Chromosomal loop anchorage of the kappa immunoglobulin gene occurs next to the enhancer in a region containing topoisomerase II sites

Repositioning of human interphase chromosomes by nucleolar dynamics in the reverse transformation of HT1080 fibrosarcoma cells

An experimental system which should be valuable for studying the role of spatial positioning of the nuclear genome in human cell function has been developed. Reverse transformation of the malignant HT1080 fibrosarcoma cell line upon treatment with 8-chloro-cAMP results in growth inhibition, cytoskeletal reorganization, changes in nuclear shape and chromatin accessibility, and formation of prominent nucleoli. Fluorescent in situ hybridization was used to study DNA positioning during nuclear remodeling. Morphometric analysis of the hybridization sites for both repetitive sequences and "painting probes" for whole chromosomes indicated dispersal of acrocentric chromosomes in untreated cells and a highly organized central location of these ribosome gene-containing chromosomes in association with one or a few large nucleoli in nondividing treated cells. The results suggest that there was a directed movement of interphase chromosomes during a response which normalized a malignant cell line. These large-scale repositionings may serve two functions in restoring a normal transcriptional setup to the nucleus. First, ribosome genes are placed in the nucleolus, their transcriptional suborganelle. Second, nucleolar anchorings together with additional perinucleolar centromeric associations orient the domain shapes of entire chromosomes, installing gene-rich chromosomal regions into pockets of (accessible) DNAse I-sensitive chromatin populated by spliceosomes.

Meiotic double-strand breaks in yeast artificial chromosomes containing human DNA

Meiotic recombination in the yeast Saccharomyces cerevisiae is initiated by double-strand breaks (DSB) in chromosomal DNA. These DSB, which can be mapped in the rad 50S mutant yeast strain, are caused by a topoisomerase II-like enzyme, the protein Spo11. Evidence suggests that this protein is located in the axial element of the meiotic chromosome which implies that the DSB are located in these chromosomes in the vicinity of the bases of the DNA loops. We have found that in the yeast artificial chromosomes carrying human DNA, at the level of resolution obtained by pulsed field gel electrophoresis (PFGE), the meiotic DSB in the diploid yeast are co-localized with the DNase I hypersensitive sites (HS) in a haploid strain of yeast. These HS are located close to sequences which, under stress, have the potential to form secondary structures containing unpaired nucleotides. Clusters of such sequences could be a hallmark of the bases of the chromatin loops.

DNA topoisomerase II sites in the histone H4 gene during the highly synchronous cell cycle of Physarum polycephalum

The nearly perfect synchrony of nuclear division in a plasmodium of Physarum polycephalum provides a powerful system to analyze topoisomerase II cleavage sites in the course of the cell cycle. The histone H4 locus, whose schedule of replication and transcription is precisely known, was chosen for this analysis. Drug-induced topoisomerase II sites are clustered downstream of the histone H4 gene and appear highly dependent on cell cycle stage. They were only detected in mitosis and at the very beginning of S phase, precisely at the time of replication of the histone H4 region. The sites, which were absent in G2 phase, reappeared at the next mitosis. Remarkably, DNase I hypersensitive sites occurred in nearly the same location, but their schedule was totally different: they were absent in mitosis and present in G2. This schedule follows H4 transcription, which peaks in mid-S phase and in the second part of G2 phase and is off during mitosis. These results suggest that topoisomerase II may not be involved in transcription, but plays a role in remodeling chromatin structure, both during chromosome condensation in prophase/metaphase to allow their decatenation and during chromosome decondensation after metaphase to allow replication fork passage throughout the region.

Nuclear matrix attachment regions of human papillomavirus type 16 point toward conservation of these genomic elements in all genital papillomaviruses

The gene functions, transcriptional regulation, and genome replication of human papillomaviruses (HPVs) have been extensively studied. Thus far, however, there has been little research on the organization of HPV genomes in the nuclei of infected cells. As a first step to understand how chromatin and suprachromatin structures may modulate the life cycles of these viruses, we have identified and mapped interactions of HPV DNAs with the nuclear matrix. The endogenous genomes of HPV type 16 (HPV-16) which are present in SiHa, HPKI, and HPKII cells, adhere in vivo to the nuclear matrixes of these cell lines. A tight association with the nuclear matrix in vivo may be common to all genital HPV types, as the genomes of HPV-11, HPV-16, HPV-18, and HPV-33 showed high affinity in vitro to preparations of the nuclear matrix of C33A cells, as did the well-known nuclear matrix attachment region (MAR) of the cellular beta interferon gene. Affinity to the nuclear matrix is not evenly spread over the HPV-16 genome. Five genomic segments have strong MAR properties, while the other parts of the genome have low or no affinity. Some of the five MARs correlate with known cis-responsive elements: a strong MAR lies in the 5' segment of the long control region (LCR), and another one lies in the E6 gene, flanking the HPV enhancer, the replication origin, and the E6 promoter. The strongest MAR coincides with the E5 gene and the early-late intergenic region. Weak MAR activity is present in the E1 and E2 genes and in the 3' part of L2. The in vitro map of MAR activity appears to reflect MAR properties in vivo, as we found for two selected fragments with and without MAR activity. As is typical for many MARs, the two segments with highest affinity, namely, the 5' LCR and the early-late intergenic region, have an extraordinarily high A-T content (up to 85%). It is likely that these MARs have specific functions in the viral life cycle, as MARs predicted by nucleotide sequence analysis, patterns of A-T content, transcription factor YY1 binding sites, and likely topoisomerase II cleavage sites are conserved in similar positions throughout all genital HPVs.

The genomic sequences bound to special AT-rich sequence-binding protein 1 (SATB1) in vivo in Jurkat T cells are tightly associated with the nuclear matrix at the bases of the chromatin loops

Special AT-rich sequence-binding protein 1 (SATB1), a DNA-binding protein expressed predominantly in thymocytes, recognizes an ATC sequence context that consists of a cluster of sequence stretches with well-mixed A's, T's, and C's without G's on one strand. Such regions confer a high propensity for stable base unpairing. Using an in vivo cross-linking strategy, specialized genomic sequences (0.1-1. 1 kbp) that bind to SATB1 in human lymphoblastic cell line Jurkat cells were individually isolated and characterized. All in vivo SATB1-binding sequences examined contained typical ATC sequence contexts, with some exhibiting homology to autonomously replicating sequences from the yeast Saccharomyces cerevisiae that function as replication origins in yeast cells. In addition, LINE 1 elements, satellite 2 sequences, and CpG island-containing DNA were identified. To examine the higher-order packaging of these in vivo SATB1-binding sequences, high-resolution in situ fluorescence hybridization was performed with both nuclear "halos" with distended loops and the nuclear matrix after the majority of DNA had been removed by nuclease digestion. In vivo SATB1-binding sequences hybridized to genomic DNA as single spots within the residual nucleus circumscribed by the halo of DNA and remained as single spots in the nuclear matrix, indicating that these sequences are localized at the base of chromatin loops. In human breast cancer SK-BR-3 cells that do not express SATB1, at least one such sequence was found not anchored onto the nuclear matrix. These findings provide the first evidence that a cell type-specific factor such as SATB1 binds to the base of chromatin loops in vivo and suggests that a specific chromatin loop domain structure is involved in T cell-specific gene regulation.

