Your search keyword '"Candice L Wike"' showing total 9 results

1. Chromatin architecture transitions from zebrafish sperm through early embryogenesis

Author

Aneasha F. Whittaker-Tademy, Mengyao Tan, Erez Lieberman Aiden, Hiroyuki Takeda, Bradley R. Cairns, Noelia Díaz, Neva C. Durand, Candice L. Wike, Dana Klatt Shaw, David Grunwald, Ryohei Nakamura, Yixuan Guo, and Juan M. Vaquerizas

Subjects

Male, animal structures, Zygote, Embryonic Development, Genome, Chromosomes, 03 medical and health sciences, 0302 clinical medicine, Genetics, medicine, Animals, Enhancer, Mitosis, Zebrafish, Genetics (clinical), 030304 developmental biology, 0303 health sciences, biology, Research, Gene Expression Regulation, Developmental, biology.organism_classification, Spermatozoa, Chromatin, Cell biology, Histone, medicine.anatomical_structure, biology.protein, Maternal to zygotic transition, Gamete, 030217 neurology & neurosurgery

Abstract

Chromatin architecture mapping in 3D formats has increased our understanding of how regulatory sequences and gene expression are connected and regulated in a genome. The 3D chromatin genome shows extensive remodeling during embryonic development, and although the cleavage-stage embryos of most species lack structure before zygotic genome activation (pre-ZGA), zebrafish has been reported to have structure. Here, we aimed to determine the chromosomal architecture in paternal/sperm zebrafish gamete cells to discern whether it either resembles or informs early pre-ZGA zebrafish embryo chromatin architecture. First, we assessed the higher-order architecture through advanced low-cell in situ Hi-C. The structure of zebrafish sperm, packaged by histones, lacks topological associated domains and instead displays “hinge-like” domains of ∼150 kb that repeat every 1–2 Mbs, suggesting a condensed repeating structure resembling mitotic chromosomes. The pre-ZGA embryos lacked chromosomal structure, in contrast to prior work, and only developed structure post-ZGA. During post-ZGA, we find chromatin architecture beginning to form at small contact domains of a median length of ∼90 kb. These small contact domains are established at enhancers, including super-enhancers, and chemical inhibition of Ep300a (p300) and Crebbpa (CBP) activity, lowering histone H3K27ac, but not transcription inhibition, diminishes these contacts. Together, this study reveals hinge-like domains in histone-packaged zebrafish sperm chromatin and determines that the initial formation of high-order chromatin architecture in zebrafish embryos occurs after ZGA primarily at enhancers bearing high H3K27ac.

Published

2021

2. Maternally-inherited anti-sense piRNAs antagonize transposon expression in teleost embryos

Author

Krista R. Gert, René F. Ketting, Yixuan Guo, Svetlana Lebedeva, Candice L. Wike, Magdalena E. Potok, Edward J. Grow, Bradley R. Cairns, and Andrea Pauli

Subjects

Transposable element, endocrine system, urogenital system, Transcription (biology), Somatic cell, Gene silencing, Piwi-interacting RNA, Retrotransposon, Biology, Germline, Long terminal repeat, Cell biology

Abstract

Transposable elements threaten genome stability, and the Piwi-piRNA system has evolved to silence transposons in the germline1–6. However, it remains largely unknown what mechanisms are utilized in early vertebrate embryos prior to germline establishment and ‘ping-pong’ piRNA production. To address this, we first characterized small RNAs in early zebrafish embryos and detected abundant maternally-deposited, Ziwi-associated, antisense piRNAs that map largely to evolutionarily young long terminal repeat (LTR) retrotransposons. Notably, the focal establishment of the repressive modification H3K9me2/3 coincides with these young LTR elements, is deposited independent of transcription, and is required for LTR silencing. We find piRNAs highly enriched and maintained in primordial germ cells (PGCs), which display lower LTR expression than somatic cells. To examine the consequences of piRNA loss, we used reciprocal zebrafish-medaka hybrids, which display selective activation of LTRs that lack maternally-contributed targeting piRNAs. Thus, the Piwi-piRNA system actively antagonizes transposons in the soma and PGCs during early vertebrate embryogenesis.

