In situ nucleoprotein structure at the SV40 major late promoter: melted and wrapped DNA flank the start site

In Cellulo DNA Analysis: LMPCR Footprinting

The in cellulo analysis of protein-DNA interactions and chromatin structure is very important to better understand the mechanisms involved in the regulation of gene expression. The nuclease-hypersensitive sites and sequences bound by transcription factors often correspond to genetic regulatory elements. Using the ligation-mediated polymerase chain reaction (LMPCR) technology, it is possible to precisely analyze these DNA sequences to demonstrate the existence of DNA-protein interactions or unusual DNA structures directly in living cells. Indeed, the ideal chromatin substrate is, of course, found inside intact cells. LMPCR, a genomic sequencing technique that map DNA single-strand breaks at the sequence level of resolution, is the method of choice for in cellulo footprinting and DNA structure studies because it can be used to investigate complex animal genomes, including human. The detailed conventional and automated LMPCR protocols are presented in this chapter.

RNA polymerase II pausing can be retained or acquired during activation of genes involved in the epithelial to mesenchymal transition

Promoter-proximal RNA polymerase II (Pol II) pausing is implicated in the regulation of gene transcription. However, the mechanisms of pausing including its dynamics during transcriptional responses remain to be fully understood. We performed global analysis of short capped RNAs and Pol II Chromatin Immunoprecipitation sequencing in MCF-7 breast cancer cells to map Pol II pausing across the genome, and used permanganate footprinting to specifically follow pausing during transcriptional activation of several genes involved in the epithelial to mesenchymal transition (EMT). We find that the gene for EMT master regulator Snail (SNAI1), but not Slug (SNAI2), shows evidence of Pol II pausing before activation. Transcriptional activation of the paused SNAI1 gene is accompanied by a further increase in Pol II pausing signal, whereas activation of non-paused SNAI2 gene results in the acquisition of a typical pausing signature. The increase in pausing signal reflects increased transcription initiation without changes in Pol II pausing. Activation of the heat shock HSP70 gene involves pausing release that speeds up Pol II turnover, but does not change pausing location. We suggest that Pol II pausing is retained during transcriptional activation and can further undergo regulated release in a signal-specific manner.

In cellulo DNA analysis (LMPCR footprinting)

The in cellulo analysis of DNA protein interactions and chromatin structure is very important to better understand the mechanisms involved in the regulation of gene expression. The nuclease-hypersensitive sites and sequences bound by transcription factors often correspond to genetic regulatory elements. Using the Ligation-mediated polymerase chain reaction (LMPCR) technology, it is possible to precisely analyze these DNA sequences to demonstrate the existence of DNA-protein interactions or unusual DNA structures directly in living cells. Indeed, the ideal chromatin substrate is, of course, found inside intact cells. LMPCR, a genomic-sequencing, technique that map DNA single-strand breaks at the sequence level of resolution, is the method of choice for in cellulo footprinting and DNA structure studies because it can be used to investigate any complex genomes, including human. The detailed conventional and automated LMPCR protocols are presented in this chapter.

Potassium permanganate as a probe to map DNA-protein interactions in vivo

Potassium permanganate (KMnO4) has widely been used in genomic footprinting assays to map unusual gene structures, including the melting DNA block in transcriptional elongation that results from promoter-proximal pausing of RNA polymerase (Pol) II complexes. Although it has been assumed that DNA-bound proteins do not protect underlying nucleic acids from KMnO4 modifications, we provide evidence herein that this chemical can readily be used to detect nuclear factor loading at a promoter when using optimized conditions. Moreover, by comparing parallel KMnO4 and dimethylsulfate (DMS) in vivo footprintings, we show that the utilization of KMnO4 in combination with another chemical probe maximizes the detection of factor occupancy at a DNA regulatory region, thus providing a better opportunity to define the actual profiles of DNA-protein contacts at given genomic sites in living cells.

Chromatin structure of the simian virus 40 late promoter: a deletional analysis

The goal of this study was to determine the minimal sequence within the simian virus 40 (SV40) late promoter region, nucleotides (nt) 255 to 424, capable of phasing nucleosomes as measured by its ability to confer the greatest endonuclease sensitivity on adjacent DNA sequences. To identify the minimal sequence, a deletional analysis of the late region was performed by utilizing a SV40 recombinant reporter system. The reporter system consisted of a series of unique restriction sites introduced into SV40 at nt 2666. The unique restriction sites allowed the insertion of test sequences as well as measurement of conferred endonuclease sensitivity. The results of the deletional analysis demonstrated that constructs capable of conferring the greatest nuclease sensitivities consistently included nt 255 to 280. The activator protein 4 (AP-4) and GTIIC transcription factor binding sequences lie within this region and were analyzed individually. Their abilities to confer nuclease sensitivity upon the reporter nearly matched that of the entire late domain. These results suggest that transcription factors AP-4 and transcription-enhancing factor which binds the GTIIC sequence are able to confer significant levels of nuclease sensitivity and are likely involved in the formation of the SV40 nucleosome-free region.