In vivo analysis of scaffold-associated regions in Drosophila: a synthetic high-affinity SAR binding protein suppresses position effect variegation

Scaffold-associated regions (SARs) were studied in Drosophila melanogaster by expressing a synthetic, high-affinity SAR-binding protein called MATH (multi-AT-hook), which consists of reiterated AT-hook peptide motifs; each motif is known to recognize a wide variety of short AT-rich sequences. MATH proteins were expressed specifically in the larval eye imaginal discs by means of the tetracycline-regulated transactivation system and tested for their effect on position effect variegation (PEV). MATH20, a highly potent SAR ligand consisting of 20 AT-hooks, was found to suppress whitemottled 4 variegation. This suppression required MATH20 expression at an early larval developmental stage. Our data suggest an involvement of the high AT-rich SARs in higher order chromatin structure and gene expression.

Human matrix attachment regions insulate transgene expression from chromosomal position effects in Drosophila melanogaster

Germ line transformation of white- Drosophila embryos with P-element vectors containing white expression cassettes results in flies with different eye color phenotypes due to position effects at the sites of transgene insertion. These position effects can be cured by specific DNA elements, such as the Drosophila scs and scs' elements, that have insulator activity in vivo. We have used this system to determine whether human matrix attachment regions (MARs) can function as insulator elements in vivo. Two different human MARs, from the apolipoprotein B and alpha1-antitrypsin loci, insulated white transgene expression from position effects in Drosophila melanogaster. Both elements reduced variability in transgene expression without enhancing levels of white gene expression. In contrast, expression of white transgenes containing human DNA segments without matrix-binding activity was highly variable in Drosophila transformants. These data indicate that human MARs can function as insulator elements in vivo.

The mapping of DNA topoisomerase sites in vivo: a tool to enlight the functions of topoisomerases

The possibility to record a trace of the precise sites of topoisomerase action has been exploited for almost 12 years in many laboratories. The large majority of the studies were performed in vitro, giving a good picture of sequence specificities of topoisomerases, and of the preference of various drugs for some sequences. Only a relatively small number of reports concern in vivo studies. Their main conclusions are the following: i) topoisomerase II sites are often found near replication origins and termini, where they are supposed to play a role in the decatenation of daughter DNA molecules, and possibly in the initiation of replication; ii) topoisomerase II sites are found in the promoter region of many genes, but they seem related to the condensation state of chromatin in this region, rather than to transcription per se; iii) some topoisomerase II sites, resistant to high salt, are found in or near matrix associated regions (MARs), suggesting a role in loop anchorage or (and) in the control of topology of individual chromatin loops; iv) topoisomerase I sites appear less localized, acting all along the transcription units, where they seem directly involved in transcription; and v) topoisomerase I sites are possibly connected with replication fork progression and (or) with the termination of replication. Despite these advances, the precise role of topoisomerases in vivo is still poorly understood, especially in recombination and chromatin condensation and decondensation during the cell cycle. Future attempts should take into account the possible specialization of the multiple topoisomerases found in a given cell, and the use of highly synchronized systems.

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.

Nuclear matrix proteins and osteoblast gene expression

The molecular mechanisms that couple osteoblast structure and gene expression are emerging from recent studies on the bone extracellular matrix, integrins, the cytoskeleton, and the nucleoskeleton (nuclear matrix). These proteins form a dynamic structural network, the tissue matrix, that physically links the genes with the substructure of the cell and its substrate. The molecular analog of cell structure is the geometry of the promoter. The degree of supercoiling and bending of promoter DNA can regulate transcriptional activity. Nuclear matrix proteins may render a change in cytoskeletal organization into a bend or twist in the promoter of target genes. We review the role of nuclear matrix proteins in the regulation of gene expression with special emphasis on osseous tissue. Nuclear matrix proteins bind to the osteocalcin and type I collagen promoters in osteoblasts. One such protein is Cbfa1, a recently described transcriptional activator of osteoblast differentiation. Although their mechanisms of action are unknown, some nuclear matrix proteins may act as "architectural" transcription factors, regulating gene expression by bending the promoter and altering the interactions between other trans-acting proteins. The osteoblast nuclear matrix is comprised of cell- and phenotype-specific proteins including proteins common to all cells. Nuclear matrix proteins specific to the osteoblast developmental stage and proteins that distinguish osteosarcoma from the osteoblast have been identified. Recent studies indicating that nuclear matrix proteins mediate bone cell response to parathyroid hormone and vitamin D are discussed.

A nuclear matrix/scaffold attachment region co-localizes with the gypsy retrotransposon insulator sequence

The 5'-untranslated region of the Drosophila gypsy retrotransposon contains an "insulator," which disrupts the interactions between enhancer and promoter elements located apart. The insulator effect is dependent on the suppressor of Hairy-wing (su(Hw)) protein, which binds to reiterated sites within the 350 base pairs of the gypsy insulator, whereby it additionally acts as a transcriptional activator of gypsy. Here, we show that the 350-base pair su(Hw) binding site-containing gypsy insulator behaves in addition as a matrix/scaffold attachment region (MAR/SAR), involved in interactions with the nuclear matrix. In vitro experiments using nuclear matrices from Drosophila, murine, and human cells demonstrate specific binding of the gypsy insulator, not observed with any other sequence within the retrotransposon. Moreover, we show that the gypsy insulator, like previously characterized MAR/SARs, specifically interacts with topoisomerase II and histone H1, i.e. with two essential components of the nuclear matrix. Finally, experiments within cells in culture demonstrate differential effects of the gypsy MAR sequence on reporter genes, namely no effect under conditions of transient transfection and a repressing effect in stable transformants, as expected for a sequence involved in chromatin structure and organization. A model for the gypsy insulator, which combines within a short "compacted" retroviral sequence three functional domains (insulator, enhancer, and the presently unraveled MAR/SAR) dispersed within more extended regions in other "boundary" domains, is discussed in relation to previously proposed models for insulation.

Scaffold-associated regions in the human type I interferon gene cluster on the short arm of chromosome 9

Scaffold-associated regions (SARs) function at the level of modeling or shaping the chromatin of DNA into loop domains. We have mapped 36 SARs in the human type I interferon (IFN) gene complex on chromosome 9, band p21-22, to examine the overall structure of this gene complex. A total of 29 strong SARs and 7 weak SARs were mapped to the flanking regions of the different interferon genes. Twenty-two strong SARs mapped to the flanking regions of 13 interferon (IFNA) alpha genes; 2 strong SARs mapped to one interferon omega (IFNW) gene; 2 strong SARs mapped to one interferon alpha pseudogene (IFNAP); and 3 strong SARs mapped to two interferon omega pseudogenes (IFNWP). One weak SAR mapped to the flanking region of one IFNA gene, whereas 6 weak SARs flanked four IFN pseudogenes (P11, P12 P20, P23). The IFN SAR structure was comparable between the BV173 leukemia cell line and the U373 glioma cell line. Analysis of two glioma deletion breakpoint junctions, where breaks occur within and outside the IFN gene cluster, revealed an association with SARs. IFN SARs showed evidence for cooperativity among the SARs, while DNA sequence analysis revealed a series of clustered A-tracts within strong SARs. These data suggest that the IFN genes may be organized into a series of small (2-10 kb) DNA loop domains, with each loop containing a coding region flanked by SARs. In our model, the SAR enrichment and the clustering of A-tracts observed at the SARs within the IFN gene complex represent a higher level of chromatin organization, which may predispose this region to breakage.

