization during Drosophila early development. The binding of HP1a at pericentromeric heterochromatin is required to establish clustering of pericentromeric regions. Moreover, HP1a binding within chromosome arms is responsible for overall chromosome folding and has an important role in the formation of B-compartment regions. However, depletion of HP1a does not affect the A-compartment, which suggests that a different molecular mechanism segregates active chromosome regions. Our work identifies HP1a as an epigenetic regulator that is involved in establishing the global structure of the genome in the early embryo.

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The Dynamic 3D Genome in Gametogenesis and Early Embryonic Development

Cells ◽

10.3390/cells8080788 ◽

2019 ◽

Vol 8 (8) ◽

pp. 788 ◽

Cited By ~ 3

Author(s):

Li ◽

An ◽

Zhang

Keyword(s):

Developmental Biology ◽

Embryonic Development ◽

Research Methods ◽

Chromatin Structure ◽

Model Systems ◽

Early Embryonic Development ◽

3D Genome ◽

Input Material ◽

3D Chromatin Structure ◽

And Function

During gametogenesis and early embryonic development, the chromatin architecture changes dramatically, and both the transcriptomic and epigenomic landscape are comprehensively reprogrammed. Understanding these processes is the holy grail in developmental biology and a key step towards evolution. The 3D conformation of chromatin plays a central role in the organization and function of nuclei. Recently, the dynamics of chromatin structures have been profiled in many model and non-model systems, from insects to mammals, resulting in an interesting comparison. In this review, we first introduce the research methods of 3D chromatin structure with low-input material suitable for embryonic study. Then, the dynamics of 3D chromatin architectures during gametogenesis and early embryonic development is summarized and compared between species. Finally, we discuss the possible mechanisms for triggering the formation of genome 3D conformation in early development.

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Predicted Archaic 3D Genome Organization Reveals Genes Related to Head and Spinal Cord Separating Modern from Archaic Humans

Cells ◽

10.3390/cells9010048 ◽

2019 ◽

Vol 9 (1) ◽

pp. 48 ◽

Cited By ~ 2

Author(s):

Daniel Batyrev ◽

Elisheva Lapid ◽

Liran Carmel ◽

Eran Meshorer

Keyword(s):

Dna Methylation ◽

Gene Regulation ◽

Genome Organization ◽

Spinal Column ◽

Detailed Comparison ◽

Modern Human ◽

High Coverage ◽

3D Genome ◽

Differentially Methylated Genes ◽

Significant Enrichment

High coverage sequences of archaic humans enabled the reconstruction of their DNA methylation patterns. This allowed comparing gene regulation between human groups, and linking such regulatory changes to phenotypic differences. In a previous work, a detailed comparison of DNA methylation in modern humans, archaic humans, and chimpanzees revealed 873 modern human-derived differentially methylated regions (DMRs). To understand the regulatory implications of these DMRs, we defined differentially methylated genes (DMGs) as genes that harbor DMRs in their promoter or gene body. While most of the modern human-derived DMRs could be linked to DMGs, many others remained unassigned. Here, we used information on 3D genome organization to link ~70 out of the remaining 288 unassigned DMRs to genes. Combined with the previously identified DMGs, we reinforce the enrichment of these genes with vocal and facial anatomy, and additionally find significant enrichment with the spinal column, chin, hair, and scalp. These results reveal the importance of 3D genomic organization in understanding gene regulation by DNA methylation.

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Sci-Hi-C: a single-cell Hi-C method for mapping 3D genome organization in large number of single cells

10.1101/579573 ◽

2019 ◽

Cited By ~ 1

Author(s):

Vijay Ramani ◽

Xinxian Deng ◽

Ruolan Qiu ◽

Choli Lee ◽

Christine M Disteche ◽

...

