i-Motif formation and spontaneous deletions in human cells

Concatemers of d(TCCC) that were first detected through their association with deletions at the RACK7 locus, are widespread throughout the human genome. Circular dichroism spectra show that d(GGGA)_n sequences form G-quadruplexes when n > 3, while i-motif structures form at d(TCCC)_n sequences at neutral pH when n ≥ 7 in vitro. In the PC3 cell line, deletions are observed only when the d(TCCC)_n variant is long enough to form significant levels of unresolved i-motif structure at neutral pH. The presence of an unresolved i-motif at a representative d(TCCC)_n element at RACK7 was suggested by experiments showing that that the region containing the d(TCCC)₉ element was susceptible to bisulfite attack in native DNA and that d(TCCC)₉ oligo formed an i-motif structure at neutral pH. This in turn suggested that that the i-motif present at this site in native DNA must be susceptible to bisulfite mediated deamination even though it is a closed structure. Bisulfite deamination of the i-motif structure in the model oligodeoxynucleotide was confirmed using mass spectrometry analysis. We conclude that while G-quadruplex formation may contribute to spontaneous mutation at these sites, deletions actually require the potential for i-motif to form and remain unresolved at neutral pH.     

Human telomeric DNA: G-quadruplex,i-motif and Watson-Crick double helix

Human telomeric DNA composed of (TTAGGG/CCCTAA)n repeats may form a classical Watson-Crick double helix. Each individual strand is also prone to quadruplex formation: the G-rich strand may adopt a G-quadruplex conformation involving G-quartets whereas the C-rich strand may fold into an i-motif based on intercalated C*C+ base pairs. Using an equimolar mixture of the telomeric oligonucleotides d[AGGG(TTAGGG)3] and d[(CCCTAA)3CCCT], we defined which structures existed and which would be the predominant species under a variety of experimental conditions. Under near-physiological conditions of pH, temperature and salt concentration, telomeric DNA was predominantly in a double-helix form. However, at lower pH values or higher temperatures, the G-quadruplex and/or the i-motif efficiently competed with the duplex. We also present kinetic and thermodynamic data for duplex association and for G-quadruplex/i-motif unfolding.     

Intramolecular folding in human ILPR fragment with three C-rich repeats

Enrichment of four tandem repeats of guanine (G) rich and cytosine (C) rich sequences in functionally important regions of human genome forebodes the biological implications of four-stranded DNA structures, such as G-quadruplex and i-motif, that can form in these sequences. However, there have been few reports on the intramolecular formation of non-B DNA structures in less than four tandem repeats of G or C rich sequences. Here, using mechanical unfolding at the single-molecule level, electrophoretic mobility shift assay (EMSA), circular dichroism (CD), and ultraviolet (UV) spectroscopy, we report an intramolecularly folded non-B DNA structure in three tandem cytosine rich repeats, 5'-TGTC4ACAC4TGTC4ACA (ILPR-I3), in the human insulin linked polymorphic region (ILPR). The thermal denaturation analyses of the sequences with systematic C to T mutations have suggested that the structure is linchpinned by a stack of hemiprotonated cytosine pairs between two terminal C4 tracts. Mechanical unfolding and Br(2) footprinting experiments on a mixture of the ILPR-I3 and a 5'-C4TGT fragment have further indicated that the structure serves as a building block for intermolecular i-motif formation. The existence of such a conformation under acidic or neutral pH complies with the strand-by-strand folding pathway of ILPR i-motif structures.     

pH-Dependant fluorescence switching of an i-motif structure incorporating an isomeric azobenzene/pyrene fluorophore

In this study, we synthesized an Azo-py phosphoramidite, featuring azobenzene and pyrene units, as a novel fluorescent and isomeric (trans- and cis-azobenzene units) material, which we incorporated in an i-motif DNA sequence. We then monitored the structural dynamics and changes in fluorescence as the modified DNA sequences transformed from single strands at pH 7 to i-motif quadruplex structures at pH 3. After incorporating Azo-py into the 4A loop position of an i-motif sequence, dramatic changes in fluorescence occurred as the DNA structures changed from single-strands to i-motif quadruplex structures. Interestingly, the cis form of Azo-py induced a more stable i-motif structure than did the trans form, as confirmed from circular dichroism spectra and melting temperature data. The absorption and fluorescence signals of these Azo-py-incorporated i-motif systems exhibited switchable and highly correlated signaling patterns. Such isomeric structures based on Azo-py might find potential applications in biology, where control over stable i-motif quadruplex structures might be performed with switchable fluorescence signaling.     

