Deletion mutants which affect the nuclease-sensitive site in simian virus 40 chromatin

SP1 and AP-1 elements direct chromatin remodeling in SV40 chromosomes during the first 6 hours of infection

To identify the SV40 regulatory sequences responsible for the chromatin remodeling associated with early transcription, SV40 chromosomes containing potential remodeling sequences inserted adjacent to a reporter region were isolated at various times within the first 6 h of infection and analyzed by a combination of restriction endonuclease digestion and competitive PCR amplification. The sequences analyzed included the early domain, the enhancer, the late domain, the early phasing element, the AP-1 element, two tandem copies of the SP1 element, and the AP-4 element. From 30 min to 3 h postinfection only the enhancer, the AP-1 element, and the two tandem copies of the SP1 element caused a change in nuclease sensitivity consistent with chromatin remodeling. These results suggest that the changes in chromatin structure seen in the promoter during activation of early transcription are most likely a result of remodeling by the AP-1 and/or SP1.

Generation of a nucleosome-free promoter region in SV40 does not require T-antigen binding to site I

The relationship between T-antigen interactions at Site I and the presence of a nucleosome-free promoter in SV40 chromatin was examined by analyzing chromatin from mutants defective for T-antigen interaction at site I (cs 1085, scs111, and tsA58) and their parental wild-type strains (776, SVS, and VA45-54, respectively). As judged by sensitivity to digestion with restriction endonucleases that recognize unique sequences within the promoter region (BglI, KpnI, and MspI), a nucleosome-free promoter was observed in a substantially larger proportion of chromosomes from the defective mutants than their wild-type parents. This result demonstrates that T-antigen binding to site I is not necessary for setting the early boundary of the nucleosome-free region, although it may function directly or indirectly in determining the proportion of chromosomes containing this feature.

Determinants for the DNase I-hypersensitive chromatin structure 5' to a human HSP70 gene

A DNase I hypersensitive site was detected in chromatin formed over a human hsp70 gene segment after amplification in COS7 cells. Deletion mutant analysis was used to evaluate the sequence requirements for this chromatin structure. Determinants sufficient to form the hypersensitive site are contained in a 280 base-pair sequence corresponding approximately to the region that is hypersensitive. Deletion of sequences from either end of this region resulted in reduced hypersensitivity, suggesting that multiple genetic elements contribute to the formation of this chromatin structure. As has been reported for other heat shock genes, the hypersensitive chromatin structure is present prior to heat treatment and does not change in intensity or position after heat shock, in spite of the fact that hsp70 gene expression is completely dependent on heat induction. Sequence requirements for hypersensitivity were generally similar to those for heat-induced gene expression when mutant plasmids were tested at low copy number (e.g. in HeLa cells or in COS cells without amplification); however, deletion of sequences between -223 and -162 with respect to the start of transcription abolished the hypersensitive site but had no effect on gene expression. A barrier to exonuclease III digestion was detected within this region (near an imperfect inverted repeat sequence centered at position -202), suggesting that proteins are tightly bound to the DNA at this location.

Structure of transcriptionally active chromatin

Transcriptionally active or potentially active genes can be distinguished by several criteria from inactive sequences. Active genes show both an increased general sensitivity to endonucleases like DNase I or micrococcal nuclease and the presence of nuclease hypersensitive sites. Frequently, the nuclease hypersensitive sites are present just upstream of the transcription initiation site covering sequences that are crucial for the promoter function. Viral or cellular transcription enhancer elements are also associated with DNase I hypersensitive sites. At least for the SV40 enhancer, it was shown by electronmicroscopic studies that the DNase I hypersensitive DNA segment is excluded from nucleosomes. It is highly plausible that the binding of regulatory proteins to enhancer or promoter sequences is responsible for the exclusion of these DNA segments from nucleosomes and for the formation of nuclease hypersensitive sites. We speculate that the binding of such proteins may switch on a change in the conformation and/or the protein composition of a chromatin segment or domain containing one to several genes. Biochemical analysis of fractionated nucleosome particles or of active and inactive chromatin fractions have revealed differences in the composition as well as in the degree of modification of histones in these two subfractions of the chromosome. However, until present it is impossible to define unambiguously what are the crucial structural elements that distinguish between particles present on active and inactive chromatin.

An SV40 "enhancer trap" incorporates exogenous enhancers or generates enhancers from its own sequences

We have transfected monkey CV-1 cells with non-infectious, linear SV40 DNA, lacking the 72 bp repeat enhancer region. Infectious virus was recovered from this "enhancer trap" upon cotransfection with enhancer DNA segments from various viruses, notably a truncated polyoma enhancer that was integrated as a dimer. Cotransfection of the "enhancer trap" with fragmented DNA of mouse, monkey, or human origin yielded no recombinant virus with integrated cellular sequences, with one possible exception. In some transfection experiments without added viral enhancer DNA, SV40 variants were generated that have a segment of their flanking "late" DNA duplicated to substitute for the deleted 72 bp repeat. In one variant, an 88 bp duplication creates a strong enhancer from this nonenhancing DNA region. Both the polyoma enhancer fragment and the spontaneously created enhancers lack the alternating purines-pyrimidines or "CACA box" suggested to be characteristic for enhancer elements and show only limited homology to the "GTGG(AAATTT)G box."

