杜氏盐藻随机MAR文库的构建

核基质附着区(Matrixattachmentregion,MAR)是一段与核基质结合的DNA序列。为分离杜氏盐藻核基质附着区,我们首次构建了杜氏盐藻MAR文库。首先用0.5%TritonX-100裂解细胞,经30%和70%Percoll不连续梯度离心分离盐藻细胞核,再用二碘水杨酸锂(lithiumdiiodosalicy-late,LIS)去除组蛋白和限制酶消化除去结合松弛的DNA片段,最后通过蛋白酶K消化和乙醇沉淀提取盐藻核基质DNA。采用4种限制酶酶切,T_4DNA连接酶连至用相应限制酶酶切的pUC18载体上,转化E.coliJM109感受态细胞,挑选阳性克隆,构建MAR文库。部分测序分析表明,克隆的DNA片段具有明显的MAR特征。为进一步研究MAR对基因表达的调控作用及其作用机制提供了基础。     

The Influences of Two Plant Nuclear Matrix Attachment Regions (MARs) on Gene Expression in Transgenic Plants

Nuclear matrix attachment regions (MARs) are thought to influencegene expression by anchoring active chromatin to the proteinaceousnuclear matrix. In this study, two plant DNA fragments withstrong MAR activity were selected and tested for their effectson expression of a linked reporter gene in transgenic tobacco.One MAR was isolated from the 5' flanking region of a pea vicilingene previously reported to be expressed in a copy number-dependentmanner in transgenic tobacco. A second MAR was isolated fromthe genome of Arabidopsis thaliana by preselection for autonomouslyreplicating sequence (ARS) activity in yeast. Flanking copiesof the A. thaliana MAR stimulated median reporter gene expressionin transgenic plants by five to ten fold. Neither MAR significantlyreduced the variation in transgene expression between individualtransformants, or conferred copy number-dependence in gene expression. (Received July 24, 1997; Accepted November 10, 1997)     

Circular YAC vectors containing a small mammalian origin sequence can associate with the nuclear matrix

Three different mammalian origins of DNA replication, 343, S3, and X24, have been cloned into a 15.8 kb circular yeast vector pYACneo. Subsequent transfection into HeLa cells resulted in the isolation of several stably maintained clones. Two cell lines, C343e2 and CS3e1, were found to have sequences maintained as episomes in long-term culture with a stability per generation of approximately 80%. Both episomes also contain matrix attachment region (MAR) sequences which mediate the binding of DNA to the nuclear skeleton and are thought to play a role in DNA replication. Using high salt extraction of the nucleus and fluorescent in situ hybridization, we were able to demonstrate an association of the 343 episome with the nuclear matrix, most probably through functional MAR sequences that allow an association with the nuclear matrix and associated regions containing essential replication proteins. The presence of functional MARs in small episomal sequences may facilitate the replication and maintenance of transfected DNA as an episome and improve their utility as small episomal constructs, potential microchromosomes. J. Cell. Biochem. 67:439–450, 1997. © 1997 Wiley-Liss, Inc.     

MFP1, a novel plant filament-like protein with affinity for matrix attachment region DNA.

The interaction of chromatin with the nuclear matrix via matrix attachment regions (MARs) on the DNA is considered to be of fundamental importance for higher order chromatin organization and regulation of gene expression. Here, we report a novel nuclear matrix-localized MAR DNA binding protein, designated MAR binding filament-like protein 1 (MFP1), from tomato. In contrast to the few animal MAR DNA binding proteins thus far identified, MFP1 contains a predicted N-terminal transmembrane domain and a long filament-like alpha-helical domain that is similar to diverse nuclear and cytoplasmic filament proteins from animals and yeast. DNA binding assays established that MFP1 can discriminate between animal and plant MAR DNAs and non-MAR DNA fragments of similar size and AT content. Deletion mutants of MFP1 revealed a novel, discrete DNA binding domain near the C terminus of the protein. MFP1 is an in vitro substrate for casein kinase II, a nuclear matrix-associated protein kinase. Its structure, MAR DNA binding activity, and nuclear matrix localization suggest that MFP1 is likely to participate in nuclear architecture by connecting chromatin with the nuclear matrix and potentially with the nuclear envelope.     

