Initiation of transcription on nucleosomal templates

Thrombin-mediated transcriptional regulation using DNA aptamers in DNA-based cell-free protein synthesis

Realizing the potential of cell-free systems will require development of ligand-sensitive gene promoters that control gene expression in response to a ligand of interest. Here, we describe an approach to designing ligand-sensitive transcriptional control in cell-free systems that is based on the combination of a DNA aptamer that binds thrombin and the T7 bacteriophage promoter. Placement of the aptamer near the T7 promoter, and using a primarily single-stranded template, results in up to a 6-fold change in gene expression in a ligand concentration-dependent manner. We further demonstrate that the sensitivity to thrombin concentration and the fold change in expression can be tuned by altering the position of the aptamer. The results described here pave the way for the use of DNA aptamers to achieve modular regulation of transcription in response to a wide variety of ligands in cell-free systems.

Chromatin modifications remodel cardiac gene expression

Signalling and transcriptional control involve precise programmes of gene activation and suppression necessary for cardiovascular physiology. Deep sequencing of DNA-bound transcription factors reveals a remarkable complexity of co-activators or co-repressors that serve to alter chromatin modification and regulate gene expression. The regulated complexes characterized by genome-wide mapping implicate the recruitment and exchange of proteins with specific enzymatic activities that include roles for histone acetylation and methylation in key developmental programmes of the heart. As for transcriptional changes in response to pathological stress, co-regulatory complexes are also differentially utilized to regulate genes in cardiac disease. Members of the histone deacetylase (HDAC) family catalyse the removal of acetyl groups from proteins whose pharmacological inhibition has profound effects preventing heart failure. HDACs interact with a complex co-regulatory network of transcription factors, chromatin-remodelling complexes, and specific histone modifiers to regulate gene expression in the heart. For example, the histone methyltransferase (HMT), enhancer of zeste homolog 2 (Ezh2), is regulated by HDAC inhibition and associated with pathological cardiac hypertrophy. The challenge now is to target the activity of enzymes involved in protein modification to prevent or reverse the expression of genes implicated with cardiac hypertrophy. In this review, we discuss the role of HDACs and HMTs with a focus on chromatin modification and gene function as well as the clinical treatment of heart failure.

The DNA sequence-dependence of nucleosome positioning in vivo and in vitro

The contribution of histone-DNA interactions to nucleosome positioning in vivo is currently a matter of debate. We argue here that certain nucleosome positions, often in promoter regions, in yeast may be, at least in part, specified by the DNA sequence. In contrast other positions may be poorly specified. Positioning thus has both statistical and DNA-determined components. We further argue that the relative affinity of the octamer for different DNA sequences can vary and therefore the interaction of histones with the DNA is a 'tunable' property.

The influence of DNA stiffness upon nucleosome formation

The rotational and translational positioning of nucleosomes on DNA is dependent to a significant extent on the physicochemical properties of the double helix. We have investigated the influence of the axial flexibility of the molecule on the affinity for the histone octamer by substituting selected DNA sequences with either inosine for guanosine or diaminopurine for adenine. These substitutions, respectively, remove or add a purine 2-amino group exposed in the minor groove and, respectively, decrease and increase the apparent persistence length. We observe that for all sequences tested inosine substitution, with one exception, increases the affinity for histone binding. Conversely diaminopurine substitution decreases the affinity. In the sole example where replacement of guanosine with inosine decreases the persistence length as well as the affinity for histones, the substitution concomitantly removes an intrinsic curvature of the DNA molecule. We show that, to a first approximation, the binding energy of DNA to histones at 1M NaCl is directly proportional to the persistence length. The data also indicate that a high local flexibility of DNA can favour strong rotational positioning.

Intrinsic DNA bends: an organizer of local chromatin structure for transcription

DNA with a curved trajectory of its helix axis is called bent DNA, or curved DNA. Interestingly, biologically important DNA regions often contain this structure, irrespective of the origin of DNA. In the last decade, considerable progress has been made in clarifying one role of bent DNA in prokaryotic transcription and its mechanism of action. However, the role of bent DNA in eukaryotic transcription remains unclear. Our recent study raises the possibility that bent DNA is implicated in the "functional packaging" of transcriptional regulatory regions into chromatin. In this article, I review recent progress in bent DNA research in eukaryotic transcription, and summarize the history of bent DNA research and several subjects relevant to this theme. Finally, I propose a hypothesis that bent DNA structures that mimic a negative supercoil, or have a right-handed superhelical writhe, organize local chromatin infrastructure to help the very first interaction between cis-acting DNA elements and activators that trigger transcription.

A common feature shared by bent DNA structures locating in the eukaryotic promoter region

Eukaryotic promoters often contain a bent DNA structure, suggesting that this structure plays some role in transcription. To reveal the role, we need more information on the promoters that contain or flank a bent DNA structure. In this study, we collected such promoters by the following approach: we first isolated human genomic DNA fragments that contained at least one bent DNA structure, then shotgun cloned them into a promoter trap vector, screened DNA fragments that functioned as a promoter, and finally found the promoters of interest by determining the bent DNA locus and the region expressing promoter activity. From 1,187 recombinant plasmids, we isolated 51 that showed promoter activity. Structural and functional analyses of randomly selected 10 clones with inserts of 548-913 bp demonstrated 11 sequences that could drive transcription. Unexpectedly, all of these clones met our purpose: i.e., each segment that showed a promoter activity (67-179 bp) was very close to the bent DNA structure (spanning about 150 bp in all clones), and in some cases overlapped it. More interestingly, these bent DNA structures all had a superhelical writhe. We propose a hypothesis that in the bent-DNA-containing eukaryotic promoters. bent DNA organizes local chromatin infrastructure appropriately for transcription initiation.

