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

Micrococcal nuclease analysis of chromatin structure

This unit describes methodology for using micrococcal nuclease to investigate the presence of nucleosomes at a particular location in chromatin and to map the positions of nucleosomes at various levels of resolution. The approaches are readily adaptable to other probes of chromatin structure that cause DNA cleavage. Results obtained from such chromatin studies provide a structural view of the molecular environment of gene in their native context in cells.

Fundamental structural units of the Escherichia coli nucleoid revealed by atomic force microscopy

A small container of several to a few hundred microm3 (i.e. bacterial cells and eukaryotic nuclei) contains extremely long genomic DNA (i.e. mm and m long, respectively) in a highly organized fashion. To understand how such genomic architecture could be achieved, Escherichia coli nucleoids were subjected to structural analyses under atomic force microscopy, and found to change their structure dynamically during cell growth, i.e. the nucleoid structure in the stationary phase was more tightly compacted than in the log phase. However, in both log and stationary phases, a fundamental fibrous structure with a diameter of approximately 80 nm was found. In addition to this '80 nm fiber', a thinner '40 nm fiber' and a higher order 'loop' structure were identified in the log phase nucleoid. In the later growth phases, the nucleoid turned into a 'coral reef structure' that also possessed the 80 nm fiber units, and, finally, into a 'tightly compacted nucleoid' that was stable in a mild lysis buffer. Mutant analysis demonstrated that these tight compactions of the nucleoid required a protein, Dps. From these results and previously available information, we propose a structural model of the E.coli nucleoid.

Mapping of abutilon mosaic geminivirus minichromosomes

The single-stranded circular DNA of Abutilon mosaic geminivirions is complemented to double-stranded DNA by host proteins after infecting cells. This double-stranded DNA serves as a template for replication as well as transcription and is assembled into host nucleosomes, yielding circular viral minichromosomes. Their chromatin structure was analyzed by use of isolated nuclei combining nuclease sensitivity assays with ligation-mediated PCR, evaluating nucleosomal ladders and topoisomer distributions in one- and two-dimensional gels by blot hybridization. Viral minichromosomes were found to exist in at least two defined structures covered with 11 or 12 nucleosomes, leaving open gaps accessible for interactions with other host factors. Nucleosome-free gaps were colocalized with promoter structures and the origin of replication in both components of genomic DNA (DNA A and DNA B). Nucleosomes were positioned over the entire viral DNA in at least two alternative phases with different periodicities. The distribution of topoisomers of monomeric viral circular double-stranded DNA confirmed the presence of variable chromatin structures revealing maximum frequencies of molecules with either 11, 12, or 13 superhelical turns (corresponding to respective numbers of nucleosomes) at maximal frequency at different stages during leaf development of infected plants. The role of variable chromatin structures for gene regulation of geminiviruses is discussed.

Mapping of abutilon mosaic geminivirus minichromosomes

The single-stranded circular DNA of Abutilon mosaic geminivirions is complemented to double-stranded DNA by host proteins after infecting cells. This double-stranded DNA serves as a template for replication as well as transcription and is assembled into host nucleosomes, yielding circular viral minichromosomes. Their chromatin structure was analyzed by use of isolated nuclei combining nuclease sensitivity assays with ligation-mediated PCR, evaluating nucleosomal ladders and topoisomer distributions in one- and two-dimensional gels by blot hybridization. Viral minichromosomes were found to exist in at least two defined structures covered with 11 or 12 nucleosomes, leaving open gaps accessible for interactions with other host factors. Nucleosome-free gaps were colocalized with promoter structures and the origin of replication in both components of genomic DNA (DNA A and DNA B). Nucleosomes were positioned over the entire viral DNA in at least two alternative phases with different periodicities. The distribution of topoisomers of monomeric viral circular double-stranded DNA confirmed the presence of variable chromatin structures revealing maximum frequencies of molecules with either 11, 12, or 13 superhelical turns (corresponding to respective numbers of nucleosomes) at maximal frequency at different stages during leaf development of infected plants. The role of variable chromatin structures for gene regulation of geminiviruses is discussed.

Tissue-specific in vivo protein-DNA interactions at the promoter region of the Xenopus 63 kDa keratin gene during metamorphosis

The Xenopus 63 kDa keratin gene is developmentally regulated and is expressed only in the epidermis. Full activation of the 63 kDa keratin gene requires two regulatory steps, the first independent and the second dependent on the thyroid hormone triiodothyronine (T3). Sequence analysis of a genomic clone of the 63 kDa keratin gene identified potential AP2 and SP1 binding sites upstream of the transcription initiation site. Electrophoretic mobility shift assays using purified or enriched proteins, as well as HeLa nuclear extract in conjunction with AP2- and SP1-specific antibodies, have been used to demonstrate that human AP2 and SP1 bind elements upstream of the transcription initiation site. In vivo footprinting with ligation mediated PCR revealed several footprints, within 350 bp upstream of the transcription initiation site, including those at the AP2 and SP1 sites, that are unique to epidermal cells which express the keratin gene. These footprints were absent in blood cells and XL177 cells which do not express the gene. Comparison of footprints between cells which express the 63 kDa keratin gene at low or high levels showed that the same binding sites are occupied, indicating that these sites are required for basal as well as T3-induced expression of the 63 kDa keratin gene.

Mouse interleukin-2 receptor alpha gene expression. Delimitation of cis-acting regulatory elements in transgenic mice and by mapping of DNase-I hypersensitive sites

The alpha chain of the interleukin-2 receptor (IL-2R alpha) is a key regulator of lymphocyte proliferation. To analyze the mechanisms controlling its expression in normal cells, we used the 5'-flanking region (base pairs -2539/+93) of the mouse gene to drive chloramphenicol acetyltransferase expression in four transgenic mouse lines. Constitutive transgene activity was restricted to lymphoid organs. In mature T lymphocytes, transgene and endogenous IL-2R alpha gene expression was stimulated by concanavalin A and up-regulated by IL-2 with very similar kinetics. In thymic T cell precursors, IL-1 and IL-2 cooperatively induced transgene and IL-2R alpha gene expression. These results show that regulation of the endogenous IL-2R alpha gene occurs mainly at the transcriptional level. They demonstrate that cis-acting elements in the 5'-flanking region present in the transgene confer correct tissue specificity and inducible expression in mature T cells and their precursors in response to antigen, IL-1, and IL-2. In a complementary approach, we screened the 5' end of the endogenous IL-2R alpha gene for DNase-I hypersensitive sites. We found three lymphocyte specific DNase-I hypersensitive sites. Two, at -0.05 and -5.3 kilobase pairs, are present in resting T cells. A third site appears at -1.35 kilobase pairs in activated T cells. It co-localizes with IL-2-responsive elements identified by transient transfection experiments.

DNA synthesis generally initiates outside the simian virus 40 core origin in vitro

The nucleotide positions at which DNA synthesis initiates in vitro, in the vicinity of the simian virus 40 origin, have been determined. Start sites for DNA synthesis are greatly suppressed over the simian virus 40 core origin. Relatively weak start sites are detected over the 21-bp repeats and T-antigen-binding site I; distal to these regions, stronger start sites are detected. Thus, studies using a model system for eukaryotic DNA replication indicate that DNA synthesis events initiate, in general, outside the core origin.

Transcription factor Oct1 binds to the AT-rich segment of the simian virus 40 replication origin

A cellular protein that binds to the AT-rich late segment of the simian virus 40 (SV40) origin of replication has been identified as transcription factor Oct1. This conclusion is based on the following observations: the late origin binding protein has a molecular mass of about 100 kDa, like factor Oct1, and shares other biochemical properties with Oct1; its binding to the origin is inhibited by antibodies directed against the POU domain of factor Oct1; the isolated POU domain of Oct1 specifically binds to the SV40 late origin region. Thus, the SV40 genome contains binding sites for transcription factor Oct1 in the origin of replication in addition to the previously characterized octamer sites in the viral promoter enhancer. Oct1, bound to the viral origin, negatively affects the DNA unwinding reaction catalyzed by the viral replication initiator T antigen, suggesting that Oct1 may have a role in the regulation of viral replication.

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

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

In vivo protein-DNA interactions at the c-jun promoter: preformed complexes mediate the UV response

Irradiation of cells with UV light triggers a genetic response, called the UV response, which results in induction of a set of genes containing AP-1-binding sites. The c-jun gene itself, which codes for AP-1-binding activity, is strongly (> 100-fold) and rapidly activated by UV. The UV induction of c-jun is mediated by two UV response elements consisting of AP-1-like sequences within its 5' control region. We have analyzed protein-DNA interactions in vivo at the c-jun promoter in noninduced and UV-irradiated HeLa cells. In vivo footprint analysis was performed by using dimethyl sulfate on intact cells and DNase I on lysolecithihin-permeabilized cells in conjunction with ligation-mediated polymerase chain reaction to cover about 450 bp of the c-jun promoter, including the transcription start sites. We find that this region does not contain methylated cytosines and is thus a typical CpG island. In uninduced cells, in vivo protein-DNA interactions were localized to an AP-1-like sequence (nucleotides [nt] -71 to -64), a CCAAT box element (nt -91 to -87), two SP1 sequences (nt -115 to -110 and -123 to -118), a nuclear factor jun site (nt -140 to -132), and a second AP-1-like sequence (nt -190 to -183). These results indicate that complex protein-DNA interactions exist at the c-jun promoter prior to induction by an external stimulus. Surprisingly, after stimulation of c-jun expression by UV irradiation, all in vivo protein-DNA contacts remained essentially unchanged, including the two UV response elements located at the AP-1-like sequences. The UV-induced signalling cascade leads to phosphorylation of c-Jun on serines 63 and 73 (Y. Devary, R.A. Gottlieb, T. Smeal, and M. Karin, Cell 71:1081-1091, 1992). Taken together, these data suggest that modification of the transactivating domain of DNA-bound c-Jun or a closely related factor may trigger the rapid induction of the c-jun gene.

In vivo protein-DNA interactions at the c-jun promoter: preformed complexes mediate the UV response

Irradiation of cells with UV light triggers a genetic response, called the UV response, which results in induction of a set of genes containing AP-1-binding sites. The c-jun gene itself, which codes for AP-1-binding activity, is strongly (> 100-fold) and rapidly activated by UV. The UV induction of c-jun is mediated by two UV response elements consisting of AP-1-like sequences within its 5' control region. We have analyzed protein-DNA interactions in vivo at the c-jun promoter in noninduced and UV-irradiated HeLa cells. In vivo footprint analysis was performed by using dimethyl sulfate on intact cells and DNase I on lysolecithihin-permeabilized cells in conjunction with ligation-mediated polymerase chain reaction to cover about 450 bp of the c-jun promoter, including the transcription start sites. We find that this region does not contain methylated cytosines and is thus a typical CpG island. In uninduced cells, in vivo protein-DNA interactions were localized to an AP-1-like sequence (nucleotides [nt] -71 to -64), a CCAAT box element (nt -91 to -87), two SP1 sequences (nt -115 to -110 and -123 to -118), a nuclear factor jun site (nt -140 to -132), and a second AP-1-like sequence (nt -190 to -183). These results indicate that complex protein-DNA interactions exist at the c-jun promoter prior to induction by an external stimulus. Surprisingly, after stimulation of c-jun expression by UV irradiation, all in vivo protein-DNA contacts remained essentially unchanged, including the two UV response elements located at the AP-1-like sequences. The UV-induced signalling cascade leads to phosphorylation of c-Jun on serines 63 and 73 (Y. Devary, R.A. Gottlieb, T. Smeal, and M. Karin, Cell 71:1081-1091, 1992). Taken together, these data suggest that modification of the transactivating domain of DNA-bound c-Jun or a closely related factor may trigger the rapid induction of the c-jun gene.

Construction of nucleosome cores from defined sequence DNA of viral origin

The de novo construction of defined nucleosomes from two DNA fragments of simian virus SV40 is described. One fragment spans the region containing the origin of replication of the virus from base -16 to base 161, a region which is nucleosome-free during virus replication. The other fragment, of 142 bp (1352 to 1493), is within the region coding for viral proteins VP2 and VP3, and serves for comparison. Both fragments form nucleosomes with similar efficiency when combined with histone cores as well as when exchanged with existing core particles. The DNase I digestion pattern and exonuclease III analysis both indicate that true nucleosome cores are formed, and that a prolonged tail is not protruding from the constructs. The efficient formation of a nucleosome core particle from the origin region of DNA implies that the absence of nucleosomes from this region during viral infection is not prescribed by the specific base sequence of origin DNA, and is therefore likely to be determined by non-histone nuclear factors associated with the SV40 replication process.

Analysis of chromatin structure by ligation-mediated PCR

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

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

Nucleosome spacing is compressed in active chromatin domains of chick erythroid cells

We have cleaved the chromatin of embryonic and adult chicken erythroid cells using a novel nuclease that is capable of resolving clearly the nucleosomes of active chromatin. We found that in active chromatin, nucleosomes are spaced up to 40 base pairs closer together than in inactive chromatin. This was true for both "housekeeping" and "luxury" genes and was observed whether the digestion was carried out on isolated nuclei in vitro or by activating the endogenous nuclease in vivo. The close spacing extended several kilobases into flanking chromatin, indicating that this is a domain property of active chromatin, not just a characteristic of regions disrupted by transcription. A simple interpretation of our results is that the nucleosomes of active chromatin are mobile in vivo and, not being constrained by linker histones, freely move closer together.

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

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

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

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

A simpler and better method to cleave chromatin with DNase 1 for hypersensitive site analyses

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

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