Characterization and developmental expression of single-stranded telomeric DNA-binding proteins from mung bean (Vigna radiata)

We have identified and characterized protein factors from mung bean (Vigna radiata) nuclear extracts that specifically bind the single-stranded G-rich telomeric DNA repeats. Nuclear extracts were prepared from three different types of plant tissue, radicle, hypocotyl, and root, in order to examine changes in the expression patterns of telomere-binding proteins during the development of mung bean. At least three types of specific complexes (A, B, and C) were detected by gel retardation assays with synthetic telomere and nuclear extract from radicle tissue, whereas the two major faster-migrating complexes (A and B) were formed with nuclear extracts from hypocotyl and root tissues. Gel retardation assays also revealed differences in relative amount of each complex forming activity in radicle, hypocotyl, and root nuclear extracts. These data suggest that the expression of telomere-binding proteins is developmentally regulated in plants, and that the factor involved in the formation of complex C may be required during the early stages of development. The binding factors have properties of proteins and are hence designated as mung bean G-rich telomere-binding proteins (MGBP). MGBPs bind DNA substrates with three or more single-stranded TTTAGGG repeats, while none of them show binding affinity to either double-stranded or single-stranded C-rich telomeric DNA. These proteins have a lower affinity to human telomeric sequences than to plant telomeric sequences and do not exhibit a significant binding activity to Tetrahymena telomeric sequence or mutated plant telomeric sequences, indicating that their binding activities are specific to plant telomere. Furthermore, RNase treatment of the nuclear extracts did not affect the complex formation activities. This result indicates that the single-stranded telomere-binding activities may be attributed to a simple protein but not a ribonucleoprotein. The ability of MGBPs to bind specifically the single-stranded TTTAGGG repeats may suggest their in vivo functions in the chromosome ends of plants.     

HOT1 is a mammalian direct telomere repeat‐binding protein contributing to telomerase recruitment

Telomeres are repetitive DNA structures that, together with the shelterin and the CST complex, protect the ends of chromosomes. Telomere shortening is mitigated in stem and cancer cells through the de novo addition of telomeric repeats by telomerase. Telomere elongation requires the delivery of the telomerase complex to telomeres through a not yet fully understood mechanism. Factors promoting telomerase–telomere interaction are expected to directly bind telomeres and physically interact with the telomerase complex. In search for such a factor we carried out a SILAC‐based DNA–protein interaction screen and identified HMBOX1, hereafter referred to as homeobox telomere‐binding protein 1 (HOT1). HOT1 directly and specifically binds double‐stranded telomere repeats, with the in vivo association correlating with binding to actively processed telomeres. Depletion and overexpression experiments classify HOT1 as a positive regulator of telomere length. Furthermore, immunoprecipitation and cell fractionation analyses show that HOT1 associates with the active telomerase complex and promotes chromatin association of telomerase. Collectively, these findings suggest that HOT1 supports telomerase‐dependent telomere elongation.     

Structure, subnuclear distribution, and nuclear matrix association of the mammalian telomeric complex

Mammalian telomeres are composed of long arrays of TTAGGG repeats complexed with the TTAGGG repeat binding factor, TRF. Biochemical and ultrastructural data presented here show that the telomeric DNA and TRF colocalize in individual, condensed structures in the nuclear matrix. Telomeric TTAGGG repeats were found to carry an array of nuclear matrix attachment sites occurring at a frequency of at least one per kb. The nuclear matrix association of the telomeric arrays extended over large domains of up to 20-30 kb, encompassing the entire length of most mammalian telomeres. TRF protein and telomeric DNA cofractionated in nuclear matrix preparations and colocalized in discrete, condensed sites throughout the nuclear volume. FISH analysis indicated that TRF is an integral component of the telomeric complex and that the presence of TRF on telomeric DNA correlates with the compact configuration of telomeres and their association with the nuclear matrix. Biochemical fractionation of TRF and telomeric DNA did not reveal an interaction with the nuclear lamina. Furthermore, ultrastructural analysis indicated that the mammalian telomeric complex occupied sites throughout the nuclear volume, arguing against a role for the nuclear envelope in telomere function during interphase. These results are consistent with the view that mammalian telomeres form nuclear matrix- associated, TRF-containing higher order complexes at dispersed sites throughout the nuclear volume.     