Chromatin and chromosomal controls in development

Chromatin and chromosomes have major regulatory roles in development. Nucleosome positioning and modification, chromatin structural transitions and domain organization all contribute to the regulation of individual genes and gene families. Chromosomal position and nuclear compartmentalization represent important contributory factors in determining cell fate. These controls may explain many interesting and unexplored features of developmental systems.

In vitro studies on the maintenance of transcription-induced stress by histones and polyamines

Several factors were evaluated to determine their role in facilitating the presence of transcription-induced stresses in a circular DNA. Transcription was done with T7 RNA polymerase in the presence of E. coli topoisomerase I and closed circular DNA. Positive stress was observed in hypotonic conditions or when one of the polyamines, spermidine or spermine, were present. Polycations such as polylysine, polyarginine, histone H1, histones H2A-H2B, and protamine were observed to induce minimal positive stress. It is known that polyamines influence DNA structure by causing both self-association and sequence-specific structural alterations (polyamine-induced localized bending). Experimental evidence indicates that the likely cause of the positive stress is the induced bending. In order to evaluate protein-mediated bending, transcription was done on nucleosomes. A minimum of three nucleosomes on a DNA of 6055 bp was sufficient to generate very high levels of positive stress. Histones H3-H4 in the absence of H2A-H2B were responsible for this effect. Since these histones by themselves are able to maintain negative coils on DNA, it is concluded that protein-mediated bending is yet another mechanism for placing rotational restriction on DNA. The bending of DNA by either polyamines or histones is an effective mechanism for promoting transcription-induced stresses at physiological ionic strength.

Ultrastructural methods for nucleic acid detection by immunocytology

In the present review are summarized recent developments in immunocytochemical detection of nucleic acids in biological materials at the ultrastructural level. Not only the approaches using antibodies to natural nucleic acids are described but also the techniques involving the use of antibodies raised against various nucleotide analogs incorporated beforehand into nucleic acids. Special emphasis is placed on each method's potential and limitations. These methods, combined or not with molecular biotechnology, are powerful tools for studying the structure and function of nucleic acids. They can be used to investigate the distribution and topological organization of DNA and RNA molecules or of specialized within these molecules in the cells.

Transcription of DNA templates associated with histone (H3 x H4)(2) tetramers

To investigate the in vitro transcription by bacteriophage T7 RNA polymerase of oligonucleosomes lacking histone H2A x H2B dimers, templates were assembled from histone (H3 x H4)(2) tetramers with and without the complementary amount of H2A x H2B dimers and two different DNA species: pGEMEX-1, devoid of nucleosome positioning sequences, and T7-207-18, which contains downstream from the promoter 18 tandem repeats of a 207-bp positioning sequence. Assembly with core histone octamers affects pGEMEX-1 transcription mainly at the initiation level, while T7-207-18 is almost exclusively inhibited at the level of elongation. With both DNA templates and under different salt conditions, RNA synthesis is much more efficient on oligonucleosomes containing only (H3 x H4)(2) tetramers than on those with whole histone octamers. Under conditions promoting a low transcription rate, it is unambiguously shown with pGEMEX-1 that the block to initiation due to the presence of core histone octamers is substantially removed when (H3 x H4)(2) is substituted for the whole octamer. With T7-207-18, under assay conditions allowing transcription of the whole coding region of the naked DNA, analysis of the transcription products indicates that RNA elongation on the template containing (H3 x H4)(2) tetramers takes place as easily as on free DNA, in contrast with the significant inhibition observed in the presence of whole histone octamers.

Trypanosoma brucei variant surface glycoprotein regulation involves coupled activation/inactivation and chromatin remodeling of expression sites

Trypanosoma brucei is an extracellular protozoan parasite that cycles between mammalian hosts and the tsetse vector. In bloodstream-form trypanosomes, only one variant surface glycoprotein gene (VSG) expression site (ES) is active at any time. Transcriptional switching between ESs results in antigenic variation. No VSG is transcribed in the insect procyclic stage. We have used bacteriophage T7 RNA polymerase (T7RNAP) to study the transcriptional accessibility of ES chromatin in vivo. We show that T7RNAP-mediated transcription from chromosomally integrated T7 promoters is repressed along the entire length of the ES in the procyclic form, but not in the bloodstream form, suggesting that the accessible chromatin of inactive bloodstream-form ESs is remodeled upon differentiation to yield a structure that is no longer permissive for T7RNAP-mediated transcription. In the bloodstream form, replacing the active ES promoter with a T7 promoter, which is incapable of sustaining high-level transcription of the entire ES, prompts an ES switch. These data suggest two distinct mechanisms for ES regulation: a chromatin-mediated developmental silencing of the ES in the procyclic form and a rapid coupled mechanism for ES activation and inactivation in the bloodstream form.

Regulated processive transcription of chromatin by T7 RNA polymerase in Trypanosoma brucei

Inability of T7 RNA polymerase to processively transcribe higher eukaryotic chromatin is interpreted as a correlate of its reported inhibition by nucleosomes on reconstituted templates in vitro . We used chromosomally integrated reporter cassettes to examine features of T7 transcription in a lower eukaryotic system. Luciferase reporters were targeted to rDNA in transgenic Trypanosoma brucei stably expressing the phage polymerase. Because trypanosome mRNAs are capped by RNA splicing in trans , T7 transcription could be gauged by luciferase activity. In contrast to findings from higher eukaryotes, T7 transcription is vigorous and processive on chromatin templates in T.brucei , surpassing levels achieved with endogenous promoters, including those recruiting RNA polymerase I. This may be a reflection of intrinsic differences in chromatin structure between differently evolved eukaryotes or of an integration site that is exceptionally permissive for T7 transcription due to a local accessible chromatin conformation. T7 transcription could be manipulated to achieve different levels of constitutive expression, through the use of promoter mutations. Moreover, T7 initiation could be regulated by the prokaryotic Tet repressor and elongation halted by T7 terminator sequences. We have exploited these features to construct a robust inducible expression system, whose utility potentially extends to other trans -splicing organisms.

