Chromosomal loop anchorage of the kappa immunoglobulin gene occurs next to the enhancer in a region containing topoisomerase II sites

A portable signal causing faithful DNA methylation de novo in Neurospora crassa

Methylation of cytosine residues in eukaryotic DNA is common, but poorly understood. Typically several percent of the cytosines are methylated; however, it is unclear what governs which sequences eventually become modified. Neurospora crassa DNA containing the "zeta-eta" (zeta-eta) region, which is a region of unusually heavy methylation, was tested for its ability to direct DNA methylation de novo. DNA stripped of its methylation by propagation in Escherichia coli was reintroduced into Neurospora crassa by transformation. The zeta-eta region reproducibly became "properly" methylated whether inserted at its native chromosomal position or at ectopic sites. Adjacent Neurospora and bacterial sequences in the transforming DNA rarely became methylated. A model is presented that accounts for position-independent faithful methylation as observed in the zeta-eta region, as well as position-dependent methylation, as occasionally observed, especially with sequences not native to Neurospora.

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.

Negative regulation contributes to tissue specificity of the immunoglobulin heavy-chain enhancer

We have identified in and around the immunoglobulin heavy-chain enhancer two apparently distinct negative regulatory elements which repress immunoglobulin H enhancer, simian virus 40 enhancer, and heterologous promoter activity in fibroblasts but not in myeloma cells. We propose that in nonlymphoid cells, negative regulatory elements prevent activation of the immunoglobulin H enhancer by ubiquitous stimulatory trans-acting factors.

Regulation and function of the Drosophila segmentation gene fushi tarazu

The Drosophila segmentation gene fushi tarazu (ftz) is expressed in a pattern of seven stripes at the blastoderm stage. Two cis-acting control elements are required for this expression: the zebra element, which confers the striped pattern by mediating the effects of a subset of segmentation genes; and the upstream element, an enhancer element requiring ftz+ activity for its action. Fusion of the upstream element to a basal promoter results in activation of the heterologous promoter in a ftz-dependent striped pattern, supporting the idea that ftz regulates itself by acting through its enhancer. The upstream element can also confer expression patterns similar to that of the homeotic gene Antennapedia, suggesting that a similar element may play a role in the activation of Antennapedia.

Protein-DNA cross-linking reveals dramatic variation in RNA polymerase II density on different histone repeats of Drosophila melanogaster

In Drosophila melanogaster the five histone genes are within a 5-kilobase region which is repeated 100 times at a single chromosomal site. These 5-kilobase repeats are of two distinct classes, short and long, that differ by approximately 200 base pairs of DNA in the spacer region between the H1 and H3 genes. Since the mRNA-homologous regions of the repeats are highly conserved, one cannot examine differential expression of the repeats by classical hybridization methods. In this study, we assessed their transcriptional activity by measuring in vivo the relative amounts of RNA polymerase II that were cross-linked by UV irradiation to the two different histone repeats. The RNA polymerase II density on the long repeat in Schneider line 2 cells was strikingly lower (10-fold) than the density on the short repeat. The magnitude of this difference cannot be accounted for by reduced transcription of only one or two genes of the repeat. The density of topoisomerase I, an indicator of transcriptional activity, was also much higher on the short repeat than on the long repeat of line 2 cells. In contrast, the RNA polymerase II density was slightly higher on the long repeat than on the short repeat in a second cell line, KcH. The major difference between active (KcH) and inactive (S2) long repeats resides in the H1-H3 nontranscribed spacer. This portion of the spacer may contain a component necessary for expression that can act over a moderate distance and affect multiple genes of the repeat.

Transcriptional enhancers in the HLA-DQ subregion

Using transient expression assays, the HLA-DQ alpha and HLA-DQ beta genes of the human major histocompatibility complex were screened for cis-acting regulatory elements. Two regions in the HLA-DQ alpha gene and one in the HLA-DQ beta gene were identified which fulfilled the criteria for transcriptional enhancers.

