Sequence and structure of the nucleolin promoter in rodents: characterization of a strikingly conserved CpG island

We report the isolation of the complete genes encoding nucleolin from rat and hamster. The DNA clones were obtained from partial genomic libraries by probing with a genomic DNA fragment containing the leader and promoter regions of the mouse nucleolin gene. We have determined the complete nucleotide sequence of the 5'-terminal region for the three rodent species. The sequenced regions extend over 1 kb downstream and upstream from the cap sites and include a conserved CpG island 1500 nucleotides (nt) long. The 5' end of the CpG island in each species has maintained a long alternating purine-pyrimidine sequence which could adopt a Z-DNA conformation. By sequence comparison, 42 blocks of homology are defined in the 5'-terminal region, of which 36 appear in the CpG island and contain numerous conserved CpG dinucleotides. Two blocks, 110 and 49 nt long, encompassing the cap sites and the region immediately upstream, respectively, present features characteristic of regulated genes: a possible TATA box (ATTA), two pyrimidine-rich nucleotide stretches and two inverted juxtaposed CCAAT-like boxes (GGTTGG). Furthermore, the adjacent upstream conserved region presents features characteristic of housekeeping genes: four G/C boxes, embedded in a high G + C-content sequence, among them one presenting a perfect consensus Sp 1-binding site (GCCCCGCCCC). Among unusual features, we report numerous large G + C-rich conserved sequences located in the first intron. One of these sequences contains two G/C boxes which border a sequence presenting a dyad symmetry (GCGCACGTGCTC). Our findings shed some light on the putative role of the CpG island. We show that CpG-rich sequence motifs are under strong selective pressure over the whole 5'-terminal region and are presumably involved in regulatory mechanisms.     

Determination of the in vivo structural DNA loop organization in the genomic region of the rat albumin locus by means of a topological approach

Nuclear DNA of metazoans is organized in supercoiled loops anchored to a proteinaceous substructure known as the nuclear matrix (NM). DNA is anchored to the NM by non-coding sequences known as matrix attachment regions (MARs). There are no consensus sequences for identification of MARs and not all potential MARs are actually bound to the NM constituting loop attachment regions (LARs). Fundamental processes of nuclear physiology occur at macromolecular complexes organized on the NM; thus, the topological organization of DNA loops must be important. Here, we describe a general method for determining the structural DNA loop organization in any large genomic region with a known sequence. The method exploits the topological properties of loop DNA attached to the NM and elementary topological principles such as that points in a deformable string (DNA) can be positionally mapped relative to a position-reference invariant (NM), and from such mapping, the configuration of the string in third dimension can be deduced. Therefore, it is possible to determine the specific DNA loop configuration without previous characterization of the LARs involved. We determined in hepatocytes and B-lymphocytes of the rat the DNA loop organization of a genomic region that contains four members of the albumin gene family.     

Matrix attachment regions and structural colinearity in the genomes of two grass species.

In order to gain insights into the relationship between spatial organization of the genome and genome function we have initiated studies of the co-linear Sh2/A1- homologous regions of rice (30 kb) and sorghum (50 kb). We have identified the locations of matrix attachment regions (MARs) in these homologous chromosome segments, which could serve as anchors for individual structural units or loops. Despite the fact that the nucleotide sequences serving as MARs were not detectably conserved, the general organizational patterns of MARs relative to the neighboring genes were preserved. All identified genes were placed in individual loops that were of comparable size for homologous genes. Hence, gene composition, gene orientation, gene order and the placement of genes into structural units has been evolutionarily conserved in this region. Our analysis demonstrated that the occurrence of various 'MAR motifs' is not indicative of MAR location. However, most of the MARs discovered in the two genomic regions were found to co-localize with miniature inverted repeat transposable elements (MITEs), suggesting that MITEs preferentially insert near MARs and/or that they can serve as MARs.     

