Nuclear Matrix Preparations Research Articles

Human satellite 3 (HS3) binding protein from the nuclear matrix: isolation and binding properties

Satellite DNA (satDNA) is the main component of residual DNA in nuclear matrix (NM) preparations. Gel mobility shift assay (GMSA) revealed specific human satellite 3 (HS3) binding activity in NM extracts. An HS3 binding protein was purified using diethylaminoethyl (DEAE)-cellulose and preparative GMSA. The binding was specific, although other satDNA fragments compete to some extent for the binding. DNase I footprinting and methylation interference revealed multiple points of protection distributed throughout the HS3 fragment with periodicity of about 10 bp, mostly inside an AT island. Polyclonal antibodies (AB) were raised against HS3-protein complexes cut from the preparative GMSA gel. On immunoblots, AB recognise a protein, which is not lamin, with apparent molecular mass 70 kDa, the same as revealed by purification (p70). In in situ nuclear matrix preparations combined immunofluorescence (AB) and fluorescent in situ hybridisation (HS3) shows that HS3 and p70 areas correspond to each other. The localisation of this protein detected with AB in interphase nuclei coincides with the heterochromatic regions which surround nucleoli in correspondence with the known HS3 position in the nuclei.

Nuclear matrix provides linkage sites for translocated NF-kappa B: morphological evidence.

In response to the binding of extracellular ligands to cell surface receptors, multiple transcription factors are activated in the cytoplasm and translocated into the nucleus where they exert positive or negative control over cellular genes. The human transcription factor NF-kappa B family regulates the expression of a large number of genes involved in the host defence mechanism. They are typically present in the cytoplasm bound to the inhibitory I kappa B proteins. The activation of NF-kappa B involves the signal-induced degradation of these proteins, allowing NF-kappa B to translocate to the nucleus. In this study, by multiparametric analysis, we recognise in RPMI-8402 DMSO-activated cells the intracellular movement of transcription factor NF-kappa B providing its definite intranuclear collocation. Intact cells, purified nuclei and nuclear matrix preparations after 4 h of treatment were processed for morphological and biochemical analyses. Light and electron microscope observations show, in untreated cells, the presence of NF-kappa B protein homogeneously retained in the cytoplasm. Treated cells display a massive presence of NF-kappa B at the nuclear level bound to the interchromatin region. Immunoblotting of the same specimens confirms the strong association of NF-kappa B with the nuclear scaffold. Taken together, the data presented in this manuscript support a model where DMSO treatment provokes the cleavage and translocation of NF-kappa B from the cytoplasm to the nucleus and, in particular, in the proteinaceous network of the nuclear matrix sustaining the active role of this subcellular structure on regulation of eukaryotic gene expression.

Nuclear matrix-like filaments and fibrogranular complexes form through the rearrangement of specific nuclear ribonucleoproteins.

The behavior of nuclear pre-mRNA-binding proteins after their nuclease and/or salt-induced release from RNA was investigated. After RNase digestion or salt extraction, two proteins that initially exist as tetramers (A2)(3)B1 in isolated heterogeneous nuclear ribonucleoprotein (hnRNP) complexes quantitatively reassociated to form regular helical filaments ranging in length from 100 nm to >10 microm. In highly magnified preparations prepared for scanning transmission electron microscopy, single filaments have diameters near 18 nm. In conventional negatively stained preparations viewed at low magnification, the diameters of the thinnest filaments range from 7 to 10 nm. At protein concentrations of >0.1 mg/ml, the filaments rapidly aggregated to form thicker filamentous networks that look like the fibrogranular structures termed the "nuclear matrix." Like the residual material seen in nuclear matrix preparations, the hnRNP filaments were insoluble in 2 M NaCl. Filament formation is associated with, and may be dependent on, disulfide bridge formation between the hnRNP proteins. The reducing agent 2-mercaptoethanol significantly attenuates filament assembly, and the residual material that forms is ultrastructurally distinct from the 7- to 10-nm fibers. In addition to the protein rearrangement leading to filament formation, nearly one-third of the protein present in chromatin-clarified nuclear extracts was converted to salt-insoluble material within 1 min of digestion with RNase. These observations are consistent with the possibility that the residual material termed the nuclear matrix may be enriched in, if not formed by, denatured proteins that function in pre-mRNA packaging, processing, and transport.

