A glimpse at chromosomal order

Two MAR DNA-binding proteins of the pea nuclear matrix identify a new class of DNA-binding proteins

Four MAR-binding proteins of 60, 65, 70 and 72 kDa have been detected by South-Western blotting and isolated from pea nuclear matrices. Two cDNAs encoding the 60 and 65 kDa proteins (MARBP-1 and MARBP-2) were isolated from a pea leaf cDNA library by screening with a PCR product obtained using degenerate primers based on an amino acid sequence from the 60 kDa protein. The proteins of 560 and 550 amino acids are 86% identical and contain several KKD/E repeats near the C-terminus. Escherichia coli-expressed MARBP-1 specifically binds A/T-rich MAR DNA. The interaction of MARBP-1/MARBP-2 with MAR DNA involves novel DNA-binding motifs. The MARBP-1 and MARBP-2 genes are expressed in a range of pea tissues and are encoded by genes at different loci. MARBP-1 and MARBP-2 are homologous to yeast nucleolar proteins Nop56p and Nop58p, which are involved in ribosome biogenesis, and to similar highly conserved proteins in other eukaryotes and in archaebacteria. MARBP-1 and MARBP-2 may have multifunctional roles in chromatin organisation and ribosome biogenesis.

Binding of the protein disulfide isomerase isoform ERp60 to the nuclear matrix-associated regions of DNA

Protein ERp60, previously found in the internal nuclear matrix in chicken liver nuclei, is a member of the protein disulfide isomerase family. It binds DNA and double helical polynucleotides in vitro with a preferential recognition toward the matrix-associated regions of DNA and poly(dA) x poly(dT), and its binding is inhibited by distamycin. ERp60 can be cross-linked chemically to DNA in the intact nuclei, suggesting that its association with DNA is present in vivo. As a whole, these results indicate that ERp60 is a component of the subset of nuclear matrix proteins that are responsible for the attachment of DNA to the nuclear matrix and for the formation of DNA loops. A distinctive feature of this protein, which has two thioredoxin-like sites, is that its affinity to poly(dA) x poly(dT) is strongly dependent on its redox state. Only its oxidized form, in fact, does it bind poly(dA) x poly(dT). The hypothesis can be made that through the intervention of ERp60, the redox state of the nucleus influences the formation or the stability of some selected nuclear matrix-DNA interactions.

Macromolecular and ultrastructural organization of the mitotic chromosome scaffold

Using electron microscopy (EM), we have examined three structural domains of the mitotic chromosome scaffold of mouse erythroleukemia (MEL) Friend cells with different morphologic organization: centromeric, intermediate, and telomeric. The intermediate, most extensive, domain exhibited a specific fibrogranular structure representing tightly packed granular bodies with diameters between 20 and 60 nm. The chromosome scaffold contained three main components: proteins (81%), RNA (12%), and DNA (7%). The residual DNA extracted from the scaffold represented short fragments, 300 bp on average, belonging to the class of tandemly arranged repetitive DNA. In situ hybridization experiments confirmed its typical centromeric location. Scaffold RNA represented three fractions: a major RNA fraction with an electrophoretic mobility corresponding to that of 5S RNA and two minor fractions with electrophoretic mobilities somewhat lower than that of 18S RNA. Scaffold RNA was localized mainly in the centromeric region. We show that the newly synthesized protein component of the chromosome scaffolds migrates slowly to the chromosomes, reaching a maximum specific radioactivity 12 h from the onset of the chase period.

Specific interaction of mutant p53 with regions of matrix attachment region DNA elements (MARs) with a high potential for base-unpairing

Mutant, but not wild-type p53 binds with high affinity to a variety of MAR-DNA elements (MARs), suggesting that MAR-binding of mutant p53 relates to the dominant-oncogenic activities proposed for mutant p53. MARs recognized by mutant p53 share AT richness and contain variations of an AATATATTT "DNA-unwinding motif," which enhances the structural dynamics of chromatin and promotes regional DNA base-unpairing. Mutant p53 specifically interacted with MAR-derived oligonucleotides carrying such unwinding motifs, catalyzing DNA strand separation when this motif was located within a structurally labile sequence environment. Addition of GC-clamps to the respective MAR-oligonucleotides or introducing mutations into the unwinding motif strongly reduced DNA strand separation, but supported the formation of tight complexes between mutant p53 and such oligonucleotides. We conclude that the specific interaction of mutant p53 with regions of MAR-DNA with a high potential for base-unpairing provides the basis for the high-affinity binding of mutant p53 to MAR-DNA.

A nuclear matrix attachment region upstream of the T cell receptor beta gene enhancer binds Cux/CDP and SATB1 and modulates enhancer-dependent reporter gene expression but not endogenous gene expression

We have previously identified a DNase I-hypersensitive site in the T cell receptor beta locus, designated HS1, that is located 400 base pairs upstream of the transcriptional enhancer Ebeta and is induced during CD4(-)CD8(-) to CD4(+)CD8(+) thymocyte differentiation. Using electrophoretic mobility shift assays, we show that HS1 induction correlates with increased binding of two nuclear factors, Cux/CDP and SATB1, to a 170-base pair DNA sequence within HS1. Furthermore, we demonstrate that HS1 is a nuclear matrix attachment region, referred to as MARbeta. These findings demonstrate that an analogous organization of cis-regulatory elements in which a nuclear matrix attachment region is in close proximity to an enhancer is conserved in the immunoglobulin and T cell receptor loci. In addition, we show that MARbeta represses Ebeta-dependent reporter gene expression in transient transfection assays. However, the targeted deletion of MARbeta from the endogenous locus does not change T cell receptor beta gene transcription in developing T cells. These contrasting results suggest a potential pitfall of functional studies of nuclear matrix attachment regions outside of their natural chromosomal context.