Published

2021

3. CTCF looping is established during gastrulation in medaka embryos

Author

Neva C. Durand, Ryohei Nakamura, Takashi Kondo, Candice L. Wike, Erez Lieberman Aiden, Hiroyuki Takeda, Shinichi Morishita, Tatsuya Tsukahara, Kaori Kondo, Yuichi Motai, Yoichiro Nakatani, Masahiko Kumagai, Haruyo Nishiyama, Bradley R. Cairns, and Atsuko Shimada

Subjects

CCCTC-Binding Factor, Oryzias, Cellular differentiation, Cell Cycle Proteins, Insulator (genetics), 03 medical and health sciences, Mice, 0302 clinical medicine, Genetics, Animals, Zebrafish, Genetics (clinical), 030304 developmental biology, 0303 health sciences, biology, Research, Gastrulation, biology.organism_classification, Chromatin, Cell biology, CTCF, Maternal to zygotic transition, 030217 neurology & neurosurgery

Abstract

Chromatin looping plays an important role in genome regulation. However, because ChIP-seq and loop-resolution Hi-C (DNA-DNA proximity ligation) are extremely challenging in mammalian early embryos, the developmental stage at which cohesin-mediated loops form remains unknown. Here, we study early development in medaka (the Japanese killifish, Oryzias latipes) at 12 time points before, during, and after gastrulation (the onset of cell differentiation) and characterize transcription, protein binding, and genome architecture. We find that gastrulation is associated with drastic changes in genome architecture, including the formation of the first loops between sites bound by the insulator protein CTCF and a large increase in the size of contact domains. In contrast, the binding of the CTCF is fixed throughout embryogenesis. Loops form long after genome-wide transcriptional activation, and long after domain formation seen in mouse embryos. These results suggest that, although loops may play a role in differentiation, they are not required for zygotic transcription. When we repeated our experiments in zebrafish, loops did not emerge until gastrulation, that is, well after zygotic genome activation. We observe that loop positions are highly conserved in synteny blocks of medaka and zebrafish, indicating that the 3D genome architecture has been maintained for >110–200 million years of evolution.

Published

2021

4. Establishment of Developmental Gene Silencing by Ordered Polycomb Complex Recruitment in Early Zebrafish Embryos

Author

Y. Guo, Patrick J. Murphy, Bradley R. Cairns, M. Tan, X. Nie, Candice L. Wike, and Glenn Hickey

Subjects

Histone, biology.protein, Gene silencing, Maternal to zygotic transition, macromolecular substances, Biology, PRC1, biology.organism_classification, PRC2, Enhancer, Zebrafish, Cell biology, Chromatin

Abstract

Vertebrate embryos achieve developmental competency during zygotic genome activation (ZGA) by establishing chromatin states that silence yet poise developmental genes for subsequent lineage-specific activation. Here, we reveal how developmental gene poising is established de novo in preZGA zebrafish embryos. Poising is established at promoters and enhancers that initially contain open/permissive chromatin with ‘Placeholder’ nucleosomes (bearing H2A.Z, H3K4me1, and H3K27ac), and DNA hypomethylation. Silencing is initiated by the recruitment of Polycomb Repressive Complex 1 (PRC1), and H2Aub1 deposition by catalytic Rnf2 during preZGA and ZGA stages. During postZGA, H2Aub1 enables Aebp2-containing PRC2 recruitment and H3K27me3 deposition. Notably, preventing H2Aub1 (via Rnf2 inhibition) eliminates recruitment of Aebp2-PRC2 and H3K27me3, and elicits transcriptional upregulation of certain developmental genes during ZGA. However, upregulation is independent of H3K27me3 – establishing H2Aub1 as the critical silencing modification at ZGA. Taken together, we reveal the logic and mechanism for establishing poised/silent developmental genes in early vertebrate embryos.Impact StatementDe novo polycomb domains are formed in zebrafish early embryos by focal histone H2Aub1 deposition by Rnf2-PRC1 – which imposes transcription silencing – followed by subsequent recruitment of Aebp2-PRC2 and H3K27me3 deposition.