Differentiation-specific nuclear matrix proteins cross-linked to DNA by cis-diammine dichloroplatinum

DNA-protein cross-linkages were performed in intact undifferentiated and differentiated-HL60 cells by the action of cis-diammine dichloroplatinum. Total nuclear matrix proteins and DNA cross-linked nuclear matrix proteins were resolved by two-dimensional gel electrophoresis. The comparison of the electrophoretic patterns allowed the identification of a set of differentiation-induced nuclear matrix proteins cross-linked to DNA. One of these proteins binds cloned histone SAR sequences. Our results outline an experimental strategy for isolating and characterizing nuclear matrix components that may play a fundamental role in the overall control and coordination of gene expression during differentiation.

DNA topoisomerase II cleavage of telomeres in vitro and in vivo

In this work, we have analyzed the reactivity of DNA topoisomerase II with telomeric DNA both in vitro and in vivo. Topoisomerase II cleavage reactions were performed on the tandem repeats of telomeric DNA. Analysis of this DNA on sequencing gels revealed that DNA topoisomerase II is catalytically active in cleaving the telomere DNA repeat. The topoisomerase II cleavage site is 5'TTAGG*G3' (cleavage site marked by the asterisk) and since telomere DNA is a tandem array of the above sequence, topoisomerase cleavage sites could exist every six base pairs. Detection of topoisomerase II cleavages was strongly dependent upon one specific topoisomerase II poison, etoposide (VP-16). A number of other topoisomerase II poisons were tested but did not stimulate cleavage activity at the telomere repeat. We have also analyzed the association of endogenous topoisomerase II with chromosomal telomeric DNA in HeLa cells. The in vivo complex of enzyme (ICE) bioassay was used to isolate topoisomerase II-DNA covalent complexes. In consistence with in vitro cleavage data, endogenous topoisomerase II-telomeric DNA complexes were detected in only etoposide-treated HeLa cells.

In vivo etoposide-resistant C6 glioma cell line: significance of altered DNA topoisomerase II activity in multi-drug resistance

We have established an in vivo etoposide-resistant glioma cell line (C6/VP) from C6 rat glioma cells by stepwise exposure to increasing doses of etoposide. The C6/VP cells were 10 times more resistant to etoposide than the parental C6 cells. In addition C6/VP cells demonstrated cross-resistance to vincristine and vinblastine, but not to ADM or m-AMSA. Interestingly, the cells had collateral sensitivity to ACNU, cisDDP and Ara-C. The C6/VP cells did not express the MDR gene or p-glycoprotein, while they showed 16 times less topoisomerase II catalytic activity compared to the C6 cells. Although there was no significant difference between C6 and C6/VP cells in amounts of topoisomerase II in nuclear extracts, the C6/VP cells had 2.9 times higher amounts of the enzyme than C6 cells in nuclear scaffold prepared from a relatively low-salt buffer (0.5 M NaCl). Northern blot analysis demonstrated that mRNAs of topoisomerase IIalpha isoforms were expressed both in C6 and C6/VP cells, and that the amounts of topoisomerase IIalpha in C6/VP cells were 14 times greater than in C6 cells. The total uptake of etoposide in tumor tissues derived from C6/VP cells was 3 times less than those derived from parental C6 cells. These results indicate that the C6/VP acquired a multi-drug resistance phenotype by a reduction of the catalytic activity of topoisomerase II and/or diminished accumulation of drugs. This phenotype did not involve the p-glycoprotein. Alterations of topoisomerase II in the C6/VP cells also were accompanied by an increased amount of the topoisomerase IIalpha isoform, most of which was localized in the nuclear scaffold (matrix). This suggests that altered binding of topoisomerase II to topologically organized DNAs in the nuclear scaffold may be the molecular basis of this multi-drug resistance phenotype.

Nuclear matrix associated DNA-binding proteins of ocular lens epithelial cells

Association of transcription factors with the nuclear matrix represents a mechanism by which nuclear architecture may influence transcriptional control of gene expression. This investigation examines nuclear matrix associated proteins (NMP's) isolated from ocular lens epithelial cells by monitoring DNA binding activities using consensus oligonucleotides recognized by the transcription factors YY1, AML-1, AP-1, SP-1 and ATF. The nuclear matrix fractions tested included an immortilized human lens epithelial cell line containing the SV40 large T-antigen, and two mouse lens epithelial cell lines derived from either a normal mouse or a cataract mouse. A rabbit epidermal epithelial cell line and HeLa cells were also included in this study for comparison. The data from these experiments reveal that ubiquitously represented and tissue restricted regulatory proteins are associated with nuclear matrix of lens epithelial cells. The functional significance of the nuclear matrix association of these transcription factors remains to be determined. However, our findings raise the possibility that the transcription factors associated with the nuclear matrix could have specific roles in gene regulation and eye tissue development.

The novel SAR-binding domain of scaffold attachment factor A (SAF-A) is a target in apoptotic nuclear breakdown

The scaffold attachment factor A (SAF-A) is an abundant component of the nuclear scaffold and of chromatin, and also occurs in heterogeneous nuclear ribonucleoprotein (hnRNP) complexes. Evidence from previous experiments had suggested that SAF-A most likely has at least two different functions, being involved both in nuclear architecture and RNA metabolism. We now show that the protein has a novel scaffold-associated region (SAR)-specific bipartite DNA-binding domain which is independent from the previously identified RNA-binding domain, the RGG box. During apoptosis, but not during necrosis, SAF-A is cleaved in a caspase-dependent way. Cleavage occurs within the bipartite DNA-binding domain, resulting in a loss of DNA-binding activity and a concomitant detachment of SAF-A from nuclear structural sites. On the other hand, cleavage does not compromise the association of SAF-A with hnRNP complexes, indicating that the function of SAF-A in RNA metabolism is not affected in apoptosis. Our results suggest that detachment of SAF-A from SARs, caused by apoptotic proteolysis of its DNA-binding domain, is linked to the formation of oligonucleosomal-sized DNA fragments and could therefore contribute to nuclear breakdown in apoptotic cells.

Matrix attachment regions and transcription units in a polygenic mammalian locus overlapping two isochores

Eukaryotic chromosomes are ponctuated by specialized DNA sequences (MARs) characterized by their ability to bind the network of nonhistone proteins that form the nuclear matrix or scaffold. We previously described an amplifiable cluster of genes with different tissue-specific expression patterns, located on Chinese hamster chromosome 1q. This model is especially appropriate to study the relationships between MARs and transcription units. We show here that four attachment regions, with sequences exhibiting motifs specific to MARs, are present within the 100 kb of screened DNA. Three of them are relatively short sequences localized in intergenic regions. The last one extends over one of the transcription units and contains a region previously identified as a recombination hot spot. Moreover, the analysis of a DNA sequence extending over some 50 Kb of this region and spanning at least four genes, disclosed a strikingly sharp change in G + C content. This strongly suggests that the studied region contains the boundary of two isochores. We propose that the frequency and the size of MARs are correlated to their localization in G + C rich or poor domains.

