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

Specificity and functional significance of DNA interaction with the nuclear matrix: new approaches to clarify the old questions

In this chapter the specificity of chromosomal DNA partitioning into topological loops is discussed. Different experimental approaches used for the analysis of the above problem are critically reviewed. This discussion is followed by presentation of a novel approach for mapping the DNA loop anchorage sites that we have developed. This approach, based on the excision of the whole DNA loops by topoisomerase II-mediated DNA cleavage at matrix attachment sites, seems to constitute a unique tool for the analysis of topological organization of chromosomal DNA in living cells. We also discuss experimental results indicating that the DNA-loop anchorage sites form "weak points" in chromosomes that are preferentially sensitive to cleavage with both endogenous and exogenous nucleases. In connection with this discussion, rationales for the supposition that DNA loops constitute basic units of eukaryotic genome organization and evolution are considered. The chapter concludes by suggesting a new model of spatial organization of eukaryotic genome within the cell nucleus that resolves apparent contradictions between different data on the specificity of DNA interaction with the nuclear matrix.

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.

A haploid expressed gene cluster exists as a single chromatin domain in human sperm

Mammalian spermiogenesis is marked by the initial disruption of the nuclear-histone-DNA complex by the transition proteins for ultimate replacement with protamines. The genes for three of these low molecular weight basic nuclear proteins exist as a single linear array of PRM1, PRM2, and TNP2 on human chromosome 16p13.2. To begin to address the mechanism governing their transcriptional potentiation, a region of approximately 40 kilo-bases of the human genome encompassing these genes was introduced into the germ line of mice. Fluorescence in situ hybridization and Southern analysis showed that this segment of the human genome integrated into independent chromosomal sites while maintaining its fidelity. Transcript analysis demonstrated that the expression of the endogenous mouse protamine Prm1 and Prm2 genes as well as the mouse transition protein Tnp2 gene were expressed along with their human transgene counterparts. The pattern of expression of these transgenic human genes within this multigenic cluster faithfully represented that observed in vivo. In addition, all members of this transgenic gene cluster were expressed in proportions similar to those in human testis. Copy number-dependent and position-independent expression of the transgenic construct demonstrated that the corresponding biological locus was contained within this segment of the human genome. Furthermore, DNase I sensitivity established that in sperm the human PRM1-->PRM2-->TNP2 genic domain was contained as an approximately 28.5-kilobase contiguous segment bounded by an array of nuclear matrix associated topoisomerase II consensus sites. This is the first description of a multigenic male gamete-specific domain as a fundamental gene regulatory unit. A model of haploid-specific gene determination is presented.

Nuclear matrix protein ARBP recognizes a novel DNA sequence motif with high affinity

ARBP is a nuclear protein that specifically binds to matrix/scaffold attachment regions (MARs/SARs). Here we characterize by DNase I footprinting, dimethyl sulfate protection, and mobility shift assays two binding sites for ARBP within a chicken lysozyme MAR fragment. Our results indicate that ARBP recognizes a novel DNA sequence motif containing the central sequence 5'-GGTGT-3' and flanking AT-rich sequences. Binding occurs through major groove contacts to two guanines of the central sequence. Collective and single-base substitutions in the 5'-GGTGT-3' core motif result in loss or significant reductions of ARBP binding, underscoring the importance of the GC-rich core sequence. Structural elements of the sequence motif are probably also recognized. The affinity of ARBP to both binding sites is surprisingly high [KD = (2-6) x 10(-10) M]. High-affinity recognition of the identified DNA motif in MARs/SARs by ARBP is likely an important feature in the domain organization of chromatin.

Transcription factor binding sites in the matrix attachment region (MAR) of the chicken alpha-globin gene

