Nucleosome positioning on the MMTV LTR results from the frequency-biased occupancy of multiple frames.

Fragoso, Gilberto; John, Sam; Roberts, Margo; Hager, Gordon L.

doi:10.1101/gad.9.15.1933

Cited by 166 publications

(134 citation statements)

References 62 publications

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“…Roberts et al (38) observed clear 10-bp periodicities for an in vitro reconstitute that contained five different core positions, demonstrating the difficulty of using this criterion for determination of high resolution positions. Similar data from several other systems (summarized in Fragoso et al (33)) is also consistent with multiply positioned cores within families. Thus, the preponderance of evidence at this time would argue that even in highly organized and reproducible systems, such as the MMTV LTR, considerable complexity exists in nucleosome positioning.…”

Section: The Mmtv Modelsupporting

confidence: 77%

“…This structure was originally characterized as a periodic array of micrococcal nuclease and methyldiumpropyl-EDTA-Fe(II) cleavage-sensitive internucleosomal linker regions (35). More recently, using an in vivo cross-linking procedure for determining nucleosome core positions, Fragoso et al (33,37) concluded that the periodic array does not represent precisely positioned nucleosomes but rather consists of a series of nucleosome families (Fig. 1A, A-F) (33).…”

Section: The Mmtv Modelmentioning

confidence: 99%

“…More recently, using an in vivo cross-linking procedure for determining nucleosome core positions, Fragoso et al (33,37) concluded that the periodic array does not represent precisely positioned nucleosomes but rather consists of a series of nucleosome families (Fig. 1A, A-F) (33). Each family contains a group of nucleosomes in a frequency-biased distribution among a set of available translational frames.…”

Section: The Mmtv Modelmentioning

confidence: 99%

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Transcriptional Regulation of Mammalian Genes in Vivo

Smith

Hager

1997

Journal of Biological Chemistry

235

152

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The past two decades have brought a major evolution in our understanding of promoter structure, transcription factors, and mechanisms by which transcriptional initiation is regulated in eukaryotes. Multiple approaches have been used to establish current models for transcriptional regulation, including the development of in vitro transcription systems using either naked DNA or reconstituted chromatin, genetic analysis of gene regulation in yeast and Drosophila, and in vivo analysis of either endogenous cellular genes or transiently transfected, exogenous gene promoters. It is now clear that chromatin structure, once considered to be transparent to the process of transcription, plays an important role in the regulation of gene expression (reviewed in Ref. 1). Since all cellular genes are packaged into ordered chromatin structures, an understanding of the mechanisms by which nucleoprotein structure influences transcription activation is necessary for a complete paradigm of gene regulation in higher eukaryotes.Studies on regulation of endogenous mammalian genes are challenging due to the lack of genetic techniques available in yeast and Drosophila systems, which allow targeted insertion of promoters and gene disruption. Structural analysis of integrated gene promoters in mammalian cells requires the time-consuming generation of multiple stable cell lines or pools, in which the integrated genes would be subject to position effects from surrounding chromatin. Therefore, the identification and characterization of factors involved in mammalian gene expression have been addressed primarily through the use of transient transfection assays. In this approach, exogenous plasmid DNA, usually promoter/reporter constructs and transcription factor expression vectors, is introduced into cultured cells and expressed transiently, without replication or integration into the cellular genome. A variety of transfection methods has been utilized, including calcium phosphate precipitation (2), DEAE-dextran (3), electroporation (4, 5), and liposomemediated transfer (6). These studies have resulted in an abundance of information about promoter structure (i.e. identification of cisacting elements), transcription factor structure and function, and the characterization of transcription factor interactions that are part of various cellular regulatory pathways. However, in light of the accumulating evidence indicating a role for chromatin structure in transcription, it is appropriate to question whether transiently transfected gene promoters are adequate models for transcriptional regulatory mechanisms active on endogenous genes in ordered, replicated chromatin. Structural Studies on Transiently Transfected DNAThe first issue to consider for transient templates is whether these molecules acquire physiologically spaced nucleosomes when introduced into cultured, mammalian cells. Since assembly of nucleosomes on endogenous genes is coupled to DNA replication, it is questionable whether transfected plasmids, which rarely carry mammalian replication...