杜氏盐藻中的核基质与核基质结合区

真核生物细胞核DNA通过核基质结合区（Matrix attachment region,MAR）附着到核基质上。为了进一步探索染色体DNA与核基质之间的相互作用,从单细胞真核藻类-杜氏盐藻中克隆出了MAR片段。首先构建了杜氏盐藻的随机MAR文库,通过体外结合实验分离出能与核基质结合的MAR序列。从构建的MAR文库中,筛选出3个能与核基质结合的MAR,其中两个片段与核基质具有较强的结合力,测序分析表明具有MAR片段的一些典型特征性基序。     

杜氏盐藻核基质附着区的分离及特征性分析

采用0.5%TritonX 100破碎细胞,15%Percoll分离盐藻细胞核,25mM二碘水杨酸锂(lithiumdi iodosalicylate,LIS)抽提核蛋白,限制酶消化除去结合松弛的DNA,蛋白酶K SDS处理,酚/氯仿抽提,乙醇 沉淀提取核基质附着DNA,限制酶酶切连至pUC18载体上构建MARs文库。随机挑选6个克隆进行体外结 合实验筛选,筛选出一能与核基质结合的克隆,测序分析结果表明该序列具明显的MAR序列特征。     

牛乳腺核基质附着区多重顺式作用序列表明其功能的多样性

高等真核细胞的染色体DNA通过基质结合区(MAR)不时地与核基质特异性结合而组织成一种空间环状结构。为了研究以DNA套环形式附着于核基质上的DNA序列的特性,从处于泌乳期的乳腺组织中克隆了多个MAR DNA序列。体外结合实验表明,这些序列能够同核基质蛋白共结合成不溶性的复合物,这些复合物可较容易的通过离心去除。其中,两个MAR序列中包含有TL、CA—和GA—阻断以及ATTA基序。这两个序列中含有多个复制／转录因子的结合位点、增强子基序、多个完全的和非完全的反向重复序列以及潜在的DNA弯曲核心序列样结构。同一DNA序列中存在不同元件的组合可能说明在控制一系列细胞的发育过程中,它们可能发挥有正的或负的调控元件的功能。     

Random distribution of mammalian replication origins in matrix and total nuclear DNA

Nuclear matrices from mouse and rat tumour cells were isolated and characterized by their microscopic appearance, protein profiles and DNA content. They presented well-defined structures containing 15-20% of the nuclear protein and 1-3% of the nuclear DNA. Matrix DNAs were immobilized on nitrocellulose filters and hybridized to nick-translation 32P-labelled homologous DNA fragments containing the corresponding replication origins. As control total nuclear DNAs were also immobilized on filters and hybridized to origin-containing DNAs. The origin-containing DNAs hybridized to the same extent to both matrix and total DNAs, which showed that they contained the same proportion of origin sequences. In an alternative series of experiments, plasmids containing either rat or mouse replication origins were immobilized on filters and were hybridized with in vitro 32P-labelled matrix and total nuclear DNAs. Here again both matrix and total nuclear DNAs hybridized to the same extent with the origin-carrying plasmids, which showed that neither rat nor mouse matrix DNAs were enriched in DNA replication origin sequences.     

Quantitative immunofluorescence and immunoelectron microscopy of the topoisomerase IIα associated with nuclear matrices from wild-type and drug-resistant Chinese hamster ovary cell lines

Topo IIα is considered an important constituent of the nuclear matrix, serving as a fastener of DNA loops to the underlying filamentous scaffolding network. To further define a mechanism of drug resistance to topo II poisons, we studied the quantity of topo IIα associated with the nuclear matrix in drug-resistant SMR₁₆ and parental cells in the presence and absence of VP-16. Nuclear matrices were prepared from nuclei isolated in EDTA buffer, followed by nuclease digestion with DNase II in the absence of RNase treatment and extraction with 2 M NaCl. Whole-mount spreading of residual structures permits, by means of isoform-specific antibody and colloidal-gold secondary antibodies, an estimate of the amount of topo IIα in individual nuclear matrices. There are significant variations in topo IIα amounts between individual nuclear matrices due to the cell cycle distribution. The parental cell line contained eight to ten times more nuclear matrix–associated topo IIα than the resistant cell line matrices. Nuclear matrix–associated topo IIα from wild-type and resistant cell lines correlated well with the immunofluorescent staining of the enzyme in nuclei of intact cells. The amount of DNA associated with residual nuclear structures was five times greater in the resistant cell line. This quantity of DNA was not proportional to the quantity of topo IIα in the same matrix; in fact they were inversely related. In situ whole-mount nuclear matrix preparations were obtained from cells grown on grids and confirmed the results from labeling of isolated residual structures. J. Cell. Biochem. 67:112–130, 1997. © 1997 Wiley-Liss, Inc.     

Chromosomal loop anchorage sites appear to be evolutionarily conserved

We have previously identified a class of DNA sequence elements, termed matrix association regions (MARs), which specifically bind to nuclear matrices in vitro and are believed to be at the bases of chromosomal loops in vivo. Here we demonstrate that nuclear matrices prepared from the yeast Saccharomyces cerevisiae will specifically bind an MAR sequence derived from the mouse kappa light chain immunoglobulin gene. This suggests that both MAR sequences and their binding sites have been strongly evolutionarily conserved.     

A matrix attachment region is located upstream from the high-molecular-weight glutenin gene Bx7 in wheat (Triticum aestivum L.).

