Conserved gene order at the nuclear periphery in Drosophila

Whether higher-order chromatin organization is related to genome stability over evolutionary time remains elusive. We find that regions of conserved gene order across the genus Drosophila are larger if they harbor genes bound by B-type lamin (Lam) and Suppressor of Under-Replication (SUUR), two proteins located at the nuclear periphery. Low recombination rates and coexpression of genes in regions of conserved gene order do not explain the lower probability of disruption in these regions by genome rearrangements. Instead, we find a significant colocalization between evolutionarily stable genomic regions associated with Lam and sequences thought to regulate local gene expression, which have the potential to impose constraints on genome rearrangement. At least in the genus Drosophila, localization of particular genomic regions at the nuclear periphery is intimately associated with their long-term integrity during evolution.     

Coordinate gene regulation during hematopoiesis is related to genomic organization

Gene loci are found in nuclear subcompartments that are related to their expression status. For instance, silent genes are often localized to heterochromatin and the nuclear periphery, whereas active genes tend to be found in the nuclear center. Evidence also suggests that chromosomes may be specifically positioned within the nucleus; however, the nature of this organization and how it is achieved are not yet fully understood. To examine whether gene regulation is related to a discernible pattern of genomic organization, we analyzed the linear arrangement of co-regulated genes along chromosomes and determined the organization of chromosomes during the differentiation of a hematopoietic progenitor to erythroid and neutrophil cell types. Our analysis reveals that there is a significant tendency for co-regulated genes to be proximal, which is related to the association of homologous chromosomes and the spatial juxtaposition of lineage-specific gene domains. We suggest that proximity in the form of chromosomal gene distribution and homolog association may be the basis for organizing the genome for coordinate gene regulation during cellular differentiation.     

Active genes at the nuclear pore complex

The nucleus is spatially and functionally organized and its architecture is now seen as a key contributor to genome functions. A central component of this architecture is the nuclear envelope, which is studded with nuclear pore complexes that serve as gateways for communication between the nucleoplasm and cytoplasm. Although the nuclear periphery has traditionally been described as a repressive compartment and repository for gene-poor chromosome regions, several recent studies in yeast have demonstrated that repressive and activating domains can both be positioned at the periphery of the nucleus. Moreover, association with the nuclear envelope favors the expression of particular genes, demonstrating that nuclear organization can play an active role in gene regulation.     

The nuclear lamina and heterochromatin: a complex relationship

In metazoan cells, the heterochromatin is generally localized at the nuclear periphery, whereas active genes are preferentially found in the nuclear interior. In the present paper, we review current evidence showing that components of the nuclear lamina interact directly with heterochromatin, which implicates the nuclear lamina in a mechanism of specific gene retention at the nuclear periphery and release to the nuclear interior upon gene activation. We also discuss recent data showing that mutations in lamin proteins affect gene positioning and expression, providing a potential mechanism for how these mutations lead to tissue-specific diseases.     

The nuclear envelope protein emerin binds directly to histone deacetylase 3 (HDAC3) and activates HDAC3 activity

Organization of the genome is critical for maintaining cell-specific gene expression, ensuring proper cell function. It is well established that the nuclear lamina preferentially associates with repressed chromatin. However, the molecular mechanisms underlying repressive chromatin formation and maintenance at the nuclear lamina remain poorly understood. Here we show that emerin binds directly to HDAC3, the catalytic subunit of the nuclear co-repressor (NCoR) complex, and recruits HDAC3 to the nuclear periphery. Emerin binding stimulated the catalytic activity of HDAC3, and emerin-null cells exhibit increased H4K5 acetylation, which is the preferred target of the NCoR complex. Emerin-null cells exhibit an epigenetic signature similar to that seen in HDAC3-null cells. Emerin-null cells also had significantly less HDAC3 at the nuclear lamina. Collectively, these data support a model whereby emerin facilitates repressive chromatin formation at the nuclear periphery by increasing the catalytic activity of HDAC3.     

Using molecular tethering to analyze the role of nuclear compartmentalization in the regulation of mammalian gene activity

The mammalian nucleus has a complex structural organization that dynamically interacts with the genome. Chromatin is organized into discrete domains by association with distinct nuclear compartments enriched in structural and regulatory proteins. Growing evidence suggests that gene activity is modulated by interactions with these sub-nuclear compartments. Therefore, analyzing how nuclear architecture controls genome activity will be necessary to fully understand complex biological processes such as development and disease. In this article we describe a molecular methodology involving inducible tethering that can be used to position genes at the inner nuclear membrane (INM)-lamina compartment. The consequences of such directed re-positioning on gene activity or other DNA transactions can then be analyzed. This approach can be generalized and extended to position genes or chromosomal domains within other nuclear compartments thereby greatly facilitating the analysis of nuclear structure and its impact on genome activity.