Identification of the goldfish 20S proteasome β6 subunit bound to nuclear matrix

Proteasomes are large, multisubunit particles that act as the proteolytic machinery for most of the regulated intracellular protein breakdown in eukaryotic cells. Proteasomes are present in both the nucleus and cytoplasm. When we analyzed the molecular composition of protein constituents of the nuclear matrix preparation of goldfish oocytes by two-dimensional polyacrylamide gel electrophoresis followed by sequence analysis, we found a 26 kDa spot identical in amino acid sequence to the β6 subunits of the 20S proteasome. No spot of other subunits of 20S proteasome was detected. Here we describe the cloning, sequencing and expression analysis of Carassius auratus, β6_ca, which encodes one of the proteasome β subunits from goldfish ovary. From the screening of an ovarian cDNA library, two types of cDNA were obtained, one 941 bp and the other 884 bp long. The deduced amino acid sequences comprise 239 and 238 residues, respectively. These deduced amino acid sequences are highly homologous to those of β6 subunits of other vertebrates. Immunoblot analysis of nuclear matrix using anti-proteasome antibodies showed only a spot of β6_ca. These results suggest that the β6 subunit of the goldfish 20S proteasome, β6_ca, is responsible for anchoring proteasomes in the nucleus.

DNA-protein cross-linking in nuclei of immature and mature chicken erythrocytes.

DNA-protein cross-linkages were formed in isolated nuclei from immature and mature chicken erythrocytes by reaction with cis-diammine dichloroplatinum. On the basis of electrophoretic behaviour, the most abundant proteins involved in the cross-linking appeared to be present also in preparations of nuclear matrix. The maturation of the erythrocyte, which is accompanied by transcriptional inactivation, leads to a decrease in the amount of DNA-interacting proteins, to a loss of proteins capable of a specific recognition of DNA sequences and, unexpectedly, to the appearence of some new DNA-protein interactions. At least three cross-linked proteins were found predominantly or exclusively in nuclei of immature cells, and three others in those of mature ones. The three DNA-bound proteins, typical of mature erythrocytes, were not found among the components of a high-salt preparation of nuclear matrix. The results obtained suggest that, in addition to the well-known histone H5 and MENT protein, these newly identified DNA-bound proteins contribute to the formation of the condensed, inactive chromatin characteristic of mature erythrocyte.

NXP-1, a Human Protein Related to Rad21/Scc1/Mcd1, Is a Component of the Nuclear Matrix

Nuclear matrix is a complex intranuclear network supposed to be involved in the various nuclear functions. In order to identify the nuclear matrix proteins, we isolated a cDNA clone from a human placenta cDNA library. This clone was partially represented a known cDNA clone HA1237. HA1237 encoded a 631-amino-acid peptide, which we designated NXP-1. NXP-1 was related to yeast Rad21/Scc1/Mcd1, Xenopus XRAD21, and mouse PW29, and identical with HR21spA isolated from a human testis cDNA library. We developed a polyclonal antibody to the purified NXP-1 bacterially expressed as a fusion protein with GST. Western blot analysis with anti-NXP-1 polyclonal antibody showed nuclear matrix localization of NXP-1 in HeLa cells. Indirect immunofluorescence staining also showed nuclear and nuclear matrix localization of the NXP-1. Results of in vitro binding assays employing nuclear matrix preparations indicated that the N-terminal region (16–128 amino acid) of NXP-1 has an important role in nuclear matrix distribution.

The nuclear matrix prepared by amine modification.

The nucleus is spatially ordered by attachments to a nonchromatin nuclear structure, the nuclear matrix. The nuclear matrix and chromatin are intimately connected and integrated structures, and so a major technical challenge in nuclear matrix research has been to remove chromatin while retaining a native nuclear matrix. Most methods for removing chromatin require first a nuclease digestion and then a salt extraction to remove cut chromatin. We have hypothesized that cut chromatin is held in place by charge interactions involving nucleosomal amino groups. We have tested this hypothesis by chemically modifying amino groups after nuclease digestion. By using this protocol, chromatin could be effectively removed at physiological ionic strength. We compared the ultrastructure and composition of this nuclear matrix preparation with the traditional high-salt nuclear matrix and with the third nuclear matrix preparation that we have developed from which chromatin is removed after extensive crosslinking. All three matrix preparations reveal internal nuclear matrix structures that are built on a network of branched filaments of about 10 nm diameter. That such different chromatin-removal protocols reveal similar principles of nuclear matrix construction increases our confidence that we are observing important architectural elements of the native structure in the living cell.

