A global but stable change in HeLa cell morphology induces reorganization of DNA structural loop domains within the cell nucleus

DNA of higher eukaryotes is organized in supercoiled loops anchored to a nuclear matrix (NM). The DNA loops are attached to the NM by means of non-coding sequences known as matrix attachment regions (MARs). Attachments to the NM can be subdivided in transient and permanent, the second type is considered to represent the attachments that subdivide the genome into structural domains. As yet very little is known about the factors involved in modulating the MAR-NM interactions. It has been suggested that the cell is a vector field in which the linked cytoskeleton-nucleoskeleton may act as transducers of mechanical information. We have induced a stable change in the typical morphology of cultured HeLa cells, by chronic exposure of the cells to the polar compound dimethylsulfoxide (DMSO). Using a PCR-based method for mapping the position of any DNA sequence relative to the NM, we have monitored the position relative to the NM of sequences corresponding to four independent genetic loci located in separate chromosomes representing different territories within the cell nucleus. Here, we show that stable modification of the NM morphology correlates with the redefinition of DNA loop structural domains as evidenced by the shift of position relative to the NM of the c-myc locus and the multigene locus PRM1 --> PRM2 --> TNP2, suggesting that both cell and nuclear shape may act as cues in the choice of the potential MARs that should be attached to the NM.     

The limits of the DNase I-sensitive domain of the human apolipoprotein B gene coincide with the locations of chromosomal anchorage loops and define the 5' and 3' boundaries of the gene

In eukaryotic cells, chromatin is organized as domains or loops that are generated by periodic attachment of the chromatin fiber to protein components of a nuclear matrix, or scaffold. These chromosomal loops may have a function in gene regulation. The length of the chromatin domain encompassing the human apolipoprotein B gene was studied by determining the locations of nuclear matrix attachment sites as well as the boundaries of the DNase I-sensitive domain in cells that express the gene (such as HepG2 and CaCo-2 cells) and in those that do not (HeLa cells). Three nuclear matrix attachment regions (MARs) of the human apolipoprotein B gene have been localized: a 3' -proximal MAR, between nucleotides +43,186 and +43,850; a 5' -proximal MAR, between nucleotides -2,765 and -1,801; and a 5' -distal MAR, between nucleotides -5,262 and -4,048. Both the 3' -proximal and the 5' -distal MARS were present in cells that express the gene (HepG2 and CaCo-2 cells) as well as in cells that do not (HeLa cells), whereas the 5' -proximal MAR was detected only in HepG2 cells. These MARs were located at the bases of chromosomal loops in histone-extracted nuclei in all three cell lines. Various classes of A/T-rich sequences resembling the recognition site for topoisomerase II were present within the MAR-containing fragments. The boundaries of the DNase I-sensitive domain coincide with the positions of the 3' -proximal and 5' -distal matrix attachment sites. These results suggest the existence of a 47.5-kilobase domain that represents a topologically sequestered functional unit containing the coding region and all known cis-acting regulatory elements of the human apolipoprotein B gene.     

Establishment of a Partially Informative Porcine Somatic Cell Hybrid Panel and Assignment of the Loci for Transition Protein 2 (TNP2) and Protamine 1 (PRM1) to Chromosome 3 and Polyubiquitin (UBC) to Chromosome 14

Porcine lymphocytes and fibroblasts were fused with 3 different permanent rodent cell lines, and 21 stable somatic cell hybrid lines were established. These hybrid cell lines were characterized cytogenetically by sequential QFQ banding and chromosome painting using fluorescence in situ hybridization with porcine DNA. The lines were further characterized by PCR analysis with primer pairs derived from genes with confirmed mapping information. Using this panel, we assigned the locus encoding polyubiquitin (UBC) to chromosome 14, and the transition protein 2 locus (TNP2) and protamine loci (PRM1 and PRM2) to chromosome 3. Two chromosomal localizations have been further refined by radioactive in situ hybridization. UBC maps to chromosome 14q12-q15 and TNP2 to 3p11-p12.     

Sequence analysis of the conserved protamine gene cluster shows that it contains a fourth expressed gene

Structural data are presented on the protamine gene cluster (PGC) of human, mouse, rat, and bull. By restriction mapping we demonstrate that the organization of the protamine cluster is conserved throughout all four species, i.e., the genes are situated in a head to tail arrangement in the order: protamine l-protamine 2-transition protein 2. Further, we established the nucleotide sequence of the entire human PGC (25 kb in total) and the 3′ portion of the rat protamine cluster (PRM2 and TNP2 genes and intergenic region). In addition, a 1 kb fragment of the bovine and murine protamine cluster, situated between PRM2 and TNP2, was sequenced. This fragment is conserved regarding sequence, position, and orientation in all species examined, and was classified as likely coding region by gene recognition program GRAIL. Using the rat fragment as a probe in RNA blots, we detected a testis-specific signal of about 0.5 kb. Finally, we demonstrate a high density of Alu elements, both full and fragmented copies, in the human PGC and discuss their localization with respect to evolutionary and functional aspects. © 1996 Wiley-Liss, Inc.     

