The human telomeric protein hTRF1 induces telomere-specific nucleosome mobility (original) (raw)
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Telomeric Nucleosomes Are Intrinsically Mobile
Journal of Molecular Biology, 2007
Nucleosomes are no longer considered only static basic units that package eukaryotic DNA but they emerge as dynamic players in all chromosomal processes. Regulatory proteins can gain access to recognition sequences hidden by the histone octamer through the action of ATP-dependent chromatin remodeling complexes that cause nucleosome sliding. In addition, it is known that nucleosomes are able to spontaneously reposition along the DNA due to intrinsic dynamic properties, but it is not clear yet to what extent sequence-dependent dynamic properties contribute to nucleosome repositioning. Here, we study mobility of nucleosomes formed on telomeric sequences as a function of temperature and ionic strength. We find that telomeric nucleosomes are highly intrinsically mobile under physiological conditions, whereas nucleosomes formed on an average DNA sequence mostly remain in the initial position. This indicates that DNA sequence affects not only the thermodynamic stability and the positioning of nucleosomes but also their dynamic properties. Moreover, our findings suggest that the high mobility of telomeric nucleosomes may be relevant to the dynamics of telomeric chromatin.
The columnar structure of human telomeric chromatin suggests mechanisms for telomere maintenance
Telomeres, the ends of eukaryotic chromosomes, play pivotal roles in ageing and cancer and are targets of DNA damage and response. However, little is known about the structure and organization of telomeric chromatin at the molecular level. We used electron microscopy and single-molecule magnetic tweezers to characterize well-defined telomeric chromatin fibers of kilobasepair length. The cryo-EM structure of the compact telomeric tetranucleosome revealed a novel columnar folding, unusually short nucleosome repeat length of ∼132bp and the role of the histone N-terminal tails in stabilizing this structure. This is the first near-high resolution structure of chromatin with a native DNA sequence. The columnar structure exposes the DNA, making them susceptible to DNA damage. The telomeric tetranucleosome also exists in an alternative well-defined state, with one nucleosome open, accessible to protein factors. This suggests that protein factors, which plays a role in maintaining telomeres,...
TRF1 and TRF2 binding to telomeres is modulated by nucleosomal organization
Nucleic Acids Research, 2015
The ends of eukaryotic chromosomes need to be protected from the activation of a DNA damage response that leads the cell to replicative senescence or apoptosis. In mammals, protection is accomplished by a six-factor complex named shelterin, which organizes the terminal TTAGGG repeats in a still ill-defined structure, the telomere. The stable interaction of shelterin with telomeres mainly depends on the binding of two of its components, TRF1 and TRF2, to double-stranded telomeric repeats. Tethering of TRF proteins to telomeres occurs in a chromatin environment characterized by a very compact nucleosomal organization. In this work we show that binding of TRF1 and TRF2 to telomeric sequences is modulated by the histone octamer. By means of in vitro models, we found that TRF2 binding is strongly hampered by the presence of telomeric nucleosomes, whereas TRF1 binds efficiently to telomeric DNA in a nucleosomal context and is able to remodel telomeric nucleosomal arrays. Our results indicate that the different behavior of TRF proteins partly depends on the interaction with histone tails of their divergent N-terminal domains. We propose that the interplay between the histone octamer and TRF proteins plays a role in the steps leading to telomere deprotection.
The Telomere Binding Protein TRF2 Induces Chromatin Compaction
PLOS One, 2011
Mammalian telomeres are specialized chromatin structures that require the telomere binding protein, TRF2, for maintaining chromosome stability. In addition to its ability to modulate DNA repair activities, TRF2 also has direct effects on DNA structure and topology. Given that mammalian telomeric chromatin includes nucleosomes, we investigated the effect of this protein on chromatin structure. TRF2 bound to reconstituted telomeric nucleosomal fibers through both its basic Nterminus and its C-terminal DNA binding domain. Analytical agarose gel electrophoresis (AAGE) studies showed that TRF2 promoted the folding of nucleosomal arrays into more compact structures by neutralizing negative surface charge. A construct containing the N-terminal and TRFH domains together altered the charge and radius of nucleosomal arrays similarly to full-length TRF2 suggesting that TRF2-driven changes in global chromatin structure were largely due to these regions. However, the most compact chromatin structures were induced by the isolated basic N-terminal region, as judged by both AAGE and atomic force microscopy. Although the N-terminal region condensed nucleosomal array fibers, the TRFH domain, known to alter DNA topology, was required for stimulation of a strand invasion-like reaction with nucleosomal arrays. Optimal strand invasion also required the C-terminal DNA binding domain. Furthermore, the reaction was not stimulated on linear histone-free DNA. Our data suggest that nucleosomal chromatin has the ability to facilitate this activity of TRF2 which is thought to be involved in stabilizing looped telomere structures.