Nuclear matrix is a nuclear protein-DNA superstructure believed to be the exclusive site of DNA replication, transcription, repair, and recombination. The attachment regions of chromatin loops to the nuclear matrix, called MARs, nest origins of replication, have transcriptional enhancer activity, and via their interaction with protein transcription factors may govern gene switch during development and tissue-specific gene expression. In this study the 967 bp MAR of the chicken alpha-globin gene is analyzed for the presence of hexanucleotides from a number (83 in total) of vertebrate protein transcription factors and core origins of replication. A total number of 760 hexanucleotides from factor sites or origins of replication were used for this search. We found that: (1) The occurrence of protein transcription factor binding sites overall on the MAR fragment as well as on the enhancer and promoter regions of other genes is only about 1.2-1.5 times higher than in random DNA, something consistent for all MAR and enhancer sequences examined. However, a high concentration (up to 2.7 times over random sequences) of hexanucleotide factor sites is observed on small stretches of the alpha-globin gene MAR. (2) Some regulatory protein binding sites are underrepresented whereas others are overrepresented, giving to an MAR a particular transcription factor flavor. (3) The DNA curvature map of the MAR sequence and the potential sites of positioned nucleosomes suggest the sites where a competition between core histone octamers and protein transcription factors for DNA might be found. This approach might provide a novel technique to diagnose for the regulatory or nonregulatory function of a stretch of DNA. Furthermore, MARs are proposed to constitute important regulatory elements of genes in addition to enhancers, promoters, silencers, locus control regions, and origins of replication. Additional parameters such as interaction of a transcription factor with other transcription factors fixed at vicinal sites, DNA methylation, intrinsic DNA curvature torsional strain, and nucleosome positioning might also determine the high-affinity binding of a transcription factor to its functional sites and its exclusion from or low affinity binding to other nonregulatory regions.

Production of pharmaceutical proteins from transgenic animals

Different systems are being studied and used to prepare recombinant proteins for pharmaceutical use. The blood, and still more the milk, from transgenic animals appear a very attractive source of pharmaceuticals. The cells from these animals are expected to produce well-matured proteins in potentially huge amounts. Several problems remain before this process becomes used in a large scale. Gene transfer remains a difficult and costly task for farm animals. The vectors carrying the genes coding for the proteins of interest are of unpredictable efficiency. Improvement of these vectors includes the choice of efficient promoters, introns and transcription terminators, the addition of matrix attached regions (MAR) and specialized chromatin sequences (SCS) to enhance the expression of the transgenes and to insulate them from the chromatin environment. Mice are routinely used to evaluate the gene constructs to be transferred into larger animals. Mice can also be utilized to prepare amounts as high as a few hundred mg of recombinant proteins from their milk. Rabbit appears adequate for amounts not higher than 1 kg per year. For larger quantities, goat, sheep, pig and cow are required. No recombinant proteins extracted from the blood or milk of transgenic animals are yet on the market. The relatively slow but real progress to improving the efficiency of this process inclines to be reasonably optimistic. Predictive reports suggest that 10% of the recombinant proteins, corresponding to a 100 million dollars annual market, will be prepared from the milk of transgenic animals by the end of the century.

Synthesis and secretion of hepatic apolipoprotein B-containing lipoproteins

Human apolipoprotein (apo) B-100 is required for the synthesis and secretion of hepatic triacyglycerol-rich lipoproteins. This review summarizes recent developments in understanding the interaction of cis-acting DNA sequences and trans-acting protein factors in regulation of apo B gene expression and apo B mRNA editing, and the role of structural determinants of apo B-100 in the assembly and secretion of hepatic lipoproteins. In particular, experimental results obtained from cell culture studies using techniques of molecular and cellular biology are described and discussed. The relationship between apo B length and its ability to recruit lipids is presented, and the involvement of factors other than apo B in hepatic triacylglycerol-rich lipoprotein production is discussed.

The role of scaffold attachment regions in the structural and functional organization of plant chromatin

Studies on nuclear scaffolds and scaffold attachment regions (SARs) have recently been extended to different plant species and indicate that SARs are involved in the structural and functional organization of the plant genome, as is the case for other eukaryotes. One type of SAR seems to delimit structural chromatin loops and may also border functional units of gene expression and DNA replication. Another group of SARs map close to regulatory elements and may be directly involved in gene expression. In this overview, we summarize the structural and functional properties of plant SARs in comparison with those of SARs from animals and yeast.

Gene expression within a chromatin domain: the role of core histone hyperacetylation

Scaffold-attached regions (SAR elements) increase transcriptional rates for integrated but not episomal templates, and this effect can be potentiated by using an epigenetically active reagent, butyrate. The action of butyrate is a direct one, not involving de novo protein synthesis, and can be mimicked by using a novel and highly specific inhibitor of histone deacetylases, (R)-trichostatin A. This leads to a model in which SAR elements serve to stabilize the chromosomal topology arising as a consequence of hyperacetylation of histone cores. The synergistic effects of histone hyperacetylation and SARs are mediated by promoter upstream elements since, for a simple TATA box, the response to both parameters is an additive one.