Transcriptional inhibitory role of the tail domains of histone (H3 x H4)2 tetramers

Histone-DNA templates for bacteriophage T7 RNA polymerase were assembled from a plasmid containing a promoter and a terminator for this polymerase, (H3 x H4)2 tetramers deprived of their tail domains, and H2A x H2B dimers. Histone (H3 x H4)2 tetramers lacking their terminal domains were obtained from trypsin-digested nucleosomal cores. The oligonucleosomal templates containing (H3 x H4)2 tetramers lacking their tail domains, like the control templates with intact core histone octamers, protect approximately 146 base pairs of DNA against micrococcal nuclease digestion. The transcriptional inhibition caused by the association of DNA with core histone octamers is significantly reduced upon elimination of the tail domains of the (H3 x H4)2 tetramers. Apparently, the terminal domains of (H3 x H4)2 must be present to block transcription efficiently. These results show the important inhibitory role played by the tail domains of the histone (H3 x H4)2 tetramers, suggesting the involvement of these regions in transcriptional regulation.

The nucleosome: a powerful regulator of transcription

Nucleosomes provide the architectural framework for transcription. Histones, DNA elements, and transcription factors are organized into precise regulatory complexes. Positioned nucleosomes can facilitate or impede the transcription process. These structures are dynamic, reflecting the capacity of chromatin to adopt different functional states. Histones are mobile with respect to DNA sequence. Individual histone domains are targeted for posttranslational modifications. Histone acetylation promotes transcription factor access to nucleosomal DNA and relieves inhibitory effects on transcriptional initiation and elongation. The nucleosomal infrastructure emerges as powerful contributor to the regulation of gene activity.

Role of histone H1 as an architectural determinant of chromatin structure and as a specific repressor of transcription on Xenopus oocyte 5S rRNA genes

We explore the role of histone H1 as a DNA sequence-dependent architectural determinant of chromatin structure and of transcriptional activity in chromatin. The Xenopus laevis oocyte- and somatic-type 5S rRNA genes are differentially transcribed in embryonic chromosomes in vivo depending on the incorporation of somatic histone H1 into chromatin. We establish that this effect can be reconstructed at the level of a single nucleosome. H1 selectively represses oocyte-type 5S rRNA genes by directing the stable positioning of a nucleosome such that transcription factors cannot bind to the gene. This effect does not occur on the somatic-type genes. Histone H1 binds to the 5' end of the nucleosome core on the somatic 5S rRNA gene, leaving key regulatory elements in the promoter accessible, while histone H1 binds to the 3' end of the nucleosome core on the oocyte 5S rRNA genes, specifically blocking access to a key promoter element (the C box). TFIIIA can bind to the somatic 5S rRNA gene assembled into a nucleosome in the presence of H1. Because H1 binds with equivalent affinities to nucleosomes containing either gene, we establish that it is the sequence-selective assembly of a specific repressive chromatin structure on the oocyte 5S rRNA genes that accounts for differential transcriptional repression. Thus, general components of chromatin can determine the assembly of specific regulatory nucleoprotein complexes.

CTG repeats associated with human genetic disease are inherently flexible

The lengthening of tracts of CTG, CGG and GAA triplet repeats during progression of a pedigree has been associated with more than 12 human genetic diseases, including fragile X syndrome, myotonic dystrophy and Friedreich's ataxia. These repetitive sequence elements have the potential to form alternative DNA secondary structures that may contribute to their instability. The alternative DNA secondary structures may mediate errors during DNA replication, repair or recombination of the triplet repeat, leading to expansion. Here we show that DNA composed of pure CTG or CGG repeats exhibits anomalously fast mobility on polyacrylamide gels, confirming a previous observation for DNA containing CTG and CGG triplet repeats flanked by mixed sequence DNA. Moreover, we show that even short tracts of duplex CTG repeats have an unusual helix structure. CTG repeats reduce overall curvature associated with phased A-tract or GGCC curves, but alone they do not introduce curvature into DNA. The reduction in curvature of phased A-tracts by CTG repeats is similar to that afforded by an interspersed flexible region associated with a (TT).(TT) mispair. CTG-containing DNAs exhibit a rapid rate of cyclization, consistent with a flexible helix. These results suggest that tracts of (CTG).(CAG) repeats are inherently flexible. In addition, our results suggest that the unusual rapid electrophoretic mobility of CTG or CGG-containing DNA may be a consequence of an extended flexible DNA chain.

Positioning and stability of nucleosomes on MMTV 3'LTR sequences

Uniquely positioned nucleosomes were mapped in vitro on mouse mammary tumor 3' long terminal repeat (MMTV 3'LTR) DNA at base-pair resolution. Nucleosome A assembly was strongly favored over nucleosome B, and heating of each as a mononucleosome caused migration to the ends of the DNA fragment at a unique rate. Taken together with DNA sequence analysis, this suggests why MMTV 3'LTV nucleosome positions reported upstream of vector-derived sequences conflict and also how flanking genomic sequences could modulate the promoter in in vivo situations. Importantly, nucleosomes are shown to migrate for significant distances along DNA under physiologically relevant conditions, and the actual rates have been measured directly in solution. Exact positioning and shifting over greater than 60 bp has important consequences for transcription factor access to this MMTV promoter and for the role of nucleosomes in general.

