Arrangements of human telomere DNA quadruplex in physiologically relevant K+ solutions

The arrangement of the human telomeric quadruplex in physiologically relevant conditions has not yet been unambiguously determined. Our spectroscopic results suggest that the core quadruplex sequence G₃(TTAG₃)₃ forms an antiparallel quadruplex of the same basket type in solution containing either K⁺ or Na⁺ ions. Analogous sequences extended by flanking nucleotides form a mixture of the antiparallel and hybrid (3 + 1) quadruplexes in K⁺-containing solutions. We, however, show that long telomeric DNA behaves in the same way as the basic G₃(TTAG₃)₃ motif. Both G₃(TTAG₃)₃ and long telomeric DNA are also able to adopt the (3 + 1) quadruplex structure: Molecular crowding conditions, simulated here by ethanol, induced a slow transition of the K⁺-stabilized quadruplex into the hybrid quadruplex structure and then into a parallel quadruplex arrangement at increased temperatures. Most importantly, we demonstrate that the same transitions can be induced even in aqueous, K⁺-containing solution by increasing the DNA concentration. This is why distinct quadruplex structures were detected for AG₃(TTAG₃)₃ by X-ray, nuclear magnetic resonance and circular dichrosim spectroscopy: Depending on DNA concentration, the human telomeric DNA can adopt the antiparallel quadruplex, the (3 + 1) structure, or the parallel quadruplex in physiologically relevant concentrations of K⁺ ions.     

Quadruplexes of human telomere dG3(TTAG3)3 sequences containing guanine abasic sites

This study was performed to evaluate how the loss of a guanine base affects the structure and stability of the three-tetrad G-quadruplex of 5′-dG₃(TTAG₃)₃, the basic quadruplex-forming unit of the human telomere DNA. None of the 12 possible abasic sites hindered the formation of quadruplexes, but all reduced the thermodynamic stability of the parent quadruplex in both NaCl and KCl. The base loss did not change the Na⁺-stabilized intramolecular antiparallel architecture, based on CD spectra, but held up the conformational change induced in dG₃(TTAG₃)₃ in physiological concentration of KCl. The reduced stability and the inhibited conformational transitions observed here in vitro for the first time may predict that unrepaired abasic sites in G-quadruplexes could lead to changes in the chromosome’s terminal protection in vivo.     

Fission yeast telomeric DNA binding protein Pot1 has the ability to unfold tetraplex structure of telomeric DNA

To understand the regulation mechanism of fission yeast telomeric DNA, we analyzed the structural properties of 4Gn: d(G(n)TTAC)(4) (n = 3, 4) and their interaction with the single-stranded telomeric DNA binding domain of telomere-binding protein Pot1 (Pot1DBD). 4G4 adopted only an antiparallel tetraplex in spite of a mixture of parallel and antiparallel tetraplexes of 4G3. The antiparallel tetraplex of 4G4 became unfolded upon the interaction with Pot1DBD. Considering that the antiparallel tetraplex inhibits telomerase-mediated telomere elongation, we conclude that the ability of Pot1 to unfold the antiparallel tetraplex is required for telomerase-mediated telomere regulation.     

Quadruplexes of human telomere DNA analogs designed to contain G:A:G:A,G:G:A:A,and A:A:A:A tetrads

Replacement of two to four guanines by adenines in the human telomere DNA repeat dG₃(TTAG₃)₃ did not hinder the formation of quadruplexes if the substitutions took place in the terminal tetrad bridged by the diagonal loop of the intramolecular antiparallel three‐tetrad scaffold, as proved by CD and PAGE in both Na⁺ and K⁺ solutions. Thermodynamic data showed that, in Na⁺ solution, the dG₃(TTAG₃)₃ quadruplex was destabilized, the least by the two G:A:G:A tetrads, the most by the G:G:A:A tetrad in which the adenosines replaced syn‐guanosines. In physiological K⁺ solution, the highest destabilization was caused by the 4A tetrad. In K⁺, only the unmodified dG₃(TTAG₃)₃ quadruplex rearranged into a K⁺‐dependent quadruplex form, none of the multiple adenine‐modified structures did so. This may imply biological consequences for nonrepaired A‐for‐G mutations. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 880–886, 2010.     