Euchromatin megabase cleavages and conjoint apoptotic-autophagic death expression with nucleolar ball-and-socket joint dislocations in human Chang liver cells arrested in S-phase by etoposide

Etoposide induced a megabase (Mb) fragmentation pattern identical with that from genomic digestion by NotI restriction endonuclease which specifically cleaves CpG islands in euchromatin domains. Redigestion by NotI produced no change, suggesting cleavage in the same or closely related sites in euchromatin domains. Preferential euchromatin cleavage was further suggested by harvested metaphase chromosomes showing self-inflicted resolution of light G-bandings (R-bandings), the euchromatin domains. Autodegeneration following Mb euchromatin fragmentations was shown by their degradation into 200 bp ladders, and expressions of apoptotic and "non-apoptotic" active death morphologies that were also seen conjointly in the same cell. The endstage further showed heterochromatin masses anchored to the nucleolus by novel ball-and-socket joints where dislocations occurred with nuclear leakage.

Characteristic immunolocalization of Ku protein as nuclear matrix

Two hybridoma clones, NMB1 and NML90, were established using nuclear matrix proteins from normal human thymi or malignant lymphoma as immunogens. They reacted with human Ku70 and Ku80, respectively, by immunoblotting. When HeLa cell nuclear proteins were fractionated and applied to immunoblotting, both Ku70 and Ku80 were detected in the nuclear matrix as well as the soluble nuclear protein fractions. By confocal scanning microscopy, the immunoreactivity of Ku70 and Ku80 was localized to distinct nucleoplasmic fibrillar network and fine granules in the interphase cell nuclei. When HeLa cells were fractionated in situ using DNase I and buffers containing 0.25 M (NH4)2SO4 and 2 M NaCl, the nucleoplasmic reticular structure was largely preserved, but granules disappeared. The nucleoplasmic distribution of Ku in the tissue and in cultured cells was distinct from each other. In the adult tissue, it consisted mostly of either distinct curvilinear lines along the nuclear periphery or of tangled, beaded lines throughout the nuclei. When xenotransplants of HeLa cell in Scid mice were examined, the "tissue type" immunolocalization pattern was reproduced consistently. In most fetal tissues, "tissue type" and "cell type" patterns were admixed. Monoclonal antibodies described here are useful tools for studying the structure and function of the nuclear matrix.

Transgene-promoted epigenetic switches of chalcone synthase activity in petunia plants

Epigenetic variation affecting pigment pattern formation in petunia flowers due to the insertion of transgenes encoding chalcone synthase is described. The loss of pigment formation in petals or parts of petals is due to the post-transcriptional degradation of chalcone synthase RNA, from both the endogenous petunia chalcone synthase genes and from the chalcone synthase transgenes. The RNA cleavage pathway and its control are described. Different epigenetic states of RNA breakdown are correlated with specific cytosine methylation changes in the coding sequences of the genes. The probability, extent and developmental location of chalcone synthase RNA breakdown are related to the number and organization of transgenes in the genome but epigenetic switches that affect RNA turnover probably occur in meristems and between sexual generations. Hypotheses to explain how the transgenes influence the levels of chalcone synthase RNA breakdown and how different epigenetic states are created are discussed.

G-band expression and megabase fragmentations in apoptosis

Apoptosis seems characterized by a cascade of megabase to 200-bp fragmentations and by a commitment to perish at the initial level. How that could be achieved seems unclear. Preferential cleavage of transcriptionally active chromatin by apoptotic nuclease activity has long been suggested. We show here the manifestation of self-inflicted G-banding patterns in mitotic chromosomes, or G-band expression, occurring concurrently with a pattern of megabase fragmentations in two apoptotic systems that we have established in human Chang liver cells using (a) staurosporine and (b) vanadyl(4) prepulsing. We further show that rare-cutting NotI and MluI restriction endonucleases with C-G dinucleotide sequence specificity had produced similar G-bandings and megabase fragmentations cascading down to the 200-bp ladder fragmentation that were also associated with the expression of characteristic apoptotic morphologies by the digested cells. CpG-specific methylation using the methylase SssI abolished the DNA fragmentation cascade, G-banding, and apoptotic expressions induced by NotI and MluI, implicating endonuclease cleavage of active chromatin, where CpG islands are concentrated, as the initiating event. Reproducing the G-bandings and megabase fragmentations by directly applying NotI and MluI endonucleases to fixed chromosomes and extracted genomic DNA, respectively, further confirmed the notion of endonucleolytic cleavage of active chromatin as the causation. Nuclease-digested light G-band regions of chromosomes appeared to be the chromosome sites providing the megabase fragments. Transcriptionally active genes of the genome are known to be preferentially cleaved by nuclease activity and are established as being concentrated in the light G-bandings that correspond to R-bandings, which are also known to be the sites of more frequent cytogenetic breakpoints. Manifestation of self-inflicted G-banding patterns (G-banding expression) in apoptosis would then imply cleavage of the transcriptionally active genes in every light G-band site of every chromosome in the genome. This must be suicidal.

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.