Coupled-enzymatic assays for the rate and mechanism of DNA site exposure in a nucleosome

The packaging of DNA in nucleosomes presents obstacles to the action of gene regulatory proteins and polymerases on their natural chromatin substrates. We recently reported that nucleosomes exist in a conformational equilibrium, transiently exposing stretches of their DNA off the histone surface. Such "site exposure" processes potentially provide the needed access of proteins to DNA in chromatin. However, the experiments that reveal site exposure are carried out on timescales of tens of minutes to hours. The actual rates of site exposure are not known. Here we use T7 RNA polymerase and exonuclease III as probes to obtain a more relevant lower bound on the rate of nucleosomal site exposure. We find that the organization of DNA into nucleosomes detectably slows the elongation rate of the polymerase, but that full-length elongation, which requires access to all of the DNA, occurs on the seconds timescale. Independent experiments with exonuclease III, which probes the outermost DNA segments only, similarly show that site exposure in these regions occurs on a timescale of seconds or faster. We conclude that site exposure is sufficiently rapid that it may play a role in the initial binding of regulatory proteins to nucleosomal target sites. These rapid rates argue against a nucleosome sliding model for the mechanism of site exposure. Surprisingly, the measured rates may be too slow to account for the known rates of polymerase elongation in vivo. Mechanisms by which polymerase progression through nucleosomes might be catalyzed are discussed.

Structural and functional features of a specific nucleosome containing a recognition element for the thyroid hormone receptor

The Xenopus thyroid hormone receptor betaA (TRbetaA) gene contains an important thyroid hormone response element (TRE) that is assembled into a positioned nucleosome. We determine the translational position of the nucleosome containing the TRE and the rotational positioning of the double helix with respect to the histone surface. Histone H1 is incorporated into the nucleosome leading to an asymmetric protection to micrococcal nuclease cleavage of linker DNA relative to the nucleosome core. Histone H1 association is without significant consequence for the binding of the heterodimer of thyroid hormone receptor and 9-cis retinoic acid receptor (TR/RXR) to nucleosomal DNA in vitro, or for the regulation of TRbetaA gene transcription following microinjection into the oocyte nucleus. Small alterations of 3 and 6 bp in the translational positioning of the TRE in chromatin are also without effect on the transcriptional activity of the TRbetaA gene, whereas a small change in the rotational position of the TRE (3 bp) relative to the histone surface significantly reduces the binding of TR/RXR to the nucleosome and decreases transcriptional activation directed by TR/RXR. Our results indicate that the specific architecture of the nucleosome containing the TRE may have regulatory significance for expression of the TRbetaA gene.

In vitro reconstitution and analysis of mononucleosomes containing defined DNAs and proteins

Increasingly, biochemical analyses of processes that occur within eukaryotic nuclei such as transcription and replication require the construction of specific chromatin substrates. Nucleosome complexes reconstituted in vitro have been key elements in a variety of recent studies of polymerase progression and trans-acting factor binding activities. Reconstituted complexes can be easily constructed from purified components in quantities suitable for biochemical and biophysical studies. In addition, reconstituted mononucleosome complexes exhibit native biochemical and biophysical properties but necessarily contain much less heterogeneity with regard to both protein and DNA components than bulk complexes isolated from natural sources. This review details the protocols for reconstitution of model mononucleosome complexes that contain unique DNA sequences and specifically tailored core histone proteins and describes common pitfalls associated with these procedures.

T7 RNA polymerase cannot transcribe through a highly knotted DNA template

The ability of T7 RNA polymerase to transcribe a plasmid DNA in vitro in its linear, supercoiled, relaxed and knotted forms was analysed. Similar levels of transcription were found on each template with the exception of plasmids showing varying degrees of knotting (obtained using stoichiometric amounts of yeast topoisomerase II). A purified fraction of knotted DNA with a high number of nodes (crosses) was found to be refractory to transcription. The unknotting of the knotted plasmids, using catalytic amounts of topoisomerase II, restored their capacity as templates for transcription to levels similar to those obtained for the other topological forms. These results demonstrate that highly knotted DNA is the only topological form of DNA that is not a template for transcription. We suggest that the regulation of transcription, which depends on the topological state of the template, might be related to the presence of knotted DNA with different number of nodes.

An intrachromosomal repeating unit based on DNA bending

DNA bending has been observed in conjunction with transcription, replication, and recombination. Furthermore, nucleosomes in eukaryotic cells are positioned through DNA bending, suggesting an active role for DNA bending in the chromosome organization. We reported previously that DNA bend sites appear every 680 bp in the human epsilon- and beta-globin gene regions. Here we showed that these sites are present at an interval of roughly 700 bp in the G gamma-A gamma-psi beta-globin gene region and that they divide the region into units. They were conserved in the promoter regions of nearly all beta-like globin genes and between human beta- and mouse beta maj-globin genes, although the periodicity of the sites was locally disturbed at the junctions of the duplicated G gamma- and A gamma-globin genes and in their second introns. This suggested that the periodicity is ranked lower in the hierarchy of genomic DNA organization than genome rearrangement and gene expression. A close inspection of one of the sites in the A gamma-globin gene region indicated that a 20-bp sequence containing periodic short (dA)n tracts was partly responsible for the bending. This sequence was shown to phase nucleosomes in this region by preferential binding to the core histones.

Nucleosome assembly on CTG triplet repeats

Expansion of CTG repeat sequences is associated with several human genetic diseases. We have examined the consequences of CTG repeat expansion for nucleosome assembly and positioning. Short CTG repeats are found within the most favored DNA sequences yet defined for nucleosome assembly. We find that as few as six CTG repeats will facilitate nucleosome assembly to a similar extent as the 50 or more repeats found in disease genes. Thus an increase in nucleosome stability on expansion of existing triplet repeats is unlikely to explain the acquisition of the disease phenotype. However, the CTG repeat sequence is efficiently wrapped around the histone octamer, preferring to associate with histones at the nucleosomal dyad. Thus short segments CTG repeat sequence will facilitate the assembly of a stable positioned nucleosome which might contribute to the expansion phenomenon and the functional organization of chromatin.

Chromatin remodeling during Saccharomyces cerevisiae ADH2 gene activation

We have analyzed at both low and high resolution the distribution of nucleosomes over the Saccharomyces cerevisiae ADH2 promoter region in its chromosomal location, both under repressing (high-glucose) conditions and during derepression. Enzymatic treatments (micrococcal nuclease and restriction endonucleases) were used to probe the in vivo chromatin structure during ADH2 gene activation. Under glucose-repressed conditions, the ADH2 promoter was bound by a precise array of nucleosomes, the principal ones positioned at the RNA initiation sites (nucleosome +1), at the TATA box (nucleosome -1), and upstream of the ADR1-binding site (UAS1) (nucleosome -2). The UAS1 sequence and the adjacent UAS2 sequence constituted a nucleosome-free region. Nucleosomes -1 and +1 were destabilized soon after depletion of glucose and had become so before the appearance of ADH2 mRNA. When the transcription rate was high, nucleosomes -2 and +2 also underwent rearrangement. When spheroplasts were prepared from cells grown in minimal medium, detection of this chromatin remodeling required the addition of a small amount of glucose. Cells lacking the ADR1 protein did not display any of these chromatin modifications upon glucose depletion. Since the UAS1 sequence to which Adr1p binds is located immediately upstream of nucleosome -1, Adr1p is presumably required for destabilization of this nucleosome and for aiding the TATA-box accessibility to the transcription machinery.

A naturally occurring T14A11 tract blocks nucleosome formation over the human neurofibromatosis type 1 (NF1)-Alu element

The nature of chromatin organization over Alu repetitive elements is of interest with respect to the maintenance of their transcriptional silencing as well as their potential to influence local chromatin structure. We previously demonstrated that the pattern of nucleosomal organization over Alu elements in native chromatin is specific and similar to the pattern observed with an in vitro reconstituted Alu template. This pattern, distinguished by a nucleosome centered over the 5 -end of the Alu element, is associated with repression of polymerase III-dependent transcription in vitro (Englander, E. W., Wolffe, A. P., and Howard, B. H. (1993) J. Biol. Chem. 268, 19565-19573; Englander, E. W., and Howard, B. H. (1995) J. Biol. Chem. 270, 10091-10096). In the current study, additional templates representing both evolutionarily old and young Alu subfamilies were found to direct a similar pattern of nucleosome assembly, consistent with the view that nucleosome positioning in vitro is shared by a majority of Alus. We discovered however, that the specific nucleosome positioning pattern was disrupted over one member of a young Alu subfamily, which recently transposed immediately downstream to a T14A11 sequence in the neurofibromatosis type 1 locus (Wallace, M. R., Andersen, L. B., Saulino, A. M., Gregory, P. E., Glover, T. W., and Collins, F. S. (1991) Nature 353, 864-866). Upon removal of this sequence motif, the expected pattern of assembly was restored to the neurofibromatosis type 1-Alu template. This finding indicates that, at least in vitro, certain sequences can override the propensity for positioning nucleosomes that is inherent to Alu elements. The finding also raises the possibility that a similar situation may occur in vivo, with potential implications for understanding mechanisms by which certain Alu elements may evade chromatin-mediated transcriptional silencing.

Probes of chromatin accessibility in the Drosophila bithorax complex respond differently to Polycomb-mediated repression

The Polycomb group (PcG) of genes are required for maintenance of the repressed state of the homeotic genes in Drosophila. There are similarities between the PcG repression and mating-type silencing in yeast or heterochromatic position effect in Drosophila, which suggest that PcG repression may involve a highly compacted chromatin structure. To test for such a structure, heterologous DNA- binding proteins were used as probes for DNA accessibility in Drosophila embryos. Binding sites for the yeast transcriptional activator GAL4 and for bacteriophage T7 RNA polymerase were inserted into the bithorax (bx) regulatory region of the endogenous Ultrabithorax (Ubx) gene, which is regulated by the PcG. Ubiquitously expressed GAL4 protein directs transcription through its binding sites only in the posterior segments where the bx region is active. The block to GAL4 activation in the more anterior segments is dependent on Polycomb (Pc) function. In contrast, T7 RNA polymerase can transcribe from its target promoter in all segments of the embryo. Thus, Pc-mediated repression blocks activated polymerase II transcription, but does not simply exclude all proteins.

The amino-terminal tails of the core histones and the translational position of the TATA box determine TBP/TFIIA association with nucleosomal DNA

We establish that the TATA binding protein (TBP) in the presence of TFIIA recognizes the TATA box in nucleosomal DNA dependent on the dissociation of the amino-terminal tails of the core histones from the nucleosome and the position of the TATA box within the nucleosome. We examine TBP/TFIIA access to the TATA box with this sequence placed in four distinct rotational frames with reference to the histone surface and at three distinct translational positions at the edge, side and dyad axis of the nucleosome. Under our experimental conditions, we find that the preferential translational position at which TBP/TFIIA can bind the TATA box is within linker DNA at the edge of the nucleosome and that binding is facilitated if contacts made by the amino-terminal tails of the histones with nucleosomal DNA are eliminated. TBP/TFIIA binding to DNA at the edge of the nucleosome occurs with the TATA box in all four rotational positions. This is indicative of TBP/TFIIA association directing the dissociation of the TATA box from the surface of the histone octamer.

Changing nucleosome positions through modification of the DNA rotational information

The effects of the rotational information of DNA in determining the in vitro localization of nucleosomal core particles (ncps) have been studied in the Saccharomyces cerevisiae 5S rRNA repeat gene. We have altered the distribution of the phased series of flexibility signals present on this DNA by inserting a 25-bp tract, and we have analyzed the effects of this mutation on the distribution and on the frequencies of ncps, as compared with the wild type and a reference 21-bp insertion mutant. The variation of the standard free energy of nucleosome reconstitution was determined. The results show that the DNA rotational information is a major determinant of ncps positioning, define how many rotationally phased signals are required for the formation of a stable particle, and teach how to modify their distribution through the alteration of the rotational signals.

Modified curved DNA that could allow local DNA underwinding at the nucleosomal pseudodyad fails to position a nucleosome in vivo

In competitive in vitro reconstitution experiments synthetic DNA composed of tandem repeats of the repetitive sequence (A/T)3NN(G/C)3NN, specifically the 20 bp 'TG sequence' (5'-TCGGTGTTAGAGCCTGTAAC-3'), was reported to associate with the histone octamer with an affinity higher than that of nucleosomally derived DNA. However, at least two groups have independently shown that tandem repeats of the TG sequence do not accommodate a stably positioned nucleosome in vivo. It was suggested that the anisotropic flexibility of the TG sequence, governed by a 10 bp sequence periodicity, is incompatible with the required underwinding of the DNA helix at the nucleosome pseudodyad while maintaining a bending preference that can be accommodated in the remainder of the nucleosome. Here we test this hypothesis directly by studying the in vivo nucleosomal structure of modified TG sequences designed to accommodate underwinding at the pseudodyad. We show that these modifications are not sufficient to allow stable incorporation of the TG sequence repeat into a nucleosome in vivo, but do note invasion from one end of the TG heptamer of a translationally random but rotationally constrained nucleosome. We discuss possible reasons for the absence of nucleosomes from the TG sequence in vivo.

Nucleosomes reconstituted in vitro on mouse mammary tumor virus B region DNA occupy multiple translational and rotational frames

The mouse mammary tumor virus acquires a highly reproducible chromatin structure when integrated into cellular DNA. Previous studies have suggested that the LTR is arranged as a series of six phased nucleosomes, that occupy specific positions on the LTR. On the basis of nucleosome reconstitution studies using DNA from the B region of the LTR, it has been argued that this sequence directs a uniquely positioned nucleosome. Here we demonstrate in vitro that reconstituted B region nucleosomes adopt at least five distinct translational positions in two rotational frames on a 206 bp fragment of DNA. We have resolved an initial reconstitute into its component species using nondenaturing gel electrophoresis, and precisely mapped the positions of each species using a hydroxyl radical footprinting assay. To confirm the nucleosome positions determined with the hydroxyl radical assay, nucleosome boundaries were mapped using exonuclease III. Comparison of the results from the hydroxyl radical footprinting and exonuclease III assays revealed a symmetrical pattern of overdigestion by exonuclease III which made unequivocal determination of nucleosome boundaries dubious. We conclude that the general use of exonuclease III to map the positions of nucleosomes may lead to incorrect assignment of position, and that assignment of position through the determination of the nucleosome pseudo-dyad from hydroxyl radical footprinting data represents a superior method of analysis.

Robert Feulgen Prize Lecture 1995. New approaches to in situ detection of nucleic acids

The present paper reviews recent results obtained by different molecular biology-based, immunocytological approaches to the localization and identification of nucleic acids in sections of biological material. Examples of sensitive, high-resolution detection methods for RNA, DNA or specialized DNA regions are presented. Special emphasis is placed on the potential values and limitations of these new methods.

Conservation and periodicity of DNA bend sites in the human beta-globin gene locus

A total of seven DNA bend sites were mapped in the 4.4-kilobase human beta-globin gene region by the circular permutation assay. The periodicity of these sites (except one) was about every 700 (average 685.5 +/- 267.7) base pairs. All of the sites contained the sequence feature of short poly(dA) tracts, which are typical of DNA bending. The relative positions of the sites to the cap site were identical to those in the epsilon-globin gene region, suggesting that the bend sites were conserved during molecular evolution of the two globin genes. To explain this periodicity and conservation of the sites within the evolutionary unstable noncoding regions, we focused upon the appearance of a potential bend core sequence, A2N8A2N8A2 (A/A/A), and its complement, T2N8T2N8T2 (T/T/T). These sequences appeared in or very close to most of the bend sites of the globin gene regions, whereas other A+T-rich sequences or candidates for DNA bending did not. The distances between any two of the core sequences in the entire beta-globin locus showed a strong bias to a length of about 700 base pairs and its multiples, suggesting that the periodicity exists throughout the locus. The data presented here strengthen the idea of sequence-directed nucleosome phasing.

Mechanism of nucleosome dissociation produced by transcription elongation in a short chromatin template

We have used a linear DNA template (239 bp) containing a nucleosome positioning sequence (NX1) downstream of the T7 RNA polymerase promoter to study the mechanism of transcription elongation through a nucleosome. Under ionic strength approaching physiological conditions we have observed that transcription causes nucleosome dissociation and histone redistribution within the template. We have examined the role of the different elements that, in principle, could induce nucleosome dissociation during transcription. The high affinity of histones for single-stranded DNA observed in titration experiments performed using the purified (+) and (-) strands of the NX1 fragment suggests that nucleosome dissociation is not due to the formation of segments of single-stranded DNA by RNA polymerase in the elongation process. Furthermore, our results show that although RNA can interact with core histones, the synthesized RNA is not bound to the histones dissociated by transcription. Our results indicate that core histones released during transcription can be bound to naked DNA and chromatin (with or without histones H1-H5). From the dynamic properties of excess histones bound to chromatin, we suggest a nucleosome transcription mechanism in which displaced histones are transiently bound to chromatin and finally are reassembled with DNA after the passage of the polymerase.

