A simple procedure for parallel sequence analysis of both strands of 5'-labeled DNA

Transcriptionally competent chromatin assembled with exogenous histones in a yeast whole cell extract

We describe a cell-free chromatin assembly system derived from the yeast Saccharomyces cerevisiae, which efficiently packages DNA into minichromosomes in a reaction dependent on exogenous core histones and an ATP-regenerating system. Both supercoiled and relaxed plasmid DNA serve as templates for nucleosomal loading in a gradual process that takes at least 6 h for completion at 30 degrees C. Micrococcal nuclease digestion of the assembled minichromosomes displays an extended nucleosomal ladder with a repeat length of 165 bp. The purified minichromosomes contain the four core histones in stoichiometric proportion and exhibit phased nucleosomes over the mouse mammary tumour virus (MMTV) promoter. The progesterone receptor and NF1 synergize on these minichromosomes resulting in efficient cell-free transcription. The ease of manipulation and the potential use of yeast strains carrying mutations in the chromatin handling machinery make this system suitable for detailed mechanistic studies.

Chromatin assembly in yeast cell-free extracts

A simple method for preparing chromatin assembly extracts has not been available for budding yeast. Here I describe such a method in detail. The assembly extract, a crude 100,000g supernatant, is prepared from cells disrupted in a manual or motorized grinder while they are frozen. The core histones and all soluble protein factors required for chromatin assembly under physiological conditions are present in the extract. Assembly is sensitive to mutation of lysine residues in the amino-terminal tail of histone H4 whose acetylation is associated with nucleosome deposition in vivo. The reaction is ATP dependent, and assembly-driven DNA supercoiling occurs with the same efficiency as in extracts from mammalian somatic cells. This simple system offers a unique opportunity to analyze chromatin metabolism by a combined biochemical and genetic approach that is not feasible for any other model organism.

DNA superstructural features and nucleosomal organization of the two centromeres of Kluyveromyces lactis chromosome 1 and Saccharomyces cerevisiae chromosome 6

Superstructural features of the Kluyveromyces lactis chromosome 1 (KlCEN1) and of the Saccharomyces cerevisiae chromosome 6 (SCEN6) centromeric DNAs were evaluated using a theoretical method, developed by our group, and experimentally measured by gel electrophoretic retardation. Both methods show that, in spite of the remarkable AT richness of the two centromeric sequences, their curvature is not very high. However the peculiar sequence features of the two centromeres allow to organize highly stable nucleosomes, with a free energy about that of the nucleosome formed on the 5S RNA gene. The good agreement between experimental and theoretical evaluation of nucleosome free energies as well as of their multiple positioning shows that in centromeres both DNA curvature and flexibility are relevant in determining nucleosomal features.

Chromatin assembly in a yeast whole-cell extract

A simple in vitro system that supports chromatin assembly was developed for Saccharomyces cerevisiae. The assembly reaction is ATP-dependent, uses soluble histones and assembly factors, and generates physiologically spaced nucleosomes. We analyze the pathway of histone recruitment into nucleosomes, using this system in combination with genetic methods for the manipulation of yeast. This analysis supports the model of sequential recruitment of H3/H4 tetramers and H2A/H2B dimers into nucleosomes. Using a similar approach, we show that DNA ligase I can play an important role in template repair during assembly. These studies demonstrate the utility of this system for the combined biochemical and genetic analysis of chromatin assembly in yeast.

In vitro chromatin assembly of the HIV-1 promoter. ATP-dependent polar repositioning of nucleosomes by Sp1 and NFkappaB

Nuclease hypersensitive sites exist in vivo in the chromatin of the integrated human immunodeficiency virus (HIV)-1 proviral genome, in the 5'-long terminal repeat (LTR) within the promoter/enhancer region near Sp1 and NFkappaB binding sites. Previous studies from the Kadonaga and Jones laboratories have shown that Sp1 and NFkappaB can establish hypersensitive sites in a truncated form of this LTR when added before in vitro chromatin assembly with Drosophila extracts, thus facilitating subsequent transcriptional activation of a linked reporter gene upon the association of additional factors (Pazin, M. J., Sheridan, P. L., Cannon, K., Cao, Z., Keck, J. G., Kadanaga, J. T., and Jones, K. A. (1996) Genes & Dev. 10, 37-49). Here we assess the role of a full-length LTR and 1 kilobase pair of downstream flanking HIV sequences in chromatin remodeling when these transcription factors are added after chromatin assembly. Using Xenopus laevis oocyte extracts to assemble chromatin in vitro, we have confirmed that Sp1 and NFkappaB can indeed induce sites hypersensitive to DNase I, micrococcal nuclease, or restriction enzymes on either side of factor binding sites in chromatin but not naked DNA. We extend these earlier studies by demonstrating that the process is ATP-dependent when the factors are added after chromatin assembly and that histone H1, AP1, TBP, or Tat had no effect on hypersensitive site formation. Furthermore, we have found that nucleosomes upstream of NFkappaB sites are rotationally positioned prior to factor binding and that their translational frame is registered after binding NFkappaB. On the other hand, binding of Sp1 positions adjacent downstream nucleosome(s). We term this polar repositioning because each factor aligns nucleosomes only on one side of its binding sites. Mutational analysis and oligonucleotide competition each demonstrated that this remodeling required Sp1 and NFkappaB binding sites.