Tetraplex structure of fission yeast telomeric DNA and unfolding of the tetraplex on the interaction with telomeric DNA binding protein Pot1

To understand the regulation mechanism of fission yeast telomeric DNA, we analysed the structural properties of Gn: d(GnTTAC) (n=2-6) and 4Gn: d(GnTTAC)4 (n=3 and 4), and their interaction with the single-stranded telomeric DNA binding domain of telomere-binding protein Pot1 (Pot1DBD). G4, G5 and G6 formed a parallel tetraplex in contrast with no tetraplex formation by G2 and G3. Also, 4G4 adopted only an antiparallel tetraplex in spite of a mixture of parallel and antiparallel tetraplexes of 4G3. The variety of tetraplex structures was governed by the number of consecutive guanines in a single copy and the number of repeats. The antiparallel tetraplex of 4G4 became unfolded upon the interaction with Pot1DBD. The interaction with mutant Pot1DBD proteins revealed that the ability to unfold the antiparallel tetraplex was strongly correlated with the specific binding affinity for the single-stranded telomeric DNA. The result suggests that the decrease in the free single strand upon the complex formation with Pot1DBD may shift the equilibrium from the tetraplex to the single strand, which may cause the tetraplex unfolding. Considering that the antiparallel tetraplex inhibits telomerase-mediated telomere elongation, we conclude that the ability of Pot1 to unfold the antiparallel tetraplex is required for telomerase-mediated telomere regulation.     

Loss of loop adenines alters human telomere d[AG3(TTAG3)3] quadruplex folding

Abasic (AP) lesions are the most frequent type of damages occurring in cellular DNA. Here we describe the conformational effects of AP sites substituted for 2′-deoxyadenosine in the first (ap7), second (ap13) or third (ap19) loop of the quadruplex formed in K⁺ by the human telomere DNA 5′-d[AG₃(TTAG₃)₃]. CD spectra and electrophoresis reveal that the presence of AP sites does not hinder the formation of intramolecular quadruplexes. NMR spectra show that the structural heterogeneity is substantially reduced in ap7 and ap19 as compared to that in the wild-type. These two (ap7 and ap19) sequences are shown to adopt the hybrid-1 and hybrid-2 quadruplex topology, respectively, with AP site located in a propeller-like loop. All three studied sequences transform easily into parallel quadruplex in dehydrating ethanol solution. Thus, the AP site in any loop region facilitates the formation of the propeller loop. Substitution of all adenines by AP sites stabilizes the parallel quadruplex even in the absence of ethanol. Whereas guanines are the major determinants of quadruplex stability, the presence or absence of loop adenines substantially influences quadruplex folding. The naturally occurring adenine-lacking sites in the human telomere DNA can change the quadruplex topology in vivo with potentially vital biological consequences.     

The guanine-rich fragile X chromosome repeats are reluctant to form tetraplexes

Using circular dichroism spectroscopy, UV absorption spectroscopy and polyacrylamide gel electrophoresis, we studied conformational properties of guanine-rich DNA strands of the fragile X chromosome repeats d(GGC)_n, d(GCG)_n and d(CGG)_n, with n = 2, 4, 8 and 16. These strands are generally considered in the literature to form guanine tetraplexes responsible for the repeat expansion. However, we show in this paper that the repeats are reluctant to form tetraplexes. At physiological concentrations of either Na⁺ or K⁺ ions, the hexamers and dodecamers associate to form homoduplexes and the longer repeats generate homoduplexes and hairpins. The tetraplexes are rarely observed being relatively most stable with d(GGC)_n and least stable with d(GCG)_n. The tetraplexes are exclusively formed in the presence of K⁺ ions, at salt concentrations higher than physiological, more easily at higher than physiological temperatures, and they arise with extremely long kinetics (even days). Moreover, the capability to form tetraplexes sharply diminishes with the oligonucleotide length. These facts make the concept of the tetraplex appearance in this motif in vivo very improbable. Rather, a hairpin of the fragile X repeats, whose stability increases with the repeat length, is the probable structure responsible for the repeat expansion in genomes.     