Published

2021

5. Excess free histone H3 localizes to centrosomes for proteasome-mediated degradation during mitosis in metazoans

Author

Candice L Wike, Jessica K. Tyler, Reva Hawkins, Arpit Wason, Hillary K. Graves, Jill M. Schumacher, and Jay Gopalakrishnan

Subjects

0301 basic medicine, Mitosis, Centrosome cycle, Cell Cycle Proteins, Biology, Protein Serine-Threonine Kinases, Models, Biological, Histones, 03 medical and health sciences, Histone H3, Histone H1, Proto-Oncogene Proteins, Histone H2A, Histone methylation, Histone code, Animals, Humans, Molecular Biology, Centrosome, Ubiquitin, Ubiquitination, Cell Biology, Cell biology, 030104 developmental biology, Histone phosphorylation, Histone methyltransferase, Mutation, Proteolysis, Proteasome Inhibitors, Developmental Biology, Reports, HeLa Cells

Abstract

The cell tightly controls histone protein levels in order to achieve proper packaging of the genome into chromatin, while avoiding the deleterious consequences of excess free histones. Our accompanying study has shown that a histone modification that loosens the intrinsic structure of the nucleosome, phosphorylation of histone H3 on threonine 118 (H3 T118ph), exists on centromeres and chromosome arms during mitosis. Here, we show that H3 T118ph localizes to centrosomes in humans, flies, and worms during all stages of mitosis. H3 abundance at the centrosome increased upon proteasome inhibition, suggesting that excess free histone H3 localizes to centrosomes for degradation during mitosis. In agreement, we find ubiquitinated H3 specifically during mitosis and within purified centrosomes. These results suggest that targeting of histone H3 to the centrosome for proteasome-mediated degradation is a novel pathway for controlling histone supply, specifically during mitosis.

Published

2016

6. Aurora-A mediated histone H3 phosphorylation of threonine 118 controls condensin I and cohesin occupancy in mitosis

Author

Jennifer J. Ottesen, Jill M. Schumacher, Hillary K. Graves, Candice L Wike, Damien F. Hudson, Michelle B. Ferdinand, Matthew D. Gibson, Reva Hawkins, Michael G. Poirier, Tao Zhang, Zhihong Chen, and Jessica K. Tyler

Subjects

0301 basic medicine, Threonine, Chromosomal Proteins, Non-Histone, Cell Cycle Proteins, Histones, 0302 clinical medicine, Histone methylation, Histone code, Histone octamer, Phosphorylation, Biology (General), Aurora Kinase A, Genetics, Adenosine Triphosphatases, General Neuroscience, condensin, General Medicine, DNA-Binding Proteins, Genes and Chromosomes, 030220 oncology & carcinogenesis, Histone methyltransferase, Medicine, Drosophila, biological phenomena, cell phenomena, and immunity, Research Article, Human, QH301-705.5, Science, Mitosis, macromolecular substances, Biology, aurora-A, General Biochemistry, Genetics and Molecular Biology, Cell Line, 03 medical and health sciences, Histone H3, Histone H1, Histone H2A, Nucleosome, Animals, Humans, General Immunology and Microbiology, DNA, C. elegans, chromosome congression, D. melanogaster, histone H3 phosphorylation, cohesion, 030104 developmental biology, Multiprotein Complexes, Protein Processing, Post-Translational