Keyword(s):

Single Cell ◽

Genome Organization ◽

Single Cells ◽

Three Dimensional ◽

Population Based ◽

Order Structure ◽

Chromosome Conformation ◽

3D Genome ◽

A Cell ◽

Cell To Cell Variability

AbstractThe highly dynamic nature of chromosome conformation and three-dimensional (3D) genome organization leads to cell-to-cell variability in chromatin interactions within a cell population, even if the cells of the population appear to be functionally homogeneous. Hence, although Hi-C is a powerful tool for mapping 3D genome organization, this heterogeneity of chromosome higher order structure among individual cells limits the interpretive power of population based bulk Hi-C assays. Moreover, single-cell studies have the potential to enable the identification and characterization of rare cell populations or cell subtypes in a heterogeneous population. However, it may require surveying relatively large numbers of single cells to achieve statistically meaningful observations in single-cell studies. By applying combinatorial cellular indexing to chromosome conformation capture, we developed single-cell combinatorial indexed Hi-C (sci-Hi-C), a high throughput method that enables mapping chromatin interactomes in large number of single cells. We demonstrated the use of sci-Hi-C data to separate cells by karytoypic and cell-cycle state differences and to identify cellular variability in mammalian chromosomal conformation. Here, we provide a detailed description of method design and step-by-step working protocols for sci-Hi-C.

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Dynamic interplay between structural variations and 3D chromosome organization in pancreatic cancer

10.1101/2021.12.15.471847 ◽

2021 ◽

Author(s):

Yongxing Du ◽

Zongting Gu ◽

Zongze Li ◽

Zan Yuan ◽

Yue Zhao ◽

...

Keyword(s):

Pancreatic Cancer ◽

Single Molecule ◽

Genome Organization ◽

Human Pancreatic Cancer ◽

Structural Variations ◽

Driver Genes ◽

Ductal Epithelial Cell ◽

Chromosome Conformation ◽

3D Genome ◽

The Impact

Structural variations (SVs) are the greatest source of variation in the genome and can lead to oncogenesis. However, the identification and interpretation of SVs in human pancreatic cancer remain largely undefined due to technological limitations. Here, we investigate the spectrum of SVs and three-dimensional (3D) chromatin architecture in human pancreatic ductal epithelial cell carcinogenesis by using state-of-the-art long-read single-molecule real-time (SMRT) and high-throughput chromosome conformation capture (Hi-C) sequencing techniques. We find that the 3D genome organization is remodeled and correlated with gene expressional change. The bulk remodeling effect of cross-boundary SVs in the 3D genome partly depends on intercellular genomic heterogeneity. Meanwhile, contact domains tend to minimize these disrupting effects of SVs within local adjacent genomic regions to maintain overall stability of 3D genome organization. Moreover, our data also demonstrates complex genomic rearrangements involving two key driver genes CDKN2A and SMAD4, and elucidates their influence on cancer-related gene expression from both linear view and 3D perspective. Overall, this study provides a valuable resource and highlights the impact, complexity and dynamicity of the interplay between SVs and 3D genome organization, which further expands our understanding of pathogenesis of SVs in human pancreatic cancer.

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Resolving the 3D landscape of transcription-linked mammalian chromatin folding

10.1101/638775 ◽

2019 ◽

Cited By ~ 9

Author(s):

Tsung-Han S. Hsieh ◽

Elena Slobodyanyuk ◽

Anders S. Hansen ◽

Claudia Cattoglio ◽

Oliver J. Rando ◽

...

Keyword(s):

Stem Cells ◽

Gene Regulation ◽

Genome Organization ◽

Regulatory Elements ◽

Genome Architecture ◽

Transcriptional Regulatory Elements ◽

3D Genome ◽

Topologically Associating Domains ◽

Transcriptional Regulatory ◽

Chromatin Folding

ABSTRACTChromatin folding below the scale of topologically associating domains (TADs) remains largely unexplored in mammals. Here, we used a high-resolution 3C-based method, Micro-C, to probe links between 3D-genome organization and transcriptional regulation in mouse stem cells. Combinatorial binding of transcription factors, cofactors, and chromatin modifiers spatially segregate TAD regions into “microTADs” with distinct regulatory features. Enhancer-promoter and promoter-promoter interactions extending from the edge of these domains predominantly link co-regulated loci, often independently of CTCF/Cohesin. Acute inhibition of transcription disrupts the gene-related folding features without altering higher-order chromatin structures. Intriguingly, we detect “two-start” zig-zag 30-nanometer chromatin fibers. Our work uncovers the finer-scale genome organization that establishes novel functional links between chromatin folding and gene regulation.ONE SENTENCE SUMMARYTranscriptional regulatory elements shape 3D genome architecture of microTADs.