Spatial Organization of Four hnRNP Proteins in Relation to Sites of Transcription, to Nuclear Speckles, and to Each Other in Interphase Nuclei and Nuclear Matrices of HeLa Cells

RNA polymerase II transcripts are complexed with heterogeneous nuclear ribonucleoprotein (hnRNP) proteins. These proteins are involved in several aspects of the maturation and transport of hnRNA. We performed a detailed study of the spatial distribution of four hnRNP proteins (hnRNP C, I, L, and U) in HeLa nuclei, using immunofluorescent labeling and confocal microscopy. Despite the fact that hnRNP proteins have been shown to coimmunoprecipitate, a hallmark of hnRNP proteins, we find that hnRNP C, I, and L have a spatial nuclear distribution that is not related to that of hnRNP U. We also examined the distribution of hnRNP proteins in relation to that of nascent transcripts. The four hnRNP proteins that we examined are not enriched at sites of RNA synthesis. Using antibodies against the nuclear poly(A)-binding protein (PAB II) we investigated the relationship between the distribution of hnRNP proteins and that of nuclear domains (nuclear speckles) that are enriched in splicing factors, poly(A)+RNA, and PAB II. We found that the four hnRNP proteins are not enriched in these domains. This indicates that the poly(A)+RNA, present in high concentration in speckles, is not complexed with these hnRNP proteins. This is in agreement with the notion that poly(A)+RNA in speckles is different from ordinary hnRNA. Previously, we have shown that hnRNP proteins are the major protein components of the fibrogranular internal nuclear matrix (K. A. Matternet al.(1996)J. Cell. Biochem.62, 275–289; K. A. Matternet al.(1997)J. Cell. Biochem.65, 42–52). We observed that in nuclear matrices the spatial distributions of the four hnRNP proteins, like that of nascent RNA and PAB II, are essentially the same as observed in intact nuclei. Moreover, also in nuclear matrix preparations, like in intact nuclei, nascent RNA and PAB II have spatial distributions that differ from those of hnRNP proteins. Our results are compatible with the notion that hnRNP proteins are able to form complexes of many different, probably overlapping, compositions.

Subcellular localization of mineralocorticoid receptors in living cells: effects of receptor agonists and antagonists.

Results on the subcellular localization of the mineralocorticoid receptor (MR) have been controversial. To determine the subcellular distribution and trafficking of the MR in living cells after binding of agonists and antagonists, we expressed a MR-green fluorescent protein (GFP) chimera in mammalian cells lacking endogenous MR. The GFP-tagged MR (GFP-MR) remained transcriptionally active, as determined in cotransfection experiments with the MR-responsive reporter, TAT3-LUC. The subcellular localization of GFP-MR was monitored by fluorescence time-lapse microscopy. In the absence of hormone, MR was present both in the cytoplasm and nucleus. Aldosterone induced a rapid nuclear accumulation of the MR. Aldosterone-bound GFP-MR was concentrated in prominent clusters within the nucleus, whereas GFP-MR did not form clusters in the absence of hormone. Similar subnuclear distribution was observed with corticosterone, another MR agonist. In the presence of the MR antagonists spironolactone or ZK91587 the rate of nuclear translocation was significantly slower and the final nuclear-to-cytoplasmic ratio in steady state was significantly lower than with aldosterone. In addition, MR antagonists did not induce formation of nuclear GFP-MR clusters. MR antagonists also were able to disrupt pre-existing nuclear clusters formed in the presence of aldosterone. GFP-MR clusters were retained in nuclear matrix preparations after in vivo crosslinking. These data strongly suggest that hormone-activated MRs accumulate in dynamic discrete clusters in the cell nucleus, and this phenomenon occurs only with transcriptionally active mineralocorticoids.

Thinking about a nuclear matrix

The possible existence in eukaryotic cells of an internal, non-chromatin nuclear structural framework that facilitates gene readout as a set of spatially concerted reactions has become a popular but controversial theater of investigation. This article endeavors to present a circumspect review of the nuclear matrix concept as we presently know it, framed around two contrasting hypotheses: (1) that an internal nuclear framework actively enhances gene expression (in much the same way the cytoskeleton mediates cell locomotion, mitosis and intracellular vesicular traffic) versus (2) that the interphase chromosomes have fixed, inherited positions and that the DNA replication, transcripton and RNA processing machinery diffusionally arrives at sites of gene readout, with some aspects of nuclear structure thus being more a result than a cause of gene expression. On balance, the available information suggests that interactions among various gene expression machines may contribute to isolated nuclear matrix preparations. Some components of isolated nuclear matrix preparations may also reflect induced or reconfigured protein-protein associations. The protein characterization and ultrastructural analysis of the isolated nuclear matrix has advanced significantly in recent years, although controversies remain. Important new clues are now coming in from promising contemporary lines of research that report on nuclear structure in living cells.