The Myb/SANT domain of the telomere-binding protein TRF2 alters chromatin structure
Nucleic Acids Research, 2009
Eukaryotic DNA is packaged into chromatin, which regulates genome activities such as telomere maintenance. This study focuses on the interactions of a myb/SANT DNA-binding domain from the telomere-binding protein, TRF2, with reconstituted telomeric nucleosomal array fibers. Biophysical characteristics of the factor-bound nucleosomal arrays were determined by analytical agarose gel electrophoresis (AAGE) and single molecules were visualized by atomic force microscopy (AFM). The TRF2 DNA-binding domain (TRF2 DBD) neutralized more negative charge on the surface of nucleosomal arrays than histone-free DNA. Binding of TRF2 DBD at lower concentrations increased the radius and conformational flexibility, suggesting a distortion of the fiber structure. Additional loading of TRF2 DBD onto the nucleosomal arrays reduced the flexibility and strongly blocked access of micrococcal nuclease as contour lengths shortened, consistent with formation of a unique, more compact higher-order structure. Mirroring the structural results, TRF2 DBD stimulated a strand invasionlike reaction, associated with telomeric t-loops, at lower concentrations while inhibiting the reaction at higher concentrations. Full-length TRF2 was even more effective at stimulating this reaction. The TRF2 DBD had less effect on histone-free DNA structure and did not stimulate the t-loop reaction with this substrate, highlighting the influence of chromatin structure on the activities of DNA-binding proteins.
Columnar structure of human telomeric chromatin
Nature
Telomeres, the ends of eukaryotic chromosomes, play pivotal roles in ageing and cancer and are targets of DNA damage and response. However, little is known about the structure and organization of telomeric chromatin at the molecular level. We used electron microscopy and single-molecule magnetic tweezers to characterize well-defined telomeric chromatin fibers of kilobasepair length. The cryo-EM structure of the compact telomeric tetranucleosome revealed a novel columnar folding, unusually short nucleosome repeat length of ~132bp and the role of the histone N-terminal tails in stabilizing this structure. This is the first near-high resolution structure of chromatin with a native DNA sequence. The columnar structure exposes the DNA, making them susceptible to DNA damage. The telomeric tetranucleosome also exists in an alternative well-defined state, with one nucleosome open, accessible to protein factors. This suggests that protein factors, which plays a role in maintaining telomeres, can bind to telomeric chromatin in its compact heterochromatic form. The features of the telomeric chromatin structure reveals important insights of significant relevance for telomere function in vivo that provides information on mechanisms of nucleosome recognition by chromatin factors (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
A beginning of the end: new insights into the functional organization of telomeres
Nucleus, 2015
E ver since the first demonstration of their repetitive sequence and unique replication pathway, telomeres have beguiled researchers with how they function in protecting chromosome ends. Of course much has been learned over the years, and we now appreciate that telomeres are comprised of the multimeric protein/DNA shelterin complex and that the formation of t-loops provides protection from DNA damage machinery. Deriving their name from D-loops, t-loops are generated by the insertion of the 3 0 overhang into telomeric repeats facilitated by the binding of TRF2. Recent studies have uncovered novel forms of chromosome end-structure that may implicate telomere organization in cellular processes beyond its essential role in telomere protection and homeostasis. In particular, we have recently described that t-loops form in a TRF2dependent manner at interstitial telomere repeat sequences, which we termed interstitial telomere loops (ITLs). These structures are also dependent on association of lamin A/C, a canonical component of the nucleoskeleton that is mutated in myriad human diseases, including human segmental progeroid syndromes. Since ITLs are associated with telomere stability and require functional lamin A/C, our study suggests a mechanistic link between cellular aging (replicative senescence induced by telomere shortening) and organismal aging (modeled by Hutchinson Gilford Progeria Syndrome). Here we speculate on other potential ramifications of ITL formation, from gene expression to genome stability to chromosome structure.
