DNA and RNA within the nucleus: How much sequence-specific spatial organization?

Spatial organization of various nuclear components is often proposed as a means by which nuclei more efficiently carry out their various tasks. Such functional compartmentalization may involve a sequence-specific packaging and placement of DNA and RNA. Here we review recent insights, allowed primarily by advances in fluorescent in situ hybridization methodology, into the organization of nucleic acids within individual nuclei.     

The sperm nuclear matrix is required for paternal DNA replication

The mammalian sperm nucleus provides an excellent model for studying the relationship between the formation of nuclear structure and the initiation of DNA replication. We previously demonstrated that mammalian sperm nuclei contain a nuclear matrix that organizes the DNA into loop domains in a manner similar to that of somatic cells. In this study, we tested the minimal components of the sperm nucleus that are necessary for the formation of the male pronucleus and for the initiation of DNA synthesis. We extracted mouse sperm nuclei with high salt and dithiothreitol to remove the protamines in order to form nuclear halos. These were then treated with either restriction endonucleases to release the DNA not directly associated with the nuclear matrix or with DNAse I to digest all the DNA. The treated sperm nuclei were injected into oocytes, and the paternal pronuclear formation and DNA synthesis was monitored. We found that restriction digested sperm nuclear halos were capable of forming paternal pronuclei and initiating DNA synthesis. However, when isolated mouse sperm DNA or sperm DNA reconstituted with the nuclear matrices were injected into oocytes, no paternal pronuclear formation or DNA synthesis was observed. These data suggest that the in situ nuclear matrix attachment organization of sperm DNA is required for mouse paternal pronuclear DNA synthesis.     

Chromatin loops,illegitimate recombination,and genome evolution

Chromosomal rearrangements frequently occur at specific places (“hot spots”) in the genome. These recombination hot spots are usually separated by 50–100 kb regions of DNA that are rarely involved in rearrangements. It is quite likely that there is a correlation between the above‐mentioned distances and the average size of DNA loops fixed at the nuclear matrix. Recent studies have demonstrated that DNA loop anchorage regions can be fairly long and can harbor DNA recombination hot spots. We previously proposed that chromosomal DNA loops may constitute the basic units of genome organization in higher eukaryotes. In this review, we consider recombination between DNA loop anchorage regions as a possible source of genome evolution.     

Dynamics of chromatin position in the interphase nucleus volume

In this article, we attempt to analyze the relationship between the processes which occur in the nucleus and the dynamics of chromatin, as well as to classify the changes in the position of chromatin in the cell nucleus during the lifetime of the cell. The proposed concept integrates possible types of chromatin movement within the nucleus.     

Structure and Functions of Nuclear Matrix Associated Regions (S/MARs)

Modern concepts on the chromatin loop–domain organization and the role of the DNA regions specifically binding the nuclear matrix or nuclear scaffold (S/MARs) during its formation, maintenance, and regulation are discussed. Some S/MAR structural features, properties of binding the nuclear matrix, and probable mechanisms of their involvement in the gene regulation of activity are considered.     

Use of matrix attachment regions (MARs) to minimize transgene silencing

Matrix attachment regions (MARs) are operationally defined as DNA elements that bind specifically to the nuclear matrix in vitro. It is possible, although unproven, that they also mediate binding of chromatin to the nuclear matrix in vivo and alter the topology of the genome in interphase nuclei. When MARs are positioned on either side of a transgene their presence usually results in higher and more stable expression in transgenic plants or cell lines, most likely by minimizing gene silencing. Our review explores current data and presents several plausible models to explain MAR effects on transgene expression.     

Genetic and epigenetic regulation in nuclear microenvironments for biological control in cancer

The regulatory machinery that governs genetic and epigenetic control of gene expression is compartmentalized in nuclear microenvironments. Temporal and spatial parameters of regulatory complex organization and assembly are functionally linked to biological control and are compromised with the onset and progression of tumorigenesis providing a novel platform for cancer diagnosis and treatment.     