Yeast histone H3 and H4 amino termini are important for nucleosome assembly in vivo and in vitro: redundant and position-independent functions in assembly but not in gene regulation

The hydrophilic amino-terminal sequences of histones H3 and H4 extend from the highly structured nucleosome core. Here we examine the importance of the amino termini and their position in the nucleosome with regard to both nucleosome assembly and gene regulation. Despite previous conclusions based on nonphysiological nucleosome reconstitution experiments, we find that the histone amino termini are important for nucleosome assembly in vivo and in vitro. Deletion of both tails, a lethal event, alters micrococcal nuclease-generated nucleosomal ladders, plasmid superhelicity in whole cells, and nucleosome assembly in cell extracts. The H3 and H4 amino-terminal tails have redundant functions in this regard because the presence of either tail allows assembly and cellular viability. Moreover, the tails need not be attached to their native carboxy-terminal core. Their exchange re-establishes both cellular viability and nucleosome assembly. In contrast, the regulation of GAL1 and the silent mating loci by the H3 and H4 tails is highly disrupted by exchange of the histone amino termini.

Assembly of nucleosomal DNA in a cell-free extract from wild-type and top1- strains of Ustilago maydis

An in vitro nucleosome assembly system has been established from cell-free extracts of the fungus Ustilago maydis. The extract catalyzed DNA supercoiling in the absence of exogenously added co-factors such as ATP and MgCl2 and was inhibited by moderate concentrations (200 mM) of KCl or NaCl. DNA supercoiling occurs via the formation of nucleosomes. Similar extracts, displaying the same activity, were prepared from Saccharomyces cerevisiae and Candida albicans, suggesting that the extract preparation protocol may be useful for many lower eukaryotic systems. An extract prepared from a strain of U. maydis lacking topoisomerase I failed to catalyze nucleosome assembly, clearly implicating this enzyme in this process. Addition of purified topoisomerase I, and, to a lesser extent, topoisomerase II, to the top1- extract regenerated the supercoiling activity. Our results provide a method for preparing assembly extracts from organisms, that are particularly amenable to genetic manipulation.

Zinc(II) ions selectively interact with DNA sequences present at the TFIIIA binding site of the Xenopus 5S-RNA gene

It has been known for some time that zinc, as well as most transition metal ions, is capable of binding to the DNA bases. However, little is known about the presence and distribution of metal binding sites along naturally occurring genomic DNA molecules. In this paper, the interaction of zinc with the Xenopus 5S-RNA gene has been studied and several metal binding sites have been identified on the basis of the changes in chemical reactivity observed in the presence of the metal. The strongest zinc-binding sites of the Xenopus 5S-RNA gene correspond to GGG trinucleotide repeats. Some GG dinucleotides also show a significant affinity for zinc. Interestingly, the binding site for TFIIIA, a zinc-finger transcription factor, contains several sites with strong zinc affinity. In particular, a TGGGA sequence which is essential for the binding of TFIIIA shows the strongest affinity for zinc. The conformational properties of this DNA sequence, together with the high electronegative potential of GGG runs, is likely to determine its strong affinity for zinc. The possible biological relevance of these results is discussed.

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.

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.

Characterization of Ustilago maydis DNA binding protein one (UBP1)

The DNA binding properties of a protein from the lower eukaryote Ustilago maydis have been characterized. Using both filter binding and gel retention assays, we demonstrate that this protein, termed UBP1 (Ustilago binding protein one), binds preferentially to DNA molecules lacking chain interruptions. The introduction of DNA breaks by a restriction enzyme or a purified nuclease, from Ustilago maydis, causes the dissociation of protein-DNA complexes. UBP1 stimulates the relaxation of negatively supercoiled DNA, mediated by Ustilago type I topoisomerase, through a mechanism most likely involving the association of UBP1 with the DNA rather than with the topoisomerase. The prebinding of UBP1 to DNA templates, subsequently assembled into minichromosomes, results in the development of a disorganized nucleosomal array. Possible roles for UBP1 in processes that involve changes in DNA topology, such as chromatin assembly, are discussed.

The glucocorticoid receptor precludes the binding of a transcriptional repressor protein to the long terminal repeat of the mouse mammary tumor virus

The long terminal repeat (LTR) of the mouse mammary tumor virus was used as a template to examine the dual binding parameters of the glucocorticoid-receptor (GR) and a repressor protein termed Inhibitory Factor 1 (IF1). The receptor binds specifically to the glucocorticoid response element and precludes the binding of IF1 to its juxtaposed binding site within the LTR. When the two DNA targets are separated by the insertion of an additional 52 base pairs, coincident binding of both proteins is observed. Gel retention assays reveal three distinct nucleoprotein complexes. The first complex consists of the receptor and the LTR, the second is comprised of IF1 and DNA and the third is a multiprotein-DNA complex consisting of the GR, IF1 and DNA, migrating at a higher molecular weight position. The inhibition of IF1 binding by the presence of prebound GR leads to the repression of transcription of juxtaposed genes. The GR may act to block access of a sequence, used by the cell to titrate repressor proteins and facilitate the onset of gene expression.