Ultrastructural and biochemical comparisons of nuclear matrices prepared by high salt or LIS extraction

We have directly compared two independently published methods for isolating operationally defined nuclear matrices by studying EM ultrastructure, protein composition and distribution of replicating DNA. Nuclear matrices prepared by extraction with 2 M NaCl consisted of fibrous pore complex lamina, residual fibrillar and granular components of nucleoli and interchromatin granules, and an extensive anastomosing internal fibrous network. These matrices were enriched in high molecular weight nonhistone proteins but were virtually devoid of histones. Consistent with previously published data, newly-replicated DNA was resistant to this high salt extraction. Nuclear matrices prepared by extraction of nuclei with 25 mM lithium 3,5-diiodosalicylate, LIS, also contained fibrous pore complex lamina, but lacked morphologically distinct residual nucleoli and were markedly depleted in internal structure. The reduced amounts and complexity of proteins associated with the LIS matrix were consistent with the ultrastructural data. Moreover, much less newly-replicated DNA was recovered in LIS matrices. The data show that LIS dissociates nuclear ultrastructure and extracts both protein and DNA in proportion to the concentration used, regardless of whether nuclei or high salt nuclear matrices are used as starting material. While the data suggest that LIS may not necessarily be an optimal reagent for preparing nuclear matrices containing internal structural elements from all tissue sources, it may be useful for selectively solubilizing and analyzing components of the nuclear matrix.

Sub-set characteristics of DNA sequences involved in tight DNA/polypeptide complexes and their homology to nuclear matrix DNA

Polypeptides co-isolating with DNA induce the binding of a fraction of native DNA fragments to nitrocellulose filters. Southern analysis reveals a high intensity of self-hybridization of the DNA sequences retained on nitrocellulose filters. Consistently, the DNA fraction passing the filters shows only weak hybridization when probed with DNA retained on filters. This indicates that the DNA/polypeptide complexes reside on a non-random sub-set of DNA sequences. Moreover, a high degree of homology was found between residual nuclear matrix DNA sequences and the DNA sequences retained on nitrocellulose filters. This indicates that the DNA sequences associated with tightly bound polypeptides originate from sites where the genome is salt-stably anchored in the nuclear matrix.

Chromatin structure of the HLA-DR alpha gene in different functional states of major histocompatibility complex class II gene expression

We utilized DNase I hypersensitivity mapping to study chromatin structure within the HLA-DR alpha gene. We found a single DNase I-hypersensitive site coinciding with the HLA-DR alpha gene promoter in all cells studied. Moreover, in cells that constitutively express HLA-DR, two additional DNase I-hypersensitive sites were observed. These lie within the first intron of the HLA-DR alpha gene and encompass DNA sequences that share homologies with regulatory loci of the immunoglobulin and immune response genes, as well as with core enhancer consensus sequences.

DNA replication-blocking properties of adducts formed by aflatoxin B1-2,3-dichloride and aflatoxin B1-2,3-oxide

The carcinogen aflatoxin B1 (AFB1), upon activation to a hypothesized AFB1-2,3-oxide (AFB1-oxide), reacts with DNA guanines. Aflatoxin B1-2,3-dichloride (AFB1-Cl2) was originally synthesized as an electronic analog for the putative AFB1-oxide, which has never been isolated due to presumed reactivity. We have previously shown that AFB1-oxide reacts with base-paired DNA guanines in a sequence-specific manner, as revealed by an alkali-degradation analysis. On the basis of a replication-block analysis, we have shown that AFB1-Cl2 reacts with single-stranded DNA preferentially at inverted repeat sequences, which were suggested to be capable of forming intrastrand base-paired structures. Here, we present data to show the following. Both AFB1-oxide and AFB1-Cl2 react with guanines in double-stranded DNA to induce similar sequence-specific, alkali-labile sites. Reactivity with partial DNA duplexes as well as the use of single-strand specific chemical probes directly demonstrates that AFB1-Cl2, like AFB1-oxide, prefers base-paired guanines over non-base-paired guanines. DNA replication block patterns induced by AFB1-oxide are essentially similar to those induced by AFB1-Cl2. Unexpectedly, and unlike other tested DNA lesions, Mn2+ does not appear to affect the template blocking properties of the adduct formed by AFB1-Cl2 or AFB1-oxide. The sites for replication stoppage as well as the lack of a Mn2+ effect on adducted templates have implications for the mechanisms of mutagenesis by activated AFB1.

Negative regulation contributes to tissue specificity of the immunoglobulin heavy-chain enhancer

We have identified in and around the immunoglobulin heavy-chain enhancer two apparently distinct negative regulatory elements which repress immunoglobulin H enhancer, simian virus 40 enhancer, and heterologous promoter activity in fibroblasts but not in myeloma cells. We propose that in nonlymphoid cells, negative regulatory elements prevent activation of the immunoglobulin H enhancer by ubiquitous stimulatory trans-acting factors.

Protein disulfide crosslinking stabilizes a polyoma large T antigen-host protein complex on the nuclear matrix

We have investigated the effects of intermolecular disulfide crosslinking and temperature-dependent insolubilization of nuclear proteins in vitro on the association of the polyoma large T antigen with the nuclear matrix in polyomavirus-infected mouse 3T6 cells. Nuclear matrices, prepared from polyomavirus-infected 3T6 cells by sequential extraction of isolated nuclei with 1% Triton X-100 (Triton wash), DNase I, and 2 M NaCl (high salt extract) at 4 degrees C, represented 18% of total nuclear protein. Incubation of nuclei with 1 mM sodium tetrathionate (NaTT) to induce disulfide crosslinks or at 37 degrees C to induce temperature-dependent insolubilization prior to extraction, transferred an additional 9-18% of the nuclear protein from the high salt extract to the nuclear matrix. This additional protein represented primarily an increased recovery of the same nuclear protein subset present in nuclear matrices prepared from untreated nuclei. Major constituents of chromatin including histones, hnRNP core proteins, and 98% of nuclear DNA were removed in the high salt extract following either incubation. Polyoma large T antigen was quantified in subcellular fractions by immunoblotting with rat anti-T ascites. Approximately 60-70% of the T antigen was retained in nuclei isolated in isotonic sucrose buffer at pH 7.2. Most (greater than 95%) of the T antigen retained in untreated nuclei was extracted by DNase-high salt treatment. Incubation at 37 degrees C or with NaTT transferred most (greater than 95%) of the T antigen to the nuclear matrix. T antigen solubilized from NaTT-treated matrices with 1% SDS sedimented on sucrose gradients as a large (50-S) complex. These complexes, isolated by immunoprecipitation with anti-T sera, were dissociated by reduction with 2-mercaptoethanol, and SDS-PAGE analysis revealed that T antigen was crosslinked in stoichiometric amounts to several host proteins: 150, 129, 72, and 70 kDa. These host proteins were not present in anti-T immunoprecipitates of solubilized nuclear matrices prepared from iodoacetamide-treated cells. Our results suggest that the majority of polyomavirus large T antigen in infected cells is localized to a specific subnuclear domain which is distinct from the bulk chromatin and is closely associated with the nuclear matrix.

Supercoiling-dependent sequence specificity of mammalian DNA methyltransferase

Negative supercoiling of substrate DNA dramatically alters the in vitro sequence specificity of mammalian DNA methyltransferase (DNA MeTase). This result suggests that in vivo site selection by DNA MeTase could be regulated by conformational information in the form of alternative secondary structures induced in DNA by local supercoiling or by the binding of specific nuclear proteins. DNA in the left-handed Z-form is shown not to be a substrate for mammalian DNA MeTase. The sensitivity of DNA MeTase to DNA structure may also make it useful as a probe for sequences which undergo supercoiling-dependent structural transitions in vitro.

Recombination at the human alpha-globin gene cluster: sequence features and topological constraints

We have characterized 170 kb of DNA around the human alpha-globin gene cluster to enable a systematic analysis of 12 naturally occurring deletions from this region. In 8 deletions, the 3' breakpoints lie within a 6-8 kb segment of DNA, identifying a breakpoint cluster region. Members of the Alu family of repetitive sequences are frequently found at the breakpoints and we describe a novel deletion due to homologous recombination between such repeats. In another deletion the breakpoints are separated by 131 bp of DNA, which we have shown to be transposed from a region 36 kb upstream from the 5' breakpoint where it is present in the inverse orientation. The sizes of these deletions, the nonrandom distribution of their breakpoints, and the nature of the inversion-duplication transposition event suggest that these rearrangements are constrained by the higher-order structure of the alpha-globin cluster.