A 2.2-kb nucleotide sequence rich in AT, located upstream from the Bx7 allele of the high-molecular-weight glutenin Glu-B1 locus in wheat (Triticum aestivum cv. Glenlea) was cloned following amplification by PCR. The 5' region of this sequence contains motifs typically found in matrix attachment regions (MARs) in other plants. We have shown that part of the 2.2-kb DNA binds to wheat nuclear matrix (NM) in vitro, at least as strongly as a known MAR (Adh1) from maize suggesting that there is a MAR upstream of Bx7. This MAR is approximately 800 bases in length running from -750 to -1560 bases, relative to the start codon. Although the MAR is associated with a tissue-specific gene and is beside a strong tissue-specific promoter, the MAR sequence did not lead to tissue-specific expression of the beta-glucuronidase marker gene under the control of the rice actin promoter in various tissues. Presence of the MAR was only slightly beneficial with respect to expression levels, which were not greatly altered in transient expression assays in various wheat tissues although a slight increase in the number of foci was observed in leaves, which have low transformation efficiencies.     

Role of nuclear matrix proteins in the formation of heterochromatin]

Heterochromatin consists mainly of satellite DNAs (stDNA), the most rapidly evolving type of DNA sequences of the eucaryotic genome. On the other hand, stDNA is involved in the formation of the functionally conserved centromere structure. Centromeres and pericentromeric stDNA, are known to be in association with nuclear matrix or chromosome scaffold at all stages of the cell cycle. Several lines of evidence show that attachment of stDNA to the nuclear matrix is specific. The first defined parts of the genes found in association with nuclear matrix/scaffold, MAR/SAR, possess some common features with the stDNA. A number of different mechanisms have previously been implicated in heterochromatin formation and centromere conservation. The role of nuclear matrix proteins, which are able to recognize common structural features of MAR/SAR and stDNA, in constitutive heterochromatin organization is discussed in the current review.     

MAF1, a novel plant protein interacting with matrix attachment region binding protein MFP1, is located at the nuclear envelope.

The interaction of chromatin with the nuclear matrix via matrix attachment region (MAR) DNA is considered to be of fundamental importance for chromatin organization in all eukaryotic cells. MAR binding filament-like protein 1 (MFP1) from tomato is a novel plant protein that specifically binds to MAR DNA. Its filament protein-like structure makes it a likely candidate for a structural component of the nuclear matrix. MFP1 is located at nuclear matrix-associated, specklelike structures at the nuclear envelope. Here, we report the identification of a novel protein that specifically interacts with MFP1 in yeast two-hybrid and in vitro binding assays. MFP1 associated factor 1 (MAF1) is a small, soluble, serine/threonine-rich protein that is ubiquitously expressed and has no similarity to known proteins. MAF1, like MFP1, is located at the nuclear periphery and is a component of the nuclear matrix. These data suggest that MFP1 and MAF1 are in vivo interaction partners and that both proteins are components of a nuclear substructure, previously undescribed in plants, that connects the nuclear envelope and the internal nuclear matrix.     

High incidence of antinuclear antibodies that recognize the matrix attachment region.

The matrix attachment region (MAR) is a distinctive genomic DNA involved in a variety of nuclear processes through association with the nuclear matrix. Recent studies suggest that nuclear matrix is altered in the process of apoptosis and presented to the immune system, leading to the production of autoantibodies against its protein components. To see whether MARs are also recognized by autoantibodies, a collection of human sera containing antinuclear antibodies was screened for the presence of binding activities against cloned MARs. We found that MAR-binding activities are quite common in these sera. There was a positive correlation among the MAR-binding titers for three different MAR probes. As expected, the MAR-binding activity was copurified with serum IgG, and subclass analysis with affinity-purified IgG on MAR-Sepharose showed a predominance of IgG2 isotype. Several lines of evidence implied that the anti-MAR antibodies detected here is distinct from the ordinary anti-DNA antibodies that are reactive to bulk DNA.     

Extrachromosomal Circular DNA from Nuclear Fraction of Higher Plants

To determine the cellular location of extrachromosomal circularDNA in higher plants, wheat (Triticum aestivum) and tobacco(Nicotiana tabacum) nuclei were isolated and purified, and theircircular DNAs were examined by electron microscopy. Covalentlyclosed circular (ccc) DNAs were found in nuclear fractions fromboth species. They showed a heterogeneous size distributionranging from 0.1 µm to more than 5 µm in contourlength, with a mean of 1.7 µm (5.3 kbp) for T. aestivumand 1.5 µm (4.7 kbp) for N. tabacum, respectively. Thisdistribution is significantly different from that for smallcircular DNAs in mitochondria. Small polydisperse circular (spc)DNA/protein complexes were also observed by a rapid microscalemethod of mica-press-adsorption for electron microscopy. Complexesof spcDNA/protein showed a similar size distribution to cccDNA.The average number of spcDNA/protein complexes per nucleus wasestimated at more than hundred. The origin and biological functionsof the nuclear circular DNAs are discussed. (Received February 13, 1985; Accepted August 8, 1985)