Isolation and Characterization of Matrix Associated Region DNA Fragments in Rice (Oryza sativa L.)

To investigate the interactions between chromosomal DNA andnuclear matrices in higher plants, matrix associated regions(MARs) of rice (Oryza sativa L.) DNAs were cloned. First, weprepared nuclear matrices from isolated nuclei by digestingthem with EcoRl and then extracting with 2 M NaCl. About 6%of the total DNA remained in the nuclear matrices after thisdigestion and extraction. The residual DNA fragments in thenuclear matrices were cloned. Some of the cloned DNA fragmentsshowed binding to certain nuclear proteins. One of the MAR fragmentscontained sequences related to known consensus motifs and ahairpin loop structure. A method is presented for isolationof matrix associated region (MAR) DNAs from plant cells. (Received January 13, 1997; Accepted July 10, 1997)     

hnRNA and its attachment to a nuclear protein matrix

In this study, DNA-depleted nuclear protein matrices are isolated from HeLa S3 cells. These nuclear matrices consist of peripheral laminae, residual nucleoli, and internal fibrillar structures. High molecular weight, heterogeneous nuclear RNA (hnRNA) is quantitatively associated with these structures and can be released intact only by affecting the integrity of the matrices. It is, therefore, concluded that hnRNA is part of a highly organized nuclear structure. By irradiation of intact cells or isolated nuclear matrices with ultraviolet light, proteins tightly associated with hnRNA can be induced to cross-link with the RNA. Performing the cross-linking in vivo is an extra guarantee that only hnRNA-protein (hnRNP) complexes existing in the intact cell are covalently linked. Such hnRNP complexes were isolated and purified under conditions that completely dissociate nonspecific RNA-protein complexes. By comparison of the hnRNP found in nuclear matrices and the published data on the composition of hnRNP particles, it was found that the so-called hnRNP "packaging" proteins (32,000-38,000 mol wt) were not efficiently cross-linked to hnRNA by UV irradiation. They were, however, present in the matrix preparations, bound to hnRNA, because they were released from nuclear matrices after ribonuclease treatment of these structures. On the other hand, two major hnRNPs (41,500 and 43,000 mol wt) were efficiently cross-linked to hnRNA. These proteins were not released by ribonuclease treatment, which suggests that they are involved in the binding of hnRNA to the nuclear matrix.     

Nuclear protein matrix of seminal vesicle epithelium

Nuclear protein matrix was isolated from guinea pig seminal vesicle epithelium and liver. The two matrices were similar in fine structure as seen by transmission electron microscopy, in protein electropherograms, and in percent composition relative to protein, DNA, and RNA. Scanning electron microscopy was used to examine intact seminal vesicle nuclei, nuclei after treatment with Triton X-100 and DNAse I, and purified nuclear matrix. The matrix surface presented a 'porous' appearance by both scanning and transmission electron microscopy. The matrices of liver and seminal vesicle epithelium (SVE) and the intact nuclei of SVE were assayed for specific binding of free synthetic androgen, 17 alpha-methyltrienolone (R1881). Saturable specific binding was demonstrable for seminal vesicle matrix but not for liver matrix. Maximal binding of androgen occurred at a concentration of approximately 12 nM and was demonstrated to be 1.34 +/- 0.22 pmol of R1881 per mg of seminal vesicle matrix protein; the Kd was approximately 8 nM. The binding of labeled R1881 to matrix could be inhibited with low concentrations of unlabeled androgens, but not with estrogens or other steroids. Our data indicate that the binding of androgen to matrix could account for at least 21% of the binding to intact nuclei.     

Nuclear matrix proteins bind very tightly to specific regions of the chicken histone H5 gene.

The nuclear matrix is operationally defined as the structure remaining after nuclease-digested nuclei are extracted with high concentrations of salt. The nuclear matrix is thought to have a role in organizing higher order chromatin into loop domains. We determined whether specific regions of the histone H5 gene were very tightly bound to protein of erythrocyte and liver nuclear matrices in vitro. We demonstrate that DNA fragments spanning sequences 5' to the promoter and the 3' enhancer region of the histone H5 gene, but not DNA fragments spanning the promoter, were very tightly bound to protein of nuclear matrices of erythrocytes and liver. The nuclear matrix consists of internal nuclear matrix and nuclear pore-lamina complex. Recently, we demonstrated that histone deacetylase could be used as a marker enzyme of the internal nuclear matrix. We demonstrate that nuclear pore-lamina complex preparations that were depleted of histone deacetylase activity, and thus of internal nuclear matrix, retained the protein that bound very tightly to the beta-globin and histone H5 enhancers. These results provide evidence that specific regions of the histone H5 gene are very tightly bound to nuclear pore-lamina complex protein.     