Kinetic hybrid i-motifs: intercepting DNA with RNA to form a DNA(2)-RNA(2) i-motif

We have constructed and characterized a long-lived hybrid DNA(2)-RNA(2) i-motif that is kinetically formed by mixing equivalent amount of C-rich RNA (R) and C-rich DNA (D). Circular dichroism shows that these hybrids are distinct from their parent DNA(4) or RNA(4) i-motif. pH dependent CD and UV thermal melting experiments showed that the complexes were maximally stable at pH 4.5, the pK(a) of cytosine, consistent with the complex being held by CH(+)-C base pairs. Fluorescence studies confirmed their tetrameric nature and established the relative strand polarities of the RNA and DNA strands in the complex. These showed that in a hybrid D(2)R(2) i-motif two DNA strands occupy one narrow groove and the two RNA strands occupy the other. This suggests that even the sugar-sugar interactions are highly specific. Interestingly, this hybrid slowly disproportionates into DNA(4) i-motifs and ssRNA which would be valuable to study intermediates in DNA(4) i-motif formation.     

Studying the Influence of the Pyrene Intercalator TINA on the Stability of DNA i-Motifs

Certain cytosine-rich (C-rich) DNA sequences can fold into secondary structures as four-stranded i-motifs with hemiprotonated base pairs. Here we synthesized C-rich TINA-intercalating oligonucleotides by inserting a nonnucleotide pyrene moiety between two C-rich regions. The stability of their i-motif structures was studied by using UV melting temperature measurements and circular dichroism spectra at different pH values under noncrowding and crowding conditions (20% poly(ethylene glycol)). When TINA ((R)-3-((4-(1-pyrenylethynyl)benzyl)oxy) propane-1,2-diol) is inserted, the oligonucleotides could form an i-motif at a higher pH than observed for the corresponding wildtype oligonucleotide.     

Calorimetric unfolding of the bimolecular and i-motif complexes of the human telomere complementary strand, d(C(3)TA(2))(4)

A combination of spectroscopic and calorimetric techniques is used to determine the unfolding thermodynamics of the complexes formed by the complementary sequence of the human telomere, d(C(3)TA(2))(4), in the pH range of 4.2 to 6. Calorimetric melting curves show biphasic transitions; both transitions are shifted to higher temperatures as the pH is decreased, indicative of cytosine protonation, which favors the formation of C*C(+) base pairs. Furthermore, the transition temperature, T(M), of the lower transition depends on strand concentration, while the T(M) of the higher transition is independent of strand concentration, indicating the following sequential melting: bimolecular complex(s)-->intramolecular complex-->random coil. The thermodynamic profiles for the formation of each complex, bimolecular and i-motif reveals small favorable free energy terms resulting from favorable enthalpy-unfavorable entropy compensations, uptake of protons, marginal uptake of counterions (i-motif) and marginal release of water molecules (i-motif). Furthermore, an enthalpy of 3.2 kcal/mol (bimolecular complex) and 5.0 kcal/mol (i-motif) is estimated for a single C*C(+)/C*C(+) base-pair stack.     

Kinetics and thermodynamics of i-DNA formation: phosphodiester versus modified oligodeoxynucleotides.

At slightly acidic or even neutral pH, oligodeoxynucleotides that include a stretch of cytidines have been shown to form a tetrameric structure in which two parallel-stranded duplexes have their hemiprotonated C.C+base pairs face to face and fully intercalated, in a so-called i-motif. Cytosine-rich pyrimidine oligodeoxynucleotides can form an intramolecular i-motif. We have studied the ability of several DNA analogs to fold into this structure. Evidence for folding was provided by thermal denaturation. We have shown that phosphorothioate and phosphodiester oligodeoxynucleotides, but not methylphosphonate or PNA oligomers, may form the i-motif. Four different PS oligodeoxynucleotides were compared with their PO counterparts. In all cases, the melting temperature (Tm) of the phosphorothioate oligomer was equal or slightly inferior (by 2-3 degreesC) to the Tmof the natural oligodeoxynucleotide. For long oligodeoxynucleotides, a small change of pH leads to a completely different melting profile: the curves are reversible at pH 6.4 or lower, and a hysteresis is obtained at pH 6.8 or higher; cooling and heating curves were not superimposed, allowing us to determine the rate constants of association (kon) and dissociation (koff) as a function of the temperature: these rate constants give linear Arrhenius plots, in agreement with the prediction of the two-state model of association-dissociation. The activation energy Eonis strongly negative and, at neutral pH, the phosphorothioate associates and dissociates nine times faster than the phosphodiester oligodeoxynucleotide of identical sequence.     