A new yeast artificial chromosome vector designed for gene transfer into mammalian cells

This report describes the construction of a new yeast artificial chromosome (YAC) vector designed for gene transfer into mammalian cells. For ease of use, the two arms of the vector were cloned separately. The vector harbours the Neo and Hyg genes for dominant selection in mammalian cells, a putative human origin of replication, a synthetic matrix attachment region and two loxP sites (one on each arm). The cloning ability of the vector was demonstrated by successful propagation of the cDNA of the cystic fibrosis gene, CFTR, as a YAC in Saccharomyces cerevisiae. A YAC containing the entire CFTR gene was also constructed by retrofitting the two arms of a pre-existing clone (37AB12) with the two arms of the novel vector. Both the cDNA and entire gene containing YACs were circularized in yeast by inducible expression of the Cre recombinase. Recombination occurred very specifically at the loxP sequences present on the two arms of the YAC. Applications of the vector to gene transfer are discussed.

Androgen responsiveness of mouse kidney beta-glucuronidase requires 5'-flanking and intragenic Gus-s sequences

Genetics studies of natural variants of the androgen response of mouse beta-glucuronidase (GUS) reveal a cis-active element closely linked to the GUS structural gene (Gus-s) that is necessary for this kidney-specific response. Results of our previous studies suggested sequences within or near an androgen-inducible deoxyribonuclease I-hypersensitive site (DH site) located in the ninth intron of Gus-s are associated with the androgen response of GUS. Using transgenic mice, we now demonstrate that at least two regions of sequence within Gus-s are involved in regulating the androgen response of GUS. The first, located within 3.8 kb of Gus-s 5'-flanking sequence, directs the response and its tissue specificity, while the second, located within a 6.4-kb fragment of Gus-s extending from the third through the ninth intron of Gus-s, protects the androgen responsiveness of the transgene from repressive influences of the insertion site.

Spatial organization of large-scale chromatin domains in the nucleus: a magnified view of single chromosome territories

We have analyzed the spatial organization of large scale chromatin domains in chinese hamster fibroblast, human lymphoid (IM-9), and marsupial kidney epithelial (PtK) cells by labeling DNA at defined stages of S phase via pulsed incorporation of halogenated deoxynucleosides. Most, if not all, chromosomes contribute multiple chromatin domains to both peripheral and internal nucleoplasmic compartments. The peripheral compartment contains predominantly late replicating G/Q bands, whereas early replicating R bands preferentially localize to the internal nucleoplasmic compartment. During mitosis, the labeled chromatin domains that were separated in interphase form a pattern of intercalated bands along the length of each metaphase chromosome. The transition from a banded (mitotic) to a compartmentalized (interphasic) organization of chromatin domains occurs during the late telophase/early G1 stage and is independent of transcriptional activation of the genome. Interestingly, generation of micronuclei with a few chromosomes showed that the spatial separation of early and late replicating chromatin compartments is recapitulated independently of chromosome number, even in micronuclei containing only a single chromosome. Our data strongly support the notion that the compartmentalization of large-scale (band size) chromatin domains seen in the intact nucleus is a magnified image of a similar compartmentalization occurring in individual chromosome territories.

The molecular biology of secreted enzyme production by fungi

Enzymes from filamentous fungi are already widely exploited, but new applications for known enzymes and new enzymic activities continue to be found. In addition, enzymes from less amenable non-fungal sources require heterologous production and fungi are being used as the production hosts. In each case there is a need to improve production and to ensure quality of product. While conventional, mutagenesis-based, strain improvement methods will continue to be applied to enzyme production from filamentous fungi the application of recombinant DNA techniques is beginning to reveal important information on the molecular basis of fungal enzyme production and this knowledge is now being applied both in the laboratory and commercially. We review the current state of knowledge on the molecular basis of enzyme production by filamentous fungi. We focus on transcriptional and post-transcriptional regulation of protein production, the transit of proteins through the secretory pathway and the structure of the proteins produced including glycosylation.

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.

A thymocyte factor SATB1 suppresses transcription of stably integrated matrix-attachment region-linked reporter genes

SATB1 specifically recognizes and binds to specialized genomic regions with an ATC sequence context with high base-unpairing propensity. Such base-unpairing regions (BURs) are typically identified within nuclear scaffold- or matrix-attachment regions (S/MARs). SATB1 is a homeodomain protein and is predominantly expressed in thymocytes. We obtained BHK cell lines expressing low levels of SATB1 by stable transfection and investigated its effect on stably integrated MAR-linked SV40 enhancer/promoter-driven luciferase reporter genes. For this study, both naturally occurring and synthetic MARs, as well as an AT-rich non-MAR control, were tested. Previous studies demonstrated that MAR sequences augment transcription of the linked reporter luciferase gene. Here, we show that SATB1 dramatically reduces the high levels of MAR-linked luciferase gene transcription. Transcription was virtually abolished for a reporter gene surrounded by two MARs at the 5' and 3' ends of the gene, which otherwise confer the highest level of transcriptional augmentation. On the other hand, SATB1 did not affect expression of an AT-rich non-MAR-linked luciferase gene or of endogenous housekeeping genes. This study shows that SATB1 acts as a strong transcriptional suppressor on a reporter gene linked to MARs when it is stably integrated into chromatin.

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 scaffold/matrix attachment region binding protein hnRNP-U (SAF-A) is directly bound to chromosomal DNA in vivo: a chemical cross-linking study

The protein heterogeneous nuclear ribonucleoprotein U (hnRNP-U, also known as scaffold attachment factor A, SAF-A) is an abundant component of hnRNP particles and of the nuclear matrix. Previous experiments have demonstrated that, in vitro, hnRNP-U specifically binds to scaffold/matrix attachment (S/MAR) region DNA elements and could thus be involved in higher order chromatin structure. In this paper we report on the use of chemical cross-linking to investigate whether the protein is also bound to DNA in vivo, which is a prerequisite for its presumed function in chromatin loop formation. We have improved published methods for cross-linking proteins to DNA with the aim to minimize unspecific fixation and possible contamination with RNA binding proteins. Our protocol is based on a limited cross-linking of living human cells with formaldehyde, followed by the purification of DNA/protein complexes by two consecutive cesium chloride density gradient centrifugations. Analysis of the protein constituents of these complexes shows a specific subset of cross-linked proteins with the histones as major components. By western blotting, we demonstrate that hnRNP-U is efficiently cross-linked to DNA under experimental conditions that yield DNA/protein complexes with a buoyant density equivalent to that of native chromatin. Dimethylsulfate cross-linking and limited protease digestion of the complexes was used to establish that hnRNP-U is bound directly to DNA and not via cross-linking to other proteins. This is the first direct demonstration of the in vivo DNA binding of a S/MAR specific protein and suggests a structural role of hnRNP-U in chromatin organization.