Positive regulation of tRNA gene expression by the mouse mammary tumor virus-long terminal repeat in vitro

The mouse mammary tumor virus long terminal repeat (MMTV-LTR) participates in the control of gene expression by providing a series of important DNA binding sites at which trans-acting factors interact. Among these factors are the steroid receptor, nuclear factor I (NFI) and the TATA box factor (TFIID). The binding of these proteins facilitates the assembly of a transcriptionally competent complex, that includes RNA polymerase II, and activates the expression of juxtaposed genes in cis. A particular DNA sequence, distinct from previously identified regulatory elements, was found in the present study to activate gene expression in trans. The sequence is located between nucleotides +3 and +43 near the 3' terminus of the LTR. This sequence binds a protein that may actively repress the expression of genes that are not located immediately in cis. This protein was purified by ion exchange chromatography and has an approximate molecular weight of 31,000 daltons, as judged by SDS-PAGE. Gel retardation experiments reveal that progressively larger protein--DNA complexes are formed when the amount of this factor is increased relative to the DNA binding site. Furthermore, this protein was found to preferentially aggregate DNA molecules containing the LTR sequence between bases +3 and +43. These results reveal the existence of a unique modulatory role for the LTR in regulating gene expression in trans.

In vitro transcription of the c-myc first exon may be influenced by the extent of chromatin assembly

The first exon of the human c-myc gene can be transcribed by either RNA polymerase II or RNA polymerase III. The molecular factors contributing to polymerase selection are not yet completely defined. We have examined the role of chromatin structure in regulating transcription by RNA polymerase III. Using as competitor a pol III gene in both a cis and trans arrangement, we demonstrate that c-myc gene expression is facilitated from templates containing a minimal number of fully assembled nucleosomes. The removal of excess histones by DNA titration leads to an elevated level of c-myc expression. These results suggest that either the c-myc expression is inhibited when the template is fully packaged into chromatin or that the affinity of RNA polymerase for the regulatory elements of this exon is such that a template, devoid of histones, is required for transcriptional initiation.

An analysis of transcription factor TFIIIA-mediated DNA supercoiling

We have analyzed transcription factor-mediated DNA supercoiling catalyzed by the Xenopus oocyte extract (S-150). Under conditions that inhibit endogenous supercoiling activity (2 mM EDTA), the 5S RNA specific transcription factor, TFIIIA, promotes a negative change in DNA linking number. The SV40 binding protein, T antigen, appears not to promote DNA supercoiling under these conditions. A nucleosomal ladder can be seen after DNase I digestions only if the DNA template is pre-bound by TFIIIA prior to the addition of the S-150 extract. These studies suggest that TFIIIA may stimulate DNA supercoiling by enhancing the development of protein-DNA interactions via a mechanism that may include nucleosome assembly.

Activation domains of stably bound GAL4 derivatives alleviate repression of promoters by nucleosomes

GAL4 derivatives containing an activation domain alleviated repression of a promoter during nucleosome assembly. A GAL4 derivative lacking an activation domain stably bound the promoter during nucleosome assembly but was not sufficient to preserve promoter function. The activation domain of GAL4 derivatives was essential for preserving promoter function, and thus the transcriptional stimulatory activity attributable to these activation domains increased dramatically during nucleosome assembly. Furthermore, promoter-bound activation domains allowed the formation of preinitiation complexes after nucleosome assembly. Finally, GAL4 derivatives containing activation domains significantly stimulated transcription through bacterially produced yeast TFIID only from nucleosome-assembled templates. These data indicate that acidic activation domains stimulate transcription by enhancing the ability of basal transcription factors to compete with nucleosomes for occupancy of the promoter.

Assembly of correctly spaced chromatin in a nuclear extract from Xenopus laevis oocytes

Assembly of nucleosomes on relaxed, covalently closed DNA has been studied in a nuclear extract of Xenopus laevis oocytes. Nucleosomes containing the four histones H3, H4, H2A and H2B but lacking histone H1 are readily assembled on the DNA. The pattern of micrococcal nuclease digestion shows that the nucleosomes assembled in the absence of ATP and Mg (II) are closely packed, with a periodicity of 150 base pairs (bp). In contrast, in the presence of ATP and Mg (II) the spacing of the nucleosomes is 180 bp, similar to that observed for nucleosomes assembled on DNA microinjected into oocyte nuclei. The ATP and Mg (II) requirements for the assembly of correctly spaced nucleosomes are unrelated to the activity of the ATP and Mg (II) dependent DNA topoisomerase II in the extract; addition of specific inhibitors of eukaryotic DNA topoisomerase II has no effect on the spacing of the reconstituted nucleosomes. The ATP requirement in the assembly of correctly spaced nucleosomes can be substituted by adenosine 5'-O-3'-thiotriphosphate (gamma-S-ATP) but not by adenyl-5'-yl imidodiphosphate (AMP-P-(NH)-P).