The SURF-6 protein is a component of the nucleolar matrix and has a high binding capacity for nucleic acids in vitro

The recently identified novel protein SURF-6 is shown to be a component of the nucleolar matrix. Immunofluorescence analysis demonstrated that SURF-6 was localized in residual nucleoli of in situ nuclear matrix preparations of mouse fibroblast cells (NIH 3T3), which were depleted of soluble and chromatin related proteins. Immunoblot analysis of biochemical nucleolar subfractions confirmed that SURF-6 was present in the nucleolar matrix fraction, and was absent from the fractions of soluble proteins released by DNase or RNase. The capacity of SURF-6 to bind nucleic acids was investigated in vitro. Both endogenous SURF-6 from nuclear extracts and recombinant SURF-6 exhibited a strong binding capacity for nucleic acids. It was shown that SURF-6 bound to both DNA and RNA, however, it showed stronger binding to RNA. The presence and nuclear distribution of SURF-6 during the cell cycle was explored by immunofluorescence analysis. It was shown that SURF-6 was always found in the nucleolus regardless of the phase of the cell cycle suggesting that it is a structural protein constitutively present in nucleolar substructures. The colocalization of SURF-6 with the major nucleolar proteins B23 and fibrillarin, which are known to be involved in the processing of ribosomal RNA (rRNA), was examined both in interphase and mitosis by double immunolabeling of cells. SURF-6 was found to be largely coincident with both proteins in interphase and it was distributed in the same cellular locations, namely the perichromosomal layer, the cytoplasm and prenucleolar bodies, in mitosis. However, colocalization of SURF-6 with fibrillarin and B23 was only partial in interphase, and the dynamics of its localization was not completely the same as those of either fibrillarin or B23 during mitosis. Taken together, these results indicate that SURF-6 is a novel nucleolar matrix component and imply that SURF-6 might support nucleolar matrix structure and function(s) via its association with nucleic acids. We propose that SURF-6 may be involved in processing of rRNA, based on its cytological characteristics, but at stages in ribosomal biogenesis which are different from those for fibrillarin and B23.

Developmental association of the beta-galactoside-binding protein galectin-1 with the nuclear matrix of rat calvarial osteoblasts.

The protein composition of the nuclear matrix changes significantly as the osteoblast matures from a proliferating pre-osteoblast to an osteocyte embedded in a mineralized matrix. These matrix protein are the result of developmental stage-specific gene expression during osteoblast differentiation. To isolate nuclear matrix proteins unique to the bone phenotype we analyzed nuclear matrix preparations from cultures of rat calvarial osteoblasts by high resolution two-dimensional gel electrophoresis at two different stages: proliferation (day 3) and differentiation (day 18, mineralized). We characterized one protein (14 kDa; pI 5.0), that was detectable only in the nuclear matrix of differentiated osteoblasts. By mass spectrometry and microsequencing, this protein was identified as the beta -galactoside-binding protein galectin-1. Both immunofluorescence staining of nuclear matrix preparations with the galectin-1 antibody and western blot analysis of subcellular fractions confirmed that galectin-1 is only associated with the nuclear matrix in differentiated osteoblasts as the result of differential retention. Galectin-1 protein and mRNA are present throughout osteoblast differentiation. Galectin-1 is present in the cytoplasmic and nuclear fractions in both proliferating and differentiated osteoblasts. However, its only stable binding is to the nuclear matrix of the differentiated osteoblast; but, in proliferating osteoblasts, galectin-1 is not retained in the nuclear matrix. Taken together, our results suggest that developmental association of galectin-1 with the nuclear matrix reflects differential subnuclear binding of galectin-1 during osteoblast differentiation.

