Phosphorylation of nuclear matrix proteins in isolated regenerating rat liver nuclei

Phosphorylation and biosynthesis of high molecular weight proteins of tumor nuclear matrix

Our previous studies showed a predominance of high molecular weight protein group in tumor nuclear matrices. Contrary to normal cells, proteins of this group are preferentially phosphorylated. Phosphoproteins of hepatoma nuclear matrix are selectively subjected to rapid proteolysis. By alkali treatment and a monoclonal antibody against phosphotyrosyl residue the presence of two high molecular weight bands of phosphotyrosyl-containing proteins was detected in nuclear matrices of tumor but not of normal liver cells. High molecular weight protein group of tumor nuclear matrices revealed also a rapid turnover and preferential incorporation of labeled amino acids selectively inhibited by chloramphenicol.

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.

Evidence for incorporation of N-acetylglucosamine in endogenous nuclear acceptors during the nuclear matrix preparation

1. The presence of glycoproteins within the nucleus of cell is now well established and the question arises on the nature of the nuclear glycosylation and the site of their glycosylation. 2. In order to study endogenous nuclear proteins acceptors, we have isolated a subnuclear fraction: nuclear matrix characterized by DNA, RNA, phospholipids and proteins content. Nuclear matrix acceptors were obtained from nuclei incubated with UDP-N-acetyl [14C]glucosamine. 3. In this report we describe the presence of three major glycoproteins labeled with N-acetyl [14C]glucosamine in the nuclear matrix fraction. We obtained gP32, gP67 and gP70 with pI values around 6.2, 6.5 and 8.2.

The nuclear matrix: a heuristic model for investigating genomic organization and function in the cell nucleus

Despite significant advances in deciphering the molecular events underlying genomic function, our understanding of these integrated processes inside the functioning cell nucleus has, until recently, met with only very limited success. A major conundrum has been the "layers of complexity" characteristic of all cell structure and function. To understand how the cell nucleus functions, we must also understand how the cell nucleus is put together and functions as a whole. The value of this neo-holistic approach is demonstrated by the enormous progress made in recent years in identifying a wide variety of nuclear functions associated with the nuclear matrix. In this article we summarize basic properties of in situ nuclear structure, isolated nuclear matrix systems, nuclear matrix-associated functions, and DNA replication in particular. Emphasis is placed on identifying current problems and directions of research in this field and illustrating the intrinsic heuristic value of this global approach to genomic organization and function.

Molecular cloning of matrin F/G: A DNA binding protein of the nuclear matrix that contains putative zinc finger motifs

We have isolated a 2.7-kilobase rat liver cDNA clone that contains the entire 544-amino acid coding sequence for matrin F/G. This protein has previously been localized to the internal, fibrogranular areas of the nuclear matrix and shown to bind to DNA on nitrocellulose blots. The predicted amino acid sequence from the coding region of this cDNA shows that this protein contains approximately 50% hydrophobic amino acids with secondary structure predictions suggesting a large percentage of beta-sheet regions. No significant homologies were found with any other known proteins, including the nuclear lamins. The predicted amino acid sequence was also searched for DNA binding motifs. Two putative zinc finger motifs were found. In addition, a 7-mer palindromic sequence (Ser-Ser-Thr-Asn-Thr-Ser-Ser) was discovered within one of these zinc finger DNA binding regions. A possible regulatory role for this element is discussed.

Association between nuclear matrix and terminal transferase: an electron microscope immunocytochemical analysis

Nuclear matrix extracted from KM-3, a human pre-B leukemia cell line, appears to have a site of linkage for terminal deoxynucleotidyl transferase (TdT). The immunocytochemical analysis of the distribution of TdT using a rabbit polyclonal antibody which recognizes human terminal transferase, shows that the nuclear framework of these cells contains sites of immunoreactivity that appear uniformly distributed on the matrix fibres, while the nucleolar region is unreactive. This evidence points out the possibility that TdT could reside in the proteinaceous scaffold of the nucleus defined as nuclear matrix, thus strengthening the evidence for the metabolic and regulatory roles ascribed to this nuclear framework.

Identification of nuclear envelope proteins and glycoproteins which co-isolate with the nuclear protein matrix

Nuclear envelopes and nuclear matrices were isolated from rat liver nuclei. Although differences in polypeptide composition of the structures are evident on SDS gel electrophoresis, they have an almost identical distribution of concanavalin A-binding glycoproteins. These matrix-associated concanavalin A-binding glycoproteins derive entirely from the nuclear envelope and are recovered almost quantitatively in the matrix. They constitute easily identifiable markers for nuclear envelope association with matrix or other nuclear subfractions. Surface labelling of nuclei with 125I using solid-phase lactoperoxidase further confirmed that a large number of envelope-associated nuclear surface proteins co-isolate with the matrix. Protein kinase activity, as well as endogenous substrates for the kinase(s) are shown to be the same in both envelopes and matrix. Envelope-derived proteins and glycoproteins may comprise a substantial proportion of total matrix protein.