Chromatin structure of the HLA-DR alpha gene in different functional states of major histocompatibility complex class II gene expression

We utilized DNase I hypersensitivity mapping to study chromatin structure within the HLA-DR alpha gene. We found a single DNase I-hypersensitive site coinciding with the HLA-DR alpha gene promoter in all cells studied. Moreover, in cells that constitutively express HLA-DR, two additional DNase I-hypersensitive sites were observed. These lie within the first intron of the HLA-DR alpha gene and encompass DNA sequences that share homologies with regulatory loci of the immunoglobulin and immune response genes, as well as with core enhancer consensus sequences.

Sequence dependence of Drosophila topoisomerase II in plasmid relaxation and DNA binding

The sequence dependence of Drosophila topoisomerase II supercoil relaxation and binding activities has been examined. The DNA substrates used in binding experiments were two fragments from Drosophila heat shock locus 87A7. One of these DNA fragments includes the coding region for the heat shock protein hsp70, and the other includes the intergenic non-coding region that separates two divergently transcribed copies of the hsp70 gene at the locus. The intergenic region was previously shown to have a much higher density of topoisomerase cleavage sites than the hsp70 coding region. Competition nitrocellulose filter binding assays demonstrate a preferential binding of the intergene fragment, and that binding specificity increases with increasing ionic strength. Dissociation kinetics indicate a greater kinetic stability of topoisomerase II complexes with the intergene DNA fragment. To study topoisomerase II relaxation activity, we used supercoiled plasmids that contained the same fragments from locus 87A7 cloned as inserts. The relative relaxation rates of the two plasmids were determined under several conditions of ionic strength, and when the plasmid substrates were included in separate reactions or when they were mixed in a single reaction. The relaxation properties of these two plasmids can be explained by a coincidence of high-affinity binding sites, strong cleavage sites, and sites used during the catalysis of strand passage events by topoisomerase II. Sequence dependence of topoisomerase II catalytic activity may therefore parallel the sequence dependence of DNA cleavage by this enzyme.

Simian virus 40 associates with nuclear superstructures at early times of infection

The association of infecting simian virus 40 with insoluble nuclear structures was assayed by disrupting infected nuclei and assaying insoluble fractions for virus. Three methods were used which lyse nuclei but maintain the insolubility of residual nuclear structures: sonication, high-salt-Triton-EDTA extraction, and low-salt-lithium diiodosalicylate extraction. After each type of nuclear extraction, infecting simian virus 40 remained associated with the residual nuclear structures. This association depended strictly on natural viral infections and on the use of buffers containing moderate amounts of salt and Mg2+ for the isolation of infected nuclei. These viral interactions exhibited behavior similar to host cell DNA interactions studied by analogous assays. Both viral DNA and coat proteins were found associated with the host cell nuclear superstructure. We concluding that at early times after infection the viral templates mimic the state of the host cell chromatin by attaching to the cellular nuclear matrix.

Intranuclear localization of UV-induced DNA repair in human VA13 cells

We have investigated the intranuclear localization of DNA-repair synthesis in G1-phase VA13 human cells. Ultraviolet-irradiated cells were permitted to perform unscheduled DNA synthesis in 3H-thymidine (3H-TdR) and then extracted with nonionic detergent and 2 M NaCl to produce nucleoids in which residual nuclear matrix was surrounded by an extended halo of DNA loops. Autoradiographic analysis of these structures permitted discrimination of DNA repair between the matrix and halo regions. Repair label in nucleoids prepared from cells after exposure to fluences of 2.5-30 J/m2 exhibited a dose-dependent association with the nuclear matrix, which ranged from 80% after 2.5 J/m2 to 50% after 30 J/m2. These results support the view that DNA repair is a nuclear matrix-associated process. This conclusion is in agreement with our preliminary study (Harless et al., 1983) and the results of McCready and Cook (1984) but contrasts with that of Mullenders et al. (1983). Questions concerning the differing experimental designs and their potential effects on the localization of DNA repair are discussed. The implications of these results to previous attempts to isolate chromatin factors associated with DNA repair are also considered.