Abstract

Phosphorylation of histone H3 threonine 118 (H3 T118ph) weakens histone DNA-contacts, disrupting the nucleosome structure. We show that Aurora-A mediated H3 T118ph occurs at pericentromeres and chromosome arms during prophase and is lost upon chromosome alignment. Expression of H3 T118E or H3 T118I (a SIN mutation that bypasses the need for the ATP-dependent nucleosome remodeler SWI/SNF) leads to mitotic problems including defects in spindle attachment, delayed cytokinesis, reduced chromatin packaging, cohesion loss, cohesin and condensin I loss in human cells. In agreement, overexpression of Aurora-A leads to increased H3 T118ph levels, causing cohesion loss, and reduced levels of cohesin and condensin I on chromatin. Normal levels of H3 T118ph are important because it is required for development in fruit flies. We propose that H3 T118ph alters the chromatin structure during specific phases of mitosis to promote timely condensin I and cohesin disassociation, which is essential for effective chromosome segregation. DOI: http://dx.doi.org/10.7554/eLife.11402.001, eLife digest In every one of our cells, our DNA is wrapped together with histone proteins to make a structure called chromatin. When a cell divides, each newly formed daughter cell must receive an identical set of chromatin. As part of this process, the chromatin is copied and then compacted, which causes a characteristic “X”-shaped chromosome to form. This “X” shape is actually made up of two identical parts, or chromatids, that are joined together until a specific time during cell division. If chromosomes separate too early or too late, the DNA will not distribute evenly to daughter cells, which could lead to diseases including cancer. Histone modifications are small chemical changes on the histone proteins that the DNA wraps around. Previous research identified a new histone modification that is located at an important contact point between the DNA and a particular histone protein. However, the role of this modification in living cells was not clear. Wike et al. have now determined that in animal cells, this histone modification occurs immediately before the chromatids separate and at specific locations along the chromosomes. The amount of this histone modification is very important: in cells with too much of the modification, the chromosomes compacted incorrectly and the chromatids separated too soon. As a result, the chromosomes were incorrectly distributed among the daughter cells. Wike et al. also show that an enzyme called Aurora-A kinase is responsible for making this histone modification. The next challenge will be to understand how the Aurora-A kinase knows when and where to add the histone modification to the chromosome. This will help us to understand how the overproduction of Aurora-A causes cancer. DOI: http://dx.doi.org/10.7554/eLife.11402.002

Published

2016

7. Conserved Roles of Mouse DUX and Human DUX4 in Activating Cleavage-Stage Genes and MERVL/HERVL Retrotransposons

Author

Jessie Dorais, Aaron L. Wilcox, Douglas T. Carrell, Stephen J. Tapscott, Jennifer L. Whiddon, Edward J. Grow, Jong-Won Lim, C. Matthew Peterson, Benjamin R. Emery, Peter G. Hendrickson, Christian Pflueger, Candice L. Wike, David A. Nix, Bradley R. Cairns, and Bradley D. Weaver

Subjects

Genetics, DUX4, Transcription (biology), Transcriptional regulation, Obstetrics and Gynecology, Retrotransposon, General Medicine, Biology, Transcription factor, Gene, Embryonic stem cell, Chromatin

Abstract

To better understand transcriptional regulation during human oogenesis and preimplantation development, we defined stage-specific transcription, which highlighted the cleavage stage as being highly distinctive. Here, we present multiple lines of evidence that a eutherian-specific multicopy retrogene, DUX4, encodes a transcription factor that activates hundreds of endogenous genes (for example, ZSCAN4, KDM4E and PRAMEF-family genes) and retroviral elements (MERVL/HERVL family) that define the cleavage-specific transcriptional programs in humans and mice. Remarkably, mouse Dux expression is both necessary and sufficient to convert mouse embryonic stem cells (mESCs) into 2-cell-embryo-like ('2C-like') cells, measured here by the reactivation of '2C' genes and repeat elements, the loss of POU5F1 (also known as OCT4) protein and chromocenters, and the conversion of the chromatin landscape (as assessed by transposase-accessible chromatin using sequencing (ATAC-seq)) to a state strongly resembling that of mouse 2C embryos. Thus, we propose mouse DUX and human DUX4 as major drivers of the cleavage or 2C state.

