Localization of SV40 genes within supercoiled loop domains

Recent studies indicate that eukaryotic DNA is organized into supercoiled loop domains. These loops appear to be anchored at their bases to an insoluble nuclear skeleton or matrix. Most of the DNA in the loops can be released from the matrix by nuclease digestion; the residual DNA remaining with the nuclear matrix represents sequences at the base of the loops, and possibly other sequences which are intimately associated with the nuclear matrix for other reasons. Using a quantitative application of the Southern blotting technique, we have found this residual DNA from SV40 infected 3T3 cells to be enriched in SV40 sequences, indicating that they reside near matrix-DNA attachment points. An enrichment of 3-7 fold relative to total cellular DNA, was found in each of three different lines of SV40 infected 3T3 cells. Control experiments with globin genes showed no such enrichment in this residual matrix DNA. This sequence specificity suggests that the spatial organization of DNA sequences within loops may be related to the functionality of these sequences within the cell.     

Sperm nuclear halos can transform into normal chromosomes after injection into oocytes

Mouse sperm nuclei extracted with an ionic detergent and 2 M NaCl retain their overall morphology, but upon subsequent reduction of the protamine disulfides they lose all elements of chromatin structure except the organization of DNA into loop that are anchored to the nuclear matrix. These DNA loops appear as a halo surrounding the nuclear matrix, and nuclei extracted in this manner are, therefore, called nuclear halos. Here, we report that sperm nuclear halos injected into oocytes can form pronuclei, then transform into chromosomes with normal morphology. This suggests that sperm nuclear halos retain all the information necessary for normal chromosomal organization, and that micromanipulation of these extracted sperm nuclei can be accomplished without major DNA damage.     

Ribosomal DNA sequences attached to the nuclear matrix

The organization of rat liver ribosomal DNA (rDNA) as matrix-attached DNA loops was examined using a protocol which fractionates chromatin from discrete regions of DNA loops. Southern blot analysis of matrix-attached and solubilized chromatin DNA fragments demonstrated that rDNA is associated with the matrix via its 5' and 3' nontranscribed spacer sequences (NTS). Although the 45 S rRNA coding sequences were approximately threefold enriched in matrix preparations, the recovery of this DNA (unlike the NTS) was dependent on the extent of nuclease digest and proportional to the length of the matrix-attached DNA fragments. The data suggest that rDNA is organized as matrix-attached DNA loops and only the NTS are directly involved in matrix binding. Further, we demonstrated that while the kinetics and extent of nuclease digestion were similar in all regions of the DNA loops, the nuclease digestion pattern of bulk nuclear and matrix DNA showed a typical nucleosome organization, but the rDNA fragments retained with the nuclear matrix did not.     

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.     

Changes in chromatin organization during early development and carcinogenesis

Similar changes in chromatin organization take place during development and carcinogenesis. The size of chromatin loop domains fixed on the nuclear skeleton (matrix) increased from 20 to approximately 200 kbp. These changes are accompanied by an increased size of replicons and altered specificity of loop attachment to the nuclear matrix. During carcinogenesis, inverse changes in the chromatin structure are observed, neoplastic cells are dedifferentiated and return to the initial state. In this review, we consider new experimental data on organization of the DFNA loops and nuclear matrix in embryogenesis and carcinogenesis.     

Changes in Chromatin Organization during Early Development and Carcinogenesis

Similar changes in chromatin organization take place during development and carcinogenesis. The size of chromatin loop domains fixed on the nuclear skeleton (matrix) increased from 20 to approximately 200 kb. These changes are accompanied by an increased size of replicons and altered specificity of loop attachment to the nuclear matrix. During carcinogenesis, inverse changes in the chromatin structure are observed, neoplastic cells are dedifferentiated and return to the initial state. In this review, we consider new experimental data on organization of the DFNA loops and nuclear matrix in embryogenesis and carcinogenesis.     

Multiple cellular mechanisms prevent chromosomal rearrangements involving repetitive DNA

Repetitive DNA is present in the eukaryotic genome in the form of segmental duplications, tandem and interspersed repeats, and satellites. Repetitive sequences can be beneficial by serving specific cellular functions (e.g. centromeric and telomeric DNA) and by providing a rapid means for adaptive evolution. However, such elements are also substrates for deleterious chromosomal rearrangements that affect fitness and promote human disease. Recent studies analyzing the role of nuclear organization in DNA repair and factors that suppress non-allelic homologous recombination (NAHR) have provided insights into how genome stability is maintained in eukaryotes. In this review, we outline the types of repetitive sequences seen in eukaryotic genomes and how recombination mechanisms are regulated at the DNA sequence, cell organization, chromatin structure, and cell cycle control levels to prevent chromosomal rearrangements involving these sequences.     

Multiple cellular mechanisms prevent chromosomal rearrangements involving repetitive DNA

Repetitive DNA is present in the eukaryotic genome in the form of segmental duplications, tandem and interspersed repeats, and satellites. Repetitive sequences can be beneficial by serving specific cellular functions (e.g. centromeric and telomeric DNA) and by providing a rapid means for adaptive evolution. However, such elements are also substrates for deleterious chromosomal rearrangements that affect fitness and promote human disease. Recent studies analyzing the role of nuclear organization in DNA repair and factors that suppress non-allelic homologous recombination (NAHR) have provided insights into how genome stability is maintained in eukaryotes. In this review, we outline the types of repetitive sequences seen in eukaryotic genomes and how recombination mechanisms are regulated at the DNA sequence, cell organization, chromatin structure, and cell cycle control levels to prevent chromosomal rearrangements involving these sequences.     