Stress-induced duplex DNA destabilization in scaffold/matrix attachment regions

S/MARs are DNA elements 300 to several thousand base-pairs long, which are operationally defined by their affinity for the nuclear scaffold or matrix. S/MARs occur exclusively in eukaryotic genomes, where they mediate several functions. Because S/MARs do not have a clearcut consensus sequence, the characteristics that define their activity are thought to be structural. Ubiquitous S/MAR binding proteins have been identified, but to date no unique binding sequence or structural motif has been found. Here we show by computational analysis that S/MARs conform to a specific design whose essential attribute is the presence of stress-induced base-unpairing regions (BURs). Stress-induced destabilization (SIDD) profiles are calculated using a previously developed statistical mechanical procedure in which the superhelical deformation is partitioned between strand separation, twisting within denatured regions, and residual superhelicity. The results of these calculations show that BURs exhibit a succession of evenly spaced destabilized sites that would render part or all of the S/MAR sequence single stranded at sufficient superhelicity. These analyses are performed for a range of sequenced S/MAR elements from the borders of eukaryotic gene domains, from centromeres, and from positions where S/MARs are known to support the action of an enhancer. The results reported here are in excellent agreement with earlier in vitro chemical reactivity studies. This approach demonstrates the potential for computational analysis to predict the points of division of the eukaryotic genome into functional units (domains), and also to locate certain cis-regulatory sequences.

Direct interaction of the KRAB/Cys2-His2 zinc finger protein ZNF74 with a hyperphosphorylated form of the RNA polymerase II largest subunit

We previously identified ZNF74 as a developmentally expressed gene commonly deleted in DiGeorge syndrome. ZNF74 encodes an RNA-binding protein tightly associated with the nuclear matrix and belongs to a large subfamily of Cys2-His2 zinc finger proteins containing a KRAB (Kruppel-associated box) repressor motif. We now report on the multifunctionality of the zinc finger domain of ZNF74. This nucleic acid binding domain is shown here to function as a nuclear matrix targeting sequence and to be involved in protein-protein interaction. By far-Western analysis and coimmunoprecipitation studies, we demonstrate that ZNF74 interacts, via its zinc finger domain, with the hyperphosphorylated largest subunit of RNA polymerase II (pol IIo) but not with the hypophosphorylated form. The importance of the phosphorylation in this interaction is supported by the observation that phosphatase treatment inhibits ZNF74 binding. Double immunofluorescence experiments indicate that ZNF74 colocalizes with the pol IIo and the SC35 splicing factor in irregularly shaped subnuclear domains. Thus, ZNF74 sublocalization in nuclear domains enriched in pre-mRNA maturating factors, its RNA binding activity, and its direct phosphodependent interaction with the pol IIo, a form of the RNA polymerase functionally associated with pre- mRNA processing, suggest a role for this member of the KRAB multifinger protein family in RNA processing.

A DNA-binding element for a steroid receptor-binding factor is flanked by dual nuclear matrix DNA attachment sites in the c-myc gene promoter

The receptor-binding factor (RBF) for the avian oviduct progesterone (Pg) receptor (PR) has previously been shown to be a unique 10-kDa nuclear matrix protein that generates high affinity PR-binding sites on avian DNA. This paper describes the use of Southwestern blot and DNA gel shift analyses with RBF protein to identify a minimal 54-base pair RBF-binding element in the matrix-associated region (MAR) of the Pg-regulated c-myc gene promoter. This element contains a 5'-GC-rich domain and a 3'-AT-rich domain, the latter of which has a homopurine/homopyrimidine structure. The gel shift assays required the generation of an RBF-maltose fusion protein (RBF-MBP), which specifically binds this element and is supershifted when the anti-RBF polyclonal antibody is added. Computer analysis of the full-length amino acid sequence for RBF predicts a DNA-binding motif involving a beta-sheet structure at the N-terminal domain. Southern blot analyses using nuclear matrix DNA suggests that there are dual MAR sites in the c-myc promoter, which flank an intervening domain containing the RBF element. The co-transfection of this MAR sequence, containing the RBF element and cloned into a luciferase reporter vector, together with an RBF expression vector construct, into steroid treated human MCF-7 cells, results in a decrease of the c-myc promoter activity relative to control transfections containing only the parent vector of the RBF expression construct. These data suggest that a unique chromatin/nuclear matrix structure, composed of the RBF-DNA element complex which is flanked by nuclear matrix attachment sites, serves to bind the PR and repress the c-myc promoter.

The matrix attachment region-binding protein SATB1 participates in negative regulation of tissue-specific gene expression

The nuclear matrix has been implicated in several cellular processes, including DNA replication, transcription, and RNA processing. In particular, transcriptional regulation is believed to be accomplished by binding of chromatin loops to the nuclear matrix and by the concentration of specific transcription factors near these matrix attachment regions (MARs). A number of MAR-binding proteins have been identified, but few have been directly linked to tissue-specific transcription. Recently, we have identified two cellular protein complexes (NBP and UBP) that bind to a region of the mouse mammary tumor virus (MMTV) long terminal repeat (LTR) previously shown to contain at least two negative regulatory elements (NREs) termed the promoter-proximal and promoter-distal NREs. These NREs are absent from MMTV strains that cause T-cell lymphomas instead of mammary carcinomas. We show here that NBP binds to a 22-bp sequence containing an imperfect inverted repeat in the promoter-proximal NRE. Previous data showed that a mutation (p924) within the inverted repeat elevated basal transcription from the MMTV promoter and destabilized the binding of NBP, but not UBP, to the proximal NRE. By using conventional and affinity methods to purify NBP from rat thymic nuclear extracts, we obtained a single major protein of 115 kDa that was identified by protease digestion and partial sequencing analysis as the nuclear matrix-binding protein special AT-rich sequence-binding protein 1 (SATB1). Antibody ablation, distamycin inhibition of binding, renaturation and competition experiments, and tissue distribution data all confirmed that the NBP complex contained SATB1. Similar types of experiments were used to show that the UBP complex contained the homeodomain protein Cux/CDP that binds the MAR of the intronic heavy-chain immunoglobulin enhancer. By using the p924 mutation within the MMTV LTR upstream of the chloramphenicol acetyltransferase gene, we generated two strains of transgenic mice that had a dramatic elevation of reporter gene expression in lymphoid tissues compared with reporter gene expression in mice expressing wild-type LTR constructs. Thus, the 924 mutation in the SATB1-binding site dramatically elevated MMTV transcription in lymphoid tissues. These results and the ability of the proximal NRE in the MMTV LTR to bind to the nuclear matrix clearly demonstrate the role of MAR-binding proteins in tissue-specific gene regulation and in MMTV-induced oncogenesis.

Clusters of S1 nuclease-hypersensitive sites induced in vivo by DNA damage

DNA end-labeling procedures were used to analyze both the frequency and distribution of DNA strand breaks in mammalian cells exposed or not to different types of DNA-damaging agents. The 3' ends were labeled by T4 DNA polymerase-catalyzed nucleotide exchange carried out in the absence or presence of Escherichia coli endonuclease IV to cleave abasic sites and remove 3' blocking groups. Using this sensitive assay, we show that DNA isolated from human cells or mouse tissues contains variable basal levels of DNA strand interruptions which are associated with normal bioprocesses, including DNA replication and repair. On the other hand, distinct dose-dependent patterns of DNA damage were assessed quantitatively in cultured human cells exposed briefly to menadione, methylmethane sulfonate, topoisomerase II inhibitors, or gamma rays. In vivo induction of single-strand breaks and abasic sites by methylmethane sulfonate was also measured in several mouse tissues. The genomic distribution of these lesions was investigated by DNA cleavage with the single-strand-specific S1 nuclease. Strikingly similar cleavage patterns were obtained with all DNA-damaging agents tested, indicating that the majority of S1-hypersensitive sites detected were not randomly distributed over the genome but apparently were clustered in damage-sensitive regions. The parallel disappearance of 3' ends and loss of S1-hypersensitive sites during post-gamma-irradiation repair periods indicates that these sites were rapidly repaired single-strand breaks or gaps (2- to 3-min half-life). Comparison of S1 cleavage patterns obtained with gamma-irradiated DNA and gamma-irradiated cells shows that chromatin structure was the primary determinant of the distribution of the DNA damage detected.