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Understanding 3D Genome Organization and Its Effect on Transcriptional Gene Regulation Under Environmental Stress in Plant: A Chromatin Perspective

Frontiers in Cell and Developmental Biology ◽

10.3389/fcell.2021.774719 ◽

2021 ◽

Vol 9 ◽

Author(s):

Suresh Kumar ◽

Simardeep Kaur ◽

Karishma Seem ◽

Santosh Kumar ◽

Trilochan Mohapatra

Keyword(s):

Gene Expression ◽

Environmental Stress ◽

Genome Organization ◽

Regulation Of Gene Expression ◽

Three Dimensional ◽

Regulatory Elements ◽

Chromosome Conformation ◽

3D Genome ◽

Chromatin Architecture ◽

Capture Techniques

The genome of a eukaryotic organism is comprised of a supra-molecular complex of chromatin fibers and intricately folded three-dimensional (3D) structures. Chromosomal interactions and topological changes in response to the developmental and/or environmental stimuli affect gene expression. Chromatin architecture plays important roles in DNA replication, gene expression, and genome integrity. Higher-order chromatin organizations like chromosome territories (CTs), A/B compartments, topologically associating domains (TADs), and chromatin loops vary among cells, tissues, and species depending on the developmental stage and/or environmental conditions (4D genomics). Every chromosome occupies a separate territory in the interphase nucleus and forms the top layer of hierarchical structure (CTs) in most of the eukaryotes. While the A and B compartments are associated with active (euchromatic) and inactive (heterochromatic) chromatin, respectively, having well-defined genomic/epigenomic features, TADs are the structural units of chromatin. Chromatin architecture like TADs as well as the local interactions between promoter and regulatory elements correlates with the chromatin activity, which alters during environmental stresses due to relocalization of the architectural proteins. Moreover, chromatin looping brings the gene and regulatory elements in close proximity for interactions. The intricate relationship between nucleotide sequence and chromatin architecture requires a more comprehensive understanding to unravel the genome organization and genetic plasticity. During the last decade, advances in chromatin conformation capture techniques for unravelling 3D genome organizations have improved our understanding of genome biology. However, the recent advances, such as Hi-C and ChIA-PET, have substantially increased the resolution, throughput as well our interest in analysing genome organizations. The present review provides an overview of the historical and contemporary perspectives of chromosome conformation capture technologies, their applications in functional genomics, and the constraints in predicting 3D genome organization. We also discuss the future perspectives of understanding high-order chromatin organizations in deciphering transcriptional regulation of gene expression under environmental stress (4D genomics). These might help design the climate-smart crop to meet the ever-growing demands of food, feed, and fodder.

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Understanding gene regulatory mechanisms based on gene classification

10.1101/2021.10.31.466641 ◽

2021 ◽

Author(s):

Hao Tian ◽

Yueying He ◽

Yue Xue ◽

Yi Qin Gao

Keyword(s):

Gene Regulation ◽

Density Distribution ◽

Genome Organization ◽

Housekeeping Genes ◽

Structural Features ◽

Regulatory Mechanisms ◽

3D Genome ◽

Human Genes ◽

Cpg Dinucleotide ◽

Gene Regulatory

The CpG dinucleotide and its methylation play vital roles in gene regulation as well as 3D genome organization. Previous studies have divided genes into several categories based on the CpG intensity around transcription starting sites (TSS) and found that housekeeping genes tend to possess high CpG density while tissue-specific genes are generally characterized by low CpG density. In this study, we investigated how the CpG density distribution of a gene affects its transcription and regulation pattern. Based on the CpG density distribution around TSS, the human genes are clearly divided into different categories. Not only sequence properties, these different clusters exhibited distinctly different structural features, regulatory mechanisms, and correlation patterns between expression level and CpG/TpG density. These results emphasized that the usage of epigenetic marks in gene regulation is partially rooted in the sequence property of genes, such as their CpG density distribution.