The interaction of transcription factors with nucleosomal DNA

Nucleosome positioning is proposed to have an essential role in facilitating the regulated transcription of eukaryotic genes. Some transcription factors can bind to DNA when it is appropriately wrapped around the histone core, others cannot bind due to the severe deformation of DNA structure. The staged assembly of nucleosomes and positioning of histone-DNA contacts away from promoter elements can facilitate the access of transcription factors to DNA. Positioned nucleosomes can also facilitate transcription through providing the appropriate scaffolding to bring regulatory factors bound at dispersed sites into juxtaposition.

Deposition of histone H1 onto reconstituted nucleosome arrays inhibits both initiation and elongation of transcripts by T7 RNA polymerase

The effect of histone H1 on transcription by bacteriophage T7 RNA polymerase was examined using reconstituted chromatin templates. A 3.8 kb linear DNA template consisting of a specific transcription promoter for T7 RNA polymerase placed upstream of 18 tandem repeats of a 207 bp nucleosome positioning sequence derived from the 5S rRNA gene of Lytechinus variegatus was used as a template for chromatin reconstitution. Regularly spaced arrays of nucleosome cores were assembled onto this DNA template from donor histone octamers by salt step dialysis. Histone H1 was incorporated onto free DNA or reconstituted chromatin templates and double label transcription assays were performed. The experiments indicated that histone H1 has a strong inhibitory effect on both transcription initiation and elongation. These effects are especially pronounced on chromatin templates, where both transcription initiation and elongation are virtually halted. The inhibition of transcription elongation appears to result from a dramatic increase in premature termination of transcripts. These experiments indicate that assembly of histone H1 into chromatin can result in structures which are completely repressed with respect to transcription.

A role for RNA synthesis in homologous pairing events

The relationship between RNA synthesis and homologous pairing in vitro, catalyzed by RecA protein, was examined by using an established strand transfer assay system. When a short DNA duplex is mixed with single-stranded circles, RecA protein promotes the transfer of the minus strand of the duplex onto the complementary region of the plus-strand circle, with the displacement of the plus strand of the duplex. However, if minus-strand RNA is synthesized from the duplex pairing partner, joint molecules containing the RNA transcript, the plus strand of the DNA duplex, and the plus-strand circle are also observed to form. This reaction, which is dependent on RNA polymerase, sequence homology, and RecA protein, produces a joint molecule that can be dissolved by treatment with RNase H but not RNase A. Under these reaction conditions, product molecules form even when the length of shared homology between duplex and circle is reduced to 15 bp.

A role for RNA synthesis in homologous pairing events

The relationship between RNA synthesis and homologous pairing in vitro, catalyzed by RecA protein, was examined by using an established strand transfer assay system. When a short DNA duplex is mixed with single-stranded circles, RecA protein promotes the transfer of the minus strand of the duplex onto the complementary region of the plus-strand circle, with the displacement of the plus strand of the duplex. However, if minus-strand RNA is synthesized from the duplex pairing partner, joint molecules containing the RNA transcript, the plus strand of the DNA duplex, and the plus-strand circle are also observed to form. This reaction, which is dependent on RNA polymerase, sequence homology, and RecA protein, produces a joint molecule that can be dissolved by treatment with RNase H but not RNase A. Under these reaction conditions, product molecules form even when the length of shared homology between duplex and circle is reduced to 15 bp.

Nucleosomal location of the STE6 TATA box and Mat alpha 2p-mediated repression

It has been proposed that yeast MATa cell-specific genes are repressed in MAT alpha cells by the Mat alpha 2p repressor-directed placement of a nucleosome in a position that incorporates the TATA box of the MATa-specific gene close to the nucleosomal pseudodyad. In this study, we address this proposal directly with a series of plasmids designed to place the MATa-specific STE6 TATA box at different locations in a nucleosome and in the internucleosomal linker. These plasmids contain different lengths of synthetic random DNA between the Mat alpha 2p operator and the TATA box of the STE6 promoter, which is located upstream of a lacZ reporter gene in a multicopy plasmid. We show that in MAT alpha cells, a nucleosome is retained in an identical translational frame relative to the Mat alpha 2p operator in all the constructs investigated, irrespective of the sequence of the DNA wrapped onto the histone octamer. This result shows that the nucleosomal organization of the STE6 promoter in MAT alpha cells is not conferred by the sequence of the promoter itself. No expression of the lacZ reporter gene was detectable in MAT alpha cells in any of the constructs, even with the TATA box located in a short internucleosomal linker. These data indicate that repression of MATa-specific genes in MAT alpha cells does not require the precise translational placement of the TATA box close to the nucleosomal pseudodyad; the gene remains repressed when the TATA box is located within the investigated 250-bp region in the organized chromatin domain abutting the Mat alpha 2p operator in MAT alpha cells and may remain repressed with the TATA box located anywhere within this organized repression domain.

DNA cruciforms facilitate in vitro strand transfer on nucleosomal templates

A single, phased nucleosome assembled on a 240 bp DNA duplex molecule blocked Escherichia coli RecA protein-promoted strand transfer of the complementary strand of the duplex onto a homologous single-stranded circle. However, when a four-armed cruciform structure was coupled to either end of the duplex the barrier to strand transfer was overcome and joint molecules were efficiently formed. Micrococcal nuclease digestion indicated that the nucleosome was dissociated by the juxtaposition of the cruciform. We interpret these results to mean that cruciform structures can act over a distance to destabilize adjacent nucleosomes and suggest that, as a consequence, the chromatin structure surrounding a crossed strand recombination intermediate might be disrupted, enabling other recombination events to initiate or the process of branch migration to proceed.