The cleavage of nuclear DNA into high molecular weight DNA fragments occurs not only during apoptosis but also accompanies changes in functional activity of the nonapoptotic cells

In this paper we demonstrate that apoptosis in primary culture of murine thymocytes and in continuously growing human cells is associated with the progressive disintegration of nuclear DNA into high molecular weight (HMW)-DNA fragments of about 50-150 kb. We also show that the formation of similarly sized HMW-DNA fragments takes place in the same cells in the absence of apoptotic inducers. Unlike an apoptotic fragmentation of nuclear DNA, the formation of HMW-DNA fragments in nonapoptotic cells is rapidly induced, has no correlation with the cell death, and is not associated with the development of oligonucleosomal "ladder" or apoptotic changes in nuclear morphology. The disintegration of DNA into HMW-fragments is also observed in nuclei isolated from healthy, nonapoptosizing tissues of various eukaryotes. We show that the formation of HMW-DNA fragments in the absence of apoptotic inducers is strongly dependent on the ionic detergents, is responsive to the topoisomerase II-specific poison, teniposide, and is completely reversible under conditions that favor topoisomerase II-dependent rejoining reaction. Also, we demonstrate that the formation of HMW-DNA fragments in continuously growing cell lines caused either by serum deprivation or monolayer establishment is of a transient nature and rapidly reverses to the control level following serum addition or dilution of monolayer. The results suggest that the cleavage of nuclear DNA into HMW-DNA fragments is associated not only with apoptosis but also accompanies changes in functional activity of nonapoptotic cells.

The osteocalcin gene: a model for multiple parameters of skeletal-specific transcriptional control

Influences of promoter regulatory elements that are responsive to basal and tissue-restricted transactivation factors, steroid hormones, growth factors and other physiologic mediators has provided the basis for understanding regulatory mechanisms contributing to developmental expression of osteocalcin, tissue specificity and biological activity (reviewed in [1-3]). These regulatory elements and cognate transcription factors support postproliferative transcriptional activation and steroid hormone (e.g. vitamin D) enhancement at the onset of extracellular matrix mineralization during osteoblast differentiation. Three parameters of nuclear structure contribute to osteocalcin gene transcriptional control. The linear representation of promoter elements provides competency for physiological responsiveness within the contexts of developmental as well as phenotype-dependent regulation. Chromatin structure and nucleosome organization reduce distances between independent regulatory elements providing a basis for integrating components of transcriptional control. The nuclear matrix supports gene expression by imposing physical constraints on chromatin related to three dimensional genomic organization. In addition, the nuclear matrix facilitates gene localization as well as the concentration and targeting of transcription factors. Several lines of evidence are presented which are consistent with involvement of multiple levels of nuclear architecture in tissue-specific gene expression during differentiation. Growth factor and steroid hormone responsive modifications in chromatin structure, nucleosome organization and the nuclear matrix are considered which influence transcription of the bone tissue-specific osteocalcin gene during progressive expression of the osteoblast phenotype.

Interaction of the nuclear matrix-associated region (MAR)-binding proteins, SATB1 and CDP/Cux, with a MAR element (L2a) in an upstream regulatory region of the mouse CD8a gene

Matrix-associated regions (MARs), AT-rich DNA segments that have an affinity for the nuclear matrix, have been shown to play a role in transcriptional regulation of eukaryotic genes. The present study demonstrates that a DNA element, called L2a, which has been implicated in the transcriptional regulation of the mouse CD8a gene encoding an important T cell coreceptor, is a MAR. Moreover, the identities of two nuclear proteins, L2a-P1 and L2a-P2, previously shown to bind to the L2a element, have been determined. The L2a-P1 protein found to be present in all CD8-positive T cell lines tested is SATB1, a known MAR-binding protein. The widely expressed L2a-P2 protein is CDP/Cux, a MAR-binding protein that has been associated with repression of gene transcription. Interaction of both proteins with the L2a element was studied using the missing nucleoside approach, DNase I footprinting, and electrophoretic mobility shift assays with wild type and mutant L2a elements. The data suggest that CDP/Cux bound to the L2a element is displaced by binding of SATB1 and the accompanying conformational change in the DNA lying between the primary binding sites of SATB1 and CDP/Cux. We suggest that displacement of CDP/Cux by SATB1 favors transcription of the CD8a gene, possibly by enhancing or altering its association with the nuclear matrix.

Cells strongly expressing Ig(kappa) transgenes show clonal recruitment of hypermutation: a role for both MAR and the enhancers

The V regions of immunoglobulin kappa transgenes are targets for hypermutation in germinal centre B cells. We show by use of modified transgenes that the recruitment of hypermutation is substantially impaired by deletion of the nuclear matrix attachment region (MAR) which flanks the intron-enhancer (Ei). Decreased mutation is also obtained if Ei, the core region of the kappa3'-enhancer (E3') or the E3'-flank are removed individually. A broad correlation between expression and mutation is indicated not only by the fact that the deletions affecting mutation also give reduced transgene expression, but especially by the finding that, within a single mouse, transgene mutation was considerably reduced in germinal centre B cells that poorly expressed the transgene as compared with strongly expressing cells. We also observed that the diminished mutation in transgenes carrying regulatory element deletions was manifested by an increased proportion of B cells in which the transgene had not been targeted at all for mutation rather than in the extent of mutation accumulation once targeted. Since mutations appear to be incorporated stepwise, the results point to a connection between transcription initiation and the clonal recruitment of hypermutation, with hypermutation being more fastidious than transcription in requiring the presence of a full complement of regulatory elements.

DNA cleavage within the MLL breakpoint cluster region is a specific event which occurs as part of higher-order chromatin fragmentation during the initial stages of apoptosis

A distinct population of therapy-related acute myeloid leukemia (t-AML) is strongly associated with prior administration of topoisomerase II (topo II) inhibitors. These t-AMLs display distinct cytogenetic alterations, most often disrupting the MLL gene on chromosome 11q23 within a breakpoint cluster region (bcr) of 8.3 kb. We recently identified a unique site within the MLL bcr that is highly susceptible to DNA double-strand cleavage by classic topo II inhibitors (e.g., etoposide and doxorubicin). Here, we report that site-specific cleavage within the MLL bcr can be induced by either catalytic topo II inhibitors, genotoxic chemotherapeutic agents which do not target topo II, or nongenotoxic stimuli of apoptotic cell death, suggesting that this site-specific cleavage is part of a generalized cellular response to an apoptotic stimulus. We also show that site-specific cleavage within the MLL bcr can be linked to the higher-order chromatin fragmentation that occurs during the initial stages of apoptosis, possibly through cleavage of DNA loops at their anchorage sites to the nuclear matrix. In addition, we show that site-specific cleavage is conserved between species, as specific DNA cleavage can also be demonstrated within the murine MLL locus. Lastly, site-specific cleavage during apoptosis can also be identified at the AML1 locus, a locus which is also frequently involved in chromosomal rearrangements present in t-AML patients. In conclusion, these results suggest the potential involvement of higher-order chromatin fragmentation which occurs as a part of a generalized apoptotic response in a mechanism leading to chromosomal translocation of the MLL and AML1 genes and subsequent t-AML.