A minimal i-motif stabilized by minor groove G:T:G:T tetrads

The repetitive DNA sequences found at telomeres and centromeres play a crucial role in the structure and function of eukaryotic chromosomes. This role may be related to the tendency observed in many repetitive DNAs to adopt non-canonical structures. Although there is an increasing recognition of the importance of DNA quadruplexes in chromosome biology, the co-existence of different quadruplex-forming elements in the same DNA structure is still a matter of debate. Here we report the structural study of the oligonucleotide d(TCGTTTCGT) and its cyclic analog d<pTCGTTTCGTT>. Both sequences form dimeric quadruplex structures consisting of a minimal i-motif capped, at both ends, by a slipped minor groove-aligned G:T:G:T tetrad. These mini i-motifs, which do not exhibit the characteristic CD spectra of other i-motif structures, can be observed at neutral pH, although they are more stable under acidic conditions. This finding is particularly relevant since these oligonucleotide sequences do not contain contiguous cytosines. Importantly, these structures resemble the loop moiety adopted by an 11-nucleotide fragment of the conserved centromeric protein B (CENP-B) box motif, which is the binding site for the CENP-B.     

Structure of a C-rich strand fragment of the human centromeric satellite III: a pH-dependent intercalation topology

Repetitive DNA sequences may adopt unusual pairing arrangements. At acid to neutral pH, cytidine-rich DNA oligodeoxynucleotides can form the i-motif structure in which two parallel-stranded duplexes with C.C(+) pairs are intercalated head-to-tail. The i-motif may be formed by multimeric associations or by intra-molecular folding, depending on the number of cytidine tracts, the nucleotide sequences between them, and the experimental conditions.We have found that a natural fragment of the human centromeric satellite III, d(CCATTCCATTCCTTTCC), can form two monomeric i-motif structures that differ in their intercalation topology and that are favored at pH values higher (the eta-form) and lower (the lambda-form) than 4.6. The change in intercalation may be related to adenine protonation in the loops.We studied the uridine derivative methylated on the first cytidine base, d(5mCCATTCCAUTCCUTTCC), whose proton spectrum is better resolved. The intercalation topologies are (C7.C17)/(5mC1.C11)/(C6.C16)/(C2.C12) for form lambda and (5mC1.C11)/(C7.C17)/(C2.C12)/(C6.C16) for form eta. We have solved the structure of the eta-form, and we present a model for the lambda-form. The switch from eta to lambda involves disruption of the i-motif. In both forms, the central AUT linker crosses the wide groove, and the first and the third linkers loop across the minor grooves. The i-motif core is extended in the eta-form by the inter-loop reverse Watson-Crick A3.U13 pair, whose dissociation constant is around 10(-2) at 0 degrees C, and in the lambda-form by the interloop T5.T15 pair.In contrast, d(5mCCATTCCTTACCTTTCC) folds into a pH-independent structure that has the same intercalation topology as the lambda-form. The i-motif core is extended below by the interloop T5.T15 pair and closed on top by the T8.A10 pair.Thus, the C-rich strand of the human satellite III tandem repeats, like the G-rich strand, can fold into various compact structures. The relevance of these features to centromeric function remains unknown.     