Biochemical properties of attachment region binding protein ARBP

ARBP (attachment region binding protein) is an abundant nuclear protein that specifically binds to matrix/scaffold attachment regions (MARs/SARs). Here we show by gel filtration and gradient sedimentation that ARBP has an elongated shape. The sedimentation coefficient was determined as only 2.1 S. Furthermore, limited proteolysis of ARBP in situ (in isolated nuclei) with several proteases generated limiting resistant peptides from 14.5 to 18 kDa, that retained the ability to bind MARs specifically. This indicates that these peptides encompass the DNA binding domain of ARBP.

Photosensitized DNA damage in human cells is localized in chromatin sensitive to DNAse I digestion

Human NHIK 3025 cells were sensitized to light by incubation with Photofrin II (PII) and aluminum phthalocyanine tetrasulphonate (AlPCS4). Light exposure of sensitized cells at 1 degree C induced DNA strand breaks causing unwinding of DNA in alkali. Subsequent to light exposure, cells were treated with deoxyribonuclease I (DNAse I) which produces DNA strand breaks in active chromatin. The combination of photo-damage, killing > 95% of the cells, and treatment with DNAse I caused the same degree of DNA unwinding as DNAse I treatment alone. This was not the case for X-irradiation. Thus, the photosensitized DNA strand breaks were selectively induced in or close to DNAse I-sensitive sites.

Characterization of a hair (wool) keratin intermediate filament gene domain

In epithelial differentiation keratin intermediate filament genes are expressed in multifarious tissue-specific and stage-specific patterns. Pairs of type I and type II intermediate filament genes, belonging to multigene families, are coordinately regulated, and 4-5 genes of each type are expressed in the hair follicle. Accumulating chromosomal mapping data points to a major locus for each intermediate filament multigene family on separate chromosomes. In this report we describe the isolation of a sheep hair keratin cosmid by chromosome walking that overlaps two previously described cosmids and establishes a continuous 100-kb segment of cloned DNA containing three hair and three hair-like type II intermediate filament keratin genes. A new hair keratin type II intermediate filament gene, KRT2.11, is located in the middle of the cluster, and partial sequence data reveal a striking conservation of its predicted N-terminal region with other sheep hair keratin type II intermediate filament proteins. Expression analyses demonstrate the presence of a 2.4-kb KRT2.11 transcript in wool follicle RNA and show that expression occurs in the follicle cortical keratinocytes above the dermal papilla. The three hair genes are clustered within about 40 kb and flanked by hair-like genes that are not expressed in the hair follicle, thereby demarcating a hair keratin gene domain.

Binding specificity of a nuclear scaffold: supercoiled, single-stranded, and scaffold-attached-region DNA

Scaffold-attached-region (SAR) elements of DNA enhance transcriptional rates, and this has been correlated with their ability to undergo separation into single strands (ssDNA) under conditions of negative superhelicity (Bode et al., 1992). The competition studies presented here suggest that the SAR-scaffold interaction is based, in part, on the recognition of single strands, while about one-half of SAR sites are inaccessible to ssDNA. Conversely, since there are 20,000 SAR sites but more than 60,000 sites for ssDNA per nuclear equivalent, not all ssDNA sites are open for SARs. In addition, a completely separate set of binding centers recognizing and enzymatically converting DNA of superhelical density below -0.04 can be titrated. These findings reflect multiple binding specificities for scaffold preparations that are routinely used for screening scaffold-attached regions.