Published

2017

8. Placeholder Nucleosomes Underlie Germline-to-Embryo DNA Methylation Reprogramming

Author

Bradley R. Cairns, Cody R. James, Patrick J. Murphy, Candice L. Wike, and Shan-Fu Wu

Subjects

Male, 0301 basic medicine, Embryo, Nonmammalian, Biology, General Biochemistry, Genetics and Molecular Biology, Histones, 03 medical and health sciences, Animals, Nucleosome, Epigenetics, Zebrafish, Genetics, Regulation of gene expression, Promoter, DNA Methylation, Zebrafish Proteins, Cellular Reprogramming, Spermatozoa, Cell biology, Nucleosomes, Germ Cells, 030104 developmental biology, Mutation, DNA methylation, H3K4me3, Maternal to zygotic transition, Reprogramming, DNA hypomethylation

Abstract

The fate and function of epigenetic marks during the germline-to-embryo transition is a key issue in developmental biology, with relevance to stem cell programming and trans-generational inheritance. In zebrafish, DNA methylation (DNAme) patterns are programmed in transcriptionally-quiescent cleavage embryos; remarkably, paternally-inherited patterns are maintained, whereas maternal patterns are reprogrammed to match the paternal. Here we provide the mechanism, by demonstrating that ‘Placeholder’ nucleosomes, containing histone H2A variant H2A.Z(FV) and H3K4me1, occupy virtually all regions lacking DNAme in both sperm and cleavage embryos, and resides at promoters encoding housekeeping and early embryonic transcription factors. Upon genome-wide transcriptional onset, genes with Placeholder become either active (H3K4me3) or silent (H3K4me3/K27me3). Importantly, functional perturbation causing Placeholder loss confers DNAme accumulation, whereas acquisition/expansion of Placeholder confers DNA hypomethylation and improper gene activation. Thus, during transcriptionally-quiescent gametic and embryonic stages, an H2A.Z(FV)/H3K4me1-containing Placeholder nucleosome deters DNAme, poising parental genes for either gene-specific activation or facultative repression.Highlights: four, 85 characters eachPlaceholder nucleosomes bear H3K4me and the histone variant H2A.Z(FV)Placeholders occupy all DNA hypomethylated loci in zebrafish sperm and early embryosAt ZGA, Placeholders resolve into either active or poised (bivalent) nucleosomesPlaceholder localization excludes DNAme, and regulates embryonic transcription

Published

2018

9. The unusual macrocycle forming thioesterase of mycolactone

Author

Tiffany Barrows-Yano, Timothy L. Foley, Michael D. Burkart, Candice L. Wike, and Jordan L. Meier

Subjects

Buruli ulcer, Macrocyclic Compounds, Bacterial Toxins, Molecular Sequence Data, Molecular Conformation, Biology, Polymerase Chain Reaction, Catalysis, Virulence factor, chemistry.chemical_compound, Polyketide, Thioesterase, Catalytic Domain, Polyketide synthase, medicine, Amino Acid Sequence, Cloning, Molecular, Mycolactone, Molecular Biology, chemistry.chemical_classification, Gene Expression Profiling, Hydrolysis, medicine.disease, biology.organism_classification, Recombinant Proteins, Kinetics, Enzyme, Biochemistry, chemistry, Cyclization, Mycobacterium ulcerans, biology.protein, Macrolides, Thiolester Hydrolases, Sequence Alignment, Sequence Analysis, Biotechnology

Abstract

Mycolactone is a polyketide natural product secreted by Mycobacterium ulcerans, the organism responsible for the tropical skin disease Buruli ulcer. The finding that this small molecule virulence factor is sufficient to reconstitute the necrotic pathology associated with Buruli ulcer suggests that a better understanding of mycolactone biosynthesis, particularly the processes which are distinct from those in human metabolism, may provide a unique avenue for the development of selective therapeutics. In the present study we have cloned, expressed, and biochemically characterized the putative macrocycle forming thioesterase for mycolactone, MLSA2 TE. We have evaluated the enzyme both as the truncated thioesterase domain and as a carrier protein-linked didomain construct. The results of these analyses distinguish MLSA2 TE from traditional fatty acid and polyketide synthase TE-domains in terms of its sequence, kinetic parameters, and susceptibility to traditional active-site directed inhibitors. These findings suggest that MLSA2 TE utilizes a unique biochemical mechanism for macrocycle formation.

Published

2008