Conformational properties of DNA containing (CCA)n and (TGG)n trinucleotide repeats

We have used CD spectroscopy, polyacrylamide gel electrophoresis, and UV absorption spectroscopy to study conformational properties of DNA fragments containing (CCA)n and (TGG)n repeats, which are the most length-polymorphic microsatellite sequences of the human genome. The (CCA)n fragments are random single strands at neutral and alkaline pH but they fold into intramolecular intercalated cytosine tetraplexes at mildly acid pH values. More acid values stabilize intermolecular tetraplex formation. The behavior of (TGG)n repeats is more complex. They form hairpins or antiparallel homoduplexes in low salt solutions which, however, are transformed into parallel-stranded guanine tetraplexes at physiological KCl concentrations. Their molecularity depends on the repeat number: (TGG)4 associates into an octameric complex, (TGG)8 forms tetramolecular complexes. (TGG)n with odd repeat numbers (5, 7, and 9) generate bimolecular and tetramolecular tetraplexes. The only (TGG)7 folds into an intramolecular tetraplex at low KCl concentrations, which is antiparallel-stranded. Moreover, the (TGG)(n) fragments provide various mutually slipped conformers whose population increases with salt concentration and with the increasing repeat number. However, the self-structures of both strands disappear in the presence of the complementary strand because both (TGG)n and (CCA)n prefer to associate into the classical heteroduplex. We suppose that the extreme conformational variability of the DNA strands stands behind the length polymorphism which the (CCA)n/(TGG)n repeats exhibit in the human genome.     

Tetraplex folding of telomere sequences and the inclusion of adenine bases.

Telomeres are required for eukaryotic chromosome stability. They consist of regularly repeating guanine-rich sequences, with a single-stranded 3' terminus. Such sequences have been demonstrated to have the propensity to adopt four-stranded structures based on a tetrad of guanine bases. The formation of an intramolecular foldback tetraplex is associated with markedly increased mobility in polyacrylamide. Most telomeric sequences are based either on a repeat of d(TnGGGG) or d(TnAGGG) sequences. We have used a combination 7-deazaguanine or 7-deaza-adenine substitution, chemical modification and gel electrophoresis to address the following aspects of intramolecular tetraplex formation. (i) Intramolecular tetraplex formation by d(TTTTGGGG)4 sequences is prevented by very low levels of 7-deazaguanine substitution. This confirms the important role of guanine N7 in the formation of the tetraplex. (ii) The sequences d(TTAGGG)4 and d(TTTTAGGG)4 fold into tetraplexes. By contrast, the electrophoretic behaviour of d(TTTTGGGA)4, d(TTTTAGAG)4 and d(TTTTGAGA)4 does not indicate formation of stable intramolecular tetraplexes under available conditions. (iii) Selective 7-deazaguanine and 7-deaza-adenine substitutions in d(TTTTAGGG)4 give results consistent with tetraplex folding by the formation of three G4 tetrads, with the adenine bases formally part of the single-stranded loops, where they probably interact with thymine bases. These results demonstrate that eukaryotic cells appear to have selected just those sequences that can adopt the tetraplex conformation for their telomeres, while those that cannot have been avoided. This suggests that the conformation may be significant in the function of the telomere, such as attachment to nuclear structures.     