Developmental association of the β-galactoside-binding protein galectin-1 with the nuclear matrix of rat calvarial osteoblasts

ABSTRACT The protein composition of the nuclear matrix changes significantly as the osteoblast matures from a proliferating pre-osteoblast to an osteocyte embedded in a mineralized matrix. These matrix protein are the result of developmental stage-specific gene expression during osteoblast differentiation. To isolate nuclear matrix proteins unique to the bone phenotype we analyzed nuclear matrix preparations from cultures of rat calvarial osteoblasts by high resolution two-dimensional gel electrophoresis at two different stages: proliferation (day 3) and differentiation (day 18, mineralized). We characterized one protein (14 kDa; pI 5.0), that was detectable only in the nuclear matrix of differentiated osteoblasts. By mass spectrometry and microsequencing, this protein was identified as the β-galactoside-binding protein galectin-1. Both immunofluorescence staining of nuclear matrix preparations with the galectin-1 antibody and western blot analysis of subcellular fractions confirmed that galectin-1 is only associated with the nuclear matrix in differentiated osteoblasts as the result of differential retention. Galectin-1 protein and mRNA are present throughout osteoblast differentiation. Galectin-1 is present in the cytoplasmic and nuclear fractions in both proliferating and differentiated osteoblasts. However, its only stable binding is to the nuclear matrix of the differentiated osteoblast; but, in proliferating osteoblasts, galectin-1 is not retained in the nuclear matrix. Taken together, our results suggest that developmental association of galectin-1 with the nuclear matrix reflects differential subnuclear binding of galectin-1 during osteoblast differentiation.

Ataxin-1 with an expanded glutamine tract alters nuclear matrix-associated structures.

Spinocerebellar ataxia type 1 (SCA1) is one of several neurodegenerative disorders caused by an expansion of a polyglutamine tract. It is characterized by ataxia, progressive motor deterioration, and loss of cerebellar Purkinje cells. To understand the pathogenesis of SCA1, we examined the subcellular localization of wild-type human ataxin-1 (the protein encoded by the SCA1 gene) and mutant ataxin-1 in the Purkinje cells of transgenic mice. We found that ataxin-1 localizes to the nuclei of cerebellar Purkinje cells. Normal ataxin-1 localizes to several nuclear structures approximately 0.5 microm across, whereas the expanded ataxin-1 localizes to a single approximately 2-microm structure, before the onset of ataxia. Mutant ataxin-1 localizes to a single nuclear structure in affected neurons of SCA1 patients. Similarly, COS-1 cells transfected with wild-type or mutant ataxin-1 show a similar pattern of nuclear localization; with expanded ataxin-1 occurring in larger structures that are fewer in number than those of normal ataxin-1. Colocalization studies show that mutant ataxin-1 causes a specific redistribution of the nuclear matrix-associated domain containing promyelocytic leukaemia protein. Nuclear matrix preparations demonstrate that ataxin-1 associates with the nuclear matrix in Purkinje and COS cells. We therefore propose that a critical aspect of SCA1 pathogenesis involves the disruption of a nuclear matrix-associated domain.

Quantitative immunofluorescence and immunoelectron microscopy of the topoisomerase II alpha associated with nuclear matrices from wild-type and drug-resistant chinese hamster ovary cell lines.

Topo II alpha is considered an important constituent of the nuclear matrix, serving as a fastener of DNA loops to the underlying filamentous scaffolding network. To further define a mechanism of drug resistance to topo II poisons, we studied the quantity of topo II alpha associated with the nuclear matrix in drug-resistant SMR16 and parental cells in the presence and absence of VP-16. Nuclear matrices were prepared from nuclei isolated in EDTA buffer, followed by nuclease digestion with DNase II in the absence of RNase treatment and extraction with 2 M NaCl. Whole-mount spreading of residual structures permits, by means of isoform-specific antibody and colloidal-gold secondary antibodies, an estimate of the amount of topo II alpha in individual nuclear matrices. There are significant variations in topo II alpha amounts between individual nuclear matrices due to the cell cycle distribution. The parental cell line contained eight to ten times more nuclear matrix-associated topo II alpha than the resistant cell line matrices. Nuclear matrix-associated topo II alpha from wild-type and resistant cell lines correlated well with the immunofluorescent staining of the enzyme in nuclei of intact cells. The amount of DNA associated with residual nuclear structures was five times greater in the resistant cell line. This quantity of DNA was not proportional to the quantity of topo II alpha in the same matrix; in fact they were inversely related. In situ whole-mount nuclear matrix preparations were obtained from cells grown on grids and confirmed the results from labeling of isolated residual structures.