An atypical homeodomain in SATB1 promotes specific recognition of the key structural element in a matrix attachment region

SATB1 is a cell type-specific nuclear matrix attachment region (MAR) DNA-binding protein, predominantly expressed in thymocytes. We identified an atypical homeodomain and two Cut-like repeats in SATB1, in addition to the known MAR-binding domain. The isolated MAR-binding domain recognizes a certain DNA sequence context within MARs that is highly potentiated for base unpairing. Unlike the MAR-binding domain, the homeodomain when isolated binds poorly and with low specificity to DNA. However, the combined action of the MAR-binding domain and the homeodomain allows SATB1 to specifically recognize the core unwinding element within the base-unpairing region. The core unwinding element is critical for MAR structure, since point mutations within this core abolish the unwinding propensity of the MAR. The contribution of the homeodomain is abolished by alanine substitutions of arginine 3 and arginine 5 in the N-terminal arm of the homeodomain. Site-directed mutagenesis of the core unwinding element in the 3' MAR of the immunoglobulin heavy chain gene enhancer revealed the sequence 5'-(C/A)TAATA-3' to be essential for the increase in affinity mediated by the homeodomain. SATB1 may regulate T-cell development and function at the level of higher order chromatin structure through the critical DNA structural elements within MARs.

Genome downsizing during ciliate development: nuclear division of labor through chromosome restructuring

The ciliated protozoa divide the labor of germline and somatic genetic functions between two distinct nuclei. The development of the somatic (macro-) nucleus from the germinal (micro-) nucleus occurs during sexual reproduction and involves large-scale, genetic reorganization including site-specific chromosome breakage and DNA deletion. This intriguing process has been extensively studied in Tetrahymena thermophila. Characterization of cis-acting sequences, putative protein factors, and possible reaction intermediates has begun to shed light on the underlying mechanisms of genome rearrangement. This article summarizes the current understanding of this phenomenon and discusses its origin and biological function. We postulate that ciliate nuclear restructuring serves to segregate the two essential functions of chromosomes: the transmission and expression of genetic information.

Threonine 1342 in human topoisomerase IIalpha is phosphorylated throughout the cell cycle

To investigate the relationship between the modulation of topoisomerase II activity and its phosphorylation state during the cell cycle, a monoclonal antibody against C-terminal peptide (residues 1335-1350) of topoisomerase IIalpha containing a consensus sequence of casein kinase II, TDDE and its phosphorylated threonine were prepared. In an enzyme-linked immunosorbent assay, the antibody, named PT1342, recognized the immunogenic phosphopeptide but not the non-phosphorylated form of the peptide. The PT1342 antibody reacted only with a 170-kDa protein from HeLa cells and recognized anti-topoisomerase IIalpha immunoprecipitants. Furthermore, the antibody did not react with the human topoisomerase IIalpha mutated at codon 1342 from threonine to alanine, showing that PT1342 was directed against the phosphorylated threonine 1342. To examine the level of phosphorylation of threonine 1342 of topoisomerase IIalpha through the cell cycle, HeLa cells were stained simultaneously for phosphorylated topoisomerase IIalpha and DNA and analyzed by flow cytometry. Cells in the G2-M phase contained about double the PT1341-reacted topoisomerase IIalpha than did cells in G1 or S phases. The antibody stained the nuclei in interphase and mitotic chromosomes and its periphery, as seen with anti-topoisomerase IIalpha antibody. Thus, threonine 1342 in topoisomerase IIalpha is phosphorylated throughout the cell cycle.

Scaffold/matrix-attached regions act upon transcription in a context-dependent manner

Scaffold/matrix-attached regions (S/MARs) are cis-acting elements with a function outside transcribed regions and in introns. Although they usually augment transcriptional rates, their action is highly context-dependent. We cloned an 800 bp S/MAR element from the upstream border of the human interferon-beta domain at various positions within a transcribed region of 4.3 kb. By use of retroviral gene transfer, the vector could be integrated into target cells as a single copy enabling a rigorous definition of the distance between the S/MAR and the transcriptional start site. At a distance of about 4 kb, the S/MAR supported transcriptional initiation, whereas at distances below 2.5 kb, transcription was essentially shut off. Controls proved the functionally of all constructs in the transient expression phase and ruled out any influence of S/MAR position on transcript stability. Moreover, no pausing or premature termination was observed within these elements. We suggest that the protein binding partners of S/MARs change according to the topological status, explaining these divergent S/MAR effects.

