Intramolecular i-motif structure at acidic pH for progressive myoclonus epilepsy (EPM1) repeat d(CCCCGCCCCGCG)n

The i-Motif as a Molecular Target: More Than a Complementary DNA Secondary Structure

Stretches of cytosine-rich DNA are capable of adopting a dynamic secondary structure, the i-motif. When within promoter regions, the i-motif has the potential to act as a molecular switch for controlling gene expression. However, i-motif structures in genomic areas of repetitive nucleotide sequences may play a role in facilitating or hindering expansion of these DNA elements. Despite research on the i-motif trailing behind the complementary G-quadruplex structure, recent discoveries including the identification of a specific i-motif antibody are pushing this field forward. This perspective reviews initial and current work characterizing the i-motif and providing insight into the biological function of this DNA structure, with a focus on how the i-motif can serve as a molecular target for developing new therapeutic approaches to modulate gene expression and extension of repetitive DNA.

Unusual Isothermal Hysteresis in DNA i-Motif pH Transitions: A Study of the RAD17 Promoter Sequence

We have interrogated the isothermal folding behavior of the DNA i-motif of the human telomere, dC₁₉, and a high-stability i-motif-forming sequence in the promoter of the human DNA repair gene RAD17 using human physiological solution and temperature conditions. We developed a circular-dichroism-spectroscopy-based pH titration method that is followed by analysis of titration curves in the derivative domain and found that the observed pH-dependent folding behavior can be significantly different and, in some cases, multiphasic, with a dependence on how rapidly i-motif folding is induced. Interestingly, the human telomere sequence exhibits unusual isothermal hysteresis in which the unfolding process always occurs at a higher pH than the folding process. For the RAD17 i-motif, rapid folding by injection into a low-pH solution results in triphasic unfolding behavior that is completely diminished when samples are slowly folded in a stepwise manner via pH titration. Chemical footprinting of the RAD17 sequence and pH titrations of dT-substituted mutants of the RAD17 sequence were used to develop a model of RAD17 folding and unfolding. These results may provide valuable information pertinent to i-motif use in sensors and materials, as well as insight into the potential biological activity of i-motif-forming sequences under stepwise or instantaneous changes in pH.

Insight into the Complexity of the i-Motif and G-Quadruplex DNA Structures Formed in the KRAS Promoter and Subsequent Drug-Induced Gene Repression

Activating KRAS mutations frequently occur in pancreatic, colorectal, and lung adenocarcinomas. While many attempts have been made to target oncogenic KRAS, no clinically useful therapies currently exist. Most efforts to target KRAS have focused on inhibiting the mutant protein; a less explored approach involves targeting KRAS at the transcriptional level. The promoter element of the KRAS gene contains a GC-rich nuclease hypersensitive site with three potential DNA secondary structure-forming regions. These are referred to as the Near-, Mid-, and Far-regions, on the basis of their proximity to the transcription start site. As a result of transcription-induced negative superhelicity, these regions can open up to form unique DNA secondary structures: G-quadruplexes on the G-rich strand and i-motifs on the C-rich strand. While the G-quadruplexes have been well characterized, the i-motifs have not been investigated as thoroughly. Here we show that the i-motif that forms in the C-rich Mid-region is the most stable and exists in a dynamic equilibrium with a hybrid i-motif/hairpin species and an unfolded hairpin species. The transcription factor heterogeneous nuclear ribonucleoprotein K (hnRNP K) was found to bind selectively to the i-motif species and to positively modulate KRAS transcription. Additionally, we identified a benzophenanthridine alkaloid that dissipates the hairpin species and destabilizes the interaction of hnRNP K with the Mid-region i-motif. This same compound stabilizes the three existing KRAS G-quadruplexes. The combined effect of the compound on the Mid-region i-motif and the G-quadruplexes leads to downregulation of KRAS gene expression. This dual i-motif/G-quadruplex-interactive compound presents a new mechanism to modulate gene expression.