In vitro interaction of 63-nickel(II) with chromatin and DNA from rat kidney and liver nuclei

The interaction of nickel(II) with chromatin was studied in vitro and in isolated nuclei from rat liver and kidney. Nickel(II) bound to chromatin, polynucleosomes (DNA + histone octamer protein complex), and to deproteinized DNA both in intact nuclei and in vitro. The amount of nickel(II) bound depended on the concentration of nickel(II), the presence of chromosomal proteins and the binding sites on DNA which provide a stable coordination environment for nickel(II). The binding of nickel(II) to chromatin and to DNA in whole nuclei was much slower than in vitro indicating that assessibility of the DNA binding sites was influenced by the presence of the nuclear membrane, nuclear matrix and nuclear proteins and/or by the condensed nuclear structure of chromatin. Since DNA containing bound nickel(II) was isolated from chromatin, nickel(II) directly interacted with stable binding sites on the DNA molecule in chromatin. Nickel(II) was associated with the histone and non-histone nuclear proteins as well as the DNA in rat liver and kidney chromatin. Nickel(II) was found to bind to calf thymus histones in vitro. Nickel(II)-nuclear protein and -DNA interactions were investigated by gel electrophoretic analysis of in vitro incubation products. Although nickel-histone and nickel-non-histone protein interactions were completely disrupted by the electrophoretic conditions, fluorography revealed the presence of inert nickel(II)-DNA and/or nickel(II)-DNA-protein complexes.     

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.     

Radioprotective thiolamines WR-1065 and WR-33278 selectively denature nonhistone nuclear proteins

Differential scanning calorimetry was used to study the interactions of nuclei isolated from Chinese hamster V79 cells with the radioprotector WR-1065, other thiol compounds, and polyamines. Differential scanning calorimetry monitors denaturation of macromolecules and resolves the major nuclear components (e.g. constrained and relaxed DNA, nucleosome core, and nuclear matrix) of intact nuclei on the basis of thermal stability. WR-1065 treatment (0.5-10 mM) of isolated nuclei led to the irreversible denaturation of nuclear proteins, a fraction of which are nuclear matrix proteins. Denaturation of 50% of the total nonhistone nuclear protein content of isolated nuclei occurred after exposure to 4.7 mM WR-1065 for 20 min at 23 degrees C. In addition, a 22% increase in the insoluble protein content of nuclei isolated from V79 cells that had been treated with 4 mM WR-1065 for 30 min at 37 degrees C was observed, indicating that WR-1065-induced protein denaturation occurs not only in isolated nuclei but also in the nuclei of intact cells. From the extent of the increase in insoluble protein in the nucleus, protein denaturation by WR-1065 is expected to contribute to drug toxicity at concentrations greater than approximately 4 mM. WR-33278, the disulfide form of WR-1065, was approximately twice as effective as the free thiol at denaturing nuclear proteins. The proposed mechanism for nucleoprotein denaturation is through direct interactions with protein cysteine groups with the formation of destabilizing protein-WR-1065 disulfides. In comparison to its effect on nuclear proteins in isolated nuclei, WR-1065 had only a very small effect on non-nuclear proteins of whole cells, isolated nuclear matrix, or the thiol-rich Ca(2+)ATPase of sarcoplasmic reticulum, indicating that WR-1065 can effectively denature protein only inside an intact nucleus, probably due to the increased concentration of the positively charged drug in the vicinity of DNA.     

The nuclear matrix continues DNA synthesis at in vivo replicational forks

Alkaline cesium chloride gradient analysis of in vivo [3H]bromodeoxyuridine-labeled and in vitro [alpha-32P]dCTP-labeled DNA was used to determine whether in vitro DNA synthesis in regenerating rat liver nuclei and nuclear matrices continued from sites of replication initiated in vivo. At least 70 and 50% of the products of total nuclear and matrix-bound in vitro DNA synthesis, respectively, were continuations of in vivo initiated replicational forks. The relationship of the in vitro DNA synthetic sites in total nuclei versus the nuclear matrix was examined by using [3H]bromodeoxyuridine triphosphate to density label in vitro synthesized DNA in isolated nuclei and [alpha-32P]dCTP to label DNA synthesized in isolated nuclear matrix. A minimum of about 40% of matrix-bound DNA synthesis continued from sites being used in vitro by isolated nuclei. Furthermore, nuclear matrices prepared from in vitro labeled nuclei were 5-fold enriched in DNA synthesized by the nuclei and were several-fold enriched, compared to total nuclear DNA, in a particularly high density labeled population of DNA molecules.     

Isolation and characterization of the nuclear matrix in Friend erythroleukemia cells: chromatin and hnRNA interactions with the nuclear matrix.

Nuclear matrices from undifferentiated and differentiated Friend erythroleukemia cells have been obtained by a method which removes DNA in a physiological buffer. These matrices preserved the characteristic topographical distribution of condensed and diffuse "chromatin" regions, as do nuclei in situ or isolated nuclei. Histone H1 was released from the nuclear matrix of undifferentiated cells by 0.3 M KCl; inner core histones were released by 1 M KCl. Nuclear matrix from differentiated cells did not maintain H1, and histone cores were fully released in 0.7 M KCl. KCl removed the core histones as an octameric structure with no evidence of preferential release of any single histone. Electron microscopy of KCl-treated matrix revealed no condensed regions but rather a network of fibrils in the whole DNA-depleted nuclei. When nuclear matrices from both types of cell were exposed to conditions of very low ionic strength, inner core histones and condensed regions remained. These observations support the contention that inner core histones are bound to matrix through natural ionic bonds or saline-labile elements, and that these interactions are implicated in chromatin condensation. hnRNA remained undegraded and tenaciously associated to the matrix fibrils, and was released only by chemical means which, by breaking hydrophobic and hydrogen bonds, produced matrix lysis. Very few nonhistone proteins were released upon complete digestion of DNA from either type of nuclei. The remaining nonhistone proteins represent a large number of species of which the majority may be matrix components. The molecular architecture in both condensed and diffuse regions of interphase nuclei appears to be constructed of two distinct kinds of fibers; the thicker chromatin fibers are interwoven with the thinner matrix fibers. The latter are formed by a heteropolymer of many different proteins.     