Transcriptional potentiation of the vitellogenin B1 promoter by a combination of both nucleosome assembly and transcription factors: an in vitro dissection

The Xenopus laevis vitellogenin B1 promoter was assembled into nucleosomes in an oocyte extract. Subsequent RNA polymerase II-dependent transcription from these DNA templates fully reconstituted in chromatin in a HeLa nuclear extract was increased 50-fold compared with naked DNA. Remarkably, under specific conditions, production of a high level of transcripts occurred at very low DNA (1 ng/microliter) and HeLa nuclear protein (1.6 micrograms/microliters) concentrations. When partially reconstituted templates were used, transcription efficiency was intermediate between that of fully reconstituted and naked DNA. These results implicate chromatin in the process of the transcriptional activation observed. Depletion from the oocyte assembly extract of an NF-I-like factor which binds in the promoter region upstream of the TATA box (-114 to -101) or deletion from the promoter of the region interacting with this factor reduced the transcriptional efficiency of the assembled templates by a factor of 5, but transcription of these templates was still 10 times higher than that of naked DNA. Together, these results indicate that the NF-I-like factor participates in the very efficient transcriptional potentiation of the vitellogenin B1 promoter which occurs during nucleosome assembly.

Transcriptional potentiation of the vitellogenin B1 promoter by a combination of both nucleosome assembly and transcription factors: an in vitro dissection

The Xenopus laevis vitellogenin B1 promoter was assembled into nucleosomes in an oocyte extract. Subsequent RNA polymerase II-dependent transcription from these DNA templates fully reconstituted in chromatin in a HeLa nuclear extract was increased 50-fold compared with naked DNA. Remarkably, under specific conditions, production of a high level of transcripts occurred at very low DNA (1 ng/microliter) and HeLa nuclear protein (1.6 micrograms/microliters) concentrations. When partially reconstituted templates were used, transcription efficiency was intermediate between that of fully reconstituted and naked DNA. These results implicate chromatin in the process of the transcriptional activation observed. Depletion from the oocyte assembly extract of an NF-I-like factor which binds in the promoter region upstream of the TATA box (-114 to -101) or deletion from the promoter of the region interacting with this factor reduced the transcriptional efficiency of the assembled templates by a factor of 5, but transcription of these templates was still 10 times higher than that of naked DNA. Together, these results indicate that the NF-I-like factor participates in the very efficient transcriptional potentiation of the vitellogenin B1 promoter which occurs during nucleosome assembly.

cis-acting enhancement of RNA polymerase III gene expression in vitro

The Xenopus laevis S-150 cell-free extract catalyzes in vitro transcription of several RNA polymerase III genes. Among these are the Xenopus 5S RNA gene (somatic type) and the Xenopus methionine tRNA gene. In this report we present an analysis of the transcriptional activity of these two genes either in trans-competition experiments or when the genes are co-localized in the same circular plasmid. In the "cis" arrangement, elevated levels of 5S and tRNA gene expression are observed, which are dependent on the relative orientation of the two genes (convergent or in tandem) and the distance between them. The results of these analyses reveal important parameters affecting the expression of juxtaposed genes.

An upstream transcription factor, USF (MLTF), facilitates the formation of preinitiation complexes during in vitro chromatin assembly

During in vitro chromatin assembly the formation of transcription complexes is in direct competition with the assembly of promoter sequences into nucleosomes. Under these conditions the fold stimulation of transcription by an upstream transcription factor (USF) was greater than that observed in the absence of nucleosome assembly. Function of USF during nucleosome assembly required the simultaneous presence of the TATA box binding protein TFIID. Unlike TFIID, USF alone was unable to prevent repression of the promoter during nucleosome assembly. Furthermore, USF displayed reduced or no transcriptional stimulatory activity when added to previously assembled minichromosomes. Under conditions of nucleosome assembly, USF increased the number of assembled minichromosomes which contained stable preinitiation complexes. Subsequent to assembly, the rate at which preformed complexes initiated transcription appeared to be independent of the presence of USF. Thus USF potentiated the subsequent transcriptional activity of the promoter indirectly, apparently by increasing the rate or stability of TFIID binding. This activity resulted in the promoter becoming resistant to nucleosome mediated repression. These observations suggest that some ubiquitous upstream factors, e.g. USF, may play an important role in establishing the transcriptional potential of cellular genes during chromatin assembly.

Reaction parameters of TFIIIA-induced supercoiling catalyzed by a Xenopus laevis cell-free extract

In addition to its fundamental role of nucleating the formation of stable transcription complexes, the Xenopus laevis 5S RNA specific transcription factor, TFIIIA, promotes a variety of DNA-associated metabolic reactions. We report that TFIIIA can induce a DNA supercoiling catalyzed by the Xenopus laevis S-150 cell-free extract on plasmids containing a single copy of the Xenopus 5S RNA gene (somatic-type). Stimulated supercoiling occurs in the presence of high concentrations of ATP (4 mM) and at a factor to DNA ratio of 1 through a mechanism most likely involving type I topoisomerase. The highest level of stimulated supercoiling occurs when TFIIIA is incubated with DNA prior to the addition of the S-150 extract. Taken together, the experiments outlined in this report establish a reliable and seminal system in which TFIIIA-induced DNA supercoiling can be observed reproducibly.