A promoter recruitment mechanism for tumor necrosis factor-alpha-induced interleukin-8 transcription in type II pulmonary epithelial cells. Dependence on nuclear abundance of Rel A, NF-kappaB1, and c-Rel transcription factors

The alveolar macrophage-derived peptide tumor necrosis factor-alpha (TNFalpha) initiates pulmonary inflammation through its ability to stimulate interleukin-8 (IL-8) synthesis in alveolar epithelial cells through an incompletely described transcriptional mechanism. In this study, we use the technique of ligation-mediated polymerase chain reaction (LMPCR) to record changes in transcription factor occupancy of the IL-8 promoter after TNFalpha stimulation of A549 human alveolar cells. Using dimethylsulfate/LMPCR, no detectable proteins bind the TATA box in unstimulated cells. By contrast, TNFalpha rapidly induces protection of G residues at -79 and -80 coincident with endogenous IL-8 gene transcription. Using DNase I/LMPCR, we observe inducible protection of nucleotides -60 to -99 (the TNF response element) and nucleotides -3 to -32 (containing the TATA box). Surprisingly, extensive TATA box protection is only seen after TNFalpha stimulation. Using a two-step microaffinity isolation/Western immunoblot DNA binding assay, we observe that the NF-kappaB subunits Rel A, NF-kappaB1, and c-Rel inducibly bind the TNF response element; these proteins undergo rapid TNFalpha-inducible increases in nuclear abundance as a consequence of IkappaBalpha proteolysis. Furthermore, the peptide aldehyde N-acetyl-Leu-Leu-norleucinal, an agent that blocks both IkappaBalpha proteolysis and NF-kappaB subunit translocation, abrogates recombinant human TNFalpha-inducible IL-8 gene transcription. These studies demonstrate that IL-8 is activated by a promoter recruitment mechanism in alveolar epithelial cells, where NF-kappaB subunit translocation is required for (and coincident with) binding of the constitutively active TATA box-binding proteins.

Characterization of the TATA-less core promoter of the cell cycle-regulated cdc25C gene

The TATA- and Inr-less promoter of the human cdc25C gene is regulated during the cell cycle through binding of a repressor to two contiguous promoter-proximal elements, the CDE and CHR. In this study we have characterized in detail the region of the cdc25C promoter immediately downstream of these elements. Several lines of evidence suggest that this region of approximately 60 bp acts as the core promoter. This sequence: (i) harbors most of the transcription initiation sites; (ii) possesses basal promoter activity in vivo ; (iii) shows no stable protein binding in vivo as indicated by genomic dimethyl sulfate and phenanthroline copper footprinting; (iv) contains single-stranded regions in vivo as shown by potassium permanganate footprinting; (v) is hypersensitive to DNase I cleavage in permeabilized cells. Mutational analysis of the core promoter revealed the presence of three sites which play a role in transcription. Two of these sites were found to represent low affinity binding sites for transcription factors of the Sp1 family. Mutation of these sites led to decreased levels of transcription, while their alteration to canonical Sp1 sites impaired cell cycle regulation. Thus the transient interaction of Sp1 with the core promoter appears to be necessary for maximal transcription without perturbing cell cycle regulation.

Nucleosome positioning and transcription-associated chromatin alterations on the human estrogen-responsive pS2 promoter

The positioning of nucleosomes on a promoter is a significant determinant in its responsiveness to inducing signals. We have mapped the chromatin structure of the human, estrogen-responsive pS2 promoter at nucleotide level resolution within the context of its normal genomic location in human mammary epithelial cells. In vivo digestion by nucleases followed by ligation-mediated polymerase chain reaction analysis revealed two rotationally phased and translationally positioned nucleosomes within the promoter between nucleotide positions -450 and +7. The estrogen response elements at -400 and TATAA box at -35 are each located at the edge of a nucleosome. The two precisely positioned nucleosomes exist in both transformed and nontransformed human mammary epithelial cells, regardless of estrogen receptor status or transcriptional activity of the gene. However, two structural alterations correlate with the transcriptional potential of the promoter. In MCF-7 cells, in which the pS2 promoter is inducible, the chromatin exhibits an increased sensitivity to DNase I in a region of DNA adjacent to the TATAA box and an additional micrococcal nuclease-hypersensitive site in the linker DNA between the two positioned nucleosomes. We were also able to demonstrate that nucleotides -1100 to +10 of the pS2 promoter are sufficient to determine the positioning of these two nucleosomes. Our results establish the structural features of the chromatin covering the pS2 promoter as well as transcriptionally associated alterations, suggesting how the nucleosomal template influences transcriptional regulation by estrogen receptor.