Structural competition involving G-quadruplex DNA and its complement

Structural competition between the G-quadruplex, the I-motif, and the Watson-Crick duplex has been implicated for repetitive DNA sequences, but the competitive mechanism of these multistranded structures still needs to be elucidated. We investigated the effects of sequence context, cation species, and pH on duplex formation by the G-quadruplex of dG(3)(T(2)AG(3))(3) and its complement the I-motif of d(C(3)TA(2))(3)C(3), using ITC, DSC, PAGE, CD, UV, and CD stopped-flow kinetic techniques. ITC and PAGE experiments confirmed Watson-Crick duplex formation by the complementary strands. The binding constant of the two DNA strands in the presence of 10 mM Mg(2+) at pH 7.0 was shown to be 5.28 x 10(7) M(-1) at 20 degrees C, about 400 times larger than that in the presence of 100 mM Na(+) at pH 5.5. The dynamic transition traces of the duplex formation from the equimolar mixture of G-/C-rich complementary sequences were obtained at both pH 7.0 and pH 5.5. Fitting to a single-exponential function gave an observed rate of 8.06 x 10(-3) s(-1) at 20 degrees C in 10 mM Mg(2+) buffer at pH 7.0, which was about 10 times the observed rate at pH 5.5 under the same conditions. Both of the observed rates increased as temperature rose, implying that the dissociation of the single-stranded structured DNAs is the rate-limiting step for the WC duplex formation. The difference between the apparent activation energy at pH 7.0 and that at pH 5.5 reflects the fact that pH significantly influences the structural competition between the G-quadruplex, the I-motif, and the Watson-Crick duplex, which also implies a possible biological role for I-motifs in biological regulation.     

i-Motif DNA: Structure,stability and targeting with ligands

i-Motifs are four-stranded DNA secondary structures which can form in sequences rich in cytosine. Stabilised by acidic conditions, they are comprised of two parallel-stranded DNA duplexes held together in an antiparallel orientation by intercalated, cytosine–cytosine⁺ base pairs. By virtue of their pH dependent folding, i-motif forming DNA sequences have been used extensively as pH switches for applications in nanotechnology. Initially, i-motifs were thought to be unstable at physiological pH, which precluded substantial biological investigation. However, recent advances have shown that this is not always the case and that i-motif stability is highly dependent on factors such as sequence and environmental conditions. In this review, we discuss some of the different i-motif structures investigated to date and the factors which affect their topology, stability and dynamics. Ligands which can interact with these structures are necessary to aid investigations into the potential biological functions of i-motif DNA and herein we review the existing i-motif ligands and give our perspective on the associated challenges with targeting this structure.     

Composite 5-methylations of cytosines modulate i-motif stability in a sequence-specific manner: Implications for DNA nanotechnology and epigenetic regulation of plant telomeric DNA

BackgroundThe i-motif is a tetrameric DNA structure based on the formation of hemiprotonated cytosine-cytosine (C⁺.C) base pairs. i-motifs are widely used in nanotechnology. In biological systems, i-motifs are involved in gene regulation and in control of genome integrity. In vivo, the i-motif forming sequences are subjects of epigenetic modifications, particularly 5-cytosine methylation. In plants, natively occurring methylation patterns lead to a complex network of C⁺.C, ^5mC⁺.C and ^5mC⁺.^5mC base-pairs in the i-motif stem. The impact of complex methylation patterns (CMPs) on i-motif formation propensity is currently unknown.MethodsWe employed CD and UV-absorption spectroscopies, native PAGE, thermal denaturation and quantum-chemical calculations to analyse the effects of native, native-like, and non-native CMPs in the i-motif stem on the i-motif stability and pK_a.ResultsCMPs have strong influence on i-motif stability and pK_a and influence these parameters in sequence-specific manner. In contrast to a general belief, i) CMPs do not invariably stabilize the i-motif, and ii) when the CMPs do stabilize the i-motif, the extent of the stabilization depends (in a complex manner) on the number and pattern of symmetric ^5mC⁺.^5mC or asymmetric ^5mC⁺.C base pairs in the i-motif stem.ConclusionsCMPs can be effectively used to fine-tune i-motif properties. Our data support the notion of epigenetic modifications as a plausible control mechanism of i-motif formation in vivo.General SignificanceOur results have implications in epigenetic regulation of telomeric DNA in plants and highlight the potential and limitations of engineered patterning of cytosine methylations on the i-motif scaffold in nanotechnological applications.     

The RNA i-motif

Oligodeoxynucleotides with stretches of cytidine residues associate into a four-stranded structure, the i-motif, in which two head-to-tail, intercalated, parallel-stranded duplexes are held together by hemiprotonated C.C+ pairs. We have investigated the possibility of forming an i-motif structure with C-rich ribonucleic acids. The four C-rich RNAs studied, r(UC5), r(C5), r(C5U) and r(UC3), associate into multiple intercalated structures at acidic pH. r(UC5) forms two i-motif structures that differ by their intercalation topologies. We report on a structural study of the main form and we analyze the small conformational differences found by comparison with the DNA i-motif. The stacking topology of the main structure avoids one of the six 2'-OH/2'-OH repulsive contacts expected in a fully intercalated structure. The C3'-endo pucker of the RNA sugars and the orientation of the intercalated C.C+ pairs result in a modest widening of the narrow grooves at the steps where the hydroxyl groups are in close contact. The free energy of the RNA i-motif, on average -4 kJ mol(-1) per C.C+ pair, is half of the value found in DNA i-motif structures.     