Single molecule studies of physiologically relevant telomeric tails reveal POT1 mechanism for promoting G-quadruplex unfolding

Human telomeres are composed of duplex TTAGGG repeats and a 3' single-stranded DNA tail. The telomeric DNA is protected and regulated by the shelterin proteins, including the protection of telomeres 1 (POT1) protein that binds telomeric single-stranded DNA. The single-stranded tail can fold into G-quadruplex (G4) DNA. Both POT1 and G4 DNA play important roles in regulating telomere length homeostasis. To date, most studies have focused on individual quadruplexes formed by four TTAGGG repeats. Telomeric tails in human cells have on average six times as many repeats, and no structural studies have examined POT1 binding in competition with G4 DNA folding. Using single molecule atomic force microscopy imaging, we observed that the majority of the telomeric tails of 16 repeats formed two quadruplexes even though four were possible. The result that physiological telomeric tails rarely form the maximum potential number of G4 units provides a structural basis for the coexistence of G4 and POT1 on the same DNA molecule, which is observed directly in the captured atomic force microscopy images. We further observed that POT1 is significantly more effective in disrupting quadruplex DNA on long telomeric tails than an antisense oligonucleotide, indicating a novel POT1 activity beyond simply preventing quadruplex folding.     

hnRNP A2/B1 binds specifically to single stranded vertebrate telomeric repeat TTAGGGn.

We have previously isolated a protein from mouse liver nuclei that specifically binds to single stranded (TTAGGG)n repeats. TTAGGG is the telomeric repeats of mammals and we therefore named the new protein single stranded telomere binding protein (sTBP). Further studies now identify sTBP as heterogeneous nuclear ribonucleoprotein (hnRNP) A2/B1 on the basis of amino acid sequence determination and antibody reactivity. A2 and B1 form a major part of the protein component of hnRNP particles and are abundant nuclear proteins. Unexpectedly, A2/B1 has a high specificity for binding to the RNA equivalent of TTAGGG, UUAGGG, but under the same conditions does not appear to have a strong affinity for a number of other RNA species.     

The yeast telomere-binding protein RAP1 binds to and promotes the formation of DNA quadruplexes in telomeric DNA.

The protein RAP1 is essential for the maintenance of the telomeres of Saccharomyces cerevisiae and binds in vitro to multiple sites found within the TG1-3 telomeric repeats. We show here that, in addition to its known binding activity for double-stranded DNA, RAP1 binds sequence-specifically to the GT-strands. This indicates that RAP1 is the protein that binds to the telomeric terminal GT-tails. Furthermore, we have found that RAP1 binds to and promotes the formation of G-tetrads, i.e. DNA quadruplexes, in GT-strand oligonucleotides at nanomolar concentrations. The formation of DNA quadruplexes appears to involve the intermolecular association of GT-strands. The minimal DNA-binding domain of RAP1 (DBD) binds only to double-stranded DNA, so that the novel DNA-binding activity we have found involves regions of the protein located outside of the DBD. The finding that a telomeric protein promotes the formation of G-tetrads argues for the use of DNA quadruplexes in telomere association.     

Specific association of a small protein with the telomeric DNA-protein complex during the onset of leaf senescence in Arabidopsis thaliana

Telomeres and their changes in length throughout the life span of cells have been intensively investigated in different organisms. Telomere length is assumed to control replicative senescence in mammalian cells. However, only very few data are available on the developmental dynamics of plant telomeres. Here, changes of telomere length and DNA-protein structure of Arabidopsis thaliana telomeres were analysed in different stages of development, with the main focus resting on the transition from pre-senescent to senescent leaves. The lengths of the telomeres, ranging from ca. 2.0 to 6.5 kb, do not significantly change during plant development indicating that telomere length is not involved in differentiation and replicative senescence nor in post-mitotic senescence of A. thaliana. In dedifferentiated cultured cells a slight increase in length can be determined. The nucleoprotein structure of the telomeric DNA was investigated by gel mobility shift assays, with synthetic oligonucleotides and nuclear protein extracts derived from four defined stages of post-mitotic leaf senescence. In all four stages, a highly salt-resistant DNA-protein complex was formed with the double-stranded as well as with the single-stranded G-rich telomeric DNA. An additional DNA-protein complex was identified in nuclear protein extracts isolated from plants in the transition stage from pre-senescence to senescence. The protein components of the DNA-protein complexes were analysed on native PAGE and SDS-PAGE gels. A protein of 67 kDa (ATBP1) bound to the telomeric DNA in all developmental stages. An additional protein of merely 22 kDa (ATBP2) was associated via protein-protein interaction with ATBP1 to form a higher-order complex exclusively during the onset of senescence. DNA interaction of this higher-order protein complex seems to be restricted to double-stranded telomeric DNA. The defined period of ATBP1/ATBP2 complex formation with the telomeric DNA probably indicates that ATBP2 is involved in the onset of post-mitotic leaf senescence by either disturbing an established or establishing an additional function exhibited by the telomeres in the interphase nuclei.     

POT1-independent single-strand telomeric DNA binding activities in Brassicaceae

Telomeres define the ends of linear eukaryotic chromosomes and are required for genome maintenance and continued cell proliferation. The extreme ends of telomeres terminate in a single-strand protrusion, termed the G-overhang, which, in vertebrates and fission yeast, is bound by evolutionarily conserved members of the POT1 (protection of telomeres) protein family. Unlike most other model organisms, the flowering plant Arabidopsis thaliana encodes two divergent POT1-like proteins. Here we show that the single-strand telomeric DNA binding activity present in A. thaliana nuclear extracts is not dependent on POT1a or POT1b proteins. Furthermore, in contrast to POT1 proteins from yeast and vertebrates, recombinant POT1a and POT1b proteins from A. thaliana , and from two additional Brassicaceae species, Arabidopsis lyrata and Brassica oleracea (cauliflower), fail to bind single-strand telomeric DNA in vitro under the conditions tested. Finally, although we detected four single-strand telomeric DNA binding activities in nuclear extracts from B. oleracea , partial purification and DNA cross-linking analysis of these complexes identified proteins that are smaller than the predicted sizes of BoPOT1a or BoPOT1b. Taken together, these data suggest that POT1 proteins are not the major single-strand telomeric DNA binding activities in A. thaliana and its close relatives, underscoring the remarkable functional divergence of POT1 proteins from plants and other eukaryotes.     

Distinct functions of POT1 at telomeres

The mammalian protein POT1 binds to telomeric single-stranded DNA (ssDNA), protecting chromosome ends from being detected as sites of DNA damage. POT1 is composed of an N-terminal ssDNA-binding domain and a C-terminal protein interaction domain. With regard to the latter, POT1 heterodimerizes with the protein TPP1 to foster binding to telomeric ssDNA in vitro and binds the telomeric double-stranded-DNA-binding protein TRF2. We sought to determine which of these functions-ssDNA, TPP1, or TRF2 binding-was required to protect chromosome ends from being detected as DNA damage. Using separation-of-function POT1 mutants deficient in one of these three activities, we found that binding to TRF2 is dispensable for protecting telomeres but fosters robust loading of POT1 onto telomeric chromatin. Furthermore, we found that the telomeric ssDNA-binding activity and binding to TPP1 are required in cis for POT1 to protect telomeres. Mechanistically, binding of POT1 to telomeric ssDNA and association with TPP1 inhibit the localization of RPA, which can function as a DNA damage sensor, to telomeres.     

The telobox, a Myb-related telomeric DNA binding motif found in proteins from yeast, plants and human.

The yeast TTAGGG binding factor 1 (Tbf1) was identified and cloned through its ability to interact with vertebrate telomeric repeats in vitro. We show here that a sequence of 60 amino acids located in its C-terminus is critical for DNA binding. This sequence exhibits homologies with Myb repeats and is conserved among five proteins from plants, two of which are known to bind telomeric-related sequences, and two proteins from human, including the telomeric repeat binding factor (TRF) and the predicted C-terminal polypeptide, called orf2, from a yet unknown protein. We demonstrate that the 111 C-terminal residues of TRF and the 64 orf2 residues are able to bind the human telomeric repeats specifically. We propose to call the particular Myb-related motif found in these proteins the 'telobox'. Antibodies directed against the Tbf1 telobox detect two proteins in nuclear and mitotic chromosome extracts from human cell lines. Moreover, both proteins bind specifically to telomeric repeats in vitro. TRF is likely to correspond to one of them. Based on their high affinity for the telomeric repeat, we predict that TRF and orf2 play an important role at human telomeres.     

Origin-dependent initiation of DNA replication within telomeric sequences

Replication of telomeres requires the action of telomerase, the semi-conservative replication machinery and the stabilization of the replication fork during passage through telomeric DNA. Whether vertebrate telomeres support initiation of replication has not been experimentally addressed. Using Xenopus cell free extracts we established a system to study replication initiation within linear telomeric DNA substrates. We show binding of TRF2 to telomeric DNA, indicating that exogenous DNA exclusively composed of telomeric repeats is recognized by shelterin components. Interaction with telomere binding proteins is not sufficient to prevent a DNA damage response. Notably, we observe regulated assembly of the pre-replicative complex proteins ORC2, MCM6 and Cdc6 to telomeric DNA. Most importantly, we detect origin-dependent replication of telomeric substrates under conditions that inhibit checkpoint activation. These results indicate that pre-replicative complexes assemble within telomeric DNA and can be converted into functional origins.     