Concentration of particular high molecular mass phosphoproteins in rat liver nuclei and nuclear matrix decreases following inhibition of RNA synthesis by alpha-amanitin

Purified liver nuclei were isolated from rats treated with non-lethal doses of alpha-amanitin, actinomycin D, galactosamine or cycloheximide. The nuclei were incubated in the presence of adenosine 5'-[gamma-32P]triphosphate, and digested with DNAase or DNAase plus high salt concentrations to prepare nuclear residual structures. Using SDS-polyacrylamide gel electrophoresis followed by autoradiography, samples from untreated rats were shown to contain major phosphoproteins in the range 76-260 kDa, with a prominent triplet of bands with 110, 117 and 128 kDa. Treatment of animals with alpha-amanitin or high doses of actinomycin D and galactosamine caused a significant decrease in the concentration of a few phosphorylated species, including the 110 kDa protein in whole nuclei, and their disappearance from the nuclear matrix or residual ribonucleoprotein structures after 1-3 h. The changes were reversible, complete recovery being observed after 5 h in the case of alpha-amanitin. No similar results were obtained with nuclei from rats treated with the translation inhibitor cycloheximide. The data are discussed in view of a possible effect of certain high molecular mass phosphoproteins on reactions of the heterogeneous nuclear RNA/mRNA pathway in the cell.

Acquired drug resistance is accompanied by modification in the karyotype and nuclear matrix of a rat carcinoma cell line

A Walker 256 breast carcinoma cell line (WR) exhibiting a greater than 20-fold resistance to alkylating agents has been selected from a parent cell line (WS). Karyotypic heterogeneity was apparent, with a number of differences evident between WR and WS cells. The modal chromosome number for WS is 62; for WR, 54; double minutes were found only in WR, whereas spontaneous chromosomal aberrations were present in approx. 40% of the WS cells. No similar aberrations were observed in WR. Using SDS-gel electrophoresis and subsequent silver staining, differences in the profile of nuclear matrix proteins in WR and WS were observed. A diffuse band at approx. 70 kD in the WS was absent in WR cells. This protein was phosphorylated, together with a number of the other major matrix polypeptides. Levels of phosphorylated matrix proteins were approximately equivalent in both WR and WS cell lines, but matrix protein phosphorylation levels were approx. 2-fold higher than corresponding values for bulk nuclear proteins. Selective pressure of drug exposure has resulted in enhanced genetic stability in WR cells and observed karyotype differences are accompanied by modifications in the structural proteins of the nuclear matrix. Whether the observed differences are the cause or result of drug resistance remains to be established.

High molecular mass phosphoproteins in the rat liver nuclear matrix identification of a prominent 110,000 Dalton species

Purified rat liver nuclei were labelled in vitro in the presence of (32P) ATP and submitted to sequential extraction with DNAse, 0.4 or 2.0 M NaCl and Triton X-100. The residual or matrix structures contained 8-10 phosphoproteins between 76 and 260 kd including a triplet of major bands with 110, 117 and 128 kd. The 110 kd species was purified by chromatography on oligo(dT)-cellulose. It was shown to be identical with the 110 kd phosphoprotein of rat liver or Morris hepatoma free polyribosomes using the technique of limited digestion with S. aureus protease V 8.

94,000- and 100,000-molecular-weight simian virus 40 T-antigens are associated with the nuclear matrix in transformed and revertant mouse cells

A small fraction of the 94,000-molecular-weight multifunctional large T-antigen of simian virus 40 was associated with the nuclear protein matrix derived from simian virus 40-transformed mouse cells. The interaction between this fraction of T-antigen and the matrix was largely or entirely independent of nuclear DNA. Similar amounts of T-antigen were retained by the nuclei of transformed and revertant cell lines. A 100,000-molecular-weight variant of T-antigen, which has been found to correlate specifically with anchorage-independent growth, was present in the nuclear protein matrix of a transformed cell line. A T-antigen-containing revertant selected for the reacquisition of a high serum requirement and an anchorage requirement for growth retained T-antigen in association with its matrix.