Nucleosomal location of the STE6 TATA box and Mat alpha 2p-mediated repression

It has been proposed that yeast MATa cell-specific genes are repressed in MAT alpha cells by the Mat alpha 2p repressor-directed placement of a nucleosome in a position that incorporates the TATA box of the MATa-specific gene close to the nucleosomal pseudodyad. In this study, we address this proposal directly with a series of plasmids designed to place the MATa-specific STE6 TATA box at different locations in a nucleosome and in the internucleosomal linker. These plasmids contain different lengths of synthetic random DNA between the Mat alpha 2p operator and the TATA box of the STE6 promoter, which is located upstream of a lacZ reporter gene in a multicopy plasmid. We show that in MAT alpha cells, a nucleosome is retained in an identical translational frame relative to the Mat alpha 2p operator in all the constructs investigated, irrespective of the sequence of the DNA wrapped onto the histone octamer. This result shows that the nucleosomal organization of the STE6 promoter in MAT alpha cells is not conferred by the sequence of the promoter itself. No expression of the lacZ reporter gene was detectable in MAT alpha cells in any of the constructs, even with the TATA box located in a short internucleosomal linker. These data indicate that repression of MATa-specific genes in MAT alpha cells does not require the precise translational placement of the TATA box close to the nucleosomal pseudodyad; the gene remains repressed when the TATA box is located within the investigated 250-bp region in the organized chromatin domain abutting the Mat alpha 2p operator in MAT alpha cells and may remain repressed with the TATA box located anywhere within this organized repression domain.

Nucleosome positioning and gene regulation

Recent genetic and biochemical studies have revealed critical information concerning the role of nucleosomes in eukaryotic gene regulation. Nucleosomes package DNA into a dynamic chromatin structure, and by assuming defined positions in chromatin, influence gene regulation. Nucleosomes can serve as repressors, presumably by blocking access to regulatory elements; consequently, the positions of nucleosomes relative to the location of cis-acting elements are critical. Some genes have a chromatin structure that is "preset," ready for activation, while others require "remodeling" for activation. Nucleosome positioning may be determined by multiple factors, including histone-DNA interactions, boundaries defined by DNA structure or protein binding, and higher-order chromatin structure.

Octamer displacement and redistribution in transcription of single nucleosomes

Single nucleosomes were assembled on a 357bp DNA fragment containing a 5S RNA gene from sea urchin and a promoter for SP6 RNA polymerase, and were fractionated as a function of their positions by gel electrophoresis. Transcribed nucleosome positions were detected by observing band disappearance in gels, which in turn provided evidence for the displacement of the histone octamer upon transcription. Differential band disappearance showed that nucleosomes closer to the promoter were harder to transcribe, and transcription was blocked when the nucleosome proximal boundary was at the start site. Nucleosomes located at discrete positions were also eluted from the gel bands and transcribed. In this case, new bands appeared as a consequence of octamer redistribution. Such redistribution occurred over all untranscribed positions, as well as over transcribed positions close enough to the promoter. Similar conclusions were derived from another previously investigated fragment containing a Xenopus 5S RNA gene.

Transcription activates RecA-promoted homologous pairing of nucleosomal DNA

RecA protein catalyzes the homologous pairing of a single-stranded circular DNA and a linear duplex DNA molecule. When the duplex is packaged into chromatin, formation of homologously paired complexes is blocked. We have established a system for studying the RecA-promoted reaction by using a duplex fragment containing a single-phased nucleosome. Under these conditions there is no reaction leading to formation of joint molecule complexes. However, transcription on the chromatin template activates the formation of complexes. Reaction is dependent on RNA synthesis and DNA sequence homology and proceeds regardless of the direction of transcription.

Transcription activates RecA-promoted homologous pairing of nucleosomal DNA

RecA protein catalyzes the homologous pairing of a single-stranded circular DNA and a linear duplex DNA molecule. When the duplex is packaged into chromatin, formation of homologously paired complexes is blocked. We have established a system for studying the RecA-promoted reaction by using a duplex fragment containing a single-phased nucleosome. Under these conditions there is no reaction leading to formation of joint molecule complexes. However, transcription on the chromatin template activates the formation of complexes. Reaction is dependent on RNA synthesis and DNA sequence homology and proceeds regardless of the direction of transcription.

Role of the histone amino termini in facilitated binding of a transcription factor, GAL4-AH, to nucleosome cores

Facilitated, "cooperative" binding of GAL4-AH to nucleosomal DNA occurred in response to inhibition from the core histone amino termini. The binding of GAL4-AH (which contains the DNA-binding and dimerization domains of GAL4) to nucleosome cores containing multiple binding sites initiated at the end of a nucleosome core and proceeded in a cooperative manner until all sites were occupied. However, following tryptic removal of the core histone amino termini, GAL4-AH binding appeared to be noncooperative, similar to binding naked DNA. Binding of GAL4-AH to nucleosomes bearing a single GAL4 site at different positions indicated that inhibition of GAL4 binding was largely mediated by the histone amino termini and primarily occurred at sites well within the core and not near the end. When the histone amino termini were intact, binding of GAL4-AH to sites near the center of a nucleosome core was greatly enhanced by the presence of additional GAL4 dimers bound to more-accessible positions. These data illustrate that the binding of a factor to more-accessible sites, near the end of a nucleosome, allows facilitated binding of additional factors to the center of the nucleosome, thereby overcoming repression from the core histone amino termini. This mechanism may contribute to the binding of multiple factors to complex promoter and enhancer elements in cellular chromatin.