Dissection of the ability of the chicken lysozyme gene 5' matrix attachment region to stimulate transgene expression and to dampen position effects

The chicken lysozyme gene domain is flanked by nuclear matrix attachment regions (MARs) on each side. We have previously shown that bilaterally flanking 5'MARs in stably transfected artificial genetic units enhance expression of a reporter transgene and dampen position effects of the chromatin structure at the site of integration. The 5' MAR was now dissected into smaller fragments that were monitored for effects on transgene expression in mouse 3T3 cells by a similar assay. Fragments, which contain 1.32 and 1.45 kb and represent the upstream and the downstream half, respectively, of the 5' MAR, retained the ability to stimulate transgene expression as well as the ability to reduce the variation in the level of expression. However, a 452 bp subfragment (H1-HaeII), which still exhibits specific binding to nuclear matrices and contains two high-affinity binding sites for the abundant nuclear matrix protein ARBP, lost both of those abilities. A dimerized 177 bp sequence from fragment H1-HaeII, which also binds selectively to nuclear matrices and includes a duplicated ARBP binding site, was also unable to stimulate reporter gene expression. Furthermore, a 0.65 kb subfragment containing an intrinsically bent sequence did not affect an elevated reporter gene expression and its dampening. Our results show that the ability of MAR fragments to bind to nuclear matrices is not sufficient to enhance and insulate transgene expression in stably transfected cells.

Binding of MAR-DNA elements by mutant p53: possible implications for its oncogenic functions

The tumor suppressor p53 is a multifunctional protein whose main duty is to preserve the integrity of the genome. This function of wild-type p53 as "guardian of the genome" is achieved at different levels, as a cell cycle checkpoint protein, halting the cell cycle upon DNA damage, and via a direct involvement in processes of DNA repair. Alternatively, p53 can induce apoptosis. Mutations in the p53 gene occur in about 50% of all human tumors and eliminate the tumor suppressor functions of p53. However, many mutant p53 proteins have not simply lost tumor suppressor functions but have gained oncogenic properties which contribute to the progression of tumor cells to a more malignant phenotype. The molecular basis for this gain of function of mutant p53 is still unknown. However, mutant (mut) p53 specifically binds to nuclear matrix attachment region (MAR) DNA elements. MAR elements constitute important higher order regulatory elements of chromatin structure and function. By binding to these elements, mut p53 could modulate important cellular processes, like gene expression, replication, and recombination, resulting in phenotypic alterations of the tumor cells. Mut p53 thus could be the first representative of a new class of oncogenes, which exert their functions via long-range alterations or perturbation of chromatin structure and function.

Purification and functional characterization of type II DNA topoisomerase from rat testis and comparison with topoisomerase II from liver

A number of studies in yeast have shown that DNA topoisomerase II is essential for chromosome condensation and disjunction during mitosis at the metaphase/anaphase transition and meiosis I. Accordingly, kinetic and mechanistic studies have implied a role for topoisomerase II in chromosome disjunction. As a step toward understanding the nature and role of topoisomerase II in a mammalian germline in vivo, we have purified topoisomerase II from rat testis to homogeneity and ascertained several of its catalytic activities in conjunction with that of the purified enzyme from liver. The purified enzymes appeared to be monomers under denaturing conditions; however, they differed in their relative molecular mass. Topoisomerase II from testis and liver have apparent molecular masses of 150 +/- 10 kDa and 160 +/- 10 kDa, respectively. The native molecular mass of testis topoisomerase II as assayed by immunoblot analysis of cell-free extracts, prepared in the presence of SDS and a number of protease inhibitors, corroborated with the size of the purified enzyme. Both enzymes are able to promote decatenation and relax supercoiled DNA substrates in an ATP and Mg(2+)-dependent manner. However, quantitative comparison of catalytic properties of topoisomerase II from testis with that of the enzyme from liver displayed significant differences in their efficiencies. Optimal pH values for testis enzyme are 6.5 to 8.5 while they are 6 to 7.5 for the liver enzyme. Intriguingly, the relaxation activity of liver topoisomerase II was inhibited by potassium glutamate at 1 M, whereas testis enzyme required about half its concentration. These findings argue that topoisomerase II from rat testis is structurally distinct from that of its somatic form and the functional differences between the two enzymes parallels with the physiological environment that is unique to these two tissues.

Evidence for silencing compartments within the yeast nucleus: a role for telomere proximity and Sir protein concentration in silencer-mediated repression

Transcriptional repression at the silent mating-type loci in yeast requires the targeting of silent information regulator (Sir) proteins through specific interactions formed at cis-acting silencer elements. We show here that a reporter gene flanked by two functional silencers is not repressed when integrated at >200 kb from a telomere. Repression is restored by creation of a new telomere 13 kb from the integrated reporter or by elevated expression of SIR1, SIR3, and/or SIR4. Coupled expression represses in an additive manner, suggesting that all three factors are in limiting concentrations. When overexpressed, Sir3 and Sir4 are dispersed throughout the nucleoplasm, in contrast to wild-type cells where they are clustered in a limited number of foci together with telomeres. Efficient silencer function thus seems to require either proximity to a pool of concentrated Sir proteins, that is, proximity to telomeres, or delocalization of the silencing factors.

Novel DNase I hypersensitive sites in the 3'-flanking region of the human c-myc gene

DNase I hypersensitivity regions correlate with genetic regulatory loci and binding sites for sequence-specific DNA-binding proteins. We present data supporting the presence of novel DNase 1 hypersensitive sites (which we have designated sites VI-IX) in both the body of the human c-myc gene downstream from exon 2 and the 3'-flanking region of the c-myc gene in HL-60 cells. All of these novel DH sites are markedly decreased when HL-60 cells are treated with either dimethyl sulfoxide (DMSO) or retinoic acid. Moreover, a similar pattern of DNase I hypersensitive sites in this region of c-myc was present in MCF-7 human breast cancer cells growing in culture. Our results suggest a potential role for these sites in transcriptional regulation of the human c-myc gene.