Human transcription factor TFIIIC2 specifically interacts with a unique sequence in the Xenopus laevis 5S rRNA gene

Transcription factor TFIIIC2 derived from human cells is required for tRNA-type gene transcription and binds with high affinity to the essential B-box promoter element of tRNA-type genes. Although 5S rRNA genes contain no homology with the tRNA-type gene B box, we show that TFIIIC2 is also required for Xenopus laevis 5S rRNA gene transcription. TFIIIC2 protected an approximately 30-base-pair (-10 to +18) region of a Xenopus 5S rRNA gene from DNase I digestion. This region, which spanned the transcription start site, included sequences that are highly conserved among eucaryotic 5S rRNA genes and have no homology with the B-box sequence of tRNA genes. Mutation of the TFIIIC2-binding site reduced transcription of the 5S rRNA gene by a factor of 10 in HeLa cell extracts. Methylation of C residues within the TFIIIC2-binding site interfered with binding of TFIIIC2. These results suggest a role of the TFIIIC2-binding sequence in 5S rRNA gene transcription. In addition, the 5S rRNA gene binding site and the tRNA-type gene B-box sequence did not compete with each other for binding to TFIIIC2 any better than did an unrelated DNA sequence, indicating that TFIIIC2 interacts with 5S rRNA genes and tRNA-type genes through separate DNA-binding domains or polypeptides.

Histone H1 represses transcription from minichromosomes assembled in vitro

We have previously shown that transcription from a Xenopus 5S rRNA gene assembled into chromatin in vitro can be repressed in the absence of histone H1 at high nucleosome densities (one nucleosome per 160 base pairs of DNA) (A. Shimamura, D. Tremethick, and A. Worcel, Mol. Cell. Biol. 8:4257-4269, 1988). We report here that transcriptional repression may also be achieved at lower nucleosome densities (one nucleosome per 215 base pairs of DNA) when histone H1 is present. Removal of histone H1 from the minichromosomes with Biorex under conditions in which no nucleosome disruption was observed led to transcriptional activation. Transcriptional repression could be restored by adding histone H1 back to the H1-depleted minichromosomes. The levels of histone H1 that repressed the H1-depleted minichromosomes failed to repress transcription from free DNA templates present in trans. The assembly of transcription complexes onto the H1-depleted minichromosomes protected the 5S RNA gene from inactivation by histone H1.

Minichromosome assembly accompanying repair-type DNA synthesis in Xenopus oocytes

Minichromosomes were assembled by injection of circular DNA into the nucleus of Xenopus oocytes. We observed that, in the course of DNA supercoiling and chromatin assembly, a small percentage of the injected DNA molecules incorporated a radioactive precursor. This DNA synthesis was carried out by aphidicolin-sensitive DNA polymerase, and generated short repair-like patches covalently linked to the injected DNA. We found that the DNA thus repaired was rapidly supercoiled almost to completion within 15 to 30 min after injection, whereas 60 to 120 min were required to supercoil the intact, bulk DNA molecules. Such differential supercoiling kinetics was also observed when UV-damaged DNA was injected. Chromatin assembly, which was characterized by DNA fragment sizes protected from micrococcal nuclease digestion, was consistent with the rapid DNA supercoiling and proceeded more efficiently on the repaired DNA. These results indicate that there are at least two kinetically distinct ways of assembling minichromosomes in the oocyte nucleus, and that the repaired DNA molecules preferentially follow the faster pathway.

DNA superhelicity enhances the assembly of transcriptionally active chromatin in vitro

Using an in vitro chromatin assembly system, we analyzed the influence of DNA superhelicity on the development of transcriptionally active minichromosomes. Plasmid DNA molecules containing either a Xenopus borealis 5S RNA gene or an X. laevis methionine tRNA gene were utilized as templates for the assembly of chromatin. Both plasmids were processed into active minichromosomes if introduced as supercoiled molecules into the extract (S-150). The degree of superhelicity is a determining factor in the assembly of active chromatin. Molecules containing varying superhelical densities were processed into minichromosomes with different transcriptional activities. The absence of supercoils leads to the assembly of chromatin with substantially lower transcriptional activity. Assembled minichromosomes are stable enough to be isolated by sucrose gradient centrifugation while retaining their transcriptional phenotype. The formation of nucleosomes with a periodic spacing occurred with the same efficiency and to the same degree regardless of the initial DNA topology. Hence, a determining factor in the development of transcriptionally active chromatin may be the initial superhelicity of the DNA molecule to which activator (trans-acting factors) or repressor (histones) proteins bind. Once the chromatin assembly process has begun, the transcriptional activity of the resulting minichromosome may already have been determined.

Histone H1 represses transcription from minichromosomes assembled in vitro

We have previously shown that transcription from a Xenopus 5S rRNA gene assembled into chromatin in vitro can be repressed in the absence of histone H1 at high nucleosome densities (one nucleosome per 160 base pairs of DNA) (A. Shimamura, D. Tremethick, and A. Worcel, Mol. Cell. Biol. 8:4257-4269, 1988). We report here that transcriptional repression may also be achieved at lower nucleosome densities (one nucleosome per 215 base pairs of DNA) when histone H1 is present. Removal of histone H1 from the minichromosomes with Biorex under conditions in which no nucleosome disruption was observed led to transcriptional activation. Transcriptional repression could be restored by adding histone H1 back to the H1-depleted minichromosomes. The levels of histone H1 that repressed the H1-depleted minichromosomes failed to repress transcription from free DNA templates present in trans. The assembly of transcription complexes onto the H1-depleted minichromosomes protected the 5S RNA gene from inactivation by histone H1.

Human transcription factor TFIIIC2 specifically interacts with a unique sequence in the Xenopus laevis 5S rRNA gene

Transcription factor TFIIIC2 derived from human cells is required for tRNA-type gene transcription and binds with high affinity to the essential B-box promoter element of tRNA-type genes. Although 5S rRNA genes contain no homology with the tRNA-type gene B box, we show that TFIIIC2 is also required for Xenopus laevis 5S rRNA gene transcription. TFIIIC2 protected an approximately 30-base-pair (-10 to +18) region of a Xenopus 5S rRNA gene from DNase I digestion. This region, which spanned the transcription start site, included sequences that are highly conserved among eucaryotic 5S rRNA genes and have no homology with the B-box sequence of tRNA genes. Mutation of the TFIIIC2-binding site reduced transcription of the 5S rRNA gene by a factor of 10 in HeLa cell extracts. Methylation of C residues within the TFIIIC2-binding site interfered with binding of TFIIIC2. These results suggest a role of the TFIIIC2-binding sequence in 5S rRNA gene transcription. In addition, the 5S rRNA gene binding site and the tRNA-type gene B-box sequence did not compete with each other for binding to TFIIIC2 any better than did an unrelated DNA sequence, indicating that TFIIIC2 interacts with 5S rRNA genes and tRNA-type genes through separate DNA-binding domains or polypeptides.

Nuclear factors specifically bind to upstream sequences of a Xenopus laevis ribosomal protein gene promoter

The upstream region of the Xenopus laevis L14 ribosomal protein gene was deleted starting from the 5' extremity in order to define the promoter length necessary to express a linked reporter CAT gene. The functional analysis indicated that a sequence located between -63 and -49 from the capsite is important for an efficient promoter activity. Band shift and ExoIII protection assays evidenced the binding to this region of a factor, called XrpFI, present in the crude nuclear extract from X.laevis oocytes. Methylation interference analysis localized the contacts in the G residues belonging to a short box, 5' CTTCC 3', positioned between -53 and -49 from the capsite. An additional factor, XrpFII, makes contacts with the sequence 5'GCCTGTTCGCC 3' located between -27 and -17 from the capsite. The deletion mutant still containing this sequence is poorly transcribed, but resumes activity when a short fragment containing the binding site for factor XrpFI is cloned in an upstream position.

Assembly and properties of chromatin containing histone H1

The Xenopus oocyte supernatant (oocyte S-150) forms chromatin in a reaction that is affected by temperature and by the concentration of ATP and Mg. Under optimal conditions at 27 degrees C, relaxed DNA plasmids are efficiently assembled into supercoiled minichromosomes with the endogenous histones H3, H4, H2A and H2B. This assembly reaction is a gradual process that takes four to six hours for completion. Micrococcal nuclease digestions of the chromatin assembled under these conditions generate an extended series of DNA fragments that are, on average, multiples of 180 base-pairs. We have examined the effect of histone H1 in this system. Exogenous histone H1, when added at a molar ratio of H1 to nucleosome of 1:1 to 5:1, causes an increase in the micrococcal nuclease resistance of the chromatin without causing chromatin aggregation under these experimental conditions. Furthermore, the periodically arranged nucleosomes display longer internucleosome distances, and the average length of the nucleosome repeat is a function of the amount of histone H1 added, when this histone is present at the onset of the assembly process. In contrast, no major change in the length of the nucleosome repeat is observed when histone H1 is added at the end of the chromatin assembly process. Protein analyses of the purified minichromosomes show that histone H1 is incorporated in the chromatin that is assembled in the S-150 supplemented with histone H1. The amount of histone H1 bound to chromatin is a function of the total amount of histone H1 added. We define here the parameters that generate histone H1-containing chromatin with native nucleosome repeats from 160 to 220 base-pairs, and we discuss the implications of these studies.

Large scale isolation of nuclei from oocytes of Xenopus laevis

We describe an improvement on the procedure of Scalenghe et al. (F. Scalenghe, M. Buscaglia, C. Steinheil, and M. Crippa (1978) Chromosoma 66, 299-308) for the large scale isolation of nuclei from Xenopus laevis oocytes. The nuclear extract obtained was tested for its ability to transcribe a cloned Xenopus 5 S RNA gene and for the presence of nuclear factors interacting with a X. laevis ribosomal protein gene promoter. Efficiency of accurate transcription and of factor binding is comparable with that of an extract prepared from manually isolated nuclei.

Characterization of early DNA synthesis in Xenopus eggs after injection of circular plasmid DNA

Circular plasmid DNA is known to replicate when injected into unfertilized eggs of Xenopus laevis. We characterized early DNA synthesis which precedes the replication. Incorporation of a radioactive precursor into covalent closed circular DNA becomes detectable as early as 2 minutes after injection. Judging from the sensitivity to aphidicolin, replicative DNA polymerase alpha or delta is involved in this reaction. However, analysis of density-labeled product as well as detection of newly synthesized, unmethylated strands by restriction endonuclease DpnI digestion, both indicated that most if not all, of the synthesized DNA is present as short repair-like patches in the injected DNA molecules. They are present randomly in all the HaeIII fragments of injected DNA, and transcriptional activation of the 5S RNA gene inserted in the plasmid does not affect the distribution. Only a minor fraction of injected DNA is utilized for this reaction, and 12% of such DNA molecules are further chased into replicated progeny DNA. This efficiency of replication is nearly the same as that of bulk injected DNA which has not been subjected to the early DNA synthesis. We concluded that, despite the common use of replicative DNA polymerase, the early DNA synthesis and the subsequent DNA replication are mutually independent processes.

Requirement of DNA topoisomerases for in vitro chromatin assembly by 3T6 mouse cell extracts

Nuclear extracts of 3T6 mouse cells were able to assemble in vitro minichromosomes which displayed a 150-bp periodicity. Activities of both DNA topoisomerases I and II were detected in these extracts. When a supercoiled pUC DNA was added, it was first relaxed in less than 3 min, then slowly supercoiled again in 1-4 h. Both reactions occurred either in the absence or the presence of added Mg2+ and/or ATP, they were not blocked by DNA topoisomerase II inhibitors and they were inhibited by an antiserum against DNA topoisomerase I and by camptothecin. These findings led us to propose that, under our in vitro assay conditions, chromatin assembly is mainly carried out by a DNA topoisomerase I.

Changes in DNA topology can modulate in vitro transcription of certain RNA polymerase III genes

The role of DNA supercoiling in eukaryotic gene expression is not fully understood. The objective of this study was to examine the regulation of in vitro chromatin assembly by topological alterations in the DNA template using a cell-free extract from Xenopus laevis oocytes (S-150). The results suggest that input DNA topology may be a determining factor in controlling the transcriptional activity of the Xenopus tRNA and one particular 5S gene. When the input topology is supercoiled, high levels of transcription are observed, whereas input relaxed DNA is transcribed to a much lower extent. Transcription from an input relaxed template is stimulated by the addition of supercoiled nonspecific, vector DNA. Furthermore, in direct competition experiments, supercoiled DNA molecules were shown to be transcriptionally dominant over relaxed DNA molecules. Taken together, these data suggest that the efficiency with which a repressor or activator binding protein interacts with DNA may be significantly influenced by the topological status of its target. We demonstrate that modulation of reaction parameters which alter the normal topological processing events catalyzed by the S-150 can dramatically influence the level of gene expression.

Characterization of the repressed 5S DNA minichromosomes assembled in vitro with a high-speed supernatant of Xenopus laevis oocytes

We describe an in vitro system, based on the Xenopus laevis oocyte supernatant of Glikin et al. (G. Glikin, I. Ruberti, and A. Worcel, Cell 37:33-41, 1984), that packages DNA into minichromosomes with regularly spaced nucleosomes containing histones H3, H4, H2A, and H2B but no histone H1. The same supernatant also assembles the 5S RNA transcription complex; however, under the conditions that favor chromatin assembly, transcription is inhibited and a phased nucleosome forms over the 5S RNA gene. The minichromosomes that are fully loaded with nucleosomes remain refractory to transcriptional activation by 5S RNA transcription factors. Our data suggest that this repression is caused by a nucleosome covering the 5S RNA gene and that histone H1 is not required for regular nucleosome spacing or for gene repression in this system.

Xenopus egg extracts: a model system for chromatin replication

A cell-free system derived from Xenopus eggs enables in vitro reproduction of the steps occurring during eukaryotic DNA replication. With a circular single-stranded DNA template, extracts obtained from high-speed centrifugation perform complementary DNA strand synthesis coupled to chromatin assembly. Nucleosomes are formed on the newly replicated DNA and the overall reaction mimics the events occurring during chromosomal replication on the lagging strand at the replication fork. ATP is necessary at all steps examined individually, including RNA priming, elongation of DNA strands and chromatin assembly. Although not required for nucleosome formation, ATP is involved in the correct spacing of nucleosomes and the stability of the assembled chromatin. Replication of double-stranded DNA was observed only with extracts obtained from low-speed centrifugation using demembraned sperm nuclei as substrate. Nuclei are reconstituted around the DNA and then undergo a series of events characteristic of a cell cycle. In contrast, neither DNA elongation or chromatin assembly require formation of the nucleus, and both are independent of the cell cycle.

Studies on DNA topoisomerase activity during in vitro chromatin assembly

The in vitro assembly of chromatin, promoted by the Xenopus cell-free extract (S-150), can be inhibited by oxolinic acid and to a lesser extent by nalidixic acid. Both of these antibiotics have been shown to block the activity of the specialized type II Topoisomerase, bacterial DNA Gyrase. Oxolinic acid induces a DNA cleavage by Micrococcal Nuclease at specific sequences in the multiple cloning vector pGEM-4. Nalidixic acid does not inhibit DNA supercoiling, but does diminish the extent of chromatin formation achieved by the S-150 on circular DNA templates. The Topoisomerase I inhibitor, berenil, does not inhibit extensive chromatin assembly, although it does diminish the level of supercoiling. Taken together, these results suggest that both topoisomerases play a role in the assembly process. Topoisomerase I may catalyze both the introduction of unconstrained supercoils into relaxed DNA and the formation of monosomes, while Topoisomerase II may promote extended chromatin assembly.