A c-erbB-2 promoter-specific nuclear matrix protein from human breast tumor tissues mediates NF-kappaB DNA binding activity

The c-erbB-2 gene overexpression plays a major role in the pathogenesis of breast cancer. Binding studies detected a nuclear matrix protein (NMP) in human breast tumor tissues that recognizes a matrix attachment region (MAR) in the immediate vicinity of the c-erbB-2 gene promoter. This NMP is expressed in breast tumor tissues and cell lines along with c-erbB-2, but is not found in corresponding normal tissues. Furthermore, when NMP purified from the breast tumors by its affinity to the MAR sequence is added to nuclear extracts of breast cancer cells, it selectively stimulates the binding of the NF-kappaB transcription factor to DNA. A model is suggested in which the association of the MAR-like sequence with the nuclear matrix raises the local concentration of the specific NMP, which in turn interacts with the nuclear factor NF-kappaB to increase its local level. Such a complex could explain at a molecular level the "increase in NF-kappaB DNA binding activity" often observed in c-erbB-2- and BRCA1-positive human breast tumors. The increased NF-kappaB activity could thereby contribute to breast cancer progression.

Distribution of topoisomerase II-mediated cleavage sites and relation to structural and functional landmarks in 830 kb of Drosophila DNA

The pattern of sites for cleavage mediated by topoisomerase II was determined in 830 kb of cloned DNA from the Drosophila X chromosome, with the objectives of comparing it with mapped structural and functional landmarks and examining if the correlations with such landmarks reported in individual loci can be generalized to a region approximately 100 times longer. The relative frequencies of topoisomerase II cleavage sites in 247 restriction fragments from 67 clones were quantified by hybridization with probes prepared from DNA fragments which abutted all cleavage sites in each clone, selected through the covalently bound topoisomerase II subunit; the specificity and quantitative nature of this method were demonstrated using a plasmid DNA model. The 12 restriction fragments with strong nuclear scaffold attachment (SAR) activity, of which seven possess autonomous replication (ARS) activity, show statistically strong coincidence or contiguity ( P </=0.11) with regions of high topoisomerase II cleavage site frequency. These regions show no correlation with repetitive sequence or A/T or C/G content and some extend over >10 kb; their sensitivity is therefore unlikely to be due to alternating purine-pyrimidine repeats or regions of Z conformation, which are preferred motifs. The hypothesis that they possess intrinsic curvature is consistent with the similarity of their length and spacing to regions of predicted curvature in the 315 kb DNA of Saccharomyces cerevisiae chromosome III and with the reported strong binding preference of topoisomerase II for curved DNA. The topoisomerase II cleavage pattern in this DNA further shows that its relationships to functional properties seen in individual loci, especially to MAR/SAR and ARS activity and to the restricted accessibility of DNA to topoisomerase II in vivo, can be generalized to much longer regions of the genome.

Position-independent and high-level expression of human alpha-lactalbumin in the milk of transgenic rats carrying a 210-kb YAC DNA

The level of expression of transgenes in transgenic animals varies among lines, and is often much lower than that of endogenous genes (position effects). In order to surmount position effects and establish a more efficient production system of transgenic animals producing pharmaceutical proteins in their milk, transgenic rats carrying 210-kb YAC DNA containing the human alpha-lactalbumin gene were produced. Three transgenic lines transmitted the transgene to the next generation. They had one copy of the alpha-lactalbumin gene and secreted human alpha-lactalbumin in their milk at concentrations of 2.0-4.3 mg/ml. No position effect was seen. The transgene was expressed specifically in the mammary gland of the transgenic rats. The 210-kb region is thought to contain all the DNA elements required for proper expression of the human alpha-lactalbumin gene. The YAC carrying the human alpha-lactalbumin gene is a potential vector for the expression of foreign genes in the mammary gland.

An enhancer-blocking element between alpha and delta gene segments within the human T cell receptor alpha/delta locus

T cell receptor (TCR) alpha and delta gene segments are organized within a single genetic locus but are differentially regulated during T cell development. An enhancer-blocking element (BEAD-1, for blocking element alpha/delta 1) was localized to a 2.0-kb region 3' of TCR delta gene segments and 5' of TCR alpha joining gene segments within this locus. BEAD-1 blocked the ability of the TCR delta enhancer (Edelta) to activate a promoter when located between the two in a chromatin-integrated construct. We propose that BEAD-1 functions as a boundary that separates the TCR alpha/delta locus into distinct regulatory domains controlled by Edelta and the TCR alpha enhancer, and that it prevents Edelta from opening the chromatin of the TCR alpha joining gene segments for VDJ recombination at an early stage of T cell development.

Expression of the (recombinant) endogenous immunoglobulin heavy-chain locus requires the intronic matrix attachment regions

The elements which regulate gene expression have traditionally been identified by their effects on reporter genes which have been transfected into cell lines or animals. It is generally assumed that these elements have a comparable role in expression of the corresponding endogenous locus. Nevertheless, several studies of immunoglobulin heavy-chain (IgH) gene expression have reported that the requirements for expressing IgH-derived transgenes differ from the requirements for expression of the endogenous IgH locus. Thus, although expression of transgenes requires multiple elements from the J(H)-C mu intron--the E mu core enhancer, the matrix attachment regions (MARs) which flank E mu, and several switch-associated elements--B-cell lines in which expression of the endogenous heavy-chain gene is maintained at the normal level in the absence of these intronic elements have occasionally been reported. Gene targeting offers an alternative method for assessing regulatory elements, one in which the role of defined segments of endogenous genes can be evaluated in situ. We have applied this approach to the IgH locus of a hybridoma cell line, generating recombinants which bear predetermined modifications in the functional, endogenous mu heavy-chain gene. Our analysis indicates the following. (i) Ninety-eight percent of the expression of the recombinant endogenous mu gene depends on elements in the MAR-E mu-MAR segment. (ii) Expression of the recombinant mu gene depends strongly on the MARs of the J(H)-C mu intron but not on the adjoining E mu core enhancer and switch regions; because our recombinant cell lines bear only a single copy of the mu gene, our results indicate that mu expression is activated by MAR elements lying within that same mu transcription unit. (iii) The MAR segment includes at least one activating element in addition to those defined previously by the binding of presumptive activating proteins in the nuclear matrix. (iv) Close association of the MARs with the E mu enhancer is not required for MAR-stimulated expression. (v) The other MARs in the IgH locus do not in their normal context provide the requisite MAR function.