Specific A . T DNA sequence binding of RP-HPLC purified HMG-I

HMG-I (alpha-protein) is a high mobility group protein which recognizes and binds specifically to A . T rich double stranded DNA. We have investigated, by electrophoretic shift assays and DNase I footprinting, the ability of reverse-phase high performance liquid chromatography purified HMG-I to bind to specific A . T rich duplex DNA sequences. We show here that when HMG-I is isolated and purified under denaturing conditions it retains its specific A . T DNA binding activity. These results suggest that reverse-phase high performance liquid chromatography to be the method of choice for the preparation of HMG-I.

Nuclear reconstitution in vitro: stages of assembly around protein-free DNA

We have developed a cell-free system derived from Xenopus eggs that reconstitutes nuclear structure around an added protein-free substrate (bacteriophage lambda DNA). Assembled nuclei are morphologically indistinguishable from normal eukaryotic nuclei: they are surrounded by a double membrane containing nuclear pores and are lined with a peripheral nuclear lamina. Nuclear assembly involves discrete intermediate steps, including nucleosome assembly, scaffold assembly, and nuclear membrane and lamina assembly, indicating that during reconstitution nuclear organization is assembled one level at a time. Topoisomerase II inhibitors block nuclear assembly. Lamin proteins and membrane vesicles bind to chromatin late in assembly, suggesting that these components do not interact with chromatin that is formed early in assembly. Reconstituted nuclei replicate their DNA; replication begins only after envelope formation has initiated, indicating that envelope attachment may be important for regulating replication.

The role of the kappa enhancer and its binding factor NF-kappa B in the developmental regulation of kappa gene transcription

We report here on a comparison of plasmacytoma cell lines that differ markedly in their ability to express kappa immunoglobulin genes introduced by transfection, but nevertheless express their endogenous kappa genes at comparable levels. The cell line that fails to express exogenous kappa genes is nonpermissive for kappa enhancer function, apparently because it lacks a specific kappa enhancer-binding nuclear factor (NF-kappa B). We show that this same nuclear factor is also lacking in pre-B cells and that treatment of these cells with bacterial lipopolysaccharide induces the appearance of NF-kappa B in nuclear extracts and concomitantly activates the kappa enhancer. These findings indicate that factor NF-kappa B controls kappa enhancer activity, and that this activity is only transiently required during B cell maturation.

Progesterone-modulation of estrogen action: rapid down regulation of nuclear acceptor sites for the estrogen receptor

Our previous studies demonstrated that progesterone down regulates the occupied form of nuclear estrogen receptor (Re). Using the density shift method, we discovered that progestins stimulate the turnover of nuclear Re within 3 h of treatment, and Re synthesis is suppressed subsequently. Thus, the primary site of progestin action in down-regulating Re is the stimulation of nuclear Re turnover followed by the inhibition of Re replenishment. A major breakthrough in our understanding of how progestin controls Re turnover was made by studying nuclear acceptor sites for Re that were found to decrease markedly within 2 h of progestin treatment. These and other results indicate that progestin induces a factor called the Re regulatory factor (ReRF) which acts to block nuclear Re acceptor sites, and this in turn decreases nuclear Re retention on chromatin acceptor sites, leading to an enhanced turnover (or processing) of nuclear Re.

Topoisomerase II: A specific marker for cell proliferation

We have used an antibody probe to measure the levels of topoisomerase II in several transformed and developmentally regulated normal cell types. Transformed cells contain roughly 1 X 10(6) copies of the enzyme. During erythropoiesis in chicken embryos the enzyme level drops from 7.8 X 10(4) copies per erythroblast to less than 300 copies per erythrocyte concomitant with the cessation of mitosis in the blood. Cultured myoblasts also lose topoisomerase II upon fusion into nonproliferating myotubes. When peripheral blood lymphocytes (which lack detectable topoisomerase II) commence proliferation, they express topoisomerase II de novo. Appearance of the enzyme exactly parallels the onset of DNA replication. These results suggest that topoisomerase II is not required for transcription in higher eukaryotes, but that it may function during DNA replication. Furthermore, topoisomerase II is a sensitive and specific marker for proliferating cells.

