Your search keyword '"Replication timing"' showing total 22 results

1. Multifaceted role of the DNA replication protein MCM10 in maintaining genome stability and its implication in human diseases.

Author

Ahmed, Sumayyah M. Q., Sasikumar, Jayaprakash, Laha, Suparna, and Das, Shankar Prasad

Abstract

MCM10 plays a vital role in genome duplication and is crucial for DNA replication initiation, elongation, and termination. It coordinates several proteins to assemble at the fork, form a functional replisome, trigger origin unwinding, and stabilize the replication bubble. MCM10 overexpression is associated with increased aggressiveness in breast, cervical, and several other cancers. Disruption of MCM10 leads to altered replication timing associated with initiation site gains and losses accompanied by genome instability. Knockdown of MCM10 affects the proliferation and migration of cancer cells, manifested by DNA damage and replication fork arrest, and has recently been shown to be associated with clinical conditions like CNKD and RCM. Loss of MCM10 function is associated with impaired telomerase activity, leading to the accumulation of abnormal replication forks and compromised telomere length. MCM10 interacts with histones, aids in nucleosome assembly, binds BRCA2 to maintain genome integrity during DNA damage, prevents lesion skipping, and inhibits PRIMPOL-mediated repriming. It also interacts with the fork reversal enzyme SMARCAL1 and inhibits fork regression. Additionally, MCM10 undergoes several post-translational modifications and contributes to transcriptional silencing by interacting with the SIR proteins. This review explores the mechanism associated with MCM10's multifaceted role in DNA replication initiation, chromatin organization, transcriptional silencing, replication stress, fork stability, telomere length maintenance, and DNA damage response. Finally, we discuss the role of MCM10 in the early detection of cancer, its prognostic significance, and its potential use in therapeutics for cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optimized Repli-seq: improved DNA replication timing analysis by next-generation sequencing.

Author

Rivera-Mulia, Juan Carlos, Trevilla-Garcia, Claudia, and Martinez-Cifuentes, Santiago

Abstract

The human genome is divided into functional units that replicate at specific times during S-phase. This temporal program is known as replication timing (RT) and is coordinated with the spatial organization of the genome and transcriptional activity. RT is also cell type–specific, dynamically regulated during development, and alterations in RT are observed in multiple diseases. Thus, the precise measure of RT is critical to understand the role of RT in gene function regulation. Distinct methods for assaying the RT program exist; however, conventional methods require thousands of cells as input, prohibiting its applicability to samples with limited cell numbers such as those from disease patients or from early developing embryos. Although single-cell RT analyses have been developed, these methods are low throughput, require generation of numerous libraries, increased sequencing costs, and produce low resolution data. Here, we developed an improved method to measure RT genome-wide that enables high-resolution analysis of low input samples. This method incorporates direct cell sorting into lysis buffer, as well as DNA fragmentation and library preparation in a single tube, resulting in higher yields, increased quality, and reproducibility with decreased costs. We also performed a systematic data processing analysis to provide standardized parameters for RT measurement. This optimized method facilitates RT analysis and will enable its application to a broad range of studies investigating the role of RT in gene expression, nuclear architecture, and disease. [ABSTRACT FROM AUTHOR]

Published

2022

3. Super-resolution microscopy reveals stochastic initiation of replication in Drosophila polytene chromosomes.

Author

Kolesnikova, Tatyana D., Pokholkova, Galina V., Dovgan, Viktoria V., Zhimulev, Igor F., and Schubert, Veit

Abstract

Studying the probability distribution of replication initiation along a chromosome is a huge challenge. Drosophila polytene chromosomes in combination with super-resolution microscopy provide a unique opportunity for analyzing the probabilistic nature of replication initiation at the ultrastructural level. Here, we developed a method for synchronizing S-phase induction among salivary gland cells. An analysis of the replication label distribution in the first minutes of S phase and in the following hours after the induction revealed the dynamics of replication initiation. Spatial super-resolution structured illumination microscopy allowed identifying multiple discrete replication signals and to investigate the behavior of replication signals in the first minutes of the S phase at the ultrastructural level. We identified replication initiation zones where initiation occurs stochastically. These zones differ significantly in the probability of replication initiation per time unit. There are zones in which initiation occurs on most strands of the polytene chromosome in a few minutes. In other zones, the initiation on all strands takes several hours. Compact bands are free of replication initiation events, and the replication runs from outer edges to the middle, where band shapes may alter. [ABSTRACT FROM AUTHOR]

Published

2022

4. Genomic methods for measuring DNA replication dynamics.

Author

Hulke, Michelle L., Massey, Dashiell J., and Koren, Amnon

Abstract

Genomic DNA replicates according to a defined temporal program in which early-replicating loci are associated with open chromatin, higher gene density, and increased gene expression levels, while late-replicating loci tend to be heterochromatic and show higher rates of genomic instability. The ability to measure DNA replication dynamics at genome scale has proven crucial for understanding the mechanisms and cellular consequences of DNA replication timing. Several methods, such as quantification of nucleotide analog incorporation and DNA copy number analyses, can accurately reconstruct the genomic replication timing profiles of various species and cell types. More recent developments have expanded the DNA replication genomic toolkit to assays that directly measure the activity of replication origins, while single-cell replication timing assays are beginning to reveal a new level of replication timing regulation. The combination of these methods, applied on a genomic scale and in multiple biological systems, promises to resolve many open questions and lead to a holistic understanding of how eukaryotic cells replicate their genomes accurately and efficiently. [ABSTRACT FROM AUTHOR]

Published

2020

5. Mrc1/Claspin: a new role for regulation of origin firing.

Author

Masai, Hisao, Yang, Chi-Chun, and Matsumoto, Seiji

Subjects

*CLASPIN, *DNA replication, *THREONINE, *SERINE, *N-terminal residues, *REPLISOMES

Abstract

Mrc1 and its vertebrate homologue Claspin serve as a mediator for replication stress checkpoint signaling, receiving the signal from Mec1/Rad3/ATR sensor kinase and transmitting it to the effector Rad53/Cds1/Chk1 kinase. They are likely to be a part of the replisome and facilitate the S-phase progression by promoting replication fork progression. Recent reports on Mrc1/Claspin indicate their new role in regulating the replication initiation through interaction with Cdc7, a key conserved serine-threonine kinase that triggers firing at each replication origin. Mrc1/Claspin has a specific domain that specifically interacts with Cdc7, and this domain is involved also in intramolecular interaction with its N-terminal segment. Mechanisms for novel regulation of origin firing and its timing through recruitment of Cdc7 to Mrc1/Claspin will be discussed. [ABSTRACT FROM AUTHOR]

Published

2017

6. A replication-time-controlling sequence element in Schizosaccharomyces pombe.

Author

Tripathi, Vishnu and Dubey, Dharani

Subjects

*REPLICATION factors (Biochemistry), *EUKARYOTIC cells, *FISSION (Asexual reproduction), *YEAST, *SCHIZOSACCHAROMYCES pombe

Abstract

Eukaryotic replication origins are highly variable in their activity and replication timing. The nature and role of cis-acting regulatory sequences that control chromosomal replication timing is not well defined. In the fission yeast, Schizosaccharomyces pombe, a 200-bp late-replication-enforcing element (LRE), has been shown to enforce late replication of ARS elements in plasmids. Here, we show that a short (133-bp) fragment of the LRE (shLRE) is required for causing late replication of adjoining origins in its native as well as in an ectopic early-replicating chromosomal location. Active from both sides of an early-replicating origin, the shLRE is a bona fide cis-acting regulatory element that imposes late replication timing in the chromosome. [ABSTRACT FROM AUTHOR]

Published

2017

7. Regulation of DNA replication timing.

Author

Kolesnikova, T.

Subjects

*DNA replication, *CHROMATIN, *CELL cycle, *EPIGENETICS, *GENETIC transcription, *CHROMOSOMES

Abstract

Although replication of different chromatin types is long known to occur at different times in the S phase, it was not until recently that the inheritance of replication timing came to be considered from the epigenetic viewpoint. Significant changes in genome replication timing are now known to occur during differentiation and are intimately linked with changes in transcriptional activity and nuclear architecture. Replication domains delineate discrete units of chromosome structure and function. The functional significance of this tight control of replication timing is not fully understood, but it is clear that replication program is a basic feature of a given differentiation state. The review focuses on the molecular mechanisms of spatial and temporal control of replication timing at the levels of both individual replication origins and extended chromatin domains. [ABSTRACT FROM AUTHOR]

Published

2013

8. Domain-wide regulation of DNA replication timing during mammalian development.

Author

Pope, Benjamin, Hiratani, Ichiro, and Gilbert, David

Abstract

Studies of replication timing provide a handle into previously impenetrable higher-order levels of chromosome organization and their plasticity during development. Although mechanisms regulating replication timing are not clear, novel genome-wide studies provide a thorough survey of the extent to which replication timing is regulated during most of the early cell fate transitions in mammals, revealing coordinated changes of a defined set of 400–800 kb chromosomal segments that involve at least half the genome. Furthermore, changes in replication time are linked to changes in sub-nuclear organization and domain-wide transcriptional potential, and tissue-specific replication timing profiles are conserved from mouse to human, suggesting that the program has developmental significance. Hence, these studies have provided a solid foundation for linking megabase level chromosome structure to function, and suggest a central role for replication in domain-level genome organization. [ABSTRACT FROM AUTHOR]

Published

2010

9. Reconciling stochastic origin firing with defined replication timing.

Author

Rhind, Nicholas, Yang, Scott, and Bechhoefer, John

Abstract

Eukaryotic chromosomes replicate with defined timing patterns. However, the mechanism that regulates the timing of replication is unknown. In particular, there is an apparent conflict between population experiments, which show defined average replication times, and single-molecule experiments, which show that origins fire stochastically. Here, we provide a simple simulation that demonstrates that stochastic origin firing can produce defined average patterns of replication firing if two criteria are met. The first is that origins must have different relative firing probabilities, with origins that have relatively high firing probability being likely to fire in early S phase and origins with relatively low firing probability being unlikely to fire in early S phase. The second is that the firing probability of all origins must increase during S phase to ensure that origins with relatively low firing probability, which are unlikely to fire in early S phase, become likely to fire in late S phase. In addition, we propose biochemically plausible mechanisms for these criteria and point out how stochastic and defined origin firing can be experimentally distinguished in population experiments. [ABSTRACT FROM AUTHOR]

Published

2010

10. Human chromosomal banding by in situ hybridization of isochores.

Author

Saccone, Salvatore and Bernardi, Giorgio

Abstract

Further to the classical methods that involve different chromosome treatments followed by staining, in situ hybridization of isochores represents a novel approach to chromosomal banding. Isochores are long compositionally homogeneous DNA segments that, in the human genome, belong to five families, two GC-poor families (L1 and L2) representing 30% and 33% of the genome, respectively, and three GC-rich families (H1, H2 and H3) representing 24%, 7.5% and 4–5– of the genome, respectively. Gene concentration increases with increasing GC levels, reaching an up to 20-fold higher level in H3 compared to L1 isochores. In situ hybridization of DNA from different isochore families on metaphase chromosomes allow to distinguish different sets of Giemsa and Reverse bands. In addition, it also provides information on the chromosomal distribution of genes. [ABSTRACT FROM AUTHOR]

Published

2001

11. Gene density in the Giemsa bands of human chromosomes.

Author

Federico, Concetta, Andreozzi, Letizia, Saccone, Salvatore, and Bernardi, Giorgio

Abstract

The human genome is formed by isochores belonging to five families, L1, L2, H1, H2 and H3, that are characterized by increasing GC levels and gene concentrations. In-situ hybridization of DNA from different isochore families provides, therefore, information not only on the correlation between isochores and chromosomal bands, but also on the distribution of genes in chromosomes. Three subsets of R(everse) bands were identified: H3+, H3* and H3−, that contain large, moderate, and no detectable amounts, respectively, of the gene-richest H2 and H3 isochores, and replicate very early and early, respectively, in S phase of the cell cycle. Here, we investigated the GC levels, replication timings and DNA compaction of G(iemsa) bands. We showed that G bands comprise two different subsets of bands, one of which is predominantly composed of L1 isochores, replicates at the end of the S phase, has a higher DNA compaction relative to H3+ bands and corresponds to the darkest G bands of Francke (1994). In contrast, the other subset is composed of L2 and H1 isochores, has less-extreme properties in replication and composition and corresponds to the less-dark G bands of Francke. [ABSTRACT FROM AUTHOR]

Published

2000

12. Analysis of replication timing at the FRA10B and FRA16B fragile site loci.

Author

Handt, Oliva, Baker, Elizabeth, Dayan, Sonia, Gartler, Stanley, Woollatt, Erica, Richards, Robert, and Hansen, R.

Abstract

The molecular basis for the cytogenetic appearance of chromosomal fragile sites is not yet understood. Late replication and further delay of replication at fragile sites expressing alleles has been observed for FRAXA, FRAXE and FRA3B fragile site loci. We analysed the timing of replication at the FRA10B and FRA16B loci to determine whether late replication is a feature which is shared by all fragile sites and, therefore, is a necessary condition for chromosomal fragile site expression. The FRA10B locus was located in a transitional region between early and late zones of replication. Fragile and non-fragile alleles exhibit a similar replication pattern proximal to the repeat, but fragile alleles are delayed relative to non-fragile ones on the distal side. Although fragility at FRA10B appears to be caused by expansion of an AT-rich repeat in the region, replication time near the repeat was similar in fragile and non-fragile alleles. The FRA16B locus was late replicating and appeared to replicate even later on fragile chromosomes. While these observations are compatible with the hypothesis that delayed replication may play a role in fragile site expression, they suggest that replication delay may not need to occur at the expanded repeat region itself in order to be permissive for fragility. [ABSTRACT FROM AUTHOR]

Published

2000

13. Replication Asynchrony Increases in Women at Risk for Aneuploid Offspring.

Author

Amiel, A., Reish, O., Gaber, E., Kedar, I., Diukman, R., and Fejgin, M.

Abstract

We attempted to demonstrate a relation between a loss of replication control, centromere dysfunction, and predisposition to non-disjunction. Couples with a Down syndrome offspring were the high-risk probands. One-color FISH (fluorescent in-situ hybridization) was applied to interphase nuclei (lymphocytes). Replication pattern of two pairs of alleles, RB-1 and 21q22, were studied, and the rate of aneuploidy was estimated using two alpha-satellite probes of chromosomes 8 and 18. Our results suggest the existence of an association between replication timing and the rate of non-disjunction. A higher rate of allele asynchrony and aneuploidy was found in older women and in mothers of a Down syndrome offspring. These findings may reflect a predisposition for meiotic non-disjunction in these women. [ABSTRACT FROM AUTHOR]

Published

2000

14. Internal modifications in the CENP-A nucleosome modulate centromeric dynamics

Author

Bui, Minh, Bui, Minh, Pitman, Mary, Nuccio, Arthur, Roque, Serene, Donlin-Asp, Paul Gregory, Nita-Lazar, Aleksandra, Papoian, Garegin A., Dalal, Yamini, Bui, Minh, Bui, Minh, Pitman, Mary, Nuccio, Arthur, Roque, Serene, Donlin-Asp, Paul Gregory, Nita-Lazar, Aleksandra, Papoian, Garegin A., and Dalal, Yamini

Abstract

Posttranslational modifications of core histones are correlated with changes in transcriptional status, chromatin fiber folding, and nucleosome dynamics. However, within the centromere-specific histone H3 variant CENP-A, few modifications have been reported, and their functions remain largely unexplored. In this multidisciplinary report, we utilize in silico computational and in vivo approaches to dissect lysine 124 of human CENP-A, which was previously reported to be acetylated in advance of replication. Computational modeling demonstrates that acetylation of K124 causes tightening of the histone core and hinders accessibility to its C-terminus, which in turn diminishes CENP-C binding. Additionally, CENP-A K124ac/H4 K79ac containing nucleosomes are prone to DNA sliding. In vivo experiments using a CENP-A acetyl or unacetylatable mimic (K124Q and K124A, respectively) reveal alterations in CENP-C levels and a modest increase in mitotic errors. Furthermore, mutation of K124 results in alterations in centromeric replication timing. Purification of native CENP-A proteins followed by mass spectrometry analysis reveals that while CENP-A K124 is acetylated at G1/S, it switches to monomethylation during early S and mid-S phases. Finally, we provide evidence implicating the histone acetyltransferase (HAT) p300 in this cycle. Taken together, our data suggest that cyclical modifications within the CENP-A nucleosome contribute to the binding of key kinetochore proteins, the integrity of mitosis, and centromeric replication. These data support the paradigm that modifications in histone variants can influence key biological processes.

Published

2017

15. Defining multiple, distinct, and shared spatiotemporal patterns of DNA replication and endoreduplication from 3D image analysis of developing maize (Zea mays L.) root tip nuclei

Author

Linda Hanley-Bowdoin, Stacey R. Joseph, Hank W. Bass, Tae-Jin Lee, George Allen, Emily E. Wear, Gregg G. Hoffman, and William F. Thompson