Aphidicolin-induced FRA3B breakpoints cluster in two distinct regions

The common fragile site at chromosomal band 3p14.2 (FRA3B) is the most sensitive single site in the human genome to induced chromosomal lesions. This fragile site may predispose chromosome 3p to breakage that is commonly observed in lung, renal, and many other cancers. We previously used aphidicolin induction of FRA3B expression in a chromosome 3-only somatic cell hybrid to generate a series of hybrids with breakpoints in the 3p14.2 region. These breakpoints were localized to two distinct clusters, separated by 200 kb, that lie on either side of a region of frequent breakage within FRA3B as observed by FISH analysis. Seven proximal aphidicolin-induced breakpoints were localized at or near the end of a THE element. The THE-1 element is flanked by LINE and Alu repetitive elements. The eight distal aphidicolin-induced breakpoints clustered in a region capable of forming multiple hairpin-like structures. Thus repetitive elements and hairpin-like structures may be responsible for chromosome fragility in this region.

Regulation of the myeloid-cell-expressed human gp91-phox gene as studied by transfer of yeast artificial chromosome clones into embryonic stem cells: suppression of a variegated cellular pattern of expression requires a full complement of distant cis elements

Identifying the full repertoire of cis elements required for gene expression in mammalian cells (or animals) is challenging, given the moderate sizes of many loci. To study how the human gp91-phox gene is expressed specifically in myeloid hematopoietic cells, we introduced yeast artificial chromosome (YAC) clones and derivatives generated in yeast into mouse embryonic stem cells competent to differentiate to myeloid cells in vitro or into mouse chimeras. Fully appropriate regulation was recapitulated with a 130-kb YAC containing 60 and 30 kb of 5' and 3' flanking sequences, respectively. Immunodetection of human gp91-phox protein revealed uniform expression in individual myeloid cells. The removal of upstream sequences led to decreased overall expression which reflected largely a variegated pattern of expression, such that cells were either "on" or "off," rather than pancellular loss of expression. The proportion of clones displaying marked variegation increased with progressive deletion. DNase I mapping of chromatin identified two hypersensitive clusters, consistent with the presence of multiple regulatory elements. Our findings point to cooperative interactions of complex regulatory elements and suggest that the presence of an incomplete set of elements reduces the probability that an open chromatin domain (or active transcriptional complex) may form or be maintained in the face of repressive influences of neighboring chromatin.

Evaluation of the role of the 3'alpha heavy chain enhancer [3'alpha E(hs1,2)] in Vh gene somatic hypermutation

Previous work on the cis-acting elements that control heavy chain variable region (VH) gene somatic hypermutation has indicated the presence of an as yet unidentified element(s) 3' of the intron enhancer that is necessary for high rate mutation. Examination of cis-acting elements involved in kappa light chain V gene hypermutation has demonstrated a requirement for both the intronic and 3' kappa enhancers in this process. To examine whether the 3'alpha heavy chain enhancer [3'alpha E(hs1,2)] is required for somatic hypermutation of VH genes, we generated two types of transgenic mice. One type was generated using a construct containing a VH promoter, a rearranged VDJ, the heavy chain intronic enhancer, and the murine heavy chain 3'alpha E(hs1,2). The transgenes in the second lines were similar to the transgenes in the first with the addition of a second complete matrix attachment region (MAR) 3' of the heavy chain intronic enhancer, and splice acceptor and polyadenylation sites between the two enhancers. Analysis of both transgenes revealed levels of mutation at least 10-fold lower than endogenous VH genes. These data suggest that the 3'alpha E(hs1,2) does not play a role analogous to the 3' kappa enhancer in the regulation of the hypermutation process. Moreover, in one of the transgenes, the presence of the 3'alpha E(hs1,2) resulted in a lack of transcription in vivo, suggesting a negative regulatory role for this enhancer in certain contexts.

Major internal nuclear matrix proteins are common to different human cell types

The nuclear matrix may be involved in the structural and functional organization of the cell nucleus. However, we still do not understand the molecular basis of the intranuclear fibrogranular network that is part of the nuclear matrix. We recently described a method to identify internal nuclear matrix proteins [Mattern et al. (1996): J Cell Biochem 62:275-289], which was done by comparing two nuclear matrix preparations: one with and one without the internal structure by using quantitative two-dimensional gel electrophoresis. In the present study, we use the same approach to compare the nuclear matrix proteins of four different human cell types to investigate whether they have a similar internal nuclear matrix protein composition. Major nuclear matrix proteins present in all these cell types likely represent the base of the internal nuclear matrix. We demonstrate that the 25 most abundant internal nuclear matrix proteins are common to all four cell types. Together, these common proteins represent more than 75% of the total internal nuclear matrix protein mass in each cell type. This set of proteins includes B23 and most hnRNP proteins. The quantity of most of these proteins is very similar in the four cell types. The fact that the internal nuclear matrix consists mainly of hnRNP proteins, which may be involved in transcription, transport, and processing of hnRNA, supports the idea that the internal nuclear matrix is the result of these processes.

Disruption of nuclear lamin organization alters the distribution of replication factors and inhibits DNA synthesis

The nuclear lamina is a fibrous structure that lies at the interface between the nuclear envelope and the nucleoplasm. The major proteins comprising the lamina, the nuclear lamins, are also found in foci in the nucleoplasm, distinct from the peripheral lamina. The nuclear lamins have been associated with a number of processes in the nucleus, including DNA replication. To further characterize the specific role of lamins in DNA replication, we have used a truncated human lamin as a dominant negative mutant to perturb lamin organization. This protein disrupts the lamin organization of nuclei when microinjected into mammalian cells and also disrupts the lamin organization of in vitro assembled nuclei when added to Xenopus laevis interphase egg extracts. In both cases, the lamina appears to be completely absent, and instead the endogenous lamins and the mutant lamin protein are found in nucleoplasmic aggregates. Coincident with the disruption of lamin organization, there is a dramatic reduction in DNA replication. As a consequence of this disruption, the distributions of PCNA and the large subunit of the RFC complex, proteins required for the elongation phase of DNA replication, are altered such that they are found within the intranucleoplasmic lamin aggregates. In contrast, the distribution of XMCM3, XORC2, and DNA polymerase alpha, proteins required for the initiation stage of DNA replication, remains unaltered. The data presented demonstrate that the nuclear lamins may be required for the elongation phase of DNA replication.

Integration of foreign DNA sequences into mouse sperm genome

Mouse epididymal sperm cells have the spontaneous ability to take up exogenous DNA. A proportion of the sperm-bound DNA is further internalized into sperm nuclei. In this work, we have followed up the fate of the foreign DNA upon internalization into nuclei. We have found that the internalized plasmid DNA becomes tightly associated with the nuclear scaffold, is extensively rearranged, and undergoes recombination with the sperm genomic DNA. Sequence analysis of two randomly selected clones independently recovered by plasmid rescue from pSV2CAT plasmid-challenged sperm cells shows that DNA fragments from the plasmid are integrated into the mouse sperm genome. The sites of integration are identical in both clones, suggesting that these events do not occur randomly, but take place at preferential sites. A topoisomerase II consensus sequence is found adjacent to one end of the integration site, suggesting a possible role of this enzyme in the process of nonhomologous recombination.

