Organization of chromatin in cancer cells: role of signalling pathways.

The role of mechanical and chemical signalling pathways in the organization and function of chromatin is the subject of this review. The mechanical signalling pathway consists of the tissue matrix system that links together the three-dimensional skeletal networks, the extracellular matrix, cytoskeleton, and nuclear matrix. Intermediate filament proteins are associated with nuclear DNA, suggesting that intermediate filaments may have a role in the organization of chromatin. In human hormone-dependent breast cancer cells, the interaction between cytokeratins and chromatin is regulated by estrogens. Transcription factors, histone acetyltransferases, and histone deacetylases, which are associated with the nuclear matrix, are components of the mechanical signalling pathway. Recently, we reported that nuclear matrix-bound human and chicken histone deacetylase 1 is associated with nuclear DNA in situ, suggesting that histone deacetylase has a role in the organization of nuclear DNA. Chemical signalling pathways such as the Ras/mitogen-activated protein kinase (Ras/MAPK) pathway stimulate the activity of kinases that modify transcription factors, nonhistone chromosomal proteins, and histones. The levels of phosphorylated histones are increased in mouse fibroblasts transformed with oncogenes, the products of which stimulate the Ras/MAPK pathway. Histone phosphorylation may lead to decondensation of chromatin, resulting in aberrant gene expression.

Direct visualization of the human estrogen receptor alpha reveals a role for ligand in the nuclear distribution of the receptor.

The human estrogen receptor alpha (ER alpha) has been tagged at its amino terminus with the S65T variant of the green fluorescent protein (GFP), allowing subcellular trafficking and localization to be observed in living cells by fluorescence microscopy. The tagged receptor, GFP-ER, is functional as a ligand-dependent transcription factor, responds to both agonist and antagonist ligands, and can associate with the nuclear matrix. Its cellular localization was analyzed in four human breast cancer epithelial cell lines, two ER+ (MCF7 and T47D) and two ER- (MDA-MB-231 and MDA-MB-435A), under a variety of ligand conditions. In all cell lines, GFP-ER is observed only in the nucleus in the absence of ligand. Upon the addition of agonist or antagonist ligand, a dramatic redistribution of GFP-ER from a reticular to punctate pattern occurs within the nucleus. In addition, the full antagonist ICI 182780 alters the nucleocytoplasmic compartmentalization of the receptor and causes partial accumulation in the cytoplasm in a process requiring continued protein synthesis. GFP-ER localization varies between cells, despite being cultured and treated in a similar manner. Analysis of the nuclear fluorescence intensity for variation in its frequency distribution helped establish localization patterns characteristic of cell line and ligand. During the course of this study, localization of GFP-ER to the nucleolar region is observed for ER- but not ER+ human breast cancer epithelial cell lines. Finally, our work provides a visual description of the "unoccupied" and ligand-bound receptor and is discussed in the context of the role of ligand in modulating receptor activity.

Chromatin, nuclear matrix and the cytoskeleton: role of cell structure in neoplastic transformation (review).

Aberrant nuclear and cellular structures are hallmarks of malignant transformation. Thus it is not surprising that the three-dimensional structure of the cell both affects and is affected by changes in gene expression. Here we review the role of the cytoskeleton, nuclear matrix, and chromatin structure in the genesis of cancer. The shape of a cell is governed by a dynamic tissue matrix, which includes extracellular matrix, cytoskeleton and nuclear matrix. Mechanical and chemical signals are transmitted to the nucleus, resulting in alterations in the three-dimensional chromatin organization of genes. The signal transduction pathways affect histone modifications, such as acetylation and phosphorylation, resulting in a relaxed chromatin structure observed in oncogene-transformed cells.

In situ cross-linking by cisplatin of nuclear matrix-bound transcription factors to nuclear DNA of human breast cancer cells.

Cisplatin is an antitumor drug that is used to treat several types of cancers. In this study, we analyzed the proteins that were cross-linked to DNA in situ in MCF-7 human breast cancer cells incubated with cisplatin. We show that cisplatin cross-links nuclear matrix proteins to DNA. In immunoblotting experiments, we found that nuclear matrix-associated transcription factors and cofactors (estrogen receptor, HET/SAF-B, hnRNP K, and histone deacetylase 1) were cross-linked to nuclear DNA. These transcription factors and cofactors have essential roles in the regulation of genes involved in the proliferation of breast cancer cells and in the organization and structure of chromatin. We applied a novel protocol to demonstrate that the nuclear matrix-bound transcription factors/cofactors were cross-linked to DNA fragments attached to the nuclear matrix. These results suggest that the cross-linking of nuclear matrix-associated transcription factors and cofactors to DNA may be one of the mechanisms by which cisplatin inhibits transcription and replication processes.