Alterations in the chromatin structure of the distal promoter region of the bovine oxytocin gene correlate with ovarian expression

The mechanisms regulating the expression of the neuropeptide hormone gene oxytocin have not yet been elucidated in detail. The binding of the orphan receptor Ad4BP, the bovine homolog of steroidogenic factor-1 (SF-1), which is correlated with in vivo oxytocin transcription in the luteinizing granulosa cells of the bovine corpus luteum, is not sufficient to explain the transcriptional up-regulation in these cells. Therefore, we started experiments to identify other regions of the oxytocin locus that are involved in gene activation. The study presented here is the very first investigation of DNA methylation and chromatin structure in the distal promoter region of the bovine oxytocin gene. We show that this region is tissue-specifically hypomethylated in bovine granulosa cells. Upon stimulation of the cells with the adenylate cyclase-activator forskolin, a DNase I-hypersensitive site is induced in the distal promoter region. Additionally, we find binding of a monomeric nuclear orphan receptor directly within the region of inducible DNase I sensitivity; this factor is not identical to Ad4BP/SF-1. This study identifies a region in the bovine oxytocin distal promoter where tissue-specific changes in DNA methylation and chromatin structure correlate with high induction of oxytocin gene transcription, and suggests that the binding of transcription factors to this region may be important for the up-regulation of oxytocin gene expression.

Aberrant silencing of the CpG island-containing human O6-methylguanine DNA methyltransferase gene is associated with the loss of nucleosome-like positioning

Tumor-associated aberrant silencing of CpG island-containing genes has been correlated with increased cytosine methylation, a "closed" chromatin structure, and exclusion of transcription factor binding in the CpG island/promoter regions of affected genes. Given the lack of understanding of what constitutes a closed chromatin structure in CpG islands, however, it has been difficult to assess the relationship among cytosine methylation, chromatin structure, and inappropriate gene silencing. In this study, nuclease accessibility analysis was used to more clearly define the chromatin structure in the CpG island of the human O6-methylguanine DNA methyltransferase (MGMT) gene. Chromatin structure was then related to in vivo DNA-protein interactions and cytosine methylation status of the MGMT CpG island in human glioma cells varying in MGMT expression. The results of these studies indicated that the "open" chromatin structure associated with the MGMT CpG island in MGMT+ cells consisted of an approximately 250-bp transcription factor-binding, nuclease-accessible, nucleosome-free region of DNA, whose formation was associated with at least four flanking, precisely positioned nucleosome-like structures. In MGMT- cells, this precise nucleosomal array was lost and was replaced by randomly positioned nucleosomes (i.e., the closed chromatin structure), regardless of whether methylation of the CpG island was spread over the entire island or limited to regions outside the transcription factor binding region. These results suggest that CpG islands facilitate the expression of housekeeping genes by facilitating nucleosomal positioning and that the conditions that alter the formation of this array (such as perhaps methylation) may indirectly affect CpG island-containing gene expression.

Analysis of chromatin structure in vivo

A number of important nuclear processes including replication, recombination, repair, and transcription involve the interaction of soluble nuclear proteins with DNA assembled as chromatin. Recent progress in a number of experimental systems has focused attention on the influence chromatin structure may exert on gene regulation in eukaryotes. With the advent of new technologies for the analysis of chromatin structure in vivo, studies evaluating the influence of chromatin structure on gene transcription have become feasible for a number of systems. This article serves as an introduction to the use of restriction endonucleases to define nucleosomal organization and characterize changes in this organization that accompany transcriptional activation in vivo. The procedure includes the isolation of intact transcriptionally competent nuclei, limited digestion with specific restriction endonucleases, and purification of the DNA. This DNA serves as the substrate for a linear amplification using single primers that generate enzyme-specific DNA fragments, which are then resolved by electrophoresis. Specific examples related to our studies of the influence of chromatin structure on steroid hormone regulation of transcription from the mouse mammary tumor virus promoter are provided to illustrate this technique and several novel variations. Alternative methods for analysis of chromatin architecture using DNase I, micrococcal nuclease, permanganate, and methidiumpropyl-EDTA-iron(II) are also described. Through the use of these methodologies one is able to determine both the translational and the rotational positions for a given nucleosome as well as quantify changes at a specific nucleosome in response to regulatory and developmental signals.

Cruciform structures and functions

In this paper, a structure-function analysis of B-DNA self-fitting is reviewed in the light of recent oligonucleotide crystal structures. Their crystal packings provided a high-resolution view of B-DNA helices closely and specifically fitted by groove-backbone interaction, a natural and biologically relevant manner to assemble B-DNA helices. In revealing that new properties of the DNA molecule emerge during condensation, these crystallographic studies have pointed to the biological importance of DNA—DNA interactions.