Topoisomerases in kinetoplastids

Topoisomerases are enzymes that mediate topological changes in DNA that are essential for nucleic acid biosynthesis and for cell survival. The kinetoplastid protozoa, which include pathogenic trypanosomes and Leishmania, have yielded an interesting variety of purified topoisomerase activities as well as several topoisomerase genes. In these parasites, topoisomerases are involved in the metabolism of both nuclear and mitochondrial (kinetoplast) DNA. In this review, Christian Burri, Armette Bodley and Theresa Shapiro summarize what is known about topoisomerases in kinetoplastids, and consider the intriguing possibility that these enzymes may act as valuable antiparasite drug targets.

Scanning electron microscopy of C-banding

The mechanism of C-banding was analyzed on the basis of the structural changes of the 30 nm chromatin fibre using scanning electron microscopy (SEM). SEM of non-banded metaphase spreads of L-cells revealed chromosomes consisting of 30 nm chromatin fibre loops along the entire length. No marked difference in both the dimension and appearance of such looped structures was discernible between the centromeric region and the rest of the chromosome. In contrast, C-banded chromosomes exhibited a conspicuous alteration of the fibre conformation in the centromeric region. The looped, fibrous structures were almost completely lost from this region, while the non-centromeric region still exhibited fibrous structures with slightly different appearances compared with those observed in the control chromosomes. On the other hand, results obtained using fluorescence microscopy showed that more DNA retained in the centromeric region than in the non-centromeric region. Since the analytical experiments exhibited that the characteristic collapsed state of the centromeric region occurred only with the alkali treatment but neither with the 2 x SSC nor acid treatments, the centromeric heterochromatin seemed to contain some specific protein which should be sensitive to alkali. The structurally collapsed but subsequently compact centromeric region may become more, or still, resistant to the DNA extraction due to the 2 x SSC treatment and the centromeric chromatin thus retained may be visualized as the C-band.

A large DNA-binding nuclear protein with RNA recognition motif and serine/arginine-rich domain

cDNA species encoding a large DNA-binding protein (NP220) of 1978 amino acids was isolated from human cDNA libraries. Human NP220 binds to double-stranded DNA fragments by recognizing clusters of cytidines. Immunofluorescent microscopy with antiserum directed against NP220 revealed a punctate or "speckled" pattern and coiled body-like structures in the nucleoplasm of various human cell lines. These structures diffused in the cytoplasm during mitosis. Western blot analysis showed that NP220 is enriched in the lithium 3,5-diiodosalicylate-insoluble fraction of nuclei. The domain essential for DNA binding is localized in C-terminal half of NP220. Human NP220 shares three types of domains (MH1, MH2, and MH3) with the acidic nuclear protein, matrin 3 (Belgrader, P., Dey, R., and Berezney, R. (1991) J. Biol. Chem. 266, 9893-9899). MH1 is a 48-amino acid sequence near the N terminus of both human NP220 and rat matrin 3. MH2 is a 75-amino acid sequence homologous to the RNA recognition motifs of heterogeneous nuclear RNP I and L. It is repeated three times in NP220 and twice in matrin 3. MH3 is a 60-amino acid sequence at the C terminus of both NP220 and matrin 3. NP220 has an arginine/serine-rich domain commonly found in pre-mRNA splicing factors. Close to the domain essential for DNA binding, there are nine repeats of the sequence LVTVDEVIEEEDL. Thus, NP220 is a novel type of nucleoplasmic protein with multiple domains.

Construction of a chromosome specific library of human MARs and mapping of matrix attachment regions on human chromosome 19

Using a novel procedure a representative human chromosome 19-specific library was constructed of short sequences, which bind preferentially to the nuclear matrix (matrix attachment regions, or MARs). Judging by 20 clones sequenced so far, the library contains > 50% of human inserts, about 90% of which are matrix-binding by the in vitro test. Computer analysis of sequences of eight human MARs did not reveal any significant homologies with the EMBL Nucleotide Data Base entries as well as between MARs themselves. Eight MARs were assigned to individual positions on the chromosome 19 physical map. The library constructed can serve as a good source of MAR sequences for comparative analysis and classification and for further chromosome mapping of MARs as well.

Effect of DNA conformation on cisplatin adduct formation

The anticancer drug cis-diamminedichloroplatinum(II) (cisplatin) has been shown previously to form adducts preferentially within internucleosomal or linker DNA rather than to DNA within the nucleosome. To determine whether other "open" regions of chromatin have an increased affinity for cisplatin, adduct formation within specific chromatin domains was analyzed. There was a significant increase in cisplatin-DNA adduct formation for DNA associated with the nuclear matrix (NM) compared with other chromatin domains and total unfractionated DNA. In contrast, treatment of the same cells with trans-diamminedichloroplatinum(II) (transplatin) did not result in preferential adduct formation. These findings led to the hypothesis that it might be possible to alter DNA to make it a more favorable target for cisplatin. The effect of arginine butyrate on cisplatin-DNA adduct formation was analyzed in human cancer cells. The combination of arginine butyrate and cisplatin resulted in a concentration-responsive increase in cisplatin-DNA adduct formation in PC-3 cells and an overall increase in cisplatin-DNA adduct formation in three other human cancer cell lines. The same combination also resulted in a significant increase in drug-induced cytotoxicity at a low concentration of cisplatin. These results suggest that chromatin configuration can affect cisplatin adduct formation.