Histone acetylation is required to maintain the unfolded nucleosome structure associated with transcribing DNA.

Nucleosomes associated with transcribing chromatin of mammalian cells have an unfolded structure in which the normally buried cysteinyl-thiol group of histone H3 is exposed. In this study we analyzed transcriptionally active/competent DNA-enriched chromatin fractions from chicken mature and immature erythrocytes for the presence of thiol-reactive nucleosomes using organomercury-agarose column chromatography and hydroxylapatite dissociation chromatography of chromatin fractions labeled with [3H]iodoacetate. In mature and immature erythrocytes, the active DNA-enriched chromatin fractions are associated with histones that are rapidly highly acetylated and rapidly deacetylated. When histone deacetylation was prevented by incubating cells with histone deacetylase inhibitors, sodium butyrate or trichostatin A, thiol-reactive H3 of unfolded nucleosomes was detected in the soluble chromatin and nuclear skeleton-associated chromatin of immature, but not mature, erythrocytes. We did not find thiol-reactive nucleosomes in active DNA-enriched chromatin fractions of untreated immature erythrocytes that had low levels of highly acetylated histones H3 and H4 or in chromatin of immature cells incubated with inhibitors of transcription elongation. This study shows that transcription elongation is required to form, and histone acetylation is needed to maintain, the unfolded structure of transcribing nucleosomes.

Effects of epidermal growth factor and estrogen on the regulation of the HMG-I/Y gene in human mammary epithelial cell lines.

Members of the HMG-I/Y family of high-mobility-group chromatin proteins have been demonstrated to regulate gene expression in human cells in vivo. They are thought to function as gene regulatory molecules by acting as architectural transcription factors that modulate DNA and/or chromatin structure. Numerous studies have indicated that elevated HMG-I/Y gene expression is directly correlated with more advanced cancers and with increased metastatic potential. The inducible expression of the HMG-I/Y gene was studied in two human mammary epithelial cell lines, MCF7 and Hs578T, in the presence, or absence, of either 17 beta-estradiol or epidermal growth factor (EGF). Northern blot analysis indicated that there was no increase in HMG-I/Y mRNA in the nonmetastatic MCF7 cells when they were treated with either 17 beta-estradiol or EGF. In contrast, in the highly metastatic Hs578T cell line, there is a dramatic induction of HMG-I/Y mRNA expression of up to 23-fold when the cells are treated with EGF. mRNA primer extension analysis indicated that only two (of the possible four different) transcription initiation start sites in the HMG-I/Y gene are induced by EGF treatment of the Hs578T cells. Additional experiments demonstrated that in both epithelial cell types HMG-I/Y mRNAs are very stable (tl/2 of approximately 30 hr) and that in the Hs578T cells treated with EGF the cellular concentrations of the HMG-I/Y proteins increase concurrently with the induced mRNA levels. Given that HMG-I/Y proteins are regulators of gene activity whose elevated in vivo concentrations are known to be correlated with increased metastatic potential, these data demonstrating an EGF-induced over-expression of HMG-I/Y in the highly metastatic Hs578T, but not in the nonmetastatic MCF7cells, may have important implications concerning the cellular mechanisms involved in the progression of mammary epithelial tumors.

Estrogen receptor diminishes DNA-binding activities of chicken GATA-1 and CACCC-binding proteins.

The estrogen receptor (ER) repressed erythroid differentiation and erythroid-specific gene expression. In this study, we investigated the effect of ER alpha (referred to throughout as ER) on DNA-binding activities of transcription factors involved in regulating the expression of erythroid-specific genes, and, in particular, the histone H5 gene. Using electrophoretic mobility shift assays, we found that in the presence of rabbit reticulocyte lysate, human ER reduced the binding activities of chicken immature erythrocyte nuclear extracted proteins to GATA and CACCC sites in the H5 promoter and enhancer. In contrast, the binding activities of NF1 and Sp1 were not affected by ER. Binding of ER to an estrogen response element was enhanced by addition of rabbit reticulocyte lysate. This lysate was also necessary for ER to diminish the DNA-binding activity of GATA-1. These results suggest that additional factor(s) are necessary for full ER function. Both GATA-1 and CACCC-binding proteins are critical for the developmentally regulated expression of erythroid-specific genes. We hypothesize that interference in DNA-binding activities of GATA-1 and CACCC-binding proteins is the mechanism by which the ER inhibits regulation of these genes.