Polite DNA: functional density and functional compatibility in genomes

Certain as yet poorly defined functions of DNA appear to involve collectively domain-sized sequences. It is proposed that most sequence segments within a domain may be either functionally superfluous or instrumental, depending on how many related sequences are present in the domain. When redundant and functionally dispensable, such DNA segments presumably still have to conform to compositional or sequence-motif patterns that characterize the domain. In its relations with neighboring sequences, such DNA is required to be "polite." Polite DNA is DNA that, without being crucially involved in function, is subject to constraints of conformity and, through its base composition, respects a function for which it is not required. This concept is developed by contrasting the distribution of specific and general functions over DNA with this distribution as found in proteins and by distinguishing functional compatibility from pivotal functionality. The sequence constraints to which heterochromatin as well as, apparently, long interspersed repetitive sequences are known to be subject seem to imply that DNA, even when it does not carry out a pivotal function, is indeed, at the very least, required to be polite.

Detection, sequence patterns and function of unusual DNA structures

Unusual DNA structures were detected by an electrophoretic procedure in which DNA fragments were separated according to size on agarose gels and then by shape on polyacrylamide gels. Fragments from yeast centromeres migrated faster in polyacrylamide than predicted from their base composition and size and this property was attributed to a nonrandom distribution of oligomeric A tracts that exhibited minima at 10-11 base intervals. Fragments from seven loci in 107 kb of DNA migrated anomalously slow and these fragments contained blocks of A2-6 in a 10-11 base periodicity which is indicative of bent DNA. The most pronounced bent sequences were found within yeast ARS1 and centered at 245 and 240 bp from the left and right ends of the adenovirus genome. Each sequence is approximately 150 bp away from a replication origin and the adenovirus sequences are within 50 bp of enhancers. Nuclear matrix attachment sites, which are also adjacent to enhancers, contain sequences characteristic of bent DNA. These results suggest that bent structures reside at the base of DNA loops in chromosomes.

ATP-independent type II topoisomerase from trypanosomes

We have characterized in Trypanosoma cruzi a DNA topoisomerase capable of decatenating complex trypanosomal kinetoplast DNA networks in the absence of ATP. The enzymatic activity requires Mg2+ and K+. Using a defined DNA topoisomer we showed that the linking number changes by steps of 2, which characterizes the enzyme as a type II topoisomerase. The enzyme can catenate supercoiled DNA molecules, unknot DNA, and cleave double-stranded DNA. The enzyme has no ATPase activity. The native enzyme has an Mr of about 200,000. Crude extracts and partially purified fractions contain an aggregating factor that can substitute spermidine in catenating reactions. Because of the presence of this factor, the kinetoplast DNA can only be decatenated by purified fractions. The enzyme is inhibited by certain drugs and provides a potential target for chemotherapy. Such an enzyme was also characterized in Trypanosoma equiperdum.

Chicken histone genes retain nuclear matrix association throughout the cell cycle

The association between histone genes and the nuclear matrix (NM) during periods of high (S-phase) and low (non-S-phase) transcriptional activity has been investigated with synchronized cells from a chicken erythroid cell line (abbreviated ts34). By DNase I and restriction enzyme analysis, these studies reveal that both core and linker histone genes (represented by H2A and H1 genes respectively) are attached to the NM independent of their transcriptional activity during the cell-cycle. The tissue-specific histone gene H5, expressed constitutively, is nuclear matrix (NM)-associated in ts34 cells but is found in the supernatant (S/N) fractions of a non-erythroid T-cell line. Furthermore, we show that DNA sequences necessary for NM-attachment of the H5 gene lie within a 780 base pair region spanning part of the coding and 5' non-translated region. Of the three non-histone genes investigated, beta-actin sequences are expressed and are NM-attached, feather keratin genes are not expressed and predominate in the S/N, and beta-globin genes although not expressed in the ts34 cell line used were found in the NM fraction. In this case the association may be fortuitous or may reflect an early event prior to transcription of globin genes in differentiating erythroid cells. These results generally support the notion that actively transcribed genes are NM-attached, but that attachment per se is not synonymous with transcription.