Separation of spermatogenic cells from adult transgenic mouse testes using unit-gravity sedimentation

During the final stage of spermatogenesis (i.e., spermiogenesis), round spermatids differentiate into mature spermatozoa. This transformation is mediated by a suite of nuclear packaging proteins. These include the transition proteins and the protamines. The two human protamines PRM1 and PRM2, and transition protein TNP2, are encoded by a single chromatin domain bounded by two regions of matrix attachment. Previous transgenic studies in our laboratory have shown that mice harboring a 40-kb segment of human chromosome 16p13.13 containing the PRM1 → PRM2 → TNP2 domain express the transgene in a haploid-specific, copy number-dependent, and position-independent manner. While these results indicate that this segment of the genome is a complete structural and functional regulatory unit, the elements governing the haploid expression of this suite of genes remain to be clearly defined. The preparation of spermatogenic cells is required to begin to address this mechanism. The CELSEP (Wescor/Dupont Inc. Wilmington, DE) unit-gravity sedimentation apparatus provides a simple, efficient, and reproducible means to separate testicular germ cells at all stages along this differentiative pathway. The high quality and integrity of germ cells obtained by this means provides a valuable resource for characterizing the molecular mechanisms governing the regulation of the PRM1 → PRM2 → TNP2 domain during spermatogenesis. A discussion of the CELSEP apparatus and the application of this methodology in our laboratory are presented.     

Protamine 3 shows evidence of weak, positive selection in mouse species (genus Mus)--but it is not a protamine

Protamines are short and highly basic sperm-specific nuclear proteins that replace somatic histones during spermiogenesis in a process that is crucial for sperm formation and function. Many mammals have two protamine genes (PRM1 and PRM2) located in a gene cluster, which appears to evolve fast. Another gene in this cluster (designated protamine 3 [PRM3]) encodes a protein that is conserved among mammals but that does not seem to be involved in chromatin condensation. We have compared protein sequences and amino acid compositions of protamines in this gene cluster, searched for evidence of positive selection of PRM3, and examined whether sexual selection (sperm competition) may drive the evolution of the PRM3 gene. Nucleotide and amino acid analyses of mouse sequences revealed that PRM3 was very different from PRM1 and from both the precursor and the mature sequences of PRM2. Among 10 mouse species, PRM3 showed weak evidence of positive selection in two species, but there was no clear association with levels of sperm competition. In analyses from among mammalian species, no evidence of positive selection was found in PRM3. We conclude that PRM3 exhibits several clear differences from other protamines and, furthermore, that it cannot be regarded as a true protamine.     

Chromosomal assignment of four rat genes coding for the spermatid-specific proteins proacrosin (ACR), transition proteins 1 (TNP1) and 2 (TNP2), and protamine 1 (PRM1)

The genes for proacrosin, protamines, and transition proteins are exclusively expressed in haploid spermatogenic cells. From the analysis of mouse x rat cell hybrids which segregate rat chromosomes, the rat gene for proacrosin (ACR) was assigned to chromosome 7, that for transition protein 1 (TNP1) to chromosome 9, and the genes for transition protein 2 (TNP2) and protamine 1 (PRM1) to chromosome 10.     

Prm3, the fourth gene in the mouse protamine gene cluster, encodes a conserved acidic protein that affects sperm motility

The protamine gene cluster containing the Prm1, Prm2, Prm3, and Tnp2 genes is present in humans, mice, and rats. The Prm1, Prm2, and Tnp2 genes have been extensively studied, but almost nothing is known about the function and regulation of the Prm3 gene. Here we demonstrate that an intronless Prm3 gene encoding a distinctive small acidic protein is present in 13 species from seven orders of mammals. We also demonstrate that the Prm3 gene has not generated retroposons, which supports the contention that genes that are expressed in meiotic and haploid spermatogenic cells do not generate retroposons. The Prm3 mRNA is first detected in early round spermatids, while the PRM3 protein is first detected in late spermatids. Thus, translation of the Prm3 mRNA is developmentally delayed similar to the Prm1, Prm2, and Tnp2 mRNAs. In contrast to PRM1, PRM2, and TNP2, PRM3 is an acidic protein that is localized in the cytoplasm of elongated spermatids and transfected NIH-3T3 cells. To elucidate the function of PRM3, the Prm3 gene was disrupted by homologous recombination. Sperm from Prm3(-/-) males exhibited reductions in motility, but the fertility of Prm3(-/-) and Prm3(+/+) males was similar in matings of one male and one female. We have developed a competition test in which a mutant male has to compete with a rival wild-type male to fertilize a female; the implications of these results are also discussed.     