A domain model for eukaryotic DNA organization: a molecular basis for cell differentiation and chromosome evolution

A model for eukaryotic chromatin organization is presented in which the basic structural and functional unit is the DNA domain. This simple model predicts that both chromosome replication and cell type-specific control of gene expression depend on a combination of stable and dynamic DNA-nuclear matrix interactions. The model suggests that in eukaryotes, DNA regulatory processes are controlled mainly by the intranuclear compartmentalization of the specific DNA sequences, and that control of gene expression involves multiple steps of specific DNA-nuclear matrix interactions. Predictions of the model are tested using available biochemical, molecular and cell biological data. In addition, the domain model is discussed as a simple molecular mechanism to explain cell differentiation in multi-cellular organisms and to explain the evolution of eukaryotic genomes consisting mainly of repetitive sequences and "junk" DNA.     

Crosslinking of nuclear proteins to DNA by cis-diamminedichloroplatinum in intact cells. Involvement of nuclear matrix proteins.

In order to detect the nuclear matrix proteins involved in DNA binding, avoiding possible artifacts derived from the disruption of nuclei, proteins were crosslinked to DNA by the action of cis-diamminedichloroplatinum on intact chicken liver cells and analyzed by two-dimensional gel electrophoresis. At least eleven species of crosslinked proteins were found to derive from the nuclear matrix prepared from the same cell type, and five of these were found also among the proteins crosslinked to DNA in intact liver cells from ox and pig. This subset of common proteins, conserved in different animal species, is likely to have a fundamental role for the anchorage of DNA to the nuclear matrix.     

Isolation and characterization of stable nuclear matrix preparations and associated DNA from avian erythroblasts

A novel procedure for isolation of nuclear matrices from chicken erythroblast cells was elaborated. The influence of variations in the isolation procedure on structural integrity and morphology of nuclear matrices as well as on properties of the nuclear matrix-associated DNA fractions was investigated. The incubation of isolated nuclei in the presence of Cu2+ ions provided significant stabilization of the nuclear matrix. Copper treatment of nuclei did not affect the properties of the nuclear skeleton-associated DNA fraction. In both copper-stabilized as well as unstabilized nuclei, nuclear matrix-attached DNA was digested to the same extent with nucleolytic enzymes, and could be totally removed from nuclear matrices by 2 M NaCl-2 M urea treatment. The fine morphology of the nuclear matrix did not change after extraction of nuclear skeleton-associated DNA fragments. In the presence or absence of copper ions, matrix DNA was found to be qualitatively different compared with total DNA, in particular with respect to the representation of specific repetitive sequences of the chicken beta globin gene domain.     

Nuclear factor 1 is a component of the nuclear matrix

Chicken histone H5 is an H1-like linker histone that is expressed only in nucleated erythrocytes. The histone H5 promoter has binding sites for Sp1 (a high affinity site) and UPE-binding protein, while the 3′ erythroid-specific enhancer has binding sites for Sp1 (one moderate and three weak affinity), GATA-1, and NF1. In this study we investigated whether trans-acting factors that bind to the chicken histone H5 promoter or enhancer are associated with adult chicken immature and mature erythrocyte nuclear matrices. We show that NF1, but not Sp1, GATA-1, or UPE-binding protein, is associated with the internal nuclear matrices of these erythroid cells. Further, we found that a subset of the NF1 family of proteins is bound to the mature erythrocyte nuclear matrix. These results suggest that in chicken erythrocytes NF1 may mediate an interaction between the histone H5 enhancer and the erythroid internal nuclear matrix. NF1 was also present in the internal nuclear matrices of chicken liver and trout liver. The observations of this study provide evidence that NF1 may have a role in a variety of cell types in targeting specific DNA sequences to the nuclear matrix. © 1994 Wiley-Liss, Inc.     

Phosphorylation of nuclear matrix proteins in isolated regenerating rat liver nuclei

The phosphorylation of nuclear matrix proteins from normal and regenerating rat liver nuclei was examined using an $\text{in vitro}$ system of isolated nuclei and γ-³²P-ATP. Phosphorylation of the nuclear matrix proteins was 2–3 fold higher than that of the total nuclear proteins in normal nuclei. The level of phosphorylation of the matrix proteins was enhanced an additional three fold at a period in liver regeneration (12 hours) just preceding the onset of DNA synthesis.