Apolipoprotein B and low-density lipoprotein structure: implications for biosynthesis of triglyceride-rich lipoproteins

ApoB100 is a very large glycoprotein essential for triglyceride transport in vertebrates. It plays functional roles in lipoprotein biosynthesis in liver and intestine, and is the ligand recognized by the LDL receptor during receptor-mediated endocytosis. ApoB100 is encoded by a single gene on chromosome 2, and the message undergoes a unique processing event to form apoB48 message in the human intestine, and, in some species, in liver as well. The primary sequence is relatively unique and appears unrelated to the sequences of other serum apolipoproteins, except for some possible homology with the receptor recognition sequence of apolipoprotein E. From its sequence, structure prediction shows the presence of both sheet and helix scattered along its length, but no transmembrane domains apart from the signal sequence. The multiple carbohydrate attachment sites have been identified, as well as the locations of most of its disulfides. ApoB is the single protein found on LDL. These lipoproteins are emulsion particles, containing a core of nonpolar cholesteryl ester and triglyceride oil, surrounded by an emulsifying agent, a monolayer of phospholipid, cholesterol, and a single molecule of apoB100. An emulsion particle model is developed to predict accurately the physical and compositional properties of an LDL of any given size. A variety of techniques have been employed to map apoB100 on the surface of the LDL, and all yield a model in which apoB surrounds the LDL like a belt. Moreover, it is concluded that apoB100 folds into a long, flexible structure with a cross-section of about 20 x 54 A2 and a length of about 585 A. This structure is embedded in the surface coat of the LDL and makes contact with the core. During lipoprotein biosynthesis in tissue culture, truncated fragments of apoB100 are secreted on lipoproteins. Here, it was found that the lipoprotein core circumference was directly proportional to the apoB fragment size. A cotranslational model has been porposed for the lipoprotein assembly, which includes these structural features, and it is concluded that in permanent hepatocyte cell lines, apoB size determines lipoprotein core circumference.

A 5' element of the chicken beta-globin domain serves as an insulator in human erythroid cells and protects against position effect in Drosophila

We have characterized an element near the 5' boundary of the chicken beta-globin domain that insulates a reporter gene from the activating effects of a nearby beta-globin locus control region (5'HS2) when assayed in the human erythroid cell line K562. We show that the insulation mechanism is directional, that it operates at the level of transcription, and that it involves the alteration of chromatin structure over the promoter of the gene. The insulator has no significant stimulatory or inhibitory effects of its own. In transgenic Drosophila, the insulator protects the white minigene from position effects. The action of the insulator thus is not restricted to erythroid or mammalian cells, suggesting that such elements may serve an important and widely distributed function in the organization of chromatin structure.

Centromeric DNA cloned from functional kinetochore fragments in mitotic cells with unreplicated genomes

Treatment of cells arrested in the cell cycle at the G1/S-phase boundary with 5 mM caffeine induces premature mitosis, resulting in chromosomal fragmentation and detachment of centromere-kinetochore fragments, which are subsequently attached to the mitotic spindle and segregated in anaphase. Taking advantage of this in vivo separation of the centromere, we have developed a procedure for isolation of a centromere-enriched fraction of mitotic chromatin. Using this method, we have isolated and cloned DNA from the centromere-enriched material of Chinese hamster cells. One of the clones thus obtained was characterized in detail. It contains 6 kb of centromere-associated sequence that exhibits no recognizable homology with other mammalian centromeric sequences and is devoid of any extensive repetitive structure. This sequence is present in a single copy on chromosome 1 and is species-specific. Distinctive features of the clone include the presence of several A+T-rich regions and clusters of multiple topoisomerase II consensus cleavage sites and other sequence motifs characteristic of nuclear matrix-associated regions. We hypothesize that these features might be related to the more compact packaging of centromeric chromatin in interphase nuclei and mitotic chromosomes.

Nature of DNA sequences at the attachment regions of genes to the nuclear matrix

Matrix-attached regions (MARs) have been demonstrated to nest origins of replication and transcriptional enhancers. A set of 13 rules is proposed aimed at facilitating the classification of a DNA sequence as a matrix attachment region.(ABSTRACT TRUNCATED AT 250 WORDS)