Secondary structure polymorphism in Oxytricha nova telomeric DNA

Tandem repeats of the telomeric DNA sequence d(T₄G₄) of Oxytricha nova are capable of forming unusually stable secondary structures incorporating Hoogsteen hydrogen bonding interactions. The biological significance of such DNA structures is supported by evidence of specific recognition of telomere end-binding proteins in the crystal state. To further characterize structural polymorphism of Oxytricha telomeric DNAs, we have obtained and interpreted Raman, ultraviolet resonance Raman (UVRR) and circular dichroism (CD) spectra of the tandem repeats d(G₄T₄G₄) (Oxy1.5), d(T₄G₄)₂ (Oxy2) and dT₆(T₄G₄)₂ (T6Oxy2) and related non-telomeric isomers in aqueous salt solutions. Raman markers of Oxy1.5 identify both C2′-endo/anti and C2′-endo/syn conformations of the deoxyguanosine residues and Hoogsteen hydrogen bonded guanine quartets, consistent with the quadruplex fold determined previously by solution NMR spectroscopy. Raman, UVRR and CD signatures and Raman dynamic measurements, to monitor imino NH→ND exchanges, show that the Oxy1.5 antiparallel quadruplex fold is distinct from the hairpin structures of Oxy2 and T6Oxy2, single-stranded structures of d(TG)₈ and dT₆(TG)₈ and previously reported quadruplex structures of d(T₄G₄)₄ (Oxy4) and dG₁₂. Spectral markers of the telomeric and telomere-related DNA structures are tabulated and novel Raman and UVRR indicators of thymidine and deoxyguanosine conformations are identified. The results will be useful for probing structures of Oxytricha telomeric repeats in complexes with telomere end-binding proteins.     

The fragile X chromosome (GCC) repeat folds into a DNA tetraplex at neutral pH

UV absorption and CD spectroscopy, along with polyacrylamide gel electrophoresis, were used to study conformational properties of DNA fragments containing the trinucleotide repeat (GCC)_n (n = 4, 8 or 16), whose expansion is correlated with the fragile X chromosome syndrome. We have found that the conformational spectrum of the (GCC)_n strand is wider than has been shown so far. (GCC)_n strands adopt the hairpin described in the literature under a wide range of salt concentrations, but only at alkaline (>7.5) pH values. However, at neutral and slightly acid pH (GCC)₄ and (GCC)₈ strands homodimerize. Our data suggest that the homodimer is a bimolecular tetraplex formed by two parallel-oriented hairpins held together by hemi-protonated intermolecular C·C⁺ pairs. The (GCC)₁₆ strand forms the same tetraplex intramolecularly. We further show that below pH 5 (GCC)_n strands generate intercalated cytosine tetraplexes, whose molecularity depends on DNA strand length. They are tetramolecular with (GCC)₄, bimolecular with (GCC)₈ and monomolecular with (GCC)₁₆. i-Tetraplex formation is a complex and slow process. The neutral tetraplex, on the other hand, arises with fast kinetics under physiological conditions. Thus it is a conformational alternative of the (GCC)_n strand duplex with a complementary (GGC)_n strand.     

Tetraplex Formation of d(GGGGGTTTTT): 1H NMR Study in Solution

Abstract

The oligonucleotide d(G₅T₅) can in principle form a fully matched duplex with G · T pairing and/or a tetraplex. Non-denaturing gel electrophoresis, circular dichroism and NMR experiments show that the tetraplex is exclusively formed by this oligomer in solution. In the presence of its complementary strand d(A₅C₅) at low temperature, d(G₅T₅) forms the tetraplex over the normally expected Watson-Crick duplex. However, when d(G₅T₅) and d(A₅C₅) are mixed together in equimolar amounts and heated for several minutes at 85°C, and then allowed to cool, the product was essentially the Watson-Crick duplex. The lack of resolution in the 500 MHz ¹H NMR spectra and the presence of extensive spin diffusion do not allow us to derive a quantitative structure for the tetraplex from the NMR data. However, we find good qualitative agreement between the NOESY and MINSY data and a theoretically derived stereochemically sound structure in which the G's and T's are part of a parallel tetraplex.     

Guanine tetraplex formation by short DNA fragments containing runs of guanine and cytosine.