Nuclear matrix support of DNA replication

In higher eukaryotic cells, DNA is tandemly arranged into 10(4) replicons that are replicated once per cell cycle during the S phase. To achieve this, DNA is organized into loops attached to the nuclear matrix. Each loop represents one individual replicon with the origin of replication localized within the loop and the ends of the replicon attached to the nuclear matrix at the bases of the loop. During late G1 phase, the replication origins are associated with the nuclear matrix and dissociated after initiation of replication in S phase. Clusters of several replicons are operated together by replication factories, assembled at the nuclear matrix. During replication, DNA of each replicon is spooled through these factories, and after completion of DNA synthesis of any cluster of replicons, the respective replication factories are dismantled and assembled at the next cluster to be replicated. Upon completion of replication of any replicon cluster, the resulting entangled loops of the newly synthesized DNA are resolved by topoisomerases present in the nuclear matrix at the sites of attachment of the loops. Thus, the nuclear matrix plays a dual role in the process of DNA replication: on one hand, it represents structural support for the replication machinery and on the other, provides key protein factors for initiation, elongation, and termination of the replication of eukaryotic DNA.     

Protein:DNA interactions at chromosomal loop attachment sites

We have recently identified an evolutionarily conserved class of sequences that organize chromosomal loops in the interphase nucleus, which we have termed "matrix association regions" (MARs). MARs are about 200 bp long, AT-rich, contain topoisomerase II consensus sequences and other AT-rich sequence motifs, often reside near cis-acting regulatory sequences, and their binding sites are abundant (greater than 10,000 per mammalian nucleus). Here we demonstrate that the interactions between the mouse kappa immunoglobulin gene MAR and topoisomerase II or the "nuclear matrix" occur between multiple and sometimes overlapping binding sites. Interestingly, the sites most susceptible to topoisomerase II cleavage are localized near the breakpoints of a previously described illegitimate recombination event. The presence of multiple binding sites within single MARs may allow DNA and RNA polymerase passage without disrupting primary loop organization.     

Visualization of chromatin domains created by the gypsy insulator of Drosophila

Insulators might regulate gene expression by establishing and maintaining the organization of the chromatin fiber within the nucleus. Biochemical fractionation and in situ high salt extraction of lysed cells show that two known protein components of the gypsy insulator are present in the nuclear matrix. Using FISH with DNA probes located between two endogenous Su(Hw) binding sites, we show that the intervening DNA is arranged in a loop, with the two insulators located at the base. Mutations in insulator proteins, subjecting the cells to a brief heat shock, or destruction of the nuclear matrix lead to disruption of the loop. Insertion of an additional gypsy insulator in the center of the loop results in the formation of paired loops through the attachment of the inserted sequences to the nuclear matrix. These results suggest that the gypsy insulator might establish higher-order domains of chromatin structure and regulate nuclear organization by tethering the DNA to the nuclear matrix and creating chromatin loops.     

家蚕（Bombyx mori）5龄幼虫丝腺染色质在核基质上的组构

家蚕(Bombyx mori)5龄幼虫丝腺的染色质高度多倍化,整个基因组达10~5至10~6个拷贝。依次经低盐和高盐抽提5龄幼虫中丝腺、后丝腺和蚕体的细胞核,得到其核晕 (nuclearhalo),限制性内切酶消化后还有一部分DNA片段与核基质紧密结合在一起,说明染色质的组织与核基质有关。通过测定核基质上残留的DNA片段的平均长度及其在全基因组DNA中所占的百分比计算出,核晕上DNAloop的平均大小在中丝腺、后丝腺以及蚕体细胞中均为67kb左右。丝腺中高度多倍化的染色质与二倍体蚕体组织之间并不存在差异,它们同样被错定在核基质上而分隔成长约67kb的染色质loop,从而保证整个基因组的有序排列。以丝素基因为探针进行DNA印迹杂交发现,在5龄后丝腺中丝素基因特异性地和核基质紧密结合,说明核基质与丝素基因的组织特异性表达有关。     

Fractionation of eukaryotic DNA in a pulsating electrical field. I. Detection and properties of discrete DNA fragments]

The fractionation of eukaryotic DNA by field inversion gel electrophoresis results in the appearance of discrete DNA-fragments. The set of these fragments is similar to that of different eukaryotic representatives and consists of various chromosomal DNAs, unified by size. The physical properties of DNA-fragments suggest that they can form multimeric structures due to the presence of sticky ends flanking discrete fragments. We suppose that the set of discrete DNA-fragments results in a specific cleavage of intact nuclear DNA and can reflect different levels of chromatin structural organization.     

Characterization of an Mg2+-dependent endonucleolytic activity of the rat hepatocyte nuclear matrix

Initial degradation of chromatin into high-molecular mass DNA fragments during apoptosis reflects the periodicity of chromatin organization into nuclear matrix-attached loops. In this article, we put forward the hypothesis that this pattern of DNA cleavage is also a result of the localization of an endonuclease on the nuclear matrix. Namely, we observed an endonucleolytic activity of the isolated rat hepatocyte nuclear matrix. It was Mg2+-dependent, with an optimal activity at pH 7.2 in the absence of either Na+ or K+. It was fully active in the presence of Zn2+ and capable of introducing single-strand breaks into plasmid DNA. It did not display a sequence-specific activity. A 23 kDa DNA nuclease that was principally localized on the rat hepatocyte nuclear matrix was detected. The enzyme shared the biochemical requirements with the nuclear matrix endonucleolytic activity, thus we proposed that p23 could be responsible for the endonucleolytic activity of the nuclear matrix. In view of its properties and preferential localization on the nuclear matrix, the endonuclease described herein could be a possible candidate that brings about initial DNA cleavage during apoptosis.