Homeodomain protein binding sites, inverted repeats, and nuclear matrix attachment regions along the human beta-globin gene complex

beta-Globin genes in primates arose during evolution by duplication of an ancestral gene, and their order of arrangement along the DNA is related to their timing of expression during development. We believe that nuclear matrix anchorage sites (MARs) along the beta-globin gene complex considered to be mass binding sites for transcription protein factors, some of which are developmental stage specific and others ubiquitous, play a decisive role in cell memory by determining the developmental stage-specific expression of the genes. The AT-rich class of MARs appears to possess a significant number of ATTA and ATTTA motifs known to be mass binding sites for homeodomain proteins that determine body formation in development. MARs also appear to harbor origins of replication, to be enriched in inverted repeats (dyad symmetry motifs) and were proposed to include the DNase I hypersensitive sites of a particular gene determined at the chromatin level. This study is an attempt to finely identify MARs at the nucleotide level along the beta-globin gene complex. Searches of a contiguous stretch of about 73.3 kb of human sequences comprising and surrounding the epsilon, gamma G-, gamma A-, delta-, and beta-globin genes of the human beta-globin gene complex for homeotic protein binding sites as well as for inverted repeats has shown that these elements are clustered nonrandomly at particular sites within the beta-globin gene complex. These sites are presumed to be the AT-rich class of MARs of the beta-globin gene complex. The inverted repeats which are characteristic of origins of replication and some promoter/enhancer regions and the homeotic protein sites seem to include the DNase I hypersensitive sites of the gene complex. Indeed, dyad symmetry sequences are present close to the four DNase I HS sites in the locus control region (LCR) of the gene complex as well as in the 5' flanking regions and the large introns of the delta- and beta-globin genes. A search of the putative MAR regions of the gene complex suggests that, in addition to their enrichment in ATTA motifs, palindromes, and DNase I hypersensitive sites, these regions may comprise TG-rich motifs and potential Z-DNA as well as polypurine and polypyrimidine blocks. From the positions of palindromes and clusters of homeodomain protein sites along the complex we propose that an extended origin of replication able to initiate at several sites is present in the LCR and two others surrounding the delta- and beta-globin genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Multitude of inverted repeats characterizes a class of anchorage sites of chromatin loops to the nuclear matrix

In order to understand the nature of DNA sequences that organize chromatin into domains or loops, we have cloned the nuclear matrix DNA (1.7% of the total DNA) from human myelogenous leukemia cells in culture. Nuclear matrix is formed by interactions between specific stretches of DNA of about 0.1 to 5.0 kb with protein transcription factors, nuclear enzymes, and structural proteins. Nuclear matrix is believed to be the exclusive nuclear microenvironment in which initiation of DNA replication, transcription, and repair take place. The matrix attachment regions (MARs) of DNA have transcriptional enhancer activity, harbor the origins of replication of the human genome, and define the borders between neighboring chromatin loops. In this study we report the sequence of the human MAR fragment 19.2 of a size of 542 bp. Hum. MAR 19.2 is composed of TG-, CA-, CT-, and GA-rich blocks and shows 8 perfect and imperfect inverted repeats. Thus, we have identified a novel class of MARs with sequence characteristics divergent from the AT-rich class of MARs. The inverted repeats of the 19.2 sequence might be stabilized into their cruciform configuration by torsional strain and by specific transcription/replication protein factors. This MAR might function in the initiation of replication of the flanking chromatin domain and in the regulation of the transcriptional activity of the gene(s) that reside in this domain.

Reverse transformation, genome exposure, and cancer

The reverse transformation reaction whereby malignant cells are restored to a more normal phenotype has been reviewed. The primary causative action is ascribed to the genome exposure reaction in which a peripheral nuclear DNA region is restored to high sensitivity to DNase I, like that in normal cells. Various aspects of genome exposure around the nucleoli and the nuclear periphery are considered. The special role of the cytoskeleton in regulating exposure resulting in normal differentiation on the one hand and malignant transformation on the other is discussed. The action of the two-level system for regulation of the mammalian genome previously proposed is reviewed in relation to normal differentiation and malignancy with brief indication of roles played by various metabolites, transcription factors, protooncogenes, cell organelles, and processes like specific phosphorylation and dephosphorylation. Possible implications for cancer therapy and prevention and for the fields of genetic disease and toxicology are indicated.

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

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

Binding of matrix attachment regions to lamin B1

Eukaryotic chromatin is organized into topologically constrained loops that are attached to the nuclear matrix. The regions of DNA that interact with the matrix are called matrix attachment regions (MARs). We studied the spatial distribution of MAR-binding sites in the nuclear matrix from rat liver cells, following a combined biochemical and ultrastructural approach. We found that MAR-binding sites are distributed equally over the internal fibrogranular network and the peripheral nuclear lamina. Internal and peripheral binding sites have similar binding characteristics: both sets of binding sites show specific and saturable binding of MARs from different organisms. By means of a DNA-binding protein blot assay and in vitro binding studies, we identified lamin B1 as a MAR-binding protein, which provides evidence for a specific interaction of DNA with the nuclear lamina.