Chromatin structure and factor site occupancies in an in vivo-assembled transcription elongation complex

The chromatin structure specific to the SV40 late transcription elongation complex as well as the occupancy of several sites that bind transcription factors have been examined. These features have been determined by assessing blockage to restriction enzyme digestion. Cleavage specific to the elongation complex has been quantified using ternary complex analysis. This method involves radioactively labeling the complex by in vitro transcription followed by determining the extent of linearization by electrophoresis in an agarose gel. It was found that not only is the origin region devoid of nucleosomes, but there is also no stable factor occupancy at the BglI, SphI, KpnI and MspI restriction enzyme sites within this region. Thus these sites were cleaved to a high degree, meaning that the binding sites for a number of transcription factors, including OBP/TEF-1, TBP, DAP, as well as a proposed positioned nucleosome, are unoccupied in the native viral transcription elongation complex. The absence of these trans-acting factors from their respective binding sites in the elongation complex indicates that they bind only transiently, possibly cycling on and off during the transcription cycle. This finding implies that various forms of transcription complex are assembled and disassembled during transcription and thus supports a 'hit-and-run' model of factor function.

Activation domain-mediated enhancement of activator binding to chromatin in mammalian cells

DNA binding by transcriptional activators is typically an obligatory step in the activation of gene expression. Activator binding and subsequent steps in transcription are repressed by genomic chromatin. Studies in vitro have suggested that overcoming this repression is an important function of some activation domains. Here we provide quantitative in vivo evidence that the activation domain of GAL4-VP16 can increase the affinity of GAL4 for its binding site on genomic DNA in mammalian cells. Moreover, the VP16 activation domain has a much greater stimulatory effect on expression from a genomic reporter gene than on a transiently transfected reporter gene, where factor binding is more permissive. We found that not all activation domains showed a greater activation potential in a genomic context, suggesting that only some activation domains can function in vivo to alleviate the repressive effects of chromatin. These data demonstrate the importance of activation domains in relieving chromatin-mediated repression in vivo and suggest that one way they function is to increase binding of the activator itself.

A developmentally modulated chromatin structure at the mouse immunoglobulin kappa 3' enhancer

Transcription of the mouse immunoglobulin kappa gene is controlled by two enhancers: the intronic enhancer (Ei) that occurs between the joining (J kappa) and constant (C kappa) exons and the 3' enhancer (E3') located 8.5 kb downstream of the gene. To understand the role of E3' in the activation of the mouse immunoglobulin kappa gene, we studied its chromatin structure in cultured B-cell lines arrested at various stages of differentiation. We found that 120 bp of the enhancer's transcriptional core becomes DNase I hypersensitive early in B-cell development. Genomic footprinting of pro-B and pre-B cells localized this chromatin alteration to B-cell-specific protections at the region including the direct repeat (DR) and the sequence downstream of the DR (DS), the PU.1-NFEM-5 site, and the core's E-box motif, identifying bound transcription factors prior to kappa gene rearrangement. Early footprints were, however, not detected at downstream sites proposed to play a negative role in transcription. The early chromatin structure persisted through the mature B-cell stage but underwent a dramatic shift in plasma cells, correlating with the loss of guanosine protection within the DR-DS junction and the appearance of novel footprints at a GC-rich motif upstream and the NF-E1 (YY1/delta)-binding site downstream. Gel shift analysis demonstrated that the DR-DS junction is bound by a factor with properties similar to those of BSAP (B-cell-specific activator protein). These results reveal developmental-stage-specific changes in the composition of nuclear factors bound to E3', clarify the role of factors that bind constitutively in vitro, and point to the differentiation of mature B cells to plasma cells as an important transitional point in the function of this enhancer. The observed changes in nuclear factor composition were accompanied by the rearrangement of positioned nucleosomes that flank the core region, suggesting a role for both nuclear factors and chromatin structure in modulating kappa E3' function during B-cell development. The functional implications of the observed chromatin alterations are discussed in the context of recent studies on kappa E3' and the factors that bind to it.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

In vivo modification of major histocompatibility complex class II DRA promoter occupancy mediated by the AIR-1 trans-activator

RJ 2.2.5 is a human B cell mutant derived from the Burkitt lymphoma Raji cell which is defective in the AIR-1 locus function. This locus encodes a transcriptional trans-activator required for the constitutive expression of major histocompatibility complex (MHC) class II genes. Here we show, by in vivo DNase I footprinting, that the AIR-1 locus defect correlates with changes in the DRA promoter occupancy. Interestingly, reexpression of human MHC class II genes in RJ 2.2.5 x mouse spleen cell hybrids is associated with partial reversion of DRA promoter occupancy to the Raji pattern. DRA promoter occupancy in other class II-negative B cell lines, derived from patients with bare lymphocyte syndrome, is drastically different from the one observed in RJ 2.2.5 and Raji cells. Moreover, the use of the DNase I as an in vivo footprinting agent reveals that the patients' cell lines do not display a completely "bare promoter" as previously reported using dimethyl sulfate as the footprinting agent. Thus, the use of DNase I allowed us, for the first time, to correlate the AIR-1 locus defect with class II promoter occupancy alterations and distinguish these alterations from the ones observed in phenotypically similar but genetically distinct MHC class II-negative cells.