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Section: The Mmtv Modelsupporting

confidence: 77%

Section: The Mmtv Modelmentioning

confidence: 99%

Section: The Mmtv Modelmentioning

confidence: 99%

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Transcriptional Regulation of Mammalian Genes in Vivo

Smith

Hager

1997

Journal of Biological Chemistry

235

152

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“…The MMTV-LTR has six well defined positioned nucleosome families, designated nucleosomes (Nuc) A-F. NucA overlaps the TATA region and the transcription start site, and NucF is the farthest 5Ј to the transcription start site (Ϫ1 kilobase) (Fig. 1A) (22,23). Four GR binding sites or hormone response elements (HREs) are located in the NucB region (Fig.…”

Section: Resultsmentioning

confidence: 99%

Steroid Hormone Receptor-mediated Histone Deacetylation and Transcription at the Mouse Mammary Tumor Virus Promoter

Sheldon

Becker

Smith

2001

Journal of Biological Chemistry

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Acetylation of lysines in histones H3 and H4 N-terminal tails is associated with transcriptional activation and deacetylation with repression. Our studies with the mouse mammary tumor virus (MMTV) promoter in chromatin show significant levels of acetylation at promoter proximal and distal regions prior to transactivation. Upon activation with glucocorticoids or progestins, promoter proximal histones become deacetylated within the region of inducible nuclease hypersensitivity. The deacetylation lags behind the initiation of transcription, indicating a role in post-activation regulation. Our results indicate a novel mechanism by which target promoters are regulated by steroid receptors and chromatin modification machinery.The association of histone acetylation with transactivation, and deacetylation with repression, was first suggested in 1964 by Allfrey et al. (1). Such associations are now well documented in numerous studies (2-4), including several with steroid hormone-regulated promoters (5-7). Acetylation of specific lysine residues in histone N-terminal tails decreases their net positive charge, which has been proposed to cause an electrostatic repulsion between the histones and the negatively charged phosphate backbone of DNA (8) that results in a more open chromatin conformation. There are, however, data that conflict with this simple model. Mutskov et al. (9) have shown that hyperacetylated and hypoacetylated histone tails can associate almost equally well with DNA in chromatin at physiological salt concentrations. Mizuguchi et al. (10) show that hyperacetylation of histones alone does not stimulate transcription from the adenovirus E4 promoter. An alternative model proposes that the pattern and nature of histone tail modification provides a "code" that can be recognized by specific factors that then associate with the tail, thereby determining the functional consequence of the histone modification (11). The two models are not mutually exclusive.Circumstantial evidence suggests that transactivation of some promoters is associated with deacetylation. Treatment with histone deacetylase (HDAC) 1 inhibitors, which results in hyperacetylation of histones, can decrease rather than increase transactivation at some promoters or result in no change at others (12). The HDAC inhibitor sodium butyrate inhibits transactivation of the ovalbumin promoter by estrogen receptors (ERs) (13), and of the tyrosine aminotransferase promoter (14) and the MMTV-LTR by glucocorticoid receptors (GRs) (15). Furthermore, Deckert and Struhl (16) have recently shown that in Saccharomyces cerevisiae both acetylated and deacetylated histones H3 and H4 can be associated with transcriptionally active promoters.Our results demonstrate that at the MMTV-LTR there is a significant level of basal acetylation at the promoter when it is inactive that decreases during hormone activation. This differs from what has generally been found at mammalian gene promoters characterized thus far (7, 17), but it has been described at some yeast promoters (R...

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“…Furthermore, the superantigen sequence is hypervariable and this affects sequences across nucB (Brandt-Carlson et al 1993), so care is needed when comparing results from different isolates and this may have led to different nucleosome mapping assignments (Piña et al 1990;Archer et al 1991;Fragoso et al 1995;Flaus and Richmond 1998).…”

Section: Mmtv Ltr Nucleosomes a And Bmentioning

confidence: 99%

Principles and practice of nucleosome positioningin vitro

Flaus

2011

Frontiers in Life Science

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Nucleosome positioning on the MMTV LTR results from the frequency-biased occupancy of multiple frames.

Cited by 166 publications

References 62 publications

Transcriptional Regulation of Mammalian Genes in Vivo

Transcriptional Regulation of Mammalian Genes in Vivo

Steroid Hormone Receptor-mediated Histone Deacetylation and Transcription at the Mouse Mammary Tumor Virus Promoter

Principles and practice of nucleosome positioningin vitro

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