Dynamics of nuclear receptor movement and transcription.
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Following a hormone signal, steroid/nuclear receptors bind regulatory elements in chromatin and initiate the recruitment of a variety of multi-protein complexes to promoter sequences. These complexes ultimately lead to the recruitment of general transcription factors and the initiation of transcription. Traditional models suggest that these factors remain statically bound to each other and to chromatin until other signals are received to reduce transcription. Recent findings demonstrate that the processes and actions involved are much more complex than traditional models convey, and that the movement of receptors and coactivators is remarkably dynamic. Transcription factors are highly mobile in the nuclear environment, and interact only briefly with target sites in the nucleus. As a result of these transient interactions, promoters move through many states during activation and repression. Two general concepts emerge from current data: (1) Various transcription factors appear to follow "ordered recruitment" to promoters on a time scale of minutes to hours in response to a stimulus. During this response, the proteins that interact with chromatin may cycle on and off the promoter multiple times. (2) During these ordered recruitment cycles, the individual molecules that form functional complexes often exchange rapidly on a time scale of seconds. This rapid exchange of molecules within a formed complex occurs independently of long-term cycling on chromatin. Several processes are implicated in rapid nuclear dynamics, including potential roles for molecular chaperones, the proteasome degradation machinery and chromatin remodeling complexes. (+info)
Nucleosome remodeling: one mechanism, many phenomena?
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The term 'nucleosome remodeling' subsumes a large number of energy-dependent alterations of canonical nucleosome structure, catalyzed by dedicated ATPases in large multiprotein complexes. The importance of these factors for gene regulation and other processes with chromatin substrate have emerged from genetic studies. Mechanistic analyses of nucleosome remodeling by different enzymes provided a diverse, almost confusing phenomenology of ATP-dependent derangement of nucleosomes in vitro, suggesting that different remodeling machines follow different strategies to disrupt histone-DNA interactions. This review explores the alternative possibility that the rich phenomenology of nucleosome remodeling may be brought about by variations of one basic remodeling reaction. (+info)
ISWI complexes in Saccharomyces cerevisiae.
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The imitation switch (ISWI) class of chromatin remodeling ATPase is ubiquitous in eukaryotes. It is becoming clear that these enzymes exist as part of larger complexes and the nature of the associated proteins dictate the function associated with a complex both in biochemical assays and in the cell. Much progress has been made in understanding these relationships in the budding yeast Saccharomyces cerevisiae, containing two ATPases, Isw1p and Isw2p. This has been aided by the ease of genetic manipulation, by a number of systematic screens designed to specifically detect ISWI function and by the plethora of data generated from a number of global screens for function. At present, many functions for yeast Isw1p and Isw2p are related to effects on RNA levels and are associated with the controlled repression of gene expression that crudely fall into three types: displacement of the basal transcription machinery to repress or silence transcription of genes (Isw2 complex and Isw1/Ioc3 complex); control of the activation of expression leading to coordination of transcription elongation; and efficient termination of transcription (Isw1/Ioc4/Ioc2 complex). The latter two functions are regulated by specific phosphorylation of residues within the carboxy terminal domain (CTD) of the largest subunit of RNA polymerase II (RNAPII). Other functions may relate to the ability of ISWI complex to displace transcription factors or enzymes from the template. Other ISWI-containing complexes that have yet to be characterized indicate that much remains to be learnt about yeast ISWI itself and importantly, how the various forms cooperate with different classes of chromatin remodeling ATPase, complexes containing histone acetylases, deacetylases, methylases and both DNA and RNA polymerases. (+info)
Multiple roles for ISWI in transcription, chromosome organization and DNA replication.
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ISWI functions as the ATPase subunit of multiple chromatin-remodeling complexes. These complexes use the energy of ATP hydrolysis to slide nucleosomes and increase chromatin fluidity, thereby modulating the access of transcription factors and other regulatory proteins to DNA. Here we discuss recent progress toward understanding the biological functions of ISWI, with an emphasis on its roles in transcription, chromosome organization and DNA replication. (+info)
Chromatin remodeling and the maintenance of genome integrity.