The Consequences of Overlapping G-Quadruplexes and i-Motifs in the Platelet-Derived Growth Factor Receptor β Core Promoter Nuclease Hypersensitive Element Can Explain the Unexpected Effects of Mutations and Provide Opportunities for Selective Targeting of Both Structures by Small Molecules To Downregulate Gene Expression

The platelet-derived growth factor receptor β (PDGFR-β) signaling pathway is a validated and important target for the treatment of certain malignant and nonmalignant pathologies. We previously identified a G-quadruplex-forming nuclease hypersensitive element (NHE) in the human PDGFR-β promoter that putatively forms four overlapping G-quadruplexes. Therefore, we further investigated the structures and biological roles of the G-quadruplexes and i-motifs in the PDGFR-β NHE with the ultimate goal of demonstrating an alternate and effective strategy for molecularly targeting the PDGFR-β pathway. Significantly, we show that the primary G-quadruplex receptor for repression of PDGFR-β is the 3'-end G-quadruplex, which has a GGA sequence at the 3'-end. Mutation studies using luciferase reporter plasmids highlight a novel set of G-quadruplex point mutations, some of which seem to provide conflicting results on effects on gene expression, prompting further investigation into the effect of these mutations on the i-motif-forming strand. Herein we characterize the formation of an equilibrium between at least two different i-motifs from the cytosine-rich (C-rich) sequence of the PDGFR-β NHE. The apparently conflicting mutation results can be rationalized if we take into account the single base point mutation made in a critical cytosine run in the PDGFR-β NHE that dramatically affects the equilibrium of i-motifs formed from this sequence. We identified a group of ellipticines that targets the G-quadruplexes in the PDGFR-β promoter, and from this series of compounds, we selected the ellipticine analog GSA1129, which selectively targets the 3'-end G-quadruplex, to shift the dynamic equilibrium in the full-length sequence to favor this structure. We also identified a benzothiophene-2-carboxamide (NSC309874) as a PDGFR-β i-motif-interactive compound. In vitro, GSA1129 and NSC309874 downregulate PDGFR-β promoter activity and transcript in the neuroblastoma cell line SK-N-SH at subcytotoxic cell concentrations. GSA1129 also inhibits PDGFR-β-driven cell proliferation and migration. With an established preclinical murine model of acute lung injury, we demonstrate that GSA1129 attenuates endotoxin-mediated acute lung inflammation. Our studies underscore the importance of considering the effects of point mutations on structure formation from the G- and C-rich sequences and provide further evidence for the involvement of both strands and associated structures in the control of gene expression.

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.

Replication Through Repetitive DNA Elements and Their Role in Human Diseases

Human cells contain various repetitive DNA sequences, which can be a challenge for the DNA replication machinery to travel through and replicate correctly. Repetitive DNA sequence can adopt non-B DNA structures, which could block the DNA replication. Prolonged stalling of the replication fork at the endogenous repeats in human cells can have severe consequences such as genome instability that includes repeat expansions, contractions, and chromosome fragility. Several neurological and muscular diseases are caused by a repeat expansion. Furthermore genome instability is the major cause of cancer. This chapter describes some of the important classes of repetitive DNA sequences in the mammalian genome, their ability to form secondary DNA structures, their contribution to replication fork stalling, and models for repeat expansion as well as chromosomal fragility. Included in this chapter are also some of the strategies currently employed to detect changes in DNA replication and proteins that could prevent the repeat-mediated disruption of DNA replication in human cells. Additionally summarized are the consequences of repeat-associated perturbation of the DNA replication, which could lead to specific human diseases.

Fundamental aspects of the nucleic acid i-motif structures

The latest research on fundamental aspects of i-motif structures is reviewed with special attention to their hypothetical rolein vivo.

Stable conformations of a single stranded deprotonated DNA i-motif

We present molecular dynamics simulations of a single stranded deprotonated DNA i-motif in explicit solvent. Our results indicate that hairpin structures are stