Gene repositioning within the cell nucleus is not random and is determined by its genomic neighborhood.

BACKGROUND: Heterochromatin has been reported to be a major silencing compartment during development and differentiation. Prominent heterochromatin compartments are located at the nuclear periphery and inside the nucleus (e.g., pericentric heterochromatin). Whether the position of a gene in relation to some or all heterochromatin compartments matters remains a matter of debate, which we have addressed in this study. Answering this question demanded solving the technical challenges of 3D measurements and the large-scale morphological changes accompanying cellular differentiation. RESULTS: Here, we investigated the proximity effects of the nuclear periphery and pericentric heterochromatin on gene expression and additionally considered the effect of neighboring genomic features on a gene's nuclear position. Using a well-established myogenic in vitro differentiation system and a differentiation-independent heterochromatin remodeling system dependent on ectopic MeCP2 expression, we first identified genes with statistically significant expression changes by transcriptional profiling. We identified nuclear gene positions by 3D fluorescence in situ hybridization followed by 3D distance measurements toward constitutive and facultative heterochromatin domains. Single-cell-based normalization enabled us to acquire morphologically unbiased data and we finally correlated changes in gene positioning to changes in transcriptional profiles. We found no significant correlation of gene silencing and proximity to constitutive heterochromatin and a rather unexpected inverse correlation of gene activity and position relative to facultative heterochromatin at the nuclear periphery. CONCLUSION: In summary, our data question the hypothesis of heterochromatin as a general silencing compartment. Nonetheless, compared to a simulated random distribution, we found that genes are not randomly located within the nucleus. An analysis of neighboring genomic context revealed that gene location within the nucleus is rather dependent on CpG islands, GC content, gene density, and short and long interspersed nuclear elements, collectively known as RIDGE (regions of increased gene expression) properties. Although genes do not move away/to the heterochromatin upon up-/down-regulation, genomic regions with RIDGE properties are generally excluded from peripheral heterochromatin. Hence, we suggest that individual gene activity does not influence gene positioning, but rather chromosomal context matters for sub-nuclear location.

Positional changes of a pluripotency marker gene during structural reorganization of fibroblast nuclei in cloned early bovine embryos.

Cloned bovine preimplantation embryos were generated by somatic cell nuclear transfer (SCNT) of bovine fetal fibroblasts with a silent copy of the pluripotency reporter gene GOF, integrated at a single site of a chromosome 13. GOF combines the regulatory Oct4/Pou5f1 sequence with the coding sequence for EGFP. EGFP expression served as a marker for pluripotency gene activation and was consistently detected in preimplantation embryos with 9 and more cells. Three-dimensional radial nuclear positions of GOF, its carrier chromosome territory and non-carrier homolog were measured in nuclei of fibroblasts, and of day 2 and day 4 embryos, carrying 2 to 9 and 15 to 22 cells, respectively. We tested, whether transcriptional activation was correlated with repositioning of GOF toward the nuclear interior either with a corresponding movement of its carrier chromosome territory 13 or via the formation of a giant chromatin loop. A significant shift of GOF away from the nuclear periphery was observed in day 2 embryos together with both carrier and non-carrier chromosome territories. At day 4, GOF, its carrier chromosome territory 13 and the non-carrier homolog had moved back toward the nuclear periphery. Similar movements of both chromosome territories ruled out a specific GOF effect. Pluripotency gene activation was preceded by a transient, radial shift of GOF toward the nuclear interior. The persistent co-localization of GOF with its carrier chromosome territory rules out the formation of a giant chromatin loop during GOF activation.

Reprogramming of fibroblast nuclei in cloned bovine embryos involves major structural remodeling with both striking similarities and differences to nuclear phenotypes of in vitro fertilized embryos.

Nuclear landscapes were studied during preimplantation development of bovine embryos, generated either by in vitro fertilization (IVF), or generated as cloned embryos by somatic cell nuclear transfer (SCNT) of bovine fetal fibroblasts, using 3-dimensional confocal laser scanning microscopy (3D-CLSM) and structured illumination microscopy (3D-SIM). Nuclear landscapes of IVF and SCNT embryonic nuclei were compared with each other and with fibroblast nuclei. We demonstrate that reprogramming of fibroblast nuclei in cloned embryos requires changes of their landscapes similar to nuclei of IVF embryos. On the way toward the 8-cell stage, where major genome activation occurs, a major lacuna, enriched with splicing factors, was formed in the nuclear interior and chromosome territories (CTs) were shifted toward the nuclear periphery. During further development the major lacuna disappeared and CTs were redistributed throughout the nuclear interior forming a contiguous higher order chromatin network. At all stages of development CTs of IVF and SCNT embryonic nuclei were built up from chromatin domain clusters (CDCs) pervaded by interchromatin compartment (IC) channels. Quantitative analyses revealed a highly significant enrichment of RNA polymerase II and H3K4me3, a marker for transcriptionally competent chromatin, at the periphery of CDCs. In contrast, H3K9me3, a marker for silent chromatin, was enriched in the more compacted interior of CDCs. Despite these striking similarities, we also detected major differences between nuclear landscapes of IVF and cloned embryos. Possible implications of these differences for the developmental potential of cloned animals remain to be investigated. We present a model, which integrates generally applicable structural and functional features of the nuclear landscape.

MeCP2 Rett mutations affect large scale chromatin organization.

Rett syndrome is a neurological, X chromosomal-linked disorder associated with mutations in the MECP2 gene. MeCP2 protein has been proposed to play a role in transcriptional regulation as well as in chromatin architecture. Since MeCP2 mutant cells exhibit surprisingly mild changes in gene expression, we have now explored the possibility that Rett mutations may affect the ability of MeCP2 to bind and organize chromatin. We found that all but one of the 21 missense MeCP2 mutants analyzed accumulated at heterochromatin and about half of them were significantly affected. Furthermore, two-thirds of all mutants showed a significantly decreased ability to cluster heterochromatin. Three mutants containing different proline substitutions (P101H, P101R and P152R) were severely affected only in heterochromatin clustering and located far away from the DNA interface in the MeCP2 methyl-binding domain structure. MeCP2 mutants affected in heterochromatin accumulation further exhibited the shortest residence time on heterochromatin, followed by intermediate binding kinetics for clustering impaired mutants. We propose that different interactions of MeCP2 with methyl cytosines, DNA and likely other heterochromatin proteins are required for MeCP2 function and their dysfunction lead to Rett syndrome.

Histone acetylation controls the inactive X chromosome replication dynamics.

In mammals, dosage compensation between male and female cells is achieved by inactivating one female X chromosome (Xi). Late replication of Xi was proposed to be involved in the maintenance of its silenced state. Here, we show a highly synchronous replication of the Xi within 1 to 2 h during early-mid S-phase by following DNA replication in living mammalian cells with green fluorescent protein-tagged replication proteins. The Xi was replicated before or concomitant with perinuclear or perinucleolar facultative heterochromatin and before constitutive heterochromatin. Ectopic expression of the X-inactive-specific transcript (Xist) gene from an autosome imposed the same synchronous replication pattern. We used mutations and chemical inhibition affecting different epigenetic marks as well as inducible Xist expression and we demonstrate that histone hypoacetylation has a key role in controlling Xi replication. The epigenetically controlled, highly coordinated replication of the Xi is reminiscent of embryonic genome replication in flies and frogs before genome activation and might be a common feature of transcriptionally silent chromatin.

FISH on 3D preserved bovine and murine preimplantation embryos.

Fluorescence in situ hybridization (FISH) is a commonly used technique for the visualization of whole chromosomes or subchromosomal regions, such as chromosome arms, bands, centromeres, or single gene loci. FISH is routinely performed on chromosome spreads, as well as on three-dimensionally preserved cells or tissues (3D FISH). We have developed 3D FISH protocol for mammalian preimplantation embryos to investigate the nuclear organization of chromosome territories and subchromosomal regions during the first developmental stages. In contrast to cells, embryos have much more depth and their nuclei are therefore less accessible to probes used to visualize specific genomic regions by FISH. The present protocol was developed to establish a balance between sufficient embryo permeabilization and maximum preservation of nuclear morphology.

Reprogramming of active and repressive histone modifications following nuclear transfer with rabbit mesenchymal stem cells and adult fibroblasts.

Following nuclear transfer (NT) the epigenetic state of a donor nucleus must be reprogrammed to an embryonic one. To evaluate the efficiency of nuclear reprogramming, we monitored the levels of histone H3 di/tri-methylated on lysine 4 (H3K4m2/3), a marker for transcriptionally active/permissive euchromatin, and of histone H3 tri-methylated on lysine 27 (H3K27m3), a modification associated with facultative heterochromatin, in embryos cloned using rabbit mesenchymal stem cells (MSC) and adult fibroblasts (RAF) isolated from the same animals. In vivo fertilized, in vitro cultured embryos served as controls. H3K27m3 was undetectable in all stages of control embryos except for weak staining in a few blastocyst cells. A similar situation was found in all NT embryos irrespective of the type of donor cells used, although both MSC and RAF stained substantially for H3K27m3. H3K4m2/3 levels were very high in one- and two-cell control embryos, but then decreased to reach a minimum at the eight-cell stage, and finally increased again to initial levels at the morula and blastocyst stage. Reprogramming of H3K4m2/3 differed remarkably among the different types NT embryos as well as between NT embryos and control embryos, and was apparently dependent on the type of donor cells. Interestingly, abnormal reprogramming of H3K4m2/3 was observed in NT embryos derived from both MSC and RAF, donor cell types with markedly different proliferation capacity. Our study demonstrates that the repressive chromatin modification, H3K27m3, is faithfully reprogrammed in NT embryos derived from MSC or RAF, while reprogramming of the activating chromatin modification, H3K4m2/3, is quite variable and does not reflect the situation observed in control embryos derived by fertilization.

Changes of higher order chromatin arrangements during major genome activation in bovine preimplantation embryos.

Gene-dense chromosome territories (CTs) are typically located more interior, gene-poor CTs more peripheral in mammalian cell nuclei. Here, we show that this gene-density correlated CT positioning holds for the most gene-rich and gene-poor bovine chromosomes 19 and 20, respectively, in bovine fibroblast and lymphocyte nuclei. In order to determine the period at which this non-random CT order is established during development, we performed fluorescence in situ hybridization, on three-dimensionally preserved bovine preimplantation embryos generated by in vitro fertilization and investigated the distribution of BTA 19 and 20 CTs. Radial arrangements of CTs 19 and 20 were the same up to the 8-cell stage. At the 10- to 16-cell stage, however, a significant difference became apparent with CTs 19 localized more internally and CTs 20 more peripherally. Since major genome activation in bovine embryos occurs at the 8- to 16-cell stage, our findings demonstrate a temporal correlation between transcriptional activation and a major rearrangement of chromatin topography in blastomere nuclei.

MeCP2 interacts with HP1 and modulates its heterochromatin association during myogenic differentiation.

There is increasing evidence of crosstalk between epigenetic modifications such as histone and DNA methylation, recognized by HP1 and methyl CpG-binding proteins, respectively. We have previously shown that the level of methyl CpG-binding proteins increased dramatically during myogenesis leading to large-scale heterochromatin reorganization. In this work, we show that the level of HP1 isoforms did not change significantly throughout myogenic differentiation but their localization did. In particular, HP1gamma relocalization to heterochromatin correlated with MeCP2 presence. Using co-immunoprecipitation assays, we found that these heterochromatic factors interact in vivo via the chromo shadow domain of HP1 and the first 55 amino acids of MeCP2. We propose that this dynamic interaction of HP1 and MeCP2 increases their concentration at heterochromatin linking two major gene silencing pathways to stabilize transcriptional repression during differentiation.

Cell Preparation and Multicolor FISH in 3D Preserved Cultured Mammalian Cells.

INTRODUCTIONFluorescence in situ hybridization (FISH) on three-dimensional preserved nuclei (3D-FISH) in combination with three-dimensional-microscopy and image reconstruction is an efficient tool to analyze the arrangement of distinct nuclear targets such as entire chromosome territories, chromosomal subregions, or single gene loci on a single-cell level. This protocol focuses on fixation, pretreatments, and 3D-FISH on cultured mammalian cells. It can be applied to a variety of cell types growing adherently or in suspension.

Common themes and cell type specific variations of higher order chromatin arrangements in the mouse.

BACKGROUND: Similarities as well as differences in higher order chromatin arrangements of human cell types were previously reported. For an evolutionary comparison, we now studied the arrangements of chromosome territories and centromere regions in six mouse cell types (lymphocytes, embryonic stem cells, macrophages, fibroblasts, myoblasts and myotubes) with fluorescence in situ hybridization and confocal laser scanning microscopy. Both species evolved pronounced differences in karyotypes after their last common ancestors lived about 87 million years ago and thus seem particularly suited to elucidate common and cell type specific themes of higher order chromatin arrangements in mammals. RESULTS: All mouse cell types showed non-random correlations of radial chromosome territory positions with gene density as well as with chromosome size. The distribution of chromosome territories and pericentromeric heterochromatin changed during differentiation, leading to distinct cell type specific distribution patterns. We exclude a strict dependence of these differences on nuclear shape. Positional differences in mouse cell nuclei were less pronounced compared to human cell nuclei in agreement with smaller differences in chromosome size and gene density. Notably, the position of chromosome territories relative to each other was very variable. CONCLUSION: Chromosome territory arrangements according to chromosome size and gene density provide common, evolutionary conserved themes in both, human and mouse cell types. Our findings are incompatible with a previously reported model of parental genome separation.

Methyl CpG-binding proteins induce large-scale chromatin reorganization during terminal differentiation.

Pericentric heterochromatin plays an important role in epigenetic gene regulation. We show that pericentric heterochromatin aggregates during myogenic differentiation. This clustering leads to the formation of large chromocenters and correlates with increased levels of the methyl CpG-binding protein MeCP2 and pericentric DNA methylation. Ectopic expression of fluorescently tagged MeCP2 mimicked this effect, causing a dose-dependent clustering of chromocenters in the absence of differentiation. MeCP2-induced rearrangement of heterochromatin occurred throughout interphase, did not depend on the H3K9 histone methylation pathway, and required the methyl CpG-binding domain (MBD) only. Similar to MeCP2, another methyl CpG-binding protein, MBD2, also increased during myogenic differentiation and could induce clustering of pericentric regions, arguing for functional redundancy. This MeCP2- and MBD2-mediated chromatin reorganization may thus represent a molecular link between nuclear genome topology and the epigenetic maintenance of cellular differentiation.

Three-dimensional arrangements of centromeres and telomeres in nuclei of human and murine lymphocytes.

The location of centromeres and telomeres was studied in human and mouse lymphocyte nuclei (G0) employing 3D-FISH, confocal microscopy, and quantitative image analysis. In both human and murine lymphocytes, most centromeres were found in clusters at the nuclear periphery. The distribution of telomere clusters, however, differed: in mouse nuclei, most clusters were detected at the nuclear periphery, while, in human nuclei, most clusters were located in the nuclear interior. In human cell nuclei we further studied the nuclear location of individual centromeres and their respective chromosome territories (CTs) for chromosomes 1, 11, 12, 15, 17, 18, 20, and X. We found a peripheral location of both centromeres and CTs for 1, 11, 12, 18, X. A mostly interior nuclear location was observed for CTs 17 and 20 and the CTs of the NOR-bearing acrocentric 15 but the corresponding centromeres were still positioned in the nuclear periphery. Autosomal centromeres, as well as the centromere of the active X, were typically located at the periphery of the respective CTs. In contrast, in about half of the inactive X-CTs, the centromere was located in the territory interior. While the centromere of the active X often participated in the formation of centromere clusters, such a participation was never observed for the centromere of the inactive X.