Intramolecular folding of a fragment of the cytosine-rich strand of telomeric DNA into an i-motif.

In the recently discovered i-motif, four stretches of cytosine form two parallel-stranded duplexes whose C.C+ base pairs are fully intercalated. The i-motif may be recognized by characteristic Overhauser cross-peaks of the proton NMR spectrum, reflecting short H1'-H1' distances across the minor groove, and short internucleotide amino-proton-H2'/H2" across the major groove. We report the observation of such cross-peaks in the spectra of a fragment of the C-rich telomeric strand of vertebrates, d[CCCTAA]3CCC. The spectra also demonstrate that the cytosines are base-paired and that proton exchange is very slow, as reported previously for the i-motif. From UV absorbance and gel chromatography measurements, we assign these properties to an i-motif which includes all or nearly all the cytosines, and which is formed by intramolecular folding at slightly acid or neutral pH. A fragment of telomeric DNA of Tetrahymena, d[CCCCAA]3CCCC, has the same properties. Hence four consecutive C stretches of a C-rich telomeric strand can fold into an i-motif. Hypothetically, this could occur in vivo.     

Effect of G-tract length on the topology and stability of intramolecular DNA quadruplexes

G-Rich sequences are known to form four-stranded structures that are based on stacks of G-quartets, and sequences with the potential to adopt these structures are common in eukaryotic genomes. However, there are few rules for predicting the relative stability of folded complexes that are adopted by sequences with different-length G-tracts or variable-length linkers between them. We have used thermal melting, circular dichroism, and gel electrophoresis to examine the topology and stability of intramolecular G-quadruplexes that are formed by sequences of the type d(GnT)4 and d(GnT2)4 (n = 3-7) in the presence of varying concentrations of sodium and potassium. In the presence of potassium or sodium, d(GnT)4 sequences form intramolecular parallel complexes with the following order of stability: n = 3 > n = 7 > n = 6 > n = 5 > n = 4. d(G3T)4 is anomalously stable. In contrast, the stability of d(GnT2)4 increases with the length of the G-tract (n = 7 > n = 6 > n = 5 > n = 4 > n = 3). The CD spectra for d(GnT)4 in the presence of potassium exhibit positive peaks around 260 nm, consistent with the formation of parallel topologies. These peaks are retained in sodium-containing buffers, but when n = 4, 5, or 6, CD maxima are observed around 290 nm, suggesting that these sequences [especially d(G5T)4] have some antiparallel characteristics. d(G3T2)4 adopts a parallel conformation in the presence of both sodium and potassium, while all the other d(GnT2)4 complexes exhibit predominantly antiparallel features. The properties of these complexes are also affected by the rate of annealing, and faster rates favor parallel complexes.     

Parallel self-associated structures formed by T,C-rich sequences at acidic pH

Oligonucleotides of nonregular heteropyrimidine sequences incorporating or not incorporating purine residues 5'-d(ACTCCCTTCTCCTCTCTA), 5'-d(ACTCCCTGGTCCTCTCTA), 5'-d(TCTCTCCTGGTCCCTCC), and 5'-d(TCTCTCCTCTTCCCTCC) can form self-associated parallel-stranded (ps) structures at pH 4-5.5. The ps structures were identified by studying at neutral and acidic pH UV melting transitions, FTIR spectra, and fluorescence of pyrene-labeled oligonucleotides as well as by chemical joining of 5'-phosphorylated oligonucleotides. A gel electrophoresis run for oligonucleotides 5'-d(TCTCTCCTCTTCCCTCC) and 5'-d(ACTCCCTTCTCCTCTCTA) has shown the formation of homoduplexes at low DNA strand concentrations. Ps structures are held by C-C(+) base pairs and have N- and S-types of sugar puckering as detected by FTIR spectroscopy in the millimolar concentration range. Guanine inserts as well as thymine and purine inserts into an oligomeric cytosine sequence make the formation of the tetraplex i-motif unfavorable. MvaI restriction endonuclease, which recognizes the CCT/AGG sequence in DNA, does not cleave parallel pseudosubstrates.