DNA loops: structural and functional properties of scaffold-attached regions

The long DNA molecules of eukaryotic genomes appear to be organized into large loops formed by the binding of dispersed DNA sequences to non-histone proteins. This partitioning of DNA into topologically constrained units constitutes one of the highest orders of DNA packing in chromosomes. DNA loops are likely to define functional units as well as topological domains, contributing to the regulation of gene expression and DNA replication. This review presents recent work on the properties of the DNA sequences and proteins thought to be involved in loop formation, and on their possible significance for replication and transcription.

Biological significance of unwinding capability of nuclear matrix-associating DNAs

Matrix attachment regions (MARs) are thought to separate chromatin into topologically constrained loop domains. A MAR located 5' of the human beta-interferon gene becomes stably base-unpaired under superhelical strain, as do the MARs flanking the immunoglobulin heavy chain gene enhancer; in both cases a nucleation site exists for DNA unwinding. Concatemerized oligonucleotides containing the unwinding nucleation site exhibited a strong affinity for the nuclear scaffold and augmented SV40 promoter activity in stable transformants. Mutated concatemerized oligonucleotides resisted unwinding, showed weak affinity for the nuclear scaffold, and did not enhance promoter activity. These results suggest that the DNA feature capable of relieving superhelical strain is important for MAR functions.

Nuclear structure and the three-dimensional organization of DNA

The organization of DNA within the nucleus has been demonstrated to be both cell and tissue specific and is arranged in a non-random fashion in both sperm and somatic cells. Nuclear structure has a pivotal role in this three-dimensional organization of DNA and RNA and contributes as well to forming fixed organizing sites for nuclear functions, such as DNA replication, transcription, and RNA processing. In sperm, DNA is also organized in a specific fashion by the nuclear matrix and DNA-protamine interactions. Within somatic cells, the nuclear matrix provides a three-dimensional framework for the tissue specific regulation of genes by directed interaction with transcriptional activators. This differential organization of the DNA by the nuclear matrix, in a tissue specific manner, contributes to tissue specific gene expression. The nuclear matrix is the first link from the DNA to the entire tissue matrix system and provides a direct structural linkage to the cytomatrix and extracellular matrix. In summary, the tissue matrix serves as a dynamic structural framework for the cell which interacts to organize and process spatial and temporal information to coordinate cellular functions and gene expression. The tissue matrix provides a structural system for integrating form and function.

Chromosome structure and eukaryotic gene organization

The DNA in the eukaryotic nucleus is highly compacted but well organized into distinct regional units. Chromosomal bands are characterized by their structure and distinctive replication time. They are subdivided into chromatin loops which serve as functional domains that have discrete boundary elements and can be regulated during development.

The nucleus: a black box being opened

Until recently our knowledge about the structural and functional organization of the cell nucleus was very limited. Recent technical developments in the field of ultrastructural analysis, combined with ongoing research on the properties of the nuclear matrix, give new insight into how the nucleus is structured. Two types of observations shape our ideas about nuclear organization. First, most nuclear functions (replication, transcription, RNA processing, and RNA transport) are highly localized within the nucleus, rather than diffusely distributed. Moreover, they are associated with the nuclear matrix. Second, chromatin is organized in discrete loops, bordered by nuclear matrix attachment sequences (MARs). Each loop may contain one or several genes. The arrangement of chromatin in loops has profound consequences for the regulation of gene expression.