Using CD spectroscopy, guanine tetraplex formation was studied with short DNA fragments in which cytosine residues were systematically added to runs of guanine either at the 5' or 3' ends. Potassium cations induced the G-tetraplex more easily with fragments having the guanine run at the 5' end, which is just an opposite tendency to what was reported for (G+T) oligonucleotides. However, the present (G+C) fragments simultaneously adopted other conformers that complicated the analysis. We demonstrate that repeated freezing/thawing, performed at low ionic strength, is a suitable method to exclusively stabilize the tetraplex in the (G+C) DNA fragments. In contrast to KCl, the repeated freeze/thaw cycles better stabilized the tetraplex with fragments having the guanine run on the 3' end. The tendency of guanine blocks to generate the tetraplex destabilized the d(G5).d(C5) duplex whose strands dissociated, giving rise to a stable tetraplex of (dG5) and single-stranded (dC5). In contrast to d(G3C3) and d(G5C5), repeated freezing/thawing induced the tetraplex even with the self-complementary d(C3G3) or d(C5G5); hence the latter oligonucleotides preferred the tetraplex to the apparently very stable duplex. The tetraplexes only included guanine blocks while the 5' end cytosines interfered neither with the tetraplex formation nor the tetraplex structure.     

Circular dichroism spectroscopy of conformers of (guanine + adenine) repeat strands of DNA

(Guanine+adenine) strands of DNA are known to associate into guanine tetraplexes, homodimerize into parallel or antiparallel duplexes, and fold into a cooperatively melting single strand resembling the protein alpha helix. Using CD spectroscopy and other methods, we studied how this conformational polymorphism depended on the primary structure of DNA. The study showed that d(GGGA)(5) and d(GGA)(7) associated into homoduplexes at low salt or in the presence of LiCl but were prone to guanine tetraplex formation, especially in the presence of KCl. In addition, they yielded essentially the same CD spectrum in the presence of ethanol as observed with the ordered single strand of d(GA)(10). Strands of d(GA)(10), d(GGAA)(5), d(GAA)(7), and d(GAAA)(5) associated into homoduplexes in both LiCl and KCl solutions, but not into guanine tetraplexes. d(GAAA)(5) and d(GAA)(7) further failed to form the single-stranded conformer in aqueous ethanol. Adenine protonation, however, stabilized the single-stranded conformer even in these adenine-rich fragments. The ordered single strands, homoduplexes as well as the guanine tetraplexes, all provided strikingly similar CD spectra, indicating that all of the conformers shared similar base stacking geometries. The increasing adenine content only decreased the conformer thermostability.     

Photoisomerizable arylstilbazolium ligands recognize parallel and antiparallel structures of G-quadruplexes

The photoisomerization and DNA interaction studies of three arylstilbazolium derivatives with various samples of nucleic acids (duplexes, triplexes and tetraplexes) are reported. The equilibrium dialysis study revealed high binding affinities of ligands to tetraplex structures. The quadruplex-binding affinity could be switched by light, e.g., the E,E and E,Z isomers of 1,4-bis(vinylquinolinium)benzene (1) interacted with parallel and antiparallel tetraplexes exhibiting different binding selectivity. The E,Z-1 showed higher binding preference for c-myc DNA (a propeller-type quadruplex), whereas the E,E-1 favorably interacted with telomeric DNA (a basket-type quadruplex). The presence of quadruplex DNA hampered photoisomerization of quadruplex-bound ligand.     