Complementary DNA cloning and kinetic characterization of a novel intracellular serine proteinase inhibitor: mechanism of action with trypsin and factor Xa as model proteinases.

The full-length cDNA encoding a novel human intracellular serine proteinase inhibitor has been sequenced and found to encode a 376 amino acid protein (M(r) approximately 42.5K) that we designate as cytoplasmic antiproteinase. Analysis of the primary structure revealed that the cytoplasmic antiproteinase has the majority of structural motifs conserved among the greater superfamily of serine proteinase inhibitors, or serpins. On the basis of several criteria such as amino acid identity and the absence of a classical N-terminal signal peptide, the cytoplasmic antiproteinase represents a new member of the intracellular serpin family. Further inspection of the cytoplasmic antiproteinase amino acid sequence identified three potential N-glycosylation sites and Arg341-Cys342 as the reactive site P1-P1' residues, respectively. We have also employed the slow binding kinetic approach to detail the mechanism of bovine trypsin and human factor Xa inhibition by the novel cytoplasmic antiproteinase. Inhibition of trypsin by the cytoplasmic antiproteinase was preceded by a two-step mechanism corresponding to the formation of an initial loose complex, followed by an isomerization step to a more stable, tight complex. The binding of the cytoplasmic antiproteinase to trypsin occurred with a second-order association rate constant of 2.8 x 10(6) M-1 s-1 and an overall equilibrium constant of 22.5 pM, demonstrating that the factor is a potent inhibitor of this proteinase. Under the appropriate conditions, the tight complex between trypsin and the cytoplasmic inhibitor was reversible, indicated by an exponential regeneration of proteinase amidolytic activity from the preformed complex. Therefore, the tight complex appears to be stabilized predominantly by reversible bonds that form between trypsin and the cytoplasmic inhibitor. In contrast to the inhibition of trypsin, the inhibition of factor Xa amidolytic activity by the cytoplasmic antiproteinase followed a single-step binding mechanism. The apparent first-order rate constant for factor Xa inhibition was found to increase as a linear function of the inhibitor concentration range studied. Formation of the inhibitory complex between factor Xa and the cytoplasmic antiproteinase occurred with a second-order association rate constant of approximately 1.3 x 10(5) M-1 s-1 and a equilibrium constant of 3.7 nM. These findings suggests that the cytoplasmic inhibitor may initially encounter significant energy barriers for proper alignment with the substrate binding cleft of factor Xa. However, once aligned, the reaction proceeds rapidly to a tight factor Xa.inhibitor complex that dissociates at a slow rate.

Organization, inducible-expression and chromosome localization of the human HMG-I(Y) nonhistone protein gene.

Members of the HMG-I(Y) family of mammalian nonhistone proteins are of importance because they have been demonstrated to bind specifically to the minor groove of A.T-rich sequences both in vitro and in vivo and to function as gene transcriptional regulatory proteins in vivo. Here we report the cloning, sequencing, characterization and chromosomal localization of the human HMG-I(Y) gene. The gene has several potential promoter/enhancer regions, a number of different transcription start sites and numerous alternatively spliced exons making it one of the most complex nonhistone chromatin protein-encoding genes so far reported. The putative promoter/enhancer regions each contain a number of conserved nucleotide sequences for potential binding of inducible regulatory transcription factors. Consistent with the presence of these conserved sequences, we found that transcription of the HMG-I(Y) gene is inducible in human lymphoid cells by factors such as phorbol esters and calcium ionophores. Detailed sequence analysis confirms our earlier suggestion that alternative splicing of precursor mRNAs gives rise to the major HMG-I and HMG-Y isoform proteins found in human cells. Furthermore, the gene's exon-intron arrangement fully accounts for all of the previously cloned human HMG-I(Y) cDNAs (1,2). Also of considerable interest is the fact that each of the three different DNA-binding domain peptides present in an individual HMG-I(Y) protein is coded for by sequences present on separate exons thus potentially allowing for exon 'shuffling' of these functional domains during evolution. And, finally, we localized the gene to the short arm of chromosome 6 (6p) in a region that is known to be involved in rearrangements, translocations and other abnormalities correlated with a number of human cancers.