The genomic instability associated with integrated simian virus 40 DNA is dependent on the origin of replication and early control region

DNA rearrangements in the form of deletions and duplications are found within and near integrated simian virus 40 (SV40) DNA in nonpermissive cell lines. We have found that rearrangements also occur frequently with integrated pSV2neo plasmid DNA. pSV2neo contains the entire SV40 control region, including the origin of replication, both promoters, and the enhancer sequences. Linearized plasmid DNA was electroporated into X1, an SV40-transformed mouse cell line that expresses SV40 large T antigen (T Ag) and shows very frequent rearrangements at the SV40 locus, and into LMtk-, a spontaneously transformed mouse cell line that contains no SV40 DNA. Stability was analyzed by subcloning G-418-resistant clones and examining specific DNA fragments for alterations in size. Five independent X1 clones containing pSV2neo DNA were unstable at both the neo locus and the T Ag locus. By contrast, four X1 clones containing mutants of pSV2neo with small deletions in the SV40 core origin and three X1 clones containing a different neo plasmid lacking SV40 sequences were stable at the neo locus, although they were still unstable at the T Ag locus. Surprisingly, five independent LMtk- clones containing pSV2neo DNA were unstable at the neo locus. LMtk- clones containing origin deletion mutants were more stable but were not as stable as the X1 clones containing the same plasmid DNA. We conclude that the SV40 origin of replication and early control region are sufficient viral components for the genomic instability at sites of SV40 integration and that SV40 T Ag is not required.

Analysis of chromatin structure by ligation-mediated PCR

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The block to transcriptional elongation within the human c-myc gene is determined in the promoter-proximal region

A conditional block to transcriptional elongation is an important mechanism for regulating c-myc gene expression. This elongation block within the first c-myc exon was defined originally in mammalian cells by nuclear run-on transcription analyses. Subsequent oocyte injection and in vitro transcription analyses suggested that sequences near the end of the first c-myc exon are sites of attenuation and/or premature termination. We report here that the mapping of single stranded DNA in vivo with potassium permanganate (KMnO4) and nuclear run-on transcription assays reveal that polymerase is paused near position +30 relative to the major c-myc transcription initiation site. Deletion of 350 bp, including the sites of 3'-end formation and intrinsic termination defined in oocyte injection and in vitro transcription assays does not affect-the pausing of polymerase in the promoter-proximal region. In addition, sequences upstream of +47 are sufficient to confer the promoter-proximal pausing of polymerases and to generate the polarity of transcription farther downstream. Thus, the promoter-proximal pausing of RNA polymerase II complexes accounts for the block to elongation within the c-myc gene in mammalian cells. We speculate that modification of polymerase complexes at the promoter-proximal pause site may determine whether polymerases can read through intrinsic sites of termination farther downstream.

In vivo stage- and tissue-specific DNA-protein interactions at the D. melanogaster alcohol dehydrogenase distal promoter and adult enhancer

We performed a high resolution analysis of the chromatin structure within the regions required for distal transcription of the Drosophila melanogaster alcohol dehydrogenase gene (Adh). Using dimethyl sulfate, DNase I, and micrococcal nuclease as structural probes, and comparing chromatin structure in tissues isolated from several developmental stages, we have identified several sites of stage- and tissue-specific DNA-protein interactions that correlate with distal transcription initiation. Most were within previously identified cis-acting elements and/or in vitro protein binding sites of the adult enhancer (AAE) and distal promoter, including the TATA box. We also detected a novel stage-specific DNA-protein interaction at the Adf-2a binding site where a non-histone protein was bound to the DNA on the surface of a positioned nucleosome previously identified between the distal promoter and adult enhancer. In addition to footprints, we have also revealed stage- and tissue-specific DNA helix deformations between many of the non-histone protein binding sites. These helix distortions suggest there are interactions among the adjacently bound proteins that result in bending or kinking of the intervening DNA. The distal promoter and AAE have an accessible chromatin conformation in fat body prior to the third larval instar and many of the regulatory proteins that bind in these regions are also available before distal transcription begins. Nevertheless, the timing of DNA-protein interactions in the distal promoter and AAE suggest these proteins do not bind individually or assemble progressively as they and their binding sites become available. Instead, there appears to be a coordinated assembly of a large cooperative complex of proteins interacting with the distal promoter, the positioned nucleosome, the enhancer of the distal promoter (the AAE), and each other.

Mapping of RNA polymerase on mammalian genes in cells and nuclei

The assembly of an RNA polymerase II initiation complex at a promoter is associated with the melting of the DNA template to allow the polymerase to read the DNA sequence and synthesize the corresponding RNA. Using the specific single-stranded modifying reagent KMnO4 and a new genomic sequencing technique, we have explored the melted regions of specific genes in genomic DNA of whole cells or of isolated nuclei. We have demonstrated for the first time in vivo the melting in the promoter proximal transcribed region that is associated with the presence of RNA polymerase II complexes. An interferon-inducible gene, ISG-54, exhibited KMnO4 sensitivity over approximately 300 nucleotides downstream of the RNA initiation site in interferon-treated cells when the gene was actively transcribed but not in untreated cells where the gene was not transcribed. The extent of KMnO4 modification was proportional to transcription levels. The KMnO4 sensitivity was retained when nuclei were isolated from induced cells but was lost if the engaged polymerases were further allowed to elongate the nascent RNA chains ("run-on"). The sensitivity to KMnO4 in isolated nuclei was retained if the run-on incubation was performed in the presence of alpha-amanitin, which blocks progress of engaged polymerases. A similar analysis identified an open sequence of only approximately 30 bases just downstream of the start site of the transthyretin (TTR) gene in nuclei isolated from mouse liver, a tissue where TTR is actively transcribed. This abrupt boundary of KMnO4 sensitivity, which was removed completely by allowing engaged polymerases to elongate RNA chains, suggests that most polymerases transcribing this gene paused at about position +20. The possibility of mapping at the nucleotide level the position of actively transcribing RNA polymerases in whole cells or isolated nuclei opens new prospects in the study of transcription initiation and elongation.

The acidic activator GAL4-AH can stimulate polymerase II transcription by promoting assembly of a closed complex requiring TFIID and TFIIA

The assembly of activated RNA polymerase II (pol II) transcription complexes has been investigated by assaying whether pre-assembly of intermediate complexes reduces the extended time required for start-site melting. The results show that a closed complex requiring factors IIA, IID, and the acidic activator GAL4-AH forms in a rate-limiting step. This directs the templates into a productive assembly pathway. Factor TFIIB is then added rapidly, affording further protection against diversion into nonproductive pathways. These events are followed by a series of rapid steps in which the remaining general factors are assembled onto the template, which is then melted using the energy of ATP hydrolysis.

Transcription factors: positive and negative regulators of cell growth and disease

Recent advances in our understanding of transcription factors that regulate RNA polymerase II transcribed genes are described. This review considers the role of alternate protein-protein interactions to yield positive or negative regulation, the consequences of deregulated factor activity on cell function and approaches to establish factor-binding specificities.

Effects of different DNA polymerases in ligation-mediated PCR: enhanced genomic sequencing and in vivo footprinting

We have developed a simplified procedure for the ligation-mediated polymerase chain reaction (LMPCR) using Thermococcus litoralis DNA polymerase (Vent DNA polymerase). We show that Vent DNA polymerase produces correct, blunt-ended primer extension products with substantially higher efficiency than Thermus aquaticus (Taq) DNA polymerase or modified T7 DNA polymerase (Sequenase). This difference leads to significantly improved genomic sequencing, methylation analysis, and in vivo footprinting with LMPCR. These improvements include representation of all bands with more uniform intensity, clear visualization of previously difficult regions of sequence, and reduction in the occurrence of spurious bands. It also simplifies the use of DNase I cut DNA for LMPCR footprinting.

Polymerase II promoter activation: closed complex formation and ATP-driven start site opening

Studies on bacterial RNA polymerases have divided the initiation pathway into three steps, namely (i) promoter binding to form the closed complex; (ii) DNA melting to form an open complex, and (iii) messenger RNA initiation. Potassium permanganate was used to detect DNA melting by mammalian RNA polymerase II in vitro. Closed complexes formed in a rate-limiting step that was stimulated by the activator GAL4-VP16. Adenosine triphosphate was then hydrolyzed to rapidly melt the DNA within the closed complex to form an open complex. Addition of nucleoside triphosphates resulted in the melted bubble moving away from the start site, completing initiation.

Potassium permanganate as an in situ probe for B-Z and Z-Z junctions

The availability of DNA structural probes that can be applied to living cells is essential for the analysis of biological functions of unusual DNA structures adopted in vivo. We have developed a chemical probe assay to detect and quantitate left-handed Z-DNA structures in recombinant plasmids in growing E. coli cells. Potassium permanganate selectively reacts with B-Z or Z-Z junction regions in supercoiled plasmids harbored in the cells. Restriction enzyme recognition sites located at these junctions are not cleaved by the corresponding endonuclease after modification with KMnO4. This inhibition of cleavage allows the determination of the relative amounts of B- and Z-forms of the cloned inserts inside the cell. We have successfully applied this method to monitor the extent of Z-DNA formation in E. coli as a function of the growth phase and mutated topoisomerase or gyrase activities. The assay can in principle be used for any unusual DNA structure that contains a restriction recognition site inside or near the structural alteration. It can be a useful tool to analyze in vivo correlations between DNA structure and gene regulatory events.