Regulation of transcription-factor activity during growth and differentiation: involvement of the nuclear matrix in concentration and localization of promoter binding proteins

Several lines of evidence are presented which support involvement of the nuclear matrix in regulating the transcription of two genes, histone and osteocalcin, that are reciprocally expressed during development of the osteoblast phenotype. In the 5' regulatory region of an H4 histone gene, which is expressed in proliferating osteoblasts early during the developmental/differentiation sequence, a dual role is proposed for the nuclear matrix binding domain designated NMP-1 (-589 to -730 upstream from the transcription start site). In addition to functioning as a nuclear matrix attachment site, the sequences contribute to the upregulation of histone gene transcription, potentially facilitated by concentration and localization of an 84kD ATF DNA binding protein. A homologous nuclear matrix binding domain was identified in the promoter of the osteocalcin gene, which is expressed in mature osteoblasts in an extracellular matrix undergoing mineralization. The NMP binding domain in the osteocalcin gene promoter resides contiguous to the vitamin D responsive element. Together with gene and transcription factor localization, a model is proposed whereby nuclear matrix-associated structural constraints on conformation of the osteocalcin gene promoter facilitates vitamin D responsiveness mediated by cooperativity at multiple regulatory elements.

Dynamic chromatin: the regulatory domain organization of eukaryotic gene loci

It is hypothesized that nuclear DNA is organized in topologically constrained loop domains defining basic units of higher order chromatin structure. Our studies are performed in order to investigate the functional relevance of this structural subdivision of eukaryotic chromatin for the control of gene expression. We used the chicken lysozyme gene locus as a model to examine the relation between chromatin structure and gene function. Several structural features of the lysozyme locus are known: the extension of the region of general DNAasel sensitivity of the active gene, the location of DNA-sequences with high affinity for the nuclear matrix in vitro, and the position of DNAasel hypersensitive chromatin sites (DHSs). The pattern of DHSs changes depending on the transcriptional status of the gene. Functional studies demonstrated that DHSs mark the position of cis-acting regulatory elements. Additionally, we discovered a novel cis-activity of the border regions of the DNAasel sensitive domain (A-elements). By eliminating the position effect on gene expression usually observed when genes are randomly integrated into the genome after transfection, A-elements possibly serve as punctuation marks for a regulatory chromatin domain. Experiments using transgenic mice confirmed that the complete structurally defined lysozyme gene domain behaves as an independent regulatory unit, expressing the gene in a tissue specific and position independent manner. These expression features were lost in transgenic mice carrying a construct, in which the A-elements as well as an upstream enhancer region were deleted, indicating the lack of a locus activation function on this construct. Experiments are designed in order to uncover possible hierarchical relationships between the different cis-acting regulatory elements for stepwise gene activation during cell differentiation. We are aiming at the definition of the basic structural and functional requirements for position independent and high level gene expression. The result of these experiments will have important consequences for random gene transfer with predictable and reproducible expression of transgenes.

A matrix/scaffold attachment region binding protein: identification, purification, and mode of binding

Matrix/scaffold attachment regions (MARs/SARs) partition chromatin into functional loop domains. Here we have identified a chicken protein that selectively binds to MARs from the chicken lysozyme locus and to MARs from Drosophila, mouse, and human genes. This protein, named ARBP (for attachment region binding protein), was purified to homogeneity and shown to bind to MARs in a cooperative fashion. ARBP is an abundant nuclear protein and a component of the internal nuclear network. Deletion mutants indicate that multiple AT-rich sequences, if contained in a minimal approximately 350 bp MAR fragment, can lead to efficient binding of ARBP. Furthermore, dimerization mutants show that, to bind ARBP efficiently, MAR sequences can act synergistically over large distances, apparently with the intervening DNA looping out. The binding characteristics of ARBP to MARs reproduce those of unfractionated matrix preparations, suggesting that ARBP is an important nuclear element for the generation of functional chromatin loops.

DNaseI hypersensitive sites at the 3' end of the human apolipoprotein B gene

The chromatin structure of the 3' end of the human apolipoprotein B gene has been examined. Two DNaseI hypersensitive sites were present in nuclei from liver-derived HepG2 cells and intestine-derived CaCo-2 cells, in which the apo-B gene is transcriptionally active, but were absent from HeLa cells, where the gene is not expressed, and from free DNA. The region in a segment enriched in recognition sites for topoisomerase II and known to participate in anchoring the 3' end of the gene to the nuclear matrix. The second DNaseI hypersensitive site resided in the 3' untranslated portion of the gene. Furthermore, nucleosomes were present along a 1.4-kilobase (HindIII-BamHI) segment of DNA containing the two 3' DNaseI hypersensitive sites, and a static array of nucleosomes was present along the A/T-rich hypervariable region.