Human dihydrofolate reductase gene organization. Extensive conservation of the G + C-rich 5' non-coding sequence and strong intron size divergence from homologous mammalian genes

The complete human dihydrofolate reductase (DHFR) gene has been cloned from four recombinant lambda libraries constructed with the DNA from a methotrexate-resistant human cell line with amplified DHFR genes. The detailed organization of the gene has been determined by restriction mapping of the cloned fragments and DNA sequencing of all the protein coding regions and adjacent intron segments, and shown to correspond to that of the native human DHFR gene. The gene spans a length of approximately 29 X 10(3) bases from the ATG initiator codon to the end of the 3' untranslated region, and contains five introns that interrupt the protein coding sequence. The number and positions of introns are identical to those found in the mouse gene. By contrast, the size of the homologous introns (with the exception of the first one) varies greatly, up to several fold, in the genes from man, mouse and Chinese hamster; the intron sequences also exhibit a great divergence, except in the junction regions. A striking sequence homology, extending over several hundred nucleotides, exists between the human and mouse gene 5' non-coding regions. These regions are characterized by an unusually high G + C content, 72% and 66% in the human and mouse genes, respectively, which is maintained in the first coding segment and first intron, and is in sharp contrast to the relatively low G + C content (approximately 40%) of the remainder of the gene.     

A map of nuclear matrix attachment regions within the breast cancer loss-of-heterozygosity region on human chromosome 16q22.1

There is abundant evidence that the DNA in eukaryotic cells is organized into loop domains that represent basic structural and functional units of chromatin packaging. To explore the DNA domain organization of the breast cancer loss-of-heterozygosity region on human chromosome 16q22.1, we have identified a significant portion of the scaffold/matrix attachment regions (S/MARs) within this region. Forty independent putative S/MAR elements were assigned within the 16q22.1 locus. More than 90% of these S/MARs are AT rich, with GC contents as low as 27% in 2 cases. Thirty-nine (98%) of the S/MARs are located within genes and 36 (90%) in gene introns, of which 15 are in first introns of different genes. The clear tendency of S/MARs from this region to be located within the introns suggests their regulatory role. The S/MAR resource constructed may contribute to an understanding of how the genes in the region are regulated and of how the structural architecture and functional organization of the DNA are related.     

核基质附着区广泛参与基因组三维结构折叠的生物信息学分析

在细胞分裂间期,每条染色质都占据着特定的染色质领域（chromosome territory,CT）。每个CT领域内进一步分成不同的拓扑学相关区域（topological associated domain,TAD）,每个TAD又由若干子TAD（sub-TAD）构成。不同的TAD相互聚集,形成基因活跃表达和不表达的A、B两种组份或区室（compartment）。然而,目前对于染色质折叠方式及维持机制的研究尚无定论。核基质附着区（matrix attachment regions,MARs）是在不同物种基因组中广泛存在的一类富含AT序列的与核基质结合的DNA元件,能够通过与CTCF、SATB1等调控蛋白质相互作用,对远距离的基因表达进行调控。本研究以染色质三维结构为背景,通过整合染色质三维结构及组蛋白修饰等组学数据,对MARs元件与染色质三维结构的关系进行研究,对MARs元件参与形成的相互作用网络的结构及功能进行探索。结果发现,MARs元件与染色质三维结构高度相关,而且在高强度相互作用中占据较大的比例,提示MARs元件在染色质折叠方面发挥作用。此外,通过拓扑结构聚类分析还首次揭示,MARs元件分为不同类型,包括维持染色质领域及空间构象等的结构单元部分,以及调控基因表达等的功能单元部分。这表明,MARs元件在基因组三维高级结构的建立、维持以及功能等方面发挥重要作用。     

Nuclear matrix association regions of rat alpha 2-macroglobulin gene

We have identified DNA fragments which bind specifically to the nuclear matrix in vitro, termed matrix association regions (MARs), in the first and fourth introns of rat alpha 2-macroglobulin gene. The MAR in the first intron is enriched with sequences closely related to the cleavage consensus of topoisomerase II, and contains the binding site of nuclear factor-alpha, a sequence-specific DNA binding protein reported previously.