Purification and molecular cloning of the scaffold attachment factor B (SAF-B), a novel human nuclear protein that specifically binds to S/MAR-DNA

We have purified to near homogeneity a novel nuclear protein from HeLa cells, that specifically binds to scaffold or matrix attachment region DNA elements (S/MAR DNA). The protein, designated SAF-B for scaffold attachment factor B, is an abundant component of chromatin, but not of the nuclear matrix and is expressed in all human tissues investigated. Antibodies against the purified protein were raised in rabbit and used to isolate the complete cDNA encoding SAF-B by immunoscreening. As predicted from the cDNA sequence, SAF-B contains 849 amino acids (96 696 Da), without significant homology to any known protein. SAF-B is rich in charged residues, leading to an aberrant migration on SDS gels, and has two putative bipartite nuclear localisation signals.

The architectural organization of nuclear metabolism

Nucleic acid metabolism is structurally organized in the nucleus. DNA replication and transcription have been localized to particular nuclear domains. Additional domains have been identified by their morphology or by their composition; for example, by their high concentration of factors involved in RNA splicing. The domain organization of the nucleus is maintained by the nuclear matrix, a nonchromatin nuclear scaffolding that holds most nuclear RNA and organizes chromatin into loops. The nuclear matrix is built on a network of highly branched core filaments that have an average diameter of 10 nm. Many of the intermediates and the regulatory and catalytic factors of nucleic acid metabolism are retained in nuclear matrix preparations, suggesting that nucleic acid synthesis and processing are structure-bound processes in cells. Tissue-specific and malignancy-induced variations in nuclear structure and metabolism may result from altered matrix architecture and composition.

Scaffold/matrix-attached regions: structural properties creating transcriptionally active loci

The expression characteristics of the human interferon-beta gene, as part of a long stretch of genomic DNA, led to the discovery of the putative domain bordering elements. The chromatin structure of these elements and their surroundings was determined during the process of gene activation and correlated with their postulated functions. It is shown that these "scaffold-attached regions" (S/MAR elements) have some characteristics in common with and others distinct from enhancers with which they cooperate in various ways. Our model of S/MAR function will focus on their properties of mediating topological changes within the respective domain.

The nuclear matrix: a structural milieu for genomic function

While significant progress has been made in elucidating molecular properties of specific genes and their regulation, our understanding of how the whole genome is coordinated has lagged behind. To understand how the genome functions as a coordinated whole, we must understand how the nucleus is put together and functions as a whole. An important step in that direction occurred with the isolation and characterization of the nuclear matrix. Aside from the plethora of functional properties associated with these isolated nuclear structures, they have enabled the first direct examination and molecular cloning of specific nuclear matrix proteins. The isolated nuclear matrix can be used for providing an in vitro model for understanding nuclear matrix organization in whole cells. Recent development of high-resolution and three-dimensional approaches for visualizing domains of genomic organization and function in situ has provided corroborative evidence for the nuclear matrix as the site of organization for replication, transcription, and post-transcriptional processing. As more is learned about these in situ functional sites, appropriate experiments could be designed to test molecular mechanisms with the in vitro nuclear matrix systems. This is illustrated in this chapter by the studies of nuclear matrix-associated DNA replication which have evolved from biochemical studies of in vitro nuclear matrix systems toward three-dimensional computer image analysis of replication sites for individual genes.

Nuclear matrix acceptor binding sites for steroid hormone receptors: a candidate nuclear matrix acceptor protein

Steroid/nuclear-hormone receptors are ligand-activated transcription factors that have been localized to the nuclear matrix. The classic model of hormone action suggests that, following activation, these receptors bind to specific "steroid response elements" on the DNA, then interact with other factors in the transcription initiation complex. However, evidence demonstrates the existence of specific chromatin proteins that act as accessory factors by facilitating the binding of the steroid receptors to the DNA. One such protein, the "receptor binding factor (RBF)-1", has been purified and shown to confer specific, high-affinity binding of the progesterone receptor to the DNA. Interestingly, the RBF-1 is localized to the nuclear matrix. Further, the RBF-1 binds specifically to a sequence of the c-myc proto-oncogene that has the appearance of a nuclear matrix attached region (MAR). These results, and other findings reviewed here, suggest that the nuclear matrix is involved intimately in steroid hormone-regulated gene expression.

Nuclear domains and the nuclear matrix

This overview describes the spatial distribution of several enzymatic machineries and functions in the interphase nucleus. Three general observations can be made. First, many components of the different nuclear machineries are distributed in the nucleus in a characteristic way for each component. They are often found concentrated in specific domains. Second, nuclear machineries for the synthesis and processing of RNA and DNA are associated with an insoluble nuclear structure, called nuclear matrix. Evidently, handling of DNA and RNA is done by immobilized enzyme systems. Finally, the nucleus seems to be divided in two major compartments. One is occupied by compact chromosomes, the other compartment is the space between the chromosomes. In the latter, transcription takes place at the surface of chromosomal domains and it houses the splicing machinery. The relevance of nuclear organization for efficient gene expression is discussed.

The immunoglobulin heavy-chain matrix-associating regions are bound by Bright: a B cell-specific trans-activator that describes a new DNA-binding protein family

B lymphocyte-restricted transcription of immunoglobulin heavy-chain (IgH) genes is specified by elements within the variable region (VH) promoter and the intronic enhancer (E mu). The gene encoding a protein that binds a VH promoter proximal site necessary for induced mu-heavy-chain transcription has been cloned. This B-cell specific protein, termed Bright (B cell regulator of IgH transcription), is found in both soluble and matrix insoluble nuclear fractions. Bright binds the minor groove of a restricted ATC sequence that is sufficient for nuclear matrix association. This sequence motif is present in previously described matrix-associating regions (MARs) proximal to the promoter and flanking E mu. Bright can activate E mu-driven transcription by binding these sites, but only when they occur in their natural context and in cell lines permissive for E mu activity. To bind DNA, Bright requires a novel tetramerization domain and a previously undescribed domain that shares identity with several proteins, including SWI1, a component of the SWI/SNF complex.