DNA-induced dimerization of the single-stranded DNA binding telomeric protein Pot1 from Schizosaccharomyces pombe

Eukaryotic chromosome ends are protected from illicit DNA joining by protein-DNA complexes called telomeres. In most studied organisms, telomeric DNA is composed of multiple short G-rich repeats that end in a single-stranded tail that is protected by the protein POT1. Mammalian POT1 binds two telomeric repeats as a monomer in a sequence-specific manner, and discriminates against RNA of telomeric sequence. While addressing the RNA discrimination properties of SpPot1, the POT1 homolog in Schizosaccharomyces pombe, we found an unanticipated ssDNA-binding mode in which two SpPot1 molecules bind an oligonucleotide containing two telomeric repeats. DNA binding seems to be achieved via binding of the most N-terminal OB domain of each monomer to each telomeric repeat. The SpPot1 dimer may have evolved to accommodate the heterogeneous spacers that occur between S. pombe telomeric repeats, and it also has implications for telomere architecture. We further show that the S. pombe telomeric protein Tpz1, like its mammalian homolog TPP1, increases the affinity of Pot1 for telomeric single-stranded DNA and enhances the discrimination of Pot1 against RNA.     

Rice proteins that bind single-stranded G-rich telomere DNA

In this work, we have identified and characterized proteins in rice nuclear extracts that specifically bind the single-stranded G-rich telomere sequence. Three types of specific DNA-protein complexes (I, II, and III) were identified by gel retardation assays using synthetic telomere substrates consisting of two or more single-stranded TTTAGGG repeats and rice nuclear extracts. Since each complex has a unique biochemical property and differs in electrophoretic mobility, at least three different proteins interact with the G-rich telomere sequences. These proteins are called rice G-rich telomere binding protein (RGBP) and none of them show binding affinity to double-stranded telomere repeats or single-stranded C-rich sequence. Changing one or two G's to C's in the TTTAGGG repeats abolishes binding activity. RGBPs have a greatly reduced affinity for human and Tetrahymena telomeric sequence and do not efficiently bind the cognate G-rich telomere RNA sequence UUUAGGG. Like other telomere binding proteins, RGBPs are resistant to high salt concentrations. RNase sensitivity of the DNA-protein interactions was tested to investigate whether an RNA component mediates the telomeric DNA-protein interaction. In this assay, we observed a novel complex (complex III) in gel retardation assays which did not alter the mobilities or the band intensities of the two pre-existing complexes (I and II). The complex III, in addition to binding to telomeric sequences, has a binding affinity to rice nuclear RNA, whereas two other complexes have a binding affinity to only single-stranded G-rich telomere DNA. Taken together, these studies suggest that RGBPs are new types of telomere-binding proteins that bind in vitro to single-stranded G-rich telomere DNA in the angiosperms.     

Comparison between TRF2 and TRF1 of their telomeric DNA-bound structures and DNA-binding activities

Mammalian telomeres consist of long tandem arrays of double-stranded telomeric TTAGGG repeats packaged by the telomeric DNA-binding proteins TRF1 and TRF2. Both contain a similar C-terminal Myb domain that mediates sequence-specific binding to telomeric DNA. In a DNA complex of TRF1, only the single Myb-like domain consisting of three helices can bind specifically to double-stranded telomeric DNA. TRF2 also binds to double-stranded telomeric DNA. Although the DNA binding mode of TRF2 is likely identical to that of TRF1, TRF2 plays an important role in the t-loop formation that protects the ends of telomeres. Here, to clarify the details of the double-stranded telomeric DNA-binding modes of TRF1 and TRF2, we determined the solution structure of the DNA-binding domain of human TRF2 bound to telomeric DNA; it consists of three helices, and like TRF1, the third helix recognizes TAGGG sequence in the major groove of DNA with the N-terminal arm locating in the minor groove. However, small but significant differences are observed; in contrast to the minor groove recognition of TRF1, in which an arginine residue recognizes the TT sequence, a lysine residue of TRF2 interacts with the TT part. We examined the telomeric DNA-binding activities of both DNA-binding domains of TRF1 and TRF2 and found that TRF1 binds more strongly than TRF2. Based on the structural differences of both domains, we created several mutants of the DNA-binding domain of TRF2 with stronger binding activities compared to the wild-type TRF2.     

