Evidence for a Common Mode of Transcription Factor Interaction with Chromatin as Revealed by Improved Quantitative Fluorescence Recovery after Photobleaching

Mueller, Florian; Wach, Paul; McNally, James G.

doi:10.1529/biophysj.107.123182

Cited by 158 publications

(247 citation statements)

References 29 publications

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“…It is also possible to estimate the minimal rate of the conformational transition in p53 required for fast search and specific binding. Using the measured diffusion coefficient for full-length p53 and in vivo time on DNA (22,23), we obtain a rate constant of about 10 3 s −1 (see SI Text). Thus, if the conformational transition happens on a submillisecond time scale, the protein can efficiently search for its cognate site.…”

Section: Discussionmentioning

confidence: 99%

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A single-molecule characterization of p53 search on DNA

Tafvizi

Huang

Fersht

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

226

301

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The tumor suppressor p53 slides along DNA while searching for its cognate site. Central to this process is the basic C-terminal domain, whose regulatory role and its coordination with the core DNAbinding domain is highly debated. Here we use single-molecule techniques to characterize the search process and disentangle the roles played by these two DNA-binding domains in the search process. We demonstrate that the C-terminal domain is capable of rapid translocation, while the core domain is unable to slide and instead hops along DNA. These findings are integrated into a model, in which the C-terminal domain mediates fast sliding of p53, while the core domain samples DNA by frequent dissociation and reassociation, allowing for rapid scanning of long DNA regions. The model further proposes how modifications of the C-terminal domain can activate "latent" p53 and reconciles seemingly contradictory data on the action of different domains and their coordination.recognition | response element | transcription factor

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Section: Discussionmentioning

confidence: 99%

“…Finally, we are able to relate our single-molecule measurements to published in vivo fluorescence recovery studies (22,23) and p53 copy-number measurements (25) to calculate the time it takes p53 to find a specific site (e.g., p21) on DNA (see SI Text).…”

Section: Discussionmentioning

confidence: 99%

A single-molecule characterization of p53 search on DNA

Tafvizi

Huang

Fersht

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

226

301

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“…Despite this fact, the diffusion constants were at least an order of magnitude smaller than those in our study. It is known, however, that when using FRAP it is very difficult to correctly account for restriction of the movement because of interactions (23). In addition, it is not straightforward to analyze mRNP mobility by FRAP if small fluorescent ligands are used to tag the particles, because the ongoing exchange of bound and free labels leads to complex recovery kinetics (24).…”

Section: µMmentioning

confidence: 99%

Discontinuous movement of mRNP particles in nucleoplasmic regions devoid of chromatin

Siebrasse

Veith

Dobay

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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Messenger ribonucleoprotein particles (mRNPs) move randomly within nucleoplasm before they exit from the nucleus. To further understand mRNP trafficking, we have studied the intranuclear movement of a specific mRNP, the BR2 mRNP, in salivary gland cells in Chironomus tentans. Their polytene nuclei harbor giant chromosomes separated by vast regions of nucleoplasm, which allows us to study mRNP mobility without interference of chromatin. The particles were fluorescently labeled with microinjected oligonucleotides (DNA or RNA) complementary to BR2 mRNA or with the RNA-binding protein hrp36, the C. tentans homologue of hnRNP A1. Using high-speed laser microscopy, we followed the intranuclear trajectories of single mRNPs and characterized their motion within the nucleoplasm. The Balbiani ring (BR) mRNPs moved randomly, but unexpectedly, in a discontinuous manner. When mobile, they diffused with a diffusion coefficient corresponding to their size. Between mobile phases, the mRNPs were slowed down 10-to 250-fold but were never completely immobile. Earlier electron microscopy work has indicated that BR particles can attach to thin nonchromatin fibers, which are sometimes connected to discrete fibrogranular clusters. We propose that the observed discontinuous movement reflects transient interactions between freely diffusing BR particles and these submicroscopic structures.Balbiani ring particles ͉ in vivo labeling ͉ mRNP trafficking ͉ single-molecule fluorescence microscopy ͉ single-particle tracking C oncomitant with transcription, the growing premessenger RNA (pre-mRNA) molecules become associated with proteins to form ribonucleoprotein (RNP) particles (1). The pre-mRNA is processed to mRNA, and the reorganized messenger RNP (mRNP) particles are prepared for export (2, 3). After being released from the gene, mRNP particles move randomly within the nucleus, apparently by free diffusion (4). However, the mobility can be affected by energy depletion, which suggests that ATP-dependent processes also play a role (5). Recently, it became feasible to track individual mRNP particles in the nucleoplasm (6, 7). It could then be confirmed that the particles move by free diffusion, but the diffusion is often spatially constrained. mRNPs travel in interchromatin channels (8, 9), and the movement of mRNPs is probably hindered in tight channels and even stalled in cavities formed by chromatin. In the single-particle-tracking experiments, ATP depletion showed no effect on the individual, still-mobile mRNPs but further constrained the movement of the particles, probably because of a more condensed organization of the chromatin (6, 7). To further study the movement of mRNPs, we have now chosen an experimental system that allows us to follow the movement of individual mRNPs in large nucleoplasmic regions lacking chromatin, and thus we avoid the complex influence of chromatin. Surprisingly, we then find that the mRNP particles move in a discontinuous fashion, suggesting that the particles transiently interact with supramolecular assemblie...

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“…The role of the N-terminal domain is unknown and is proposed to be involved in proper positioning and anchoring of the globular domain onto chromatin. FRAP 2 is a powerful system for measuring protein dynamics in living cells (31,32). However, it does not account for biological and experimental variations leading to discrepancies in quantitative interexperimental conclusions and is prone to several drawbacks that can lead to faulty inferences (33).…”

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confidence: 99%

N- and C-terminal Domains Determine Differential Nucleosomal Binding Geometry and Affinity of Linker Histone Isotypes H10 and H1c

Vyas

Brown

2012

Journal of Biological Chemistry

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Background: Linker histones are functionally heterogeneous. Results: Using a novel FRAP approach, the N-terminal domain modulates binding affinities of H1 0 and H1c; the C-terminal domain influences the nucleosomal orientation of the globular domain. Conclusion:The variable terminal domains have distinct roles in the chromatin binding characteristics of linker histones. Significance: Evidence for a structural basis for the functional heterogeneity of linker histones is presented.

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Evidence for a Common Mode of Transcription Factor Interaction with Chromatin as Revealed by Improved Quantitative Fluorescence Recovery after Photobleaching

Cited by 158 publications

References 29 publications

A single-molecule characterization of p53 search on DNA

A single-molecule characterization of p53 search on DNA

Discontinuous movement of mRNP particles in nucleoplasmic regions devoid of chromatin

N- and C-terminal Domains Determine Differential Nucleosomal Binding Geometry and Affinity of Linker Histone Isotypes H10 and H1c

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