Characterization of the repressed 5S DNA minichromosomes assembled in vitro with a high-speed supernatant of Xenopus laevis oocytes

We describe an in vitro system, based on the Xenopus laevis oocyte supernatant of Glikin et al. (G. Glikin, I. Ruberti, and A. Worcel, Cell 37:33-41, 1984), that packages DNA into minichromosomes with regularly spaced nucleosomes containing histones H3, H4, H2A, and H2B but no histone H1. The same supernatant also assembles the 5S RNA transcription complex; however, under the conditions that favor chromatin assembly, transcription is inhibited and a phased nucleosome forms over the 5S RNA gene. The minichromosomes that are fully loaded with nucleosomes remain refractory to transcriptional activation by 5S RNA transcription factors. Our data suggest that this repression is caused by a nucleosome covering the 5S RNA gene and that histone H1 is not required for regular nucleosome spacing or for gene repression in this system.

Events during eucaryotic rRNA transcription initiation and elongation: conversion from the closed to the open promoter complex requires nucleotide substrates

Chemical footprinting and topological analysis were carried out on the Acanthamoeba castellanii rRNA transcription initiation factor (TIF) and RNA polymerase I complexes with DNA during transcription initiation and elongation. The results show that the binding of TIF and polymerase to the promoter does not alter the supercoiling of the DNA template and the template does not become sensitive to modification by diethylpyrocarbonate, which can identify melted DNA regions. Thus, in contrast to bacterial RNA polymerase, the eucaryotic RNA polymerase I-promoter complex is in a closed configuration preceding addition of nucleotides in vitro. Initiation and 3'-O-methyl CTP-limited translocation by RNA polymerase I results in separation of the polymerase-TIF footprints, leaving the TIF footprint unaltered. In contrast, initiation and translocation result in a significant change in the conformation of the polymerase-DNA complex, culminating in an unwound DNA region of at least 10 base pairs.

Events during eucaryotic rRNA transcription initiation and elongation: conversion from the closed to the open promoter complex requires nucleotide substrates

Chemical footprinting and topological analysis were carried out on the Acanthamoeba castellanii rRNA transcription initiation factor (TIF) and RNA polymerase I complexes with DNA during transcription initiation and elongation. The results show that the binding of TIF and polymerase to the promoter does not alter the supercoiling of the DNA template and the template does not become sensitive to modification by diethylpyrocarbonate, which can identify melted DNA regions. Thus, in contrast to bacterial RNA polymerase, the eucaryotic RNA polymerase I-promoter complex is in a closed configuration preceding addition of nucleotides in vitro. Initiation and 3'-O-methyl CTP-limited translocation by RNA polymerase I results in separation of the polymerase-TIF footprints, leaving the TIF footprint unaltered. In contrast, initiation and translocation result in a significant change in the conformation of the polymerase-DNA complex, culminating in an unwound DNA region of at least 10 base pairs.

Inhibition of host cell RNA polymerase III-mediated transcription by poliovirus: inactivation of specific transcription factors

The inhibition of transcription by RNA polymerase III in poliovirus-infected cells was studied. Experiments utilizing two different cell lines showed that the initiation step of transcription by RNA polymerase III was impaired by infection of these cells with the virus. The observed inhibition of transcription was not due to shut-off of host cell protein synthesis by poliovirus. Among four distinct components required for accurate transcription in vitro from cloned DNA templates, activities of RNA polymerase III and transcription factor TFIIIA were not significantly affected by virus infection. The activity of transcription factor TFIIIC, the limiting component required for transcription of RNA polymerase III genes, was severely inhibited in infected cells, whereas that of transcription factor TFIIIB was inhibited to a lesser extent. The sequence-specific DNA-binding of TFIIIC to the adenovirus VA1 gene internal promoter, however, was not altered by infection of cells with the virus. We conclude that (i) at least two transcription factors, TFIIIB and TFIIIC, are inhibited by infection of cells with poliovirus, (ii) inactivation of TFIIIC does not involve destruction of its DNA-binding domain, and (iii) sequence-specific DNA binding by TFIIIC may be necessary but is not sufficient for the formation of productive transcription complexes.

Binding of transcription factor TFIID to the major late promoter during in vitro nucleosome assembly potentiates subsequent initiation by RNA polymerase II

A plasmid containing the major late promoter was assembled into nucleosomes in a Xenopus oocyte extract, isolated by gel filtration, and found to be refractory to transcription initiation in vitro. However, exposure of the promoter to HeLa nuclear extract or to a mixture of isolated transcription factors prior to nucleosome assembly prevented nucleosome-mediated repression of the promoter. Inactivation or elimination of the TATA box-binding factor (TFIID) abolished the ability of these treatments to preserve promoter function. Preincubation with TFIID alone prevented repression and resulted in TFIID being sequestered into the nucleosome-assembled templates. Preincubation with all the transcription factors resulted in the assembly of nucleosome templates containing a near complete preinitiation complex, which required only the addition of TFIIE for transcription initiation.