POT1 and TRF2 cooperate to maintain telomeric integrity

Mammalian telomeric DNA contains duplex TTAGGG repeats and single-stranded overhangs. POT1 (protection of telomeres 1) is a telomere-specific single-stranded DNA-binding protein, highly conserved in eukaryotes. The biological function of human POT1 is not well understood. In the present study, we demonstrate that POT1 plays a key role in telomeric end protection. The reduction of POT1 by RNA interference led to the loss of telomeric single-stranded overhangs and induced apoptosis, chromosomal instability, and senescence in cells. POT1 and TRF2 interacted with each other to form a complex with telomeric DNA. A dominant negative TRF2, TRF2(DeltaBDeltaM), bound to POT1 and prevented it from binding to telomeres. POT1 overexpression protected against TRF2(DeltaBDeltaM)-induced loss of telomeric single-stranded overhangs, chromosomal instability, and senescence. These results demonstrate that POT1 and TRF2 share in part in the same pathway for telomere capping and suggest that POT1 binds to the telomeric single-stranded DNA in the D-loop and cooperates with TRF2 in t-loop maintenance.     

A mammalian factor that binds telomeric TTAGGG repeats in vitro.

We have identified a DNA-binding activity with specificity for the TTAGGG repeat arrays found at mammalian telomeres. This factor, called TTAGGG repeat factor (TRF), is present in nuclear extracts of human, mouse, and monkey cells. TRF from HeLa cells was characterized in detail by electrophoretic mobility shift assays. It binds double-stranded TTAGGG repeats in linear and circular DNAs. Single-stranded repeats are not recognized. The optimal site for TRF appears to contain more than six contiguous TTAGGG repeats. Tandem arrays of TAGGG, TTTAGGG, TTTTAGGG, TTGGGG, and TTAGGC repeats do not bind TRF well, indicating that TRF preferentially recognizes the telomeric repeat sequence present at mammalian chromosome ends. The apparent molecular mass of this factor, based on recovery of TRF from sodium dodecyl sulfate-polyacrylamide gels, is approximately 50 kDa. We suggest that TRF binds along the length of mammalian telomeres.     

RPA and POT1

Telomere maintenance in cycling cells relies on both DNA replication and capping by the protein complex shelterin. Two single-stranded DNA (ssDNA)-binding proteins, replication protein A (RPA) and protection of telomere 1 (POT1) play critical roles in DNA replication and telomere capping, respectively. While RPA binds to ssDNA in a non-sequence-specific manner, POT1 specifically recognizes singlestranded TTAGGG telomeric repeats. Loss of POT1 leads to aberrant accumulation of RPA at telomeres and activation of the ataxia telangiectasia and Rad3-related kinase (ATR)-mediated checkpoint response, suggesting that POT1 antagonizes RPA binding to telomeric ssDNA. The requirement for both POT1 and RPA in telomere maintenance and the antagonism between the two proteins raises the important question of how they function in concert on telomeric ssDNA. Two interesting models were proposed by recent studies to explain the regulation of POT1 and RPA at telomeres. Here, we discuss how these models help unravel the coordination, and also the antagonism, between POT1 and RPA during the cell cycle.     

DNA recognition and binding by the Euplotes telomere protein.

The 51-kDa telomere protein from Euplotes crassus binds to the extreme terminus of macronuclear telomeres, generating a very salt-stable telomeric DNA-protein complex. The protein recognizes both the sequence and the structure of the telomeric DNA. To explore how the telomere protein recognizes and binds telomeric DNA, we have examined the DNA-binding specificity of the purified protein using oligonucleotides that mimic natural and mutant versions of Euplotes telomeres. The protein binds very specifically to the 3' terminus of single-stranded oligonucleotides with the sequence (T4G4) > or = 3 T4G2; even slight modifications to this sequence reduce binding dramatically. The protein does not bind oligonucleotides corresponding to the complementary C4A4 strand of the telomere or to double-stranded C4A4.T4G4-containing sequences. Digestion of the telomere protein with trypsin generates an N-terminal protease-resistant fragment of approximately 35 kDa. This 35-kDa peptide appears to comprise the DNA-binding domain of the telomere protein as it retains most of the DNA-binding characteristics of the native 51-kDa protein. For example, the 35-kDa peptide remains bound to telomeric DNA in 2 M KCl. Additionally, the peptide binds well to single-stranded oligonucleotides that have the same sequence as the T4G4 strand of native telomeres but binds very poorly to mutant telomeric DNA sequences and double-stranded telomeric DNA. Removal of the C-terminal 15 kDa from the telomere protein does diminish the ability of the protein to bind only to the terminus of a telomeric DNA molecule.