Computer prediction of sites associated with various elements of the nuclear matrix

Attachment regions of the eukaryotic chromosomal DNA to the nuclear scaffold/matrix (S/MARs) participate in various important cellular processes. However, no obvious characteristics common for these nucleotide sequences have been revealed, except that S/MARs are non-coding sites containing putative regulatory elements and binding sites of DNA-topoisomerase II. Heterogeneity among S/MARs can be caused by a variety of biological factors. In this paper, the accuracy of two S/MARs prediction programs, MAR-Finder (Singh, Kramer and Krawetz, 1997) and ChrClass (Glazkov, Rogozin and Glazko, 1998) are compared and it is concluded that both programs can be recommended for analysis of eukaryotic genomes. However, results of their prediction should be interpreted with caution since estimation of prediction accuracy of both programs needs further analysis. Problems of S/MARs prediction are illustrated on several examples of human protein-coding genes, repeated elements and the beta-globin locus from different mammalian species. Results of our analysis suggest that the proportion of missed S/MARs is lower for ChrClass, whereas the proportion of wrong S/MARs is lower for MAR-Finder (a default set of parameters).     

Trans-inactivation: Repression in a wrong place

Trans-inactivation is the repression of genes on a normal chromosome under the influence of a rearranged homologous chromosome demonstrating the position effect variegation (PEV). This phenomenon was studied in detail on the example of brown^Dominant allele causing the repression of wild-type brown gene on the opposite chromosome. We have investigated another trans-inactivation-inducing chromosome rearrangement, In(2)A4 inversion. In both cases, brown^Dominant and In(2)A4, the repression seems to be the result of dragging of the euchromatic region of the normal chromosome into the heterochromatic environment. It was found that cis-inactivation (classical PEV) and trans-inactivation show different patterns of distribution along the chromosome and respond differently to PEV modifying genes. It appears that the causative mechanism of trans-inactivation is de novo heterochromatin assembly on euchromatic sequences dragged into the heterochromatic nuclear compartment. Trans-inactivation turns out to be the result of a combination of heterochromatin-induced position effect and the somatic interphase chromosome pairing that is widespread in Diptera.     

The type of DNA attachment sites recovered from nuclear matrix depends on isolation procedure used

A large variety of DNA sequences have been described in nuclear matrix attachment regions. It could be most likely a result of the different methods used for their isolation. The idea about how different types of known DNA sequences (strongly attached to the nuclear matrix, weakly attached, or not attached) directly participate in anchoring DNA loops to the nuclear matrices isolated by different experimental procedures was tested in this study. Matrix-attached (M) and matrix-independent or loop (L) fractions as well as nuclear matrices were isolated using extractions of nuclei with 25 mM lithium 3,5-diiodosalicylate (LIS), 2 M NaCl, 0.65 M ammonium sulphate containing buffers followed by DNase I/RNase A digestion, or according to so designated conventional method. Using PCR-based and in vitro binding assays it was established that LIS and ammonium sulphate extractions gave similar results for the type of attachment of sequences investigated. The harsh extraction with 2 M NaCl or the conventional procedure led to some rearrangements in the attachment of DNA loops. As a result a big part of matrix attached sequences were found detached in the loop fractions. However, the in vitro binding abilities of the MARs to the nuclear matrices isolated by different methods did not change.     

核基质结合序列（MAR）与基因表达调控

核基质结合序列（MAR）是能在体外与核基质特异结合的DNA序列,广泛存在于染色质Loop结构的边界序列中。随着研究的深入,发现MAR序列不仅在染色质折叠中起到重要作用,影响邻近内源基因表达,而且将MAR序列构建到外源基因表达盒两侧转化动植物时,也影响外源基因的表达。因此,MAR序列是基因组中一种重要的基因间边界序列,为阐明非编码序列在基因表达中的作用和构建真核生物高效表达载体提供了新途径。