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DNA damage of any type is threatening for a cell. If lesions are left unrepaired, genomic instability can arise, faithful transmission of genetic information is greatly compromised eventually leading the cell to undergo apoptosis or carcinogenesis. In order to access/detect and repair these damages, repair factors must circumvent the natural repressive barrier of chromatin. This review will present recent progress showing the intricate link between chromatin, its remodeling and the DNA repair process. Several studies demonstrated that one of the first events following specific types of DNA damage is the phosphorylation of histone H2A. This mark or the damage itself are responsible for the association of chromatin-modifying complexes near damaged DNA. These complexes are able to change the chromatin structure around the wounded DNA in order to allow the repair machinery to gain access and repair the lesion. Chromatin modifiers include ATP-dependent remodelers such as SWI/SNF and Rad54 as well as histone acetyltransferases (HATs) like SAGA/NuA4-related complexes and p300/CBP, which have been shown to facilitate DNA accessibility and repair in different pathways leading to the maintenance of genome integrity. (+info)
TOUSLED kinase activity oscillates during the cell cycle and interacts with chromatin regulators.
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The TOUSLED (TSL)-like nuclear protein kinase family is highly conserved in plants and animals. tsl loss of function mutations cause pleiotropic defects in both leaf and flower development, and growth and initiation of floral organ primordia is abnormal, suggesting that basic cellular processes are affected. TSL is more highly expressed in exponentially growing Arabidopsis culture cells than in stationary, nondividing cells. While its expression remains constant throughout the cell cycle in dividing cells, TSL kinase activity is higher in enriched late G2/M-phase and G1-phase populations of Arabidopsis suspension culture cells compared to those in S-phase. tsl mutants also display an aberrant pattern and increased expression levels of the mitotic cyclin gene CycB1;1, suggesting that TSL represses CycB1;1 expression at certain times during development or that cells are delayed in mitosis. TSL interacts with and phosphorylates one of two Arabidopsis homologs of the nucleosome assembly/silencing protein Asf1 and histone H3, as in humans, and a novel plant SANT/myb-domain protein, TKI1, suggesting that TSL plays a role in chromatin metabolism. (+info)
A defect in nucleosome remodeling prevents IL-12(p35) gene transcription in neonatal dendritic cells.
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To gain insight into the inability of newborns to mount efficient Th1 responses, we analyzed the molecular basis of defective IL-12(p35) expression in human neonatal monocyte-derived dendritic cells (DCs). Determination of IL-12(p35) pre-mRNA levels by real-time RT-PCR revealed that transcriptional activation of the gene in lipopolysaccharide-stimulated neonatal DCs was strongly impaired compared with adult DCs. We next showed that p50/p65 and p65/p65 dimers interact with kB#1 site, a critical cis-acting element of the IL-12(p35) promoter. We found that LPS-induced p65 activation was similar in adult and newborn DCs. Likewise, in vitro binding activity to the Sp1#1 site, previously shown to be critical for IL-12(p35) gene activation, did not differ in adults and newborns. Since the accessibility to this Sp1#1 site was found to depend on nucleosome remodeling, we used a chromatin accessibility assay to compare remodeling of the relevant nucleosome (nuc-2) in adult and neonatal DCs. We observed that nuc-2 remodeling in neonatal DCs was profoundly impaired in response to lipopolysaccharide. Both nuc-2 remodeling and IL-12(p35) gene transcription were restored upon addition of recombinant interferon-gamma. We conclude that IL-12(p35) transcriptional repression in neonatal DCs takes place at the chromatin level. (+info)
Spt3 and Mot1 cooperate in nucleosome remodeling independently of TBP recruitment.
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We have investigated the requirements for nucleosome remodeling upon transcriptional induction of the GAL1 promoter. We found that remodeling was dependent on two SAGA complex components, Gcn5 and Spt3. The involvement of the latter was surprising as its function has been suggested to be directly involved in TATA-binding protein (TBP) recruitment. We demonstrated that this novel function was in fact independent of TBP recruitment and this was further validated using a Gal4-driven synthetic promoter. Most importantly, we showed that the involvement of Spt3 in chromatin remodeling was independent of transcription, as it was also observed for a nonpromoter nucleosome located next to an activator-binding site. In an effort to explore how the Spt3 function was elicited, we found that Mot1, an ATPase of the Snf2 family that genetically interacts with Spt3, was also required for nucleosome remodeling independently of TBP recruitment. Interestingly enough, Spt3 and Mot1 were recruited on the GAL1 promoter as well as on the nonpromoter site in an interdependent manner. These findings show that the two proteins cooperate in nucleosomal transactions. (+info)