Yeast telomeric sequences function as chromosomal anchorage points in vivo

Site-specific recombination in Saccharomyces cerevisiae was used to generate non-replicative DNA rings containing yeast telomeric sequences. In topoisomerase mutants expressing Escherichia coli topoisomerase I, the rings adopted a novel DNA topology consistent with the ability of yeast telomeric DNA to block or retard the axial rotation of DNA. DNA fragments bearing portions of the terminal repeat sequence C1-3 A/TG1-3 were both necessary and sufficient to create a barrier to DNA rotation. Synthetic oligonucleotide sequences containing Rap1p binding sites, a well represented motif in naturally occurring C1-3A arrays, also conferred immobilization; mutant Rap1p binding sites and telomeric sequences from other organisms were not sufficient. DNA anchoring was diminished by addition of competing telomeric sequences, implicating a role for an as yet unidentified limiting trans-acting factor. Though Rap1p is a likely protein constituent of the DNA anchor, deletion of the non-essential C-terminal domain did not affect the topology of telomeric DNA rings. Similarly, disruption of SIR2, SIR3 and SIR4, genes which influence a variety of telomere functions in yeast, also had no effect. We propose that telomeric DNA supports the formation of a SIR-independent macromolecular protein-DNA assembly that hinders the motion of DNA because of its linkage to an insoluble nuclear structure. Potential roles for DNA anchoring in telomere biology are discussed.

Untangling the role of DNA topoisomerase II in mitotic chromosome structure and function

DNA topoisomerase II (topo II) is involved in chromosome structure and function, although its exact location and role in mitosis are somewhat controversial. This is due in part to the varied reports of its localization on mitotic chromosomes, which has been described at different times as uniformly distributed, axial on the chromosome arms and predominantly centromeric. These disparate results are probably due to several factors, including use of different preparation and fixation techniques, species differences and changes in distribution during the cell cycle. Recently, several papers have re-investigated the distribution of topo II on chromosomes as a function of cell cycle and species(1-3). The new studies suggest that Topo II has a dynamic pattern of distribution on the chromosomes, in general becoming axial as chromosomes condense during prophase and then concentrating at centromeres during metaphase. These experiments suggest a novel role for topo II in centromere structure and function.

In vivo occupancy of the kappa light chain enhancers in primary pro- and pre-B cells: a model for kappa locus activation

The immunoglobulin kappa light chain locus has two enhancer elements: the intronic enhancer, which lies between the Jkappa cluster and the Ckappa exon, and the 3'kappa enhancer, which is located downstream of Ckappa. To address the contribution of these elements to the developmentally regulated activation of germline kappa locus transcription and rearrangement, we purified primary pro- and pre-B cells and determined by in vivo footprinting the sites within each enhancer that were occupied. We found that the kappa intronic enhancer NF-kappaB site is occupied in both pro- and pre-B cells, while CRE, BSAP, and PU.1/pip sites within the 3'kappa enhancer undergo changes in occupancy as cells progress from the pro-B to the pre-B cell stage. These findings suggest that regulation of the kappa locus in primary pre-B cells may be mediated by factors that bind the 3'kappa enhancer.

Extension of chromatin accessibility by nuclear matrix attachment regions

Transcription of the variable region of the rearranged immunoglobulin mu gene is dependent on an enhancer sequence situated within one of the introns of the gene. Experiments with transgenic mice have shown that activation of the promoter controlling this transcription also requires the matrix-attachment regions (MARs) that flank the intronic enhancer. As this mu gene enhancer can establish local areas of accessible chromatin, we investigated whether the MARs can extend accessibility to more distal positions. We eliminated interactions between enhancer- and promoter-bound factors by linking mu enhancer/MAR fragments to the binding sites for bacteriophage RNA polymerases that were either close to or one kilobase distal to the enhancer. The mu enhancer alone mediated chromatin accessibility at the proximal site but required a flanking MAR to confer accessibility upon the distal promoter. This long-range accessibility correlates with extended demethylation of the gene construct but not with whether it is being actively transcribed. MARs thus collaborate with the mu enhancer to generate an extended domain of accessible chromatin.

Matrix-attachment regions in the mouse chromosome 7F imprinted domain

We have mapped the matrix-attachment regions (MARs) in 200 kilobases of the mouse Chromosome (Chr) 7F imprinted domain. MARs are genetic elements known to have effects in cis on methylation at nonimprinted loci. The imprinting of the Igf2 and Ins2 genes is dependent on the transcription of the downstream H19 gene. The transcription of H19 is dependent in turn on its methylation status. The cis-acting regulators of methylation at this site are not known. As MARs are potential regulators not only of methylation but also other elements of genomic imprinting, we mapped the MARs within the 200 kilobases around H19. This report describes the mapping of four MARs from this region.

Co-integration of beta-lactoglobulin/human serum albumin hybrid genes with the entire beta-lactoglobulin gene or the matrix attachment region element: repression of human serum albumin and beta-lactoglobulin expression in the mammary gland and dual regulation of the transgenes

The effect of co-integration of the entire beta-lactoglobulin (BLG) gene or matrix attachment region (MAR) sequences on the expression of various BLG/ human serum albumin (HSA) gene constructs was tested in transgenic mice. These former sequences were chosen because of their reported ability to insulate transgenes from the neighboring host genomic DNA sequences and/or to provide a more permissive transcriptional environment. When introduced alone, a cDNA-based BLG/HSA construct was expressed in 60% of transgenic strains and HSA was secreted at levels up to 0.3 mg/ml into the milk. Upon co-integration with either the entire BLG gene or MAR element, HSA RNA and protein expression were completely abrogated. While the co-integrated BLG gene suppressed the proportion of expresser strains carrying cDNA as well as genomic BLG/HSA constructs, the MAR element only exerted its negative effect on the cDNA-based BLG/HSA construct. In transgenics expressing both HSA and BLG, the tissue specificity and developmental patterns of BLG expression were altered and resembled the less stringent pattern of the BLG/HSA expression. These results demonstrate that rescue of transgene expression through co-integration with BLG or MAR sequences do not apply universally.

The non-random distribution of UV-induced photoproducts in the nuclear matrix and non-matrix DNA fractions

The formation of UV-induced photoproducts in the chromatin fractions of human lymphocytes was studied by 32P-post-labeling. A higher level of DNA lesions was found in the matrix-attached DNA fraction as compared to non-matrix DNA of irradiated cells (about 150 and 110 adducts per 10(6) nucleotides, respectively, at a 500 J/m2 254 nm-UV dose). Formation of photoproducts in a MAR (matrix attached region) sequence from the mouse kappa immunoglobulin gene irradiated in vitro was examined as well. The MAR sequence showed a two-fold higher level of adducts as compared to non-MAR DNA. The effect of photoproducts on complex-formation between MAR DNA and proteins of the nuclear matrix was studied in vitro. The amount of UV-induced adducts was 1.5-fold higher in matrix-bound fraction as compared to non-fractionated DNA (and five-fold higher as compared to unbound fraction), which possibly resulted from preferential binding of lesion-containing DNA fragments to the nuclear matrix proteins.

The yeast Rad6 protein: a mediator of homologous recombination across the scaffold attached region at the replication origin ARS1

Here we show that the ubiquitin-conjugating enzyme Rad6p plays a crucial role in locus-specific replacement recombination in the TRP1-ARS1 region. In rad6-1 strains, where this ubiquitination activity is modified, homologous recombination across a 150 bp continuous region is completely abolished. Our results unambiguously identified the ARS1 scaffold attached region (SAR) as being the region where this impediment for replacement recombination is located, since a merging of the location of the recombination impediment and binding properties in a scaffold exchange assay with deletion mutations was observed. Our observations strongly support the notion of torsionally separated chromosomal domains being organized by SARs and scaffold proteins, and being dynamically realigned as a consequence of ubiquitination and proteolysis.