46 Effect of guanine substitutions in human telomeric G3(T2AG3)3 DNA sequence

In addition to the well-known Watson–Crick double helix, DNA can form other structures. One of them is a four-stranded quadruplex, formation of which was also acknowledged in in vivo conditions. It was suggested that the presence of quadruplexes in e.g. telomeric region has a significant biological importance. We have studied structural properties of the human telomeric quadruplex formed by G₃(T₂AG₃)₃ and related sequences, in which each guanine base was one-by-one replaced by adenine. In the next step, we have studied sequences, in which two, or even four guanines were replaced by adenine. These sequences were studied in the presence of sodium or potassium ions. Using CD spectroscopy, UV thermal stability measurements, and polyacrylamide gel electrophoresis we found that none of the substitutions hindered the formation of the antiparallel quadruplex formed by the unsubstituted sequence in sodium solutions. However, the effect of substitution differed depending on the position of the guanine replaced. The middle quartet of the antiparallel basket scaffold was the most sensitive and led to the least stable structures. With other sequences, the effect of substitution depends on the position and also on the syn/anti glycosidic bond orientation of the appropriate guanosine in the original quadruplex structure. In the case of the multiple A for G substitutions, the G₃(T₂AG₃)₃ quadruplex was most destabilized by the G:G:A:A tetrad, in which the adenosines substituted syn guanosines. Interestingly, unlike with G₃(T₂AG₃)₃, no structural transitions were observed with the A-containing analogs of the sequence when sodium ions were replaced by potassium ions. The basic quadruplex topology remained antiparallel for all modified sequences in both salts. As in vivo misincorporation of A for a G in the telomeric sequence is possible and potassium is a physiological salt, these findings may be biologically important. In our next studies, we have compared the effect of the G to A substitutions in the human telomere sequence with 8-oxoguanine substituted samples or samples containing guanine apurinic sites. Data obtained from our study show a noticeable trend: it is not the type of the lesion but the position of the modification determines the effect on the conformation and stability of the quadruplex.     

Influence of chain length on mono- versus di-alkylation in the reactivity of [Pt2(μ-S)2(PPh3)4] towards α,ω-dihalo-n-alkanes; a synthetic route to platinum(II) ω-haloalkylthiolate complexes

The reactions of [Pt₂(μ-S)₂(PPh₃)₄] with α,ω-dibromoalkanes Br(CH₂)_nBr (n = 4, 5, 6, 8, 12) gave mono-alkylated [Pt₂(μ-S){μ-S(CH₂)_nBr}(PPh₃)₄]⁺ and/or di-alkylated [Pt₂(μ-S(CH₂)_nS}(PPh₃)₄]²⁺ products, depending on the alkyl chain length and the reaction conditions. With longer chains (n = 8, 12), intramolecular di-alkylation does not proceed in refluxing methanol, with the mono-alkylated products [Pt₂(μ-S){μ-S(CH₂)_nBr}(PPh₃)₄]⁺ being the dominant products when excess alkylating agent is used. The bridged complex [{Pt₂(μ-S)₂(PPh₃)₄}₂{μ-(CH₂)₁₂}]²⁺ was accessible from the reaction of [Pt₂(μ-S)₂(PPh₃)₄] with 0.5 mol equivalents of Br(CH₂)₁₂Br. [Pt₂(μ-S){μ-S(CH₂)₄Br}(PPh₃)₄]⁺ can be cleanly isolated as its BPh₄⁻ salt, but undergoes facile intramolecular di-alkylation at −18 °C, giving the known species [Pt₂(μ-S(CH₂)₄S}(PPh₃)₄]²⁺. The reaction of I(CH₂)₆I with [Pt₂(μ-S)₂(PPh₃)₄] similarly gives [Pt₂(μ-S){μ-S(CH₂)₆I}(PPh₃)₄]⁺, which is fairly stable towards intramolecular di-alkylation once isolated. These reactions provide a facile route to ω-haloalkylthiolate complexes which are poorly defined in the literature. X-ray crystal structures of [Pt₂(μ-S){μ-S(CH₂)₅Br}(PPh₃)₄]BPh₄ and [Pt₂(μ-S(CH₂)₅S}(PPh₃)₄](BPh₄)₂ are reported, together with a study of these complexes by electrospray ionisation mass spectrometry. All complexes fragment by dissociation of PPh₃ ligands, and the bromoalkylthiolate complexes show additional fragment ions [Pt₂(μ-S){μ-S(CH₂)_n−2CHCH₂}(PPh₃)_m]⁺ (m = 2 or 3; m ≠ 4), most significant for n = 4, formed by elimination of HBr.     