Subjects

0106 biological sciences, DNA Replication, Euchromatin, DNA, Plant, Heterochromatin, DNA Replication Timing, Meristem, Plant Science, Biology, Cell cycle, Genes, Plant, 01 natural sciences, Models, Biological, Zea mays, Article, S Phase, 03 medical and health sciences, Imaging, Three-Dimensional, Genetics, Endoreduplication, Gene, Mitosis, 030304 developmental biology, 2. Zero hunger, Cell Nucleus, 0303 health sciences, Replication timing, DNA synthesis, Grass, DNA replication, General Medicine, Cell biology, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Spatiotemporal patterns of DNA replication have been described for yeast and many types of cultured animal cells, frequently after cell cycle arrest to aid in synchronization. However, patterns of DNA replication in nuclei from plants or naturally developing organs remain largely uncharacterized. Here we report findings from 3D quantitative analysis of DNA replication and endoreduplication in nuclei from pulse-labeled developing maize root tips. In both early and middle S phase nuclei, flow-sorted on the basis of DNA content, replicative labeling was widely distributed across euchromatic regions of the nucleoplasm. We did not observe the perinuclear or perinucleolar replicative labeling patterns characteristic of middle S phase in mammals. Instead, the early versus middle S phase patterns in maize could be distinguished cytologically by correlating two quantitative, continuous variables, replicative labeling and DAPI staining. Early S nuclei exhibited widely distributed euchromatic labeling preferentially localized to regions with weak DAPI signals. Middle S nuclei also exhibited widely distributed euchromatic labeling, but the label was preferentially localized to regions with strong DAPI signals. Highly condensed heterochromatin, including knobs, replicated during late S phase as previously reported. Similar spatiotemporal replication patterns were observed for both mitotic and endocycling maize nuclei. These results revealed that maize euchromatin exists as an intermingled mixture of two components distinguished by their condensation state and replication timing. These different patterns might reflect a previously described genome organization pattern, with “gene islands” mostly replicating during early S phase followed by most of the intergenic repetitive regions replicating during middle S phase. Electronic supplementary material The online version of this article (doi:10.1007/s11103-015-0364-4) contains supplementary material, which is available to authorized users.

16. Epigenetic analyses in blood cells of men suspected of prostate cancer predict the outcome of biopsy better than serum PSA levels

Author

Igor Bounkin, Samuel Cytron, Evgeni Stepnov, Lydia Avivi, Aviva Dotan, and Maya Mashevich

Subjects

Oncology, PCA3, medicine.medical_specialty, Malignancy, Prostate cancer, PSA, FISH, Prostate, Internal medicine, Biopsy, Genetics, Medicine, Blood test, Molecular Biology, Genetics (clinical), medicine.diagnostic_test, business.industry, Asynchronous replication, medicine.disease, medicine.anatomical_structure, Immunology, Replication timing, Cancer biomarkers, Original Article, business, Developmental Biology, Fluorescence in situ hybridization

Abstract

Lymphocytes from the peripheral blood of patients with prostate cancer-the most frequent (noncutaneous) tumor in men-display epigenetic aberrations (altered modes of allelic replication) characteristic of the malignant phenotype. The present study aims to determine whether replication aberrations add certainty to the suspicion of prostate cancer provided by the prostate-specific antigen (PSA) blood test. The allelic replication mode (whether synchronous or asynchronous) was exemplified for RB1 and AML1. These two genes normally exhibit a synchronous mode of allelic replication. Fluorescence in situ hybridization (FISH) replication assay was used for replication analyses. The FISH assays were applied to PHA-stimulated lymphocytes, established from peripheral blood samples of 35 men referred to biopsy due to suspected prostate cancer. Following biopsy 13 out of these 35 men were found positive for prostate malignancy. The FISH assay-showing asynchronous or synchronous RB1 and AML1 replication-was able to predict, respectively, the results of all biopsy-positive men and in 18 out of the 22 biopsy-negative ones. These measurements, distinguishing biopsy-positive from biopsy-negative men, were highly significant (P 10(-8); 100% sensitivity and 81.8% specificity). Yet, distinguishing between the two groups of men based on the PSA measurements was nonsignificant (P 0.70). The FISH replication assay applied to peripheral blood lymphocytes of 35 men referred for biopsy significantly predicted the outcome of the pathological examination, more precisely than the serum PSA test. As such, the epigenetic alteration offers a potential noninvasive blood marker, complementary to the PSA, for a preliminary prostate cancer diagnosis.

17. LINEs of evidence: noncanonical DNA replication as an epigenetic determinant

Author

Ekaterina Belan

Subjects

Pluripotency, Embryonic stem cells, Immunology, L1 retrotransposon, Retrotransposon, Review, DNA replication, Biology, Origin of replication, General Biochemistry, Genetics and Molecular Biology, Mice, LINE-1, 03 medical and health sciences, 0302 clinical medicine, Neoplasms, Animals, Epigenetics, Chromatin domains, Gene, Ecology, Evolution, Behavior and Systematics, Cell Proliferation, Cancer, 030304 developmental biology, Genetics, 0303 health sciences, Replication timing, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Applied Mathematics, Cell Differentiation, RNA-Directed DNA Polymerase, Embryo, Mammalian, Reverse transcriptase, Up-Regulation, Chromatin, Long Interspersed Nucleotide Elements, Origins of replication, 030220 oncology & carcinogenesis, Modeling and Simulation, General Agricultural and Biological Sciences