In vitro assembly of a positioned nucleosome near the hypersensitive region in simian virus 40 chromatin

Previous studies have identified a nucleosome near a potential late boundary for the nuclease-hypersensitive region in simian virus 40 chromatin. We have performed in vitro reconstitution analysis to determine whether the underlying DNA sequence encodes for the assembly of this nucleosome and applied hydroxyl radical and DNase I footprinting techniques to examine the structure of the reconstituted nucleosome. Both methods revealed the formation of a precisely positioned nucleosome in vitro, on a fragment spanning the strong in vivo nucleosome location site determined previously in the viral chromatin. The center of the positioned nucleosome maps between nucleotide 384 and 387 on simian virus 40 DNA. The corresponding nucleosome core includes the major-late transcription site (12 base-pairs within the core), the MspI site, and a segment shown previously to adopt a bent structure in the absence of proteins. The hydroxyl radical produces a strikingly well-defined cleavage pattern over the bent DNA incorporated in nucleosomes. The dominant periodicity of DNA in this nucleosome is 10.26 base-pairs per turn. The distribution of the .OH cut sites in the positioned nucleosome provides strong support for models in which the minor grooves of the A/T-rich tracts are oriented toward the histone core while the minor grooves of the G/C-rich sequences are facing outward.

Chromatin differences between active and inactive X chromosomes revealed by genomic footprinting of permeabilized cells using DNase I and ligation-mediated PCR

Ligation-mediated polymerase chain reaction (LMPCR) provides adequate sensitivity for nucleotide-level analysis of single-copy genes. Here, we report that chromatin structure can be studied by enzyme treatment of permeabilized cells followed by LMPCR. DNase I treatment of lysolecithin-permeabilized cells was found to give very clear footprints and to show differences between active and inactive X chromosomes (Xa and Xi, respectively) at the human X-linked phosphoglycerate kinase (PGK-1) locus. Beginning 380 bp upstream and continuing 70 bp downstream of the major transcription start site of PGK-1, we analyzed both strands of this promoter and CpG island and discovered the following: (1) The transcriptionally active Xa in permeabilized cells has several upstream regions that are almost completely protected on both strands from DNase I nicking. (2) Nuclei isolated in polyamine-containing buffers lack these footprints, suggesting that data from isolated nuclei can be flawed; other buffers are less disruptive. (3) The Xa has no detectable footprints at the transcription start and HIP1 consensus sequence. (4) The heterochromatic and transcriptionally inactive Xi has no footprints but has two regions showing increased DNase I sensitivity at 10-bp intervals, suggesting that the DNA is wrapped on the surface of a particle; one nucleosome-sized particle seems to be positioned over the transcription start site and another is centered approximately 260 bp upstream. (5) Potassium permanganate and micrococcal nuclease (MNase) studies indicate no melted or otherwise unusual DNA structures in the region analyzed, and MNase, unlike restriction endonuclease MspI, does cut within the positioned particles on the Xi. Results are discussed in the context of X chromosome inactivation and the maintenance of protein and DNA methylation differences between euchromatin and facultative heterochromatin at CpG islands.

Estrogen receptor alters the topology of plasmid DNA containing estrogen responsive elements

We have recently used DNA containing estrogen responsive element (ERE) sequences for affinity purification to prepare calf uterine estrogen receptor (ER) at near homogeneity. The capacity of this purified ER to alter DNA topology upon binding was examined. Although the ER is not a topoisomerase, the presence of ER changes the distribution of topoisomers generated by incubation of plasmid DNA with excess wheat germ topoisomerase I. This effect is larger in plasmids containing a consensus ERE sequence. Two dimensional gel electrophoretic analysis suggested that interaction of ER and ERE causes negative supercoiling in regions of the plasmid accessible to topoisomerase I, resulting from overwinding of DNA contacting the ER. The extent of topological alteration was dependent on ER concentration. We suggest that the observed conformational changes in the DNA could have a role in regulation of transcription.

Transcription on nucleosomal templates by RNA polymerase II in vitro: inhibition of elongation with enhancement of sequence-specific pausing

The process by which RNA polymerase II elongates RNA chains in vivo, where the template is at least partially in a nucleosomal configuration, remains poorly understood. To approach this question we have partially purified RNA polymerase II transcription complexes paused early in elongation. These complexes were then used as substrates for chromatin reconstitution. Elongation of the nascent RNA chains on these nucleosomal templates is severely inhibited relative to elongation on naked DNA templates. Elongation on the nucleosomal templates results in a reproducible template-specific pattern of transcripts generated by RNA polymerase pausing. The RNA polymerases are not terminated because the large majority will resume elongation upon the addition of Sarkosyl or 400 mM KCl. The effectiveness of RNA polymerase II pause/termination sites is enhanced by the presence of nucleosomes. For example, a pause site similar in sequence to the c-myc gene exon 1 terminator is used four to seven times more effectively in reconstituted templates. A comparison of elongation on templates bearing phased nucleosomes and on reconstituted templates that show no predominant phasing pattern indicates that the locations of pause sites are not related to the positions of the nucleosomes. Rather, the major determinant of RNA polymerase pausing on the nucleosomal templates appears to be the underlying DNA sequence.