DNase I sensitivity of integrated simian virus 40 DNA

We undertook an analysis of integrated simian virus 40 (SV40) DNA to learn whether the DNase I-sensitive region is retained in the integrated array of mouse transformants. Our results indicate that full-length integrated SV40 chromatin retains a DNase I-hypersensitive region at the same point as in nonintegrated SV40 chromatin. Thus, the lack of a DNase I-hypersensitive region is not likely to be the reason for nonpermissivity of SV40 in mouse cells. In addition, results reported here indicate that a deletion of about 200 base pairs of DNA in the region of the DNase I-hypersensitive site severely reduces the sensitivity of integrated SV40 chromatin. This result is similar to a previously reported result obtained with deletion mutants of SV40 analyzed in the lytic cycle. It is the first report of a DNA lesion affecting DNase I hypersensitivity of a mammalian chromosome.

Induction of altered chromatin structures by simian virus 40 enhancer and promoter elements

Two simian virus 40 transcriptional promoter elements, the 72-base pair (bp) repeat and the 21-bp repeat region, induce chromatin structures of increased DNase I sensitivity when transposed elsewhere in the viral genome. The induction of a sufficiently long stretch of DNase I-sensitive chromatin leads to the appearance of a visible nucleosome-free region.

Nucleosome arrangement in green monkey alpha-satellite chromatin. Superimposition of non-random and apparently random patterns

We have studied the structure of tandemly repetitive alpha-satellite chromatin (alpha-chromatin) in African green monkey cells (CV-1 line), using restriction endonucleases and staphylococcal nuclease as probes. While more than 80% of the 172-base-pair (bp) alpha-DNA repeats have a HindIII site, less than 15% of the alpha-DNA repeats have an EcoRI site, and most of the latter alpha-repeats are highly clustered within the CV-1 genome. EcoRI and HindIII solubilize approximately 8% and 2% of the alpha-chromatin, respectively, under the conditions used. EcoRI is thus approximately 30 times more effective than HindIII in solubilizing alpha-chromatin, with relation to the respective cutting frequencies of HindIII and EcoRI on alpha-DNA. EcoRI and HindIII solubilize largely non-overlapping subsets of alpha-chromatin. The DNA size distributions of both EcoRI- and HindIII-solubilized alpha-chromatin particles peak at alpha-monomers. These DNA size distributions are established early in digestion and remain strikingly constant throughout the digestion with either EcoRI or HindIII. Approximately one in every four of both EcoRI- and HindIII-solubilized alpha-chromatin particles is an alpha-monomer. Two-dimensional (deoxyribonucleoprotein leads to DNA) electrophoretic analysis of the EcoRI-solubilized, sucrose gradient-fractionated alpha-oligonucleosomes shows that they do not contain "hidden" EcoRI cuts. Moreover, although the EcoRI-solubilized alpha-oligonucleosomes contain one EcoRI site in every 172-bp alpha-DNA repeat, they are completely resistant to redigestion with EcoRI. This striking difference between the EcoRI-accessible EcoRI sites flanking an EcoRI-solubilized alpha-oligonucleosome and completely EcoRI-resistant internal EcoRI sites in the same alpha-oligonucleosome indicates either that the flanking EcoRI sites occur within a modified chromatin structure or that an altered nucleosome arrangement in the vicinity of a flanking EcoRI site is responsible for its location in the nuclease-sensitive internucleosomal (linker) region. Analogous redigestions of the EcoRI-solubilized alpha-oligonucleosomes with either HindIII, MboII or HaeIII (both before and after selective removal of histone H1 by an exchange onto tRNA) produce a self-consistent pattern of restriction site accessibilities. Taken together, these data strongly suggest a preferred nucleosome arrangement within the EcoRI-solubilized subset of alpha-oligonucleosomes, with the centers of most of the nucleosomal cores being approximately 20 bp and approximately 50 bp away from the nearest EcoRI and HindIII sites, respectively, within the 172-bp alpha-DNA repeat. However, as noted above, the clearly preferred pattern of nucleosome arrangement within the EcoRI-solubilized alpha-oligonucleosomes is invariably violated at the ends of every such alpha-oligonucleosomal particle, suggesting at least a partially statistical origin of this apparently non-random nucleosome arrangement.(ABSTRACT TRUNCATED AT 400 WORDS)