The (gt)n(ga)m containing intron 2 of HLA-DRB alleles binds a zinc-dependent protein and forms non B-DNA structures

We studied protein binding and structural features of perfect and imperfect composite (gt)_n(ga)_m blocks from different HLA-DRB1 alleles in their original genomic and artificial environments. The major retarded protein/DNA complex of the genomic (gt)_n(ga)_m fragments comprises a zinc-dependent protein present in nuclear extracts from different cell types. The protein binding is characterized by moderate affinities independent of the polymorphic form of the physiological microsatellite allele. The binding affinity depends on the 5′ and 3′ adjacent single copy parts. DNase I footprinting of genome-derived fragments revealed that the 5′ adjacent sequence and the (gt)_n repeat are preferentially protected on the (gt)_n(ga)_m strand. Comparing three alleles, a regular pattern of footprints was not detectable in the (gt)_n part, indicating that the zinc-dependent protein recognizes structural rather than sequence-specific features in this region. Chemical probing resulted in a pattern characteristic for Z-DNA in the (gt)_n tract of the fragments. However, EMSA experiments using the Z-DNA specific monoclonal antibody mABZ-22 did not prove the presence of Z-DNA. As demonstrated by chemical modifications of the different (ga)_m targets, only one of three (gt)_n(ga)_m fragments formed intramolecular triplexes of the type H-y3 and H-y5. DNase I footprinting revealed only weak protection, if any, in the homopurine tract. Rather, the (tc)_m strands are hypersensitive for DNase I. This is probably due to structural conversions into intramolecular *H-triplexes after binding of HIZP.     

Telomerase-dependent repeat divergence at the 3' ends of yeast telomeres

Yeast telomeres consist of ~300 nt of degenerate repeats with the consensus sequence G_2–3(TG)_1–6. We developed a method for the amplification of a genetically marked telomere by PCR, allowing precise length and sequence determination of the G-rich strand including the 3′ terminus. We examined wild-type cells, telomerase RNA deficient cells and a strain deleted for YKU70, which encodes for a protein involved in telomere maintenance and DNA double strand break repair. The 3′ end of the G-rich strand was found to be at a variable position within the telomeric repeat. No preference for either thymine or guanine as the 3′ base was detected. Comparison of telomere sequences from clonal populations revealed that telomeres consist of a centromere-proximal region of stable sequence and a distal region with differing degenerate repeats. In wild-type as well as yku70-Δ cells, variation in the degenerate telomeric repeats was detected starting 40–100 nt from the 3′ end. Sequence divergence was abolished after deletion of the telomerase RNA gene. Thus, this region defines the domain where telomere shortening and telomerase-mediated extension occurs. Since this domain is much larger than the number of nucleo­tides lost per generation in the absence of telomerase, we propose that telomerase does not extend a given telomere in every cell cycle.     

Recognition of 5-aminouracil (U(#)) in the central strand of a DNA triplex: orientation selective binding of different third strand bases

A necessary feature of the natural base triads for triplex formation is the requirement of a purine (A or G) in the central position, since only these provide sets of two hydrogen bond donors/acceptors in the major groove of the double helix. Pyrimidine bases devoid of this feature have incompatible complementarity and lead to triplexes with lower stability. This paper demonstrates that 5-aminouracil (U^#) (I), a pyrimidine nucleobase analogue of T in which 5-methyl is replaced by 5-amino group, with hydrogen bonding sites on both sides, is compatible in the central position of triplex triad X*U^#·A, where X = A/G/C/T/2-aminopurine (AP), and * and · represent Hoogsteen and Watson–Crick hydrogen bonding patterns respectively. A novel recognition selectivity based on the orientation (parallel/antiparallel) of the third strand purines A, G or AP with A in the parallel motif (A_p*U^#·A), and G/AP in the antiparallel motif (G_ap/AP_ap*U^#·A) is observed. Similarly for pyrimidines in the third strand, C is accepted only in a parallel mode (C_p*U^#·A). Significantly, T is recognised in both parallel and antiparallel modes (T_p/T_ap*U^#·A), with the antiparallel mode being stable compared to the parallel one. The ‘U^#’ triplexes are also more stable than the corresponding control ‘T’ triplexes. The results expand the lexicon of triplex triads with a recognition motif consisting of pyrimidine in the central strand.