Cohabitation of scaffold binding regions with upstream/enhancer elements of three developmentally regulated genes of D. melanogaster

We find DNA fragments attached to the nuclear scaffold (SARs) both 5' and 3' of three Drosophila genes, defining looped domains ranging from 4.5 to 13 kb. For the two-promoter-containing gene Adh (alcohol dehydrogenase), we find two upstream and two downstream SARs. For Sgs-4, the 5' SAR covers 866 bp immediately upstream of the transcript, and in the case of fushi tarazu, the 5' SAR is found on a small fragment 4.8 kb upstream of the start of transcription. These four upstream scaffold-attached fragments comap with enhancer-like regulatory sequences. Sequence analysis of five upstream SARs reveals clusters of sequences closely related to the cleavage consensus of topoisomerase II, several copies of a specific 10 bp A-rich sequence (AATAAATCAAA), and another 10 bp T-rich stretch.

Chromosomal loop anchorage sites appear to be evolutionarily conserved

We have previously identified a class of DNA sequence elements, termed matrix association regions (MARs), which specifically bind to nuclear matrices in vitro and are believed to be at the bases of chromosomal loops in vivo. Here we demonstrate that nuclear matrices prepared from the yeast Saccharomyces cerevisiae will specifically bind an MAR sequence derived from the mouse kappa light chain immunoglobulin gene. This suggests that both MAR sequences and their binding sites have been strongly evolutionarily conserved.

The DNase I sensitive domain of the chicken lysozyme gene spans 24 kb

We have determined the DNase I sensitive chromatin domain of the lysozyme gene in the hen oviduct. When nuclei were digested with DNase I, about 14 kb of upstream and 6 kb of downstream sequences in addition to the 4 kb long transcribed region were preferentially degraded. The transcription start site is located near the center of the approximately 24 kb long sensitive domain. At the 3' boundary there is a rather abrupt transition from the DNase I sensitive to the resistant chromatin configuration whereas at the 5' border this transition occurs in a gradual fashion over 6-7 kb of DNA. No obvious correlation between the boundaries of the domain and repetitive sequences could be established. DNase I-hypersensitive sites are clustered within the boundaries of the sensitive domain which seems to represent a functional unit of the gene.

Nuclear factors bind to regulatory regions of the mouse kappa immunoglobulin gene

At least two regions of the mouse kappa immunoglobulin gene are necessary for appropriate transcription. One is located within the J-C intron; another is located 5' of the transcription start site in all variable region gene segments and contains a highly conserved octanucleotide sequence, ATTTGCAT. Trans-acting nuclear factors have been thought to interact with these regions on the basis of studies with transient transfection of modified immunoglobulin genes into lymphoid and fibroblast cell lines. Using a sensitive gel electrophoresis DNA binding assay, we have found nuclear factors that bind to these two regulatory regions of the kappa gene. Two patterns of specific binding of nuclear factors to DNA sequences containing the J-C intron enhancer were observed. One pattern was seen in cell lines which do not express immunoglobulin, while a different pattern was observed in cell lines which actively transcribe light chain genes. We also find factors which bind to the octanucleotide containing 5' sequence which are distinct from those which bind the J-C enhancer region.

The active immunoglobulin kappa chain gene is packaged by non-ubiquitin-conjugated nucleosomes

To elucidate the molecular features of active chromatin, we have mapped, by two-dimensional electrophoresis, the protein composition of nucleosomes that package the immunoglobulin kappa chain gene of mouse plasmacytoma cells. Nucleoprotein particles that possess the active kappa chain gene comigrate with bulk mononucleosomes that contain high mobility group proteins HMG-14 or -17 but lack histone H1. High electrophoretic resolution of the underlying core particles, after removal of ubiquitin by isopeptidase treatment, reveals that these nucleosomes are nonubiquitinated, even though they coincidently migrate with bulk ubiquitinated particles. This distinctive electrophoretic behavior may be correlated with the presence of histone H2A.X. Nucleosomes exhibiting these unusual properties appear to span at least 10 kilobases, in both transcribed and nontranscribed regions, suggesting that mechanisms independent of transcription exist to initiate, maintain, and propagate a common chromatin phenotype over long distances along the kappa chain locus.