Rapid in vivo footprinting technique identifies proteins bound to the TTR gene in the mouse liver

In vivo examination of the occupancy of DNA elements that can regulate transcription is critical to reveal which proteins actually take part in establishing and maintaining gene expression. We describe a new genomic sequencing method involving the rapid purification of relevant DNA segments from the bulk of the genomic DNA using a biotinylated riboprobe. The purified sequences are revealed by a single primer extension using Taq DNA polymerase. We used this technique to study the promoter and the enhancer of mouse transthyretin (TTR), a gene highly expressed in the liver. Footprints showed high liver-specific occupancy of some, but not all, of the DNA sites that had been identified as important for expression by transfection studies in hepatoma cells. In addition, several previously undetected sites were observed that bound proteins specifically in liver. These results suggest that not all demonstrable binding sites are involved in ongoing transcription and that in vivo studies may reveal additional and probably more relevant sites.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Genomic footprinting of the yeast HSP82 promoter reveals marked distortion of the DNA helix and constitutive occupancy of heat shock and TATA elements

We describe here for the first time successful application of the hydroxyl radical technique for genomic footprinting. In combination with two complementary techniques, DNase I footprinting and dimethyl sulfate methylation protection, we have obtained a high-resolution map of the promoter region of the yeast HSP82 heat shock gene, which resides within a constitutive nuclease hypersensitive site. We find that irrespective of transcriptional state, basal or induced, only one of three putative heat shock elements, HSE1, and the TATA box are tightly bound by proteins, presumably heat shock factor (HSF) and TFIID, respectively. Whereas the HSE1-associated factor binds tightly within the major groove of DNA, as discerned by protection of guanine residues from methylation by dimethyl sulfate in intact cells, the TATA factor appears to bind principally to the sugar-phosphate backbone, as revealed by strong protection from hydroxyl radical cleavage in whole-cell lysates. In addition, while HSE1 is strongly footprinted by DNase I in lysates, the TATA box is only weakly footprinted. Strikingly, both elements are associated with marked distortion of the DNA double helix in chromatin. Protein binding to HSE1 appears to cause a non-B-conformation, on the basis of a local 12 base-pair periodicity of hydroxyl radical protection and the presence of multiple DNase I hyperreactive cleavages flanking HSE1, whose pattern changes following heat shock. Similarly, helix distortion is evident in the vicinity of the TATA box, since hydroxyl radical detects a lower strand-specific hypersensitive site at the dyad center of an adjacent polypurine tract. Finally, the absence of discernable modulation in the DNase I cleavage pattern argues against the presence of a specifically positioned nucleosome within the IISP82 promoter region.

PCR-aided DNaseI footprinting of single copy gene sequences in permeabilized cells

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Location of nucleosomes in simian virus 40 chromatin

Over the past decade, the results of numerous indirect mappings analyses have not clarified whether or not nucleosomes occupy preferred positions in simian virus 40 (SV40) chromatin. To address this question more directly, we followed a shotgun cloning approach and determined the nucleotide sequences of over 400 cloned nucleosomal DNA fragments obtained from digestion of SV40 chromatin with micrococcal nuclease. Our results demonstrate and establish that nucleosomes do not occupy unique positions in SV40 minichromosomes and thus indicate the existence of at least several types of chromatin molecules having different nucleosome organization patterns. We developed two types of statistical analysis in order to examine the cloning data in greater detail. One type, overlap analysis, revealed the distribution of the cloned fragments with respect to SV40 DNA. The distribution exhibits an oscillating pattern, dividing the genome into regions of weak or strong nucleosome density. The other analysis determined the distribution of the midpoints of the cloned fragments and revealed potential strong and weak nucleosome location sites, and an early versus late distinction in organization of nucleosomes in SV40 chromatin. The late region appears to contain more strong nucleosome location sites (8) than the early region (4). The strongest nucleosome abuts the late side of the nuclease-hypersensitive region and includes the major transcription initiation site of the late genes. Another strong site precedes this nucleosome and includes sequences implicated in controlling the expression of the SV40 early and late genes. A strong or weak nucleosome location site is not apparent near the early side of the nucleosome-hypersensitive region. Only weak and overlapping nucleosome location sites are found in the region where replication terminates in the SV40 minichromosomes.

In situ nucleoprotein structure involving origin-proximal SV40 DNA control elements

Nucleoprotein structures at the SV40 GC-box and adjacent AT-rich region have been probed by nucleases in permeabilized cells at nucleotide level resolution. The patterns of nuclease protection and hypersensitivity in these permeabilized cells that allow initiation of RNA and DNA synthesis are quite different from those observed in isolated nuclei that are inactive. Whereas simple DNA protection by factors is found in nuclei, the pattern in permeabilized cells includes very strong nuclease hypersensitive sites. Their arrangement suggests that the region exists as a higher order nucleoprotein complex in vivo, which is disturbed during the preparation of nuclei. The pattern is also found to be disturbed in permeabilized cells when T-antigen is inactivated by temperature-sensitive mutation. Since T-antigen origin binding sites and the GC-box region have been shown previously to interact functionally, the existence of a higher order structure involving both components provides a likely physical basis for the functional interaction of separate control elements.