Does CTCF mediate between nuclear organization and gene expression?

The multifunctional zinc‐finger protein CCCTC‐binding factor (CTCF) is a very strong candidate for the role of coordinating the expression level of coding sequences with their three‐dimensional position in the nucleus, apparently responding to a “code” in the DNA itself. Dynamic interactions between chromatin fibers in the context of nuclear architecture have been implicated in various aspects of genome functions. However, the molecular basis of these interactions still remains elusive and is a subject of intense debate. Here we discuss the nature of CTCF‐DNA interactions, the CTCF‐binding specificity to its binding sites and the relationship between CTCF and chromatin, and we examine data linking CTCF with gene regulation in the three‐dimensional nuclear space. We discuss why these features render CTCF a very strong candidate for the role and propose a unifying model, the “CTCF code,” explaining the mechanistic basis of how the information encrypted in DNA may be interpreted by CTCF into diverse nuclear functions.     

Nuclear architecture by RNA

The dynamic organization of the cell nucleus into subcompartments with distinct biological activities represents an important determinant of cell function. Recent studies point to a crucial role of RNA as an architectural factor for shaping the genome and its nuclear environment. Here, we outline general principles by which RNA organizes functionally different nuclear subcompartments in mammalian cells. RNA is a structural component of mobile DNA-free nuclear bodies like paraspeckles or Cajal bodies, and is involved in establishing specific chromatin domains. The latter group comprises largely different structures that require RNA for the formation of active or repressive chromatin compartments with respect to gene expression as well as separating boundaries between these.     

Chromatin mechanisms in genomic imprinting

Mammalian imprinted genes are clustered in chromosomal domains. Their mono-allelic, parent-of-origin-specific expression is regulated by imprinting control regions (ICRs), which are essential sequence elements marked by DNA methylation on one of the two parental alleles. These methylation “imprints” are established during gametogenesis and, after fertilization, are somatically maintained throughout development. Nonhistone proteins and histone modifications contribute to this epigenetic process. The way ICRs mediate imprinted gene expression differs between domains. At some domains, for instance, ICRs produce long noncoding RNAs that mediate chromatin silencing. Lysine methylation on histone H3 is involved in this developmental process and is particularly important for imprinting in the placenta and brain. Together, the newly discovered chromatin mechanisms provide further clues for addressing imprinting-related pathologies in humans.     

Dynamic genome architecture in the nuclear space: regulation of gene expression in three dimensions

The regulation of gene expression is mediated by interactions between chromatin and protein complexes. The importance of where and when these interactions take place in the nucleus is currently a subject of intense investigation. Increasing evidence indicates that gene activation or silencing is often associated with repositioning of the locus relative to nuclear compartments and other genomic loci. At the same time, however, structural constraints impose limits on chromatin mobility. Understanding how the dynamic nature of the positioning of genetic material in the nuclear space and the higher-order architecture of the nucleus are integrated is therefore essential to our overall understanding of gene regulation.     

Epigenetic gene regulation by noncoding RNAs

Functional noncoding RNAs have distinct roles in epigenetic gene regulation. Large RNAs have been shown to control gene expression from a single locus (Tsix RNA), from chromosomal regions (Air RNA), and from entire chromosomes (roX and Xist RNAs). These RNAs regulate genes in cis; although the Drosophila roX RNAs can also function in trans. The chromatin modifications mediated by these RNAs can increase or decrease gene expression. These results suggest that the primary role of RNA molecules in epigenetic gene regulation is to restrict chromatin modifications to particular regions of the genome. However, given that RNA has been shown to be at the catalytic core of other ribonucleoprotein complexes, it is also possible that RNA also plays a role in modulating changes in chromatin structure.     