Nuclear matrix attachment occurs in several regions of the IgH locus

The genome is thought to be divided into domains by DNA elements which mediate anchorage of chromosomal DNA to the nuclear matrix or chromosome scaffold. The positions of nuclear matrix anchorage regions (MARs) have been mapped within the 200 kb mouse immunoglobulin heavy chain constant region locus, thereby allowing an estimate of the size of DNA domains within a segment of the genome. MARs were identified in four regions, which appear to divide the locus into looped DNA domains of 30, 20, 30 and greater than 70 kb in length. These DNA domain sizes fall within the range of DNA loop sizes observed in histone-extracted nuclei and chromosomes. In two regions, large clusters of MARs were identified, and many of these MARs lie on DNA fragments that include repetitive DNA elements, perhaps indicating that repetitive DNA integrates into the genome close to MARs, or that some classes of repeats could themselves act as MARs.     

Homeotic protein binding sites, origins of replication, and nuclear matrix anchorage sites share the ATTA and ATTTA motifs.

Nuclear matrix organizes the mammalian chromatin into loops. This is achieved by binding of nuclear matrix proteins to characteristic DNA landmarks in introns as well as proximal and distal sites flanking the 5' and 3' ends of genes. Matrix anchorage sites (MARs), origins of replication (ORIs), and homeotic protein binding sites share common DNA sequence motifs. In particular, the ATTA and ATTTA motifs, which constitute the core elements recognized by the homeobox domain from species as divergent as flies and humans, are frequently occurring in the matrix attachment sites of several genes. The human apolipoprotein B 3' MAR and a stretch of the Chinese hamster DHFR gene intron and human HPRT gene intron shown to anchor these genes to the nuclear matrix are mosaics of ATTA and ATTTA motifs. Several origins of replication also share these elements. This observation suggests that homeotic proteins which control the expression level of many genes and pattern formation during development are components of the nuclear matrix. Thus, the nuclear matrix, known as the site of DNA replication, might sculpture the crossroads of the differential activation of origins during development and S-phase and the control of gene expression and pattern formation in embryogenesis.     

Identification of a candidate regulatory region in the human CD8 gene complex by colocalization of DNase I hypersensitive sites and matrix attachment regions which bind SATB1 and GATA-3

To locate elements regulating the human CD8 gene complex, we mapped nuclear matrix attachment regions (MARs) and DNase I hypersensitive (HS) sites over a 100-kb region that included the CD8B gene, the intergenic region, and the CD8A gene. MARs facilitate long-range chromatin remodeling required for enhancer activity and have been found closely linked to several lymphoid enhancers. Within the human CD8 gene complex, we identified six DNase HS clusters, four strong MARs, and several weaker MARs. Three of the strong MARs were closely linked to two tissue-specific DNase HS clusters (III and IV) at the 3' end of the CD8B gene. To further establish the importance of this region, we obtained 19 kb of sequence and screened for potential binding sites for the MAR-binding protein, SATB1, and for GATA-3, both of which are critical for T cell development. By gel shift analysis we identified two strong SATB1 binding sites, located 4.5 kb apart, in strong MARs. We also detected strong GATA-3 binding to an oligonucleotide containing two GATA-3 motifs located at an HS site in cluster IV. This clustering of DNase HS sites and MARs capable of binding SATB1 and GATA-3 at the 3' end of the CD8B gene suggests that this region is an epigenetic regulator of CD8 expression.     

Silencing by nuclear matrix attachment distinguishes cell-type specificity: association with increased proliferation capacity

DNA loop organization by nuclear scaffold/matrix attachment is a key regulator of gene expression that may provide a means to modulate phenotype. We have previously shown that attachment of genes to the NaCl-isolated nuclear matrix correlates with their silencing in HeLa cells. In contrast, expressed genes were associated with the lithium 3,5-diiodosalicylate (LIS)-isolated nuclear scaffold. To define their role in determining phenotype matrix attached regions (MARs) on human chromosomes 14–18 were identified as a function of expression in a primary cell line. The locations of MARs in aortic adventitial fibroblast (AoAF) cells were very stable (r = 0.909) and 96% of genes attached at MARs are silent (P < 0.001). Approximately one-third of the genes uniquely expressed in AoAF cells were associated with the HeLa cell nuclear matrix and silenced. Comparatively, 81% were associated with the AoAF cell nuclear scaffold (P < 0.001) and expressed. This suggests that nuclear scaffold/matrix association mediates a portion of cell type-specific gene expression thereby modulating phenotype. Interestingly, nuclear matrix attachment and thus silencing of specific genes that regulate proliferation and maintain the integrity of the HeLa cell genome suggests that transformation may at least in part be achieved through aberrant nuclear matrix attachment.     

核基质附着区与转基因表达

核基质附着区 (matrixattachmentregions,MARs)是与核基质 (或核骨架 )特异结合的DNA序列 ,属于非编码序列 ,富含AT。通过与核基质的结合 ,它能使染色质形成独立的环状结构 ,调控基因的转录和表达 ,减少由于位置效应引起的转基因沉默。MARs在提高转基因表达水平、消除转基因个体间表达水平的差异、抑制转基因沉默等方面起着重要的作用。就MAR的一些结构功能特征及其在基因工程中的应用等方面进行了阐述。