Association of polyoma T antigen and DNA with the nuclear matrix from lytically infected 3T6 cells

Nuclear matrix prepared from mouse 3T6 cells lytically infected with polyoma virus retained significant amounts of the 100K T antigen and intact viral genomes. Bound T antigen was resistant to the extraction by high salt (2 M NaCl), detergent (1% Triton X-100) and exhaustive DNAase treatment. Only conditions sufficient to disrupt the integrity of the matrix itself solubilized the matrix T antigen. During the time period of 16-30 hr after infection, both the accumulation (in microgram) and the incorporation of 35S-methionine into T antigen increased steadily in cell extracts to a peak at 26 hr and then declined. In contrast, the amount of labeled T antigen retained by the matrix was relatively constant over the same time period. Matrix-bound T antigen was more highly phosphorylated and newly synthesized compared with the extractable T antigen. Viral DNA steadily accumulates in nuclei and on the matrix from 18 to 30 hr after infection. The fraction of viral DNA retained by the matrix was greatest early in infection (25% at 16 hr), declining to less than 10% by 24 hr. These data are consistent with the existence of a fixed (and limited) number of sites for T antigen (more highly phosphorylated) on the matrix and implicate the nuclear matrix as a site of viral DNA replication and possibly encapsidation.

In vitro ribosomal ribonucleoprotein transport upon nuclear expansion

The interdependence of nuclear rRNA release and nuclear size is investigated in macronuclei isolated from Tetrahymena. Nuclei are induced to contract and to expand, without any structural disintegration of the nuclear envelope, by final Ca2+/Mg2+ (3:2) concentrations of 5 and 1.5 mM, respectively. Upon expansion, the average volume of nuclei increases from 600 +/- 42 to 811 +/- 76 micron3. Concomitantly, nuclei begin to release RNA following saturation kinetics. This RNA release stops immediately upon nuclear contraction. Similar to the in vivo situation, only advanced rRNA processing products are released in the form of ribosomal precursor particles, as identified in detail by polyacrylamide gel electrophoresis and rate zonal and isopycnic density gradient centrifugation. Three particle ty9es are released having average buoyant densities of 1.495, 1.470, and 1.532 g/cm3, exhibiting average sedimentation coefficients of 62, 62, and 35 S, and containing the immediate precursor to the 25S rRNA, 26S rRNA, and 17S rRNA, respectively. Tje rRNP release if ATP independent and noncoincident with the release of endogenous nuclear Pi, though it is Be2+ sensitive. Our data are compatible with the views that nuclear expansion is the prerequisite rather than the cause for the rRNP release and that nuclear pore complex associated ATPases play only, if at all, a minor role in nucleocytoplasmic exchange of rRNP.

Fractionation of the nuclear matrix. I. Partial separation into matrix protein fibrils and a residual ribonucleoprotein fraction

Isolated rat liver nuclear matrices have been partially separated by means of mild sonication into a matrix protein (matricin) fraction and a residual ribonucleoprotein (RNP) fraction. The initial matricin fraction is composed largely of protein (91.1%) but also contains significant amounts of DNA (8.4%). Reconstruction experiments indicate that this DNA is not the result of the artifactual binding of DNA to the matrix during the extraction procedures. Subsequent treatment with DNase I results in purified matricin composed of greater than 99.5% protein. SDS acrylamide gel electrophoresis of the matrix protein fibrils reveals only three bands: the primary matrix polypeptides of 62,000, 66,000, and 70,000 daltons. Electron microscopy demonstrates a diffuse reticulum with fibrils as thin as 30--50 A and the presence of 80--100-A globular structures. The residual RNP fraction is composed largely of protein (80.1%) and RNA (19.5%), with only traces of DNA (1.1%). Over 98% of the total matrix-associated RNA is recovered in this fraction. SDS acrylamide gel electrophoresis indicates an enrichment in both low and high molecular weight secondary matrix polypeptides, although the 60,000--70,000-dalton polypeptides are present in significant amounts as well. Ultrastructural analysis of the residual RNP fraction reveals distinct electron-dense-staining matrix particles (150--350 A) attached to a fibrous matricin network.

Labelling of histones and nonhistones in lung nuclear matrix and chromatin fractions

Rat lung tissue is labelled in vitro with [3H]leucine and nuclei are prepared. They are digested with deoxyribonuclease II and four subfractions are isolated after differential centrifugation: MgCl2-soluble (active) and MgCl2-insoluble (inactive) chromatin, nuclear matrix sediment and matrix extract using 2M NaCl. The matrix extract fraction is found to be enriched in radioactive DNA after a short pulse of [3H]thymidine. The labelling kinetics of histones are similar in each subfraction, suggesting that histones are not preferentially incorporated onto nascent DNA. Nonhistones isolated from the subfractions, except for the matrix sediment fraction, also follow closely similar incorporation kinetics with [3H]-leucine. The matrix sedimnent fraction is three times more actively labelled than nonhistones of the other fractions and displaying a unique protein composition, suggesting distinct functional properties.