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Establishment of 3D chromatin structure after fertilization and the metabolic switch at the morula-to-blastocyst transition require CTCF

10.1101/2021.07.07.451492 ◽

2021 ◽

Author(s):

Maria Jose Andreu ◽

Alba Alvarez-Franco ◽

Marta Portela ◽

Daniel Gimenez-Llorente ◽

Ana Cuadrado ◽

...

Keyword(s):

Chromatin Structure ◽

Zinc Finger Protein ◽

De Novo ◽

Genome Structure ◽

Blastocyst Stage ◽

Mammalian Development ◽

Metabolic Switch ◽

3D Genome ◽

3D Chromatin Structure ◽

The Impact

The eukaryotic genome is tightly packed inside the nucleus, where it is organized in 3D at different scales. This structure is driven and maintained by different chromatin states and by architectural factors that bind DNA, such as the multi-zinc finger protein CTCF. Zygotic genome structure is established de novo after fertilization, but the impact of such structure on genome function during the first stages of mammalian development is still unclear. Here, we show that deletion of the Ctcf gene in mouse embryos impairs the correct establishment of chromatin structure, but initial lineage decisions take place and embryos are viable until the late blastocyst stage. Furthermore, we observe that maternal CTCF is not necessary for development. Transcriptomic analyses of mutant embryos show that the changes in metabolic and protein homeostasis programs that occur during the progression from the morula to the blastocyst depend on CTCF. Yet, these changes in gene expression do not correlate with disruption of chromatin structure, but mainly with proximal binding of CTCF to the promoter region of genes downregulated in mutants. Our results show that CTCF regulates both 3D genome organization and transcription during mouse preimplantation development, but mostly as independent processes.

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Tm7sf2 Disruption Alters Radial Gene Positioning in Mouse Liver Leading to Metabolic Defects and Diabetes Characteristics

Frontiers in Cell and Developmental Biology ◽

10.3389/fcell.2020.592573 ◽

2020 ◽

Vol 8 ◽

Author(s):

Leonardo Gatticchi ◽

Jose I. de las Heras ◽

Aishwarya Sivakumar ◽

Nikolaj Zuleger ◽

Rita Roberti ◽

...

Keyword(s):

Cell Lines ◽

Nuclear Membrane ◽

Genome Organization ◽

Specific Gene ◽

Primary Cells ◽

Animal Tissues ◽

Tissue Specific ◽

Metabolic Defects ◽

Enzymatic Function ◽

Gene Positioning

Tissue-specific patterns of radial genome organization contribute to genome regulation and can be established by nuclear envelope proteins. Studies in this area often use cancer cell lines, and it is unclear how well such systems recapitulate genome organization of primary cells or animal tissues; so, we sought to investigate radial genome organization in primary liver tissue hepatocytes. Here, we have used a NET47/Tm7sf2–/– liver model to show that manipulating one of these nuclear membrane proteins is sufficient to alter tissue-specific gene positioning and expression. Dam-LaminB1 global profiling in primary liver cells shows that nearly all the genes under such positional regulation are related to/important for liver function. Interestingly, Tm7sf2 is a paralog of the HP1-binding nuclear membrane protein LBR that, like Tm7sf2, also has an enzymatic function in sterol reduction. Fmo3 gene/locus radial mislocalization could be rescued with human wild-type, but not TM7SF2 mutants lacking the sterol reductase function. One central pathway affected is the cholesterol synthesis pathway. Within this pathway, both Cyp51 and Msmo1 are under Tm7sf2 positional and expression regulation. Other consequences of the loss of Tm7sf2 included weight gain, insulin sensitivity, and reduced levels of active Akt kinase indicating additional pathways under its regulation, several of which are highlighted by mispositioning genes. This study emphasizes the importance for tissue-specific radial genome organization in tissue function and the value of studying genome organization in animal tissues and primary cells over cell lines.

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