Abstract

LINE-1 (L1) retrotransposons are repetitive elements in mammalian genomes. They are capable of synthesizing DNA on their own RNA templates by harnessing reverse transcriptase (RT) that they encode. Abundantly expressed full-length L1s and their RT are found to globally influence gene expression profiles, differentiation state, and proliferation capacity of early embryos and many types of cancer, albeit by yet unknown mechanisms. They are essential for the progression of early development and the establishment of a cancer-related undifferentiated state. This raises important questions regarding the functional significance of L1 RT in these cell systems. Massive nuclear L1-linked reverse transcription has been shown to occur in mouse zygotes and two-cell embryos, and this phenomenon is purported to be DNA replication independent. This review argues against this claim with the goal of understanding the nature of this phenomenon and the role of L1 RT in early embryos and cancers. Available L1 data are revisited and integrated with relevant findings accumulated in the fields of replication timing, chromatin organization, and epigenetics, bringing together evidence that strongly supports two new concepts. First, noncanonical replication of a portion of genomic full-length L1s by means of L1 RNP-driven reverse transcription is proposed to co-exist with DNA polymerase-dependent replication of the rest of the genome during the same round of DNA replication in embryonic and cancer cell systems. Second, the role of this mechanism is thought to be epigenetic; it might promote transcriptional competence of neighboring genes linked to undifferentiated states through the prevention of tethering of involved L1s to the nuclear periphery. From the standpoint of these concepts, several hitherto inexplicable phenomena can be explained. Testing methods for the model are proposed. Reviewers This article was reviewed by Dr. Philip Zegerman (nominated by Dr. Orly Alter), Dr. I. King Jordan, and Dr. Panayiotis (Takis) Benos. For the complete reviews, see the Reviewers’ Reports section.

18. Differences in the epigenetic and reprogramming properties of pluripotent and extra-embryonic stem cells implicate chromatin remodelling as an important early event in the developing mouse embryo

Author

Matthias Merkenschlager, Véronique Azuara, Aida Di-Gregorio, C. Filipe Pereira, Joana Santos, Amanda G. Fisher, Thomas Spruce, Olivia Alder, Tristan A. Rodriguez, and Biotechnology and Biological Sciences Research Council (BBSRC)

Subjects

lcsh:QH426-470, Biology, IMPRINTED X-INACTIVATION, E-CADHERIN, Genetics, TROPHECTODERM, Epigenetics, TRANSCRIPTION, Molecular Biology, GENE-EXPRESSION, Genetics & Heredity, Replication timing, 0604 Genetics, Science & Technology, Research, DEVELOPMENTAL REGULATORS, DNA-REPLICATION, VISCERAL ENDODERM, Embryonic stem cell, Chromatin, lcsh:Genetics, Histone, DIFFERENTIATION, DNA methylation, biology.protein, Stem cell, ES CELLS, Reprogramming, Life Sciences & Biomedicine

Abstract

Background During early mouse development, two extra-embryonic lineages form alongside the future embryo: the trophectoderm (TE) and the primitive endoderm (PrE). Epigenetic changes known to take place during these early stages include changes in DNA methylation and modified histones, as well as dynamic changes in gene expression. Results In order to understand the role and extent of chromatin-based changes for lineage commitment within the embryo, we examined the epigenetic profiles of mouse embryonic stem (ES), trophectoderm stem (TS) and extra-embryonic endoderm (XEN) stem cell lines that were derived from the inner cell mass (ICM), TE and PrE, respectively. As an initial indicator of the chromatin state, we assessed the replication timing of a cohort of genes in each cell type, based on data that expressed genes and acetylated chromatin domains, generally, replicate early in S-phase, whereas some silent genes, hypoacetylated or condensed chromatin tend to replicate later. We found that many lineage-specific genes replicate early in ES, TS and XEN cells, which was consistent with a broadly 'accessible' chromatin that was reported previously for multiple ES cell lines. Close inspection of these profiles revealed differences between ES, TS and XEN cells that were consistent with their differing lineage affiliations and developmental potential. A comparative analysis of modified histones at the promoters of individual genes showed that in TS and ES cells many lineage-specific regulator genes are co-marked with modifications associated with active (H4ac, H3K4me2, H3K9ac) and repressive (H3K27me3) chromatin. However, in XEN cells several of these genes were marked solely by repressive modifications (such as H3K27me3, H4K20me3). Consistent with TS and XEN having a restricted developmental potential, we show that these cells selectively reprogramme somatic cells to induce the de novo expression of genes associated with extraembryonic differentiation. Conclusions These data provide evidence that the diversification of defined embryonic and extra-embryonic lineages is accompanied by chromatin remodelling at specific loci. Stem cell lines from the ICM, TE and PrE can each dominantly reprogramme somatic cells but reset gene expression differently, reflecting their separate lineage identities and increasingly restricted developmental potentials.

19. Compositional patterns in the genomes of unicellular eukaryotes

Author

Rosalia Cammarano, Fernando Alvarez-Valin, Susan Costantini, Giorgio Bernardi, and Maria Costantini

Subjects

Biology, Genome, 03 medical and health sciences, 0302 clinical medicine, Phylogenetics, Genetics, Gene, Phylogeny, 030304 developmental biology, 0303 health sciences, Replication timing, Base Composition, Phylogenetic tree, Models, Genetic, Unicellular eukaryotes, Eukaryota, DNA, Chromatin, Multicellular organism, Evolutionary biology, Compositional organization, DNA microarray, Isochores, 030217 neurology & neurosurgery, Research Article, Biotechnology

Abstract

Background The genomes of multicellular eukaryotes are compartmentalized in mosaics of isochores, large and fairly homogeneous stretches of DNA that belong to a small number of families characterized by different average GC levels, by different gene concentration (that increase with GC), different chromatin structures, different replication timing in the cell cycle, and other different properties. A question raised by these basic results concerns how far back in evolution the compartmentalized organization of the eukaryotic genomes arose. Results In the present work we approached this problem by studying the compositional organization of the genomes from the unicellular eukaryotes for which full sequences are available, the sample used being representative. The average GC levels of the genomes from unicellular eukaryotes cover an extremely wide range (19%-60% GC) and the compositional patterns of individual genomes are extremely different but all genomes tested show a compositional compartmentalization. Conclusions The average GC range of the genomes of unicellular eukaryotes is very broad (as broad as that of prokaryotes) and individual compositional patterns cover a very broad range from very narrow to very complex. Both features are not surprising for organisms that are very far from each other both in terms of phylogenetic distances and of environmental life conditions. Most importantly, all genomes tested, a representative sample of all supergroups of unicellular eukaryotes, are compositionally compartmentalized, a major difference with prokaryotes.

20. Murine esBAF chromatin remodeling complex subunits BAF250a and Brg1 are necessary to maintain and reprogram pluripotency-specific replication timing of select replication domains

Author

Zhong Wang, Peng Fang, Xiaolin Gao, Yong Fan, Tyrone Ryba, Dana Battaglia, Miguel A. Esteban, Gerald R. Crabtree, David M. Gilbert, Vishnu Dileep, Takayo Sasaki, Jiong Tang, Ienglam Lei, and Shin-ichiro Takebayashi

Subjects

Genetics, 0303 health sciences, Replication timing, Developmental regulation, Research, 030302 biochemistry & molecular biology, Eukaryotic DNA replication, Biology, Chromosome, Pre-replication complex, Replication domains, Cell biology, DNA replication factor CDT1, 03 medical and health sciences, Licensing factor, Control of chromosome duplication, Minichromosome maintenance, biology.protein, Origin recognition complex, esBAF complex, Molecular Biology, 030304 developmental biology

Abstract

Background Cellular differentiation and reprogramming are accompanied by changes in replication timing and 3D organization of large-scale (400 to 800 Kb) chromosomal domains (‘replication domains’), but few gene products have been identified whose disruption affects these properties. Results Here we show that deletion of esBAF chromatin-remodeling complex components BAF250a and Brg1, but not BAF53a, disrupts replication timing at specific replication domains. Also, BAF250a-deficient fibroblasts reprogrammed to a pluripotency-like state failed to reprogram replication timing in many of these same domains. About half of the replication domains affected by Brg1 loss were also affected by BAF250a loss, but a much larger set of domains was affected by BAF250a loss. esBAF binding in the affected replication domains was dependent upon BAF250a but, most affected domains did not contain genes whose transcription was affected by loss of esBAF. Conclusions Loss of specific esBAF complex subunits alters replication timing of select replication domains in pluripotent cells.

21. The impact of chromatin modifiers on the timing of locus replication in mouse embryonic stem cells

Author

Helle F. Jørgensen, Anna Terry, Tatyana B. Nesterova, Bernard Ramsahoye, Mikhail Spivakov, Shannon Amoils, Bradley S. Cobb, Véronique Azuara, Amanda G. Fisher, Matthias Merkenschlager, and Medical Research Council (MRC)

Subjects

DNA Replication, Bioinformatics, 05 Environmental Sciences, RIBOSOMAL-RNA GENES, Eukaryotic DNA replication, Biology, SATELLITE REPEATS, DNA, Satellite, Chromatin remodeling, H3 LYSINE-9 METHYLATION, Cell Line, S Phase, Histones, Mice, Control of chromosome duplication, Histone code, Animals, Embryonic Stem Cells, Genetics, Genetics & Heredity, Replication timing, Science & Technology, MLL-MUTANT MICE, POLYCOMB-GROUP GENE, Research, DNA-REPLICATION, Gene Expression Regulation, Developmental, NEURAL INDUCTION, Acetylation, DNA Methylation, 06 Biological Sciences, Chromatin, S-PHASE, Biotechnology & Applied Microbiology, HISTONE ACETYLATION, Mutation, Origin recognition complex, 08 Information and Computing Sciences, PERICENTRIC HETEROCHROMATIN, Life Sciences & Biomedicine, Bivalent chromatin

Abstract

A panel of mutant embryonic stem (ES) cell lines lacking important chromatin modifiers was used to dissect the relationship between chromatin structure and replication timing, revealing the importance of several chromatin modifiers for maintaining correct replication of satellite sequences in pluripotent ES cells., Background The time of locus replication during S-phase is tightly regulated and correlates with chromatin state. Embryonic stem (ES) cells have an unusual chromatin profile where many developmental regulator genes that are not yet expressed are marked by both active and repressive histone modifications. This poised or bivalent state is also characterized by locus replication in early S-phase in ES cells, while replication timing is delayed in cells with restricted developmental options. Results Here we used a panel of mutant mouse ES cell lines lacking important chromatin modifiers to dissect the relationship between chromatin structure and replication timing. We show that temporal control of satellite DNA replication is sensitive to loss of a variety of chromatin modifiers, including Mll, Eed, Dnmt1, Suv39h1/h2 and Dicer. The replication times of many single copy loci, including a 5 Mb contiguous region surrounding the Rex1 gene, were retained in chromatin modifier mutant ES cells, although a subset of loci were affected. Conclusion This analysis demonstrates the importance of chromatin modifiers for maintaining correct replication of satellite sequences in pluripotent ES cells and highlights the sensitivity of some single copy loci to the influence of chromatin modifiers. Abundant histone acetylation is shown to correlate well with early replication. Surprisingly, loss of DNA methylation or histone methylation was tolerated by many loci, suggesting that these modifications may be less influential for the timing of euchromatin replication.

22. The evolution of isochore patterns in vertebrate genomes

Author

Rosalia Cammarano, Giorgio Bernardi, and Maria Costantini

Subjects

Genome evolution, lcsh:QH426-470, lcsh:Biotechnology, Genome, Evolution, Molecular, 03 medical and health sciences, Species Specificity, lcsh:TP248.13-248.65, biology.animal, Gene density, Genetics, Animals, Humans, 030304 developmental biology, 0303 health sciences, Replication timing, Natural selection, biology, 030302 biochemistry & molecular biology, Vertebrate, Chromosome, GC Rich Sequence, lcsh:Genetics, Vertebrates, Human genome, Isochores, Research Article, Biotechnology

Abstract

Background Previous work from our laboratory showed that (i) vertebrate genomes are mosaics of isochores, typically megabase-size DNA segments that are fairly homogeneous in base composition; (ii) isochores belong to a small number of families (five in the human genome) characterized by different GC levels; (iii) isochore family patterns are different in fishes/amphibians and mammals/birds, the latter showing GC-rich isochore families that are absent or very scarce in the former; (iv) there are two modes of genome evolution, a conservative one in which isochore patterns basically do not change (e.g., among mammalian orders), and a transitional one, in which they do change (e.g., between amphibians and mammals); and (v) isochores are tightly linked to a number of basic biological properties, such as gene density, gene expression, replication timing and recombination. Results The present availability of a number of fully sequenced genomes ranging from fishes to mammals allowed us to carry out investigations that (i) more precisely quantified our previous conclusions; (ii) showed that the different isochore families of vertebrate genomes are largely conserved in GC levels and dinucleotide frequencies, as well as in isochore size; and (iii) isochore family patterns can be either conserved or change within both warm- and cold-blooded vertebrates. Conclusion On the basis of the results presented, we propose that (i) the large conservation of GC levels and dinucleotide frequencies may reflect the conservation of chromatin structures; (ii) the conservation of isochore size may be linked to the role played by isochores in chromosome structure and replication; (iii) the formation, the maintainance and the changes of isochore patterns are due to natural selection.