A novel matrix attachment region DNA binding motif identified using a random phage peptide library

SATB1 is a nuclear matrix attachment DNA (MAR)-binding protein which is predominantly expressed in thymocytes. This protein binds to the minor groove specifically recognizing an unusual DNA context exhibited by a specific MAR region with strong base-unpairing propensity. A phage library displaying nonamer random peptides without any built-in structure was used to identify a MAR binding motif of SATB1. One predominant cyclic peptide C1 of CRQNWGLEGC selected by a MAR-affinity column showed 50% identity with a segment in SATB1 (amino acids 355-363). Replacement of the C1 similarity segment in SATB1 by a random amino acid sequence or its truncation resulted in more than 80% reduction in MAR binding. In contrast, replacement of the same SATB1 segment with the C1 peptide restored full MAR binding activity and specificity as the wild-type protein. Single amino acid mutation of the conserved Arg or Glu residue to Ala greatly reduced MAR binding. Taken together our data show that a nine amino acid sequence in SATB1 represents a key MAR binding motif. Phage display may provide a general tool for rapid identification of DNA binding peptide motifs.

Endogenous endonuclease hypersensitive sites in Schizosaccharomyces pombe chromosomes

A novel method was used to characterize the long range susceptibility of Schizosaccharomyces pombe chromosomal DNA to endogenous endonuclease cleavage. Analyses of pulsed field gel experiments revealed two periodicities in the distribution of endogenous endonuclease hypersensitive sites. Endonuclease cleavage sites occurred, roughly at 30-509 kilobase pairs (kb) intervals under physiological conditions (25 mM KCl). At higher salt concentrations (250 mM KCl or 0.2 M and 0.9 M NaCl), endonuclease hypersensitive sites occurred at 200-300 kb intervals. Endonuclease hypersensitive sites in different chromosomal regions were monitored during different stages of the cell cycle. DNA sequencing around the endonuclease hypersensitive sites revealed the presence of clusters of A+T-rich motifs, autonomously replicating sequences (ARSs) in sequences (a characteristic of the scaffold-associated regions (SARs) and the presence of a CTG trinucleotide at most sites.

Structure of the hepatic control region of the human apolipoprotein E/C-I gene locus

The specificity of expression in the liver of the human apolipoprotein (apo) E/C-I gene locus is determined by a hepatic control region (HCR) that is located 15 kilobases downstream of the apoE gene. DNase I footprint studies of this sequence using nuclear extracts identified a region of the HCR that is enriched in nuclear protein-binding sites. Nuclease analysis of chromatin revealed liver-specific DNase I-hypersensitive sites that were associated with this region, and additional liver-specific nuclease-sensitive sites associated with the apoE gene were identified. The HCR domain has a limited binding affinity for the nuclear scaffold. The specific domain required for liver expression was tested by ligating subfragments of the HCR to the apoE gene and examining their activity in transgenic mice. A segment of 319 nucleotides that contained several potential regulatory sequences was required for full activity of liver-specific transcription with shorter segments yielding much lower levels of expression in the liver. All constructs that contained a fully active HCR were expressed in approximately a copy-dependent manner, suggesting that transgene expression was independent of integration position. Taken together, the properties of the HCR are consistent with its function as a locus control region for the liver-specific expression of the apoE gene.

Heterologous expression as a tool for gene identification and analysis

These days, genome research mainly concerns the accumulation of sequence data and their theoretical interpretation based on analogies to known genes, proteins and structures. However, a final identification of gene function can only be verified by experimental data. One step in this process is the expression of the isolated gene in pro- and eukaryotes. In this article we will review some of the basic features of expression in Escherichia coli and mammalian cells that are relevant to the design of expression experiments. Emphasis is put on the first instance of attaining a high enough level of expression in order to be able to detect the cellular effects or to isolate the product of the transferred gene.

A 3.5-kb DNA fragment contains the cis-regulatory elements for retina-specific expression and partial dosage compensation of the Arrestin B (ArrB) gene of Drosophila miranda

A 3.5-kb genomic DNA fragment containing the X1R chromosome-linked retina-specific Arrestin B gene (also called Arrestin 2) of Drosophila miranda (ArrB-mr) was introduced into the Drosophila melanogaster genome via germ-line transformation. The results showed that the ArrB-mr transgene was expressed only in the retina of the transformed flies. The transgene also showed male-specific transcriptional hyperactivation or dosage compensation, but the level was found to be 71-79% of the expected value. The endogenous autosomal ArrB-ml gene of D. melanogaster, as expected, was not found to be dosage compensated in the transformants. Thus, while the cis-regulatory elements for retina-specific expression are fully present in the 3.5-kb DNA, part of the sequences needed for full dosage compensation are missing in this DNA. Nucleotide (nt) sequence comparison of the upstream DNA revealed that both ArrB-mr and ArrB-ml possess a putative TATA box at -32 nt. They also have an 11-bp motif (5'-AATCCAGTTAG) similar to the photoreceptor conserved element I (PCE I) believed to play an important role in retina-specific expression of the D. melanogaster opsin and mouse Arr genes. In addition, both genes contain a TGACCT motif which is known to bind a transcription factor activated by retinoic acid and vitamin D3. However, five tandem repeats of a heptanucleotide sequence (TGGGCNR) and a 29-bp sequence with the potential to form a stem-loop structure, are found only in the ArrB-ml gene. These sequences may play an important role in dosage compensation of the X1R-linked ArrB-mr gene.