Cytometry Part A, 2009
Telomeres are complex end structures that confer functional integrity and positional stability to human chromosomes. Despite their critical importance, there is no clear view on telomere organization in cycling human cells and their dynamic behavior throughout the cell cycle. We investigated spatiotemporal organization of telomeres in living human ECV-304 cells stably expressing telomere binding proteins TRF1 and TRF2 fused to mCitrine using four dimensional microscopy. We thereby made use of controlled light exposure microscopy (CLEM), a novel technology that strongly reduces photodamage by limiting excitation in parts of the image where full exposure is not needed. We found that telomeres share small territories where they dynamically associate. These territories are preferentially positioned at the interface of chromatin domains. TRF1 and TRF2 are abundantly present in these territories but not firmly bound. At the onset of mitosis, the bulk of TRF protein dissociates from telomere regions, territories disintegrate and individual telomeres become faintly visible. The combination of stable cell lines, CLEM and cytometry proved essential in providing novel insights in compartment-based nuclear organization and may serve as a model approach for investigating telomere-driven genome-instability and studying long-term nuclear dynamics. ' 2008 International Society for Advancement of Cytometry Key terms telomere; TRF1; TRF2; nuclear organization; chromatin dynamics; CLEM; live cell imaging TELOMERES are the natural ends of linear chromosomes. A mammalian telomere consists of a double stranded array of simple TTAGGG repeats ending in a single stranded overhang that folds back to form a T-loop structure (1). In combination with sufficient telomere repeats, a complex of indirect and direct telomere binding proteins, dubbed shelterin, assures proper telomere structure and function. The specificity of shelterin for telomeric DNA is due to the recognition of TTAGGG repeats by three of its components: the homodimers telomeric repeat binding factor 1 and 2 (TRF1 and TRF2) that bind the duplex part of telomeres, and protection of telomeres 1 that binds to the single stranded TTAGGG repeats present at the three-overhang and in the D loop of the T-loop configuration (2-5).
Unraveling secrets of telomeres: One molecule at a time
DNA Repair, 2014
Telomeres play important roles in maintaining the stability of linear chromosomes. Telomere maintenance involves dynamic actions of multiple proteins interacting with long repetitive sequences and complex dynamic DNA structures, such as G-quadruplexes, T-loops and t-circles. Given the heterogeneity and complexity of telomeres, single-molecule approaches are essential to fully understand the structure-function relationships that govern telomere maintenance. In this review, we present a brief overview of the principles of single-molecule imaging and manipulation techniques. We then highlight results obtained from applying these single-molecule techniques for studying structure, dynamics and functions of G-quadruplexes, telomerase, and shelterin proteins.
Nucleolar Localization of hTERT Protein Is Associated with Telomerase Function
Experimental Cell Research, 2002
Although there are also other associated proteins in this complex, the catalytic activity of this complex is composed of two components. One is a reverse transcriptase subunit, TERT (telomerase reverse transcriptase); another is an RNA template subunit, TR (telomerase RNA). However, where these two parts are assembled in mammalian cells is unclear. In the present study, we investigated the intracellular distribution of human TERT (hTERT) protein and observed that hTERT protein in individual cells could concentrate in or be excluded from the nucleolus. Further we have identified a nucleolar targeting signal in the hTERT protein. Point mutations that disrupted this signal region interrupted telomerase RNP complex formation, decreased telomerase activity, and caused telomere shortening in cells transfected with mutated hTERT. Our results indicate that the amino acid sequence of the extreme N-terminus (1-15) of hTERT, which targets nucleolar localization of the protein, is required for full telomerase function. © 2002 Elsevier Science (USA)