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

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

Association of protein kinase CK2 with nuclear matrix: Influence of method of preparation of nuclear matrix

Nuclear matrix (NM) plays roles of fundamental structural and functional significance as the site of replication, transcription, and RNA processing and transport, acting as an anchor or attachment site for a variety of enzymes and other proteins involved in these activities. We have previously documented that protein kinase CK2 translocates from the cytosol to the nucleus, where it associates preferentially with chromatin and NM, in response to certain growth stimuli. Considering that characteristics of the isolated NM can depend on the procedure employed for its isolation, we compared three standard methods for NM preparation to confirm the association of intrinsic CK2 with this structure. Our data suggest that the method used for isolating the NM can quantitatively influence the measurable NM-associated CK2. However, all three methods employed yielded qualitatively similar results with respect to the stimulus-mediated modulation of NM-associated CK2, thus further supporting the notion that NM is an important site for physiologically relevant functions of CK2. In addition, core filaments and cytoskeleton that were isolated by two of the preparative methods had a small but significant level of associated CK2 activity. J. Cell. Biochem. 64:499–504. © 1997 Wiley-Liss, Inc. 1 This article is a U.S. Government work and, as such, is in the public domain in the United States of America.

Association of protein kinase CK2 with nuclear matrix: Influence of method of preparation of nuclear matrix

Nuclear matrix (NM) plays a role of fundamental structural and functional significance as the site of replication, transcription, and RNA processing and transport, acting as an anchor or attachment site for a variety of enzymes and other proteins involved in these activities. We have previously documented that protein kinase CK2 translocates from the cytosol to the nucleus, where it associates preferentially with chromatin and NM, in response to certain growth stimuli. Considering that characteristics of the isolated NM can depend on the procedural employed for its isolation, we compared three standard methods for NM preparation to confirm the association of intrinsic CK2 with this structure. Our data suggest that the method used for isolating the NM can qualitatively influence the measurable NM-associated CK2. However, all three methods employed yielded qualitatively similar results with respect to the stimulus-mediated modulation of NM-associated CK2, thus further supporting the notion that NM is an important site for physiologically relevant functions of CK2. In addition, core filaments and cytoskeleton that were isolated by two of the preparative methods had a small but significant level of associated CK2 activity.

Structure, subnuclear distribution, and nuclear matrix association of the mammalian telomeric complex.

Mammalian telomeres are composed of long arrays of TTAGGG repeats complexed with the TTAGGG repeat binding factor, TRF. Biochemical and ultrastructural data presented here show that the telomeric DNA and TRF colocalize in individual, condensed structures in the nuclear matrix. Telomeric TTAGGG repeats were found to carry an array of nuclear matrix attachment sites occurring at a frequency of at least one per kb. The nuclear matrix association of the telomeric arrays extended over large domains of up to 20-30 kb, encompassing the entire length of most mammalian telomeres. TRF protein and telomeric DNA cofractionated in nuclear matrix preparations and colocalized in discrete, condensed sites throughout the nuclear volume. FISH analysis indicated that TRF is an integral component of the telomeric complex and that the presence of TRF on telomeric DNA correlates with the compact configuration of telomeres and their association with the nuclear matrix. Biochemical fractionation of TRF and telomeric DNA did not reveal an interaction with the nuclear lamina. Furthermore, ultrastructural analysis indicated that the mammalian telomeric complex occupied sites throughout the nuclear volume, arguing against a role for the nuclear envelope in telomere function during interphase. These results are consistent with the view that mammalian telomeres form nuclear matrix-associated, TRF-containing higher order complexes at dispersed sites throughout the nuclear volume.

INMP, a novel intranuclear matrix protein related to the family of intermediate filament-like proteins: molecular cloning and sequence analysis

An important step in understanding nuclear structure and its function in replication and gene regulation is the cloning and characterisation of nuclear matrix proteins. A full-length cDNA-clone, encoding a novel nuclear matrix protein, was isolated from a (λ gt11 cDNA library derived from murine macrophages. The antibody used for the screen was raised against a single polypeptide isolated from two-dimensional gel electrophoresis of nuclear matrix preparations. The cDNA encodes a protein of 446 amino acids named INMP for intranuclear matrix protein. INMP displays several salient features, a coiled-coil domain, a leucine zipper, a number of phosphorylation sites and a putative nuclear localisation signal. Sequence homology comparisons indicate that INMP is a unique protein which is evolutionary related to the gene family of intermediate filament-like proteins, especially the nuclear lamins.