The role of CTCF in coordinating the expression of single gene loci

The CCCTC-binding factor (CTCF), which binds insulator elements in vertebrates, also facilitates coordinated gene expression at several gene clusters, including the β-globin, Igf2/H19 (insulin like growth factor 2/H19 noncoding RNA), and major histocompatibility complex (MHC) class II loci. CTCF controls expression of these genes both by enabling insulator function and facilitating higher order chromatin interactions. While the role of CTCF in gene regulation is best studied at these multi-gene loci, there is also evidence that CTCF contributes to the regulated expression of single genes. Here, we discuss how CTCF participates in coordinating gene expression at the CFTR (cystic fibrosis transmembrane conductance regulator) and IFNG (interferon-gamma) loci. We consider the structural similarities between the loci with regard to CTCF-binding elements, the possible interaction between nuclear receptors and CTCF, and the role of CTCF in chromatin looping at these genes. These comparisons reveal a functional model that may be applicable to other single-gene loci that require CTCF for coordinated gene expression.     

"Chromatomics" the analysis of the chromatome

Chromatin is a highly complex mixture of proteins and DNA that is involved in the regulation and coordination of gene expression within the eukaryotic nucleus. Changes in chromatin structure can convey heritable changes of gene activity in response to external stimuli without altering the primary DNA sequence. This epigenetic inheritance of particular traits very likely plays a major role during evolutionary processes. It is however, still ill-defined how this non DNA-mediated inheritance is accomplished at a molecular level. The advent of new methods to systematically study genome-wide changes in chromatin condensation, DNA methylation levels, RNA synthesis and the association of specific proteins or protein modifications now allows a thorough investigation of changes in chromatin structure and function in response to environmental alterations. We would like to review some of these global approaches and to introduce the term "chromatomics" for the systematic analysis of the DNA, RNA and protein content of the genetic material in the eukaryotic nucleus.     

NuMA interaction with chromatin is vital for proper chromosome decondensation at the mitotic exit

NuMA is an abundant long coiled-coil protein that plays a prominent role in spindle organization during mitosis. In interphase, NuMA is localized to the nucleus and hypothesized to control gene expression and chromatin organization. However, because of the prominent mitotic phenotype upon NuMA loss, its precise function in the interphase nucleus remains elusive. Here, we report that NuMA is associated with chromatin in interphase and prophase but released upon nuclear envelope breakdown (NEBD) by the action of Cdk1. We uncover that NuMA directly interacts with DNA via evolutionarily conserved sequences in its C-terminus. Notably, the expression of the DNA-binding–deficient mutant of NuMA affects chromatin decondensation at the mitotic exit, and nuclear shape in interphase. We show that the nuclear shape defects observed upon mutant NuMA expression are due to its potential to polymerize into higher-order fibrillar structures. Overall, this work establishes the spindle-independent function of NuMA in choreographing proper chromatin decompaction and nuclear shape by directly associating with the DNA.     

Joining the loops: beta-globin gene regulation

The mammalian beta-globin locus is a multigene locus containing several globin genes and a number of regulatory elements. During development, the expression of the genes changes in a process called "switching." The most important regulatory element in the locus is the locus control region (LCR) upstream of the globin genes that is essential for high-level expression of these genes. The discovery of the LCR initially raised the question how this element could exert its effect on the downstream globin genes. The question was solved by the finding that the LCR and activate globin genes are in physical contact, forming a chromatin structure named the active chromatin hub (ACH). Here we discuss the significance of ACH formation, provide an overview of the proteins implicated in chromatin looping at the beta-globin locus, and evaluate the relationship between nuclear organization and beta-globin gene expression.     

In vitro synthesis of RNA with “aggregate” enzyme,chromatin, and DNA from liver of methylazoxymethanol acetate-treated rats

“Aggregate” enzyme, chromatin and DNA preparations were isolated from livers of rats treated with the carcinogen, methylazoxymethanol (MAM) acetate. DNA template activity for RNA synthesis in vitro was unimpaired while the template activity of chromatin was slightly reduced. There was a marked inhibition of UTP incorporation into RNA, however, when the “aggregate” enzyme preparation was the source of both template and RNA polymerase. Circular dichroism analysis of the “aggregate” enzyme preparation indicated a change in conformation of the protein component. The results suggest that MAM acetate interacts with nuclear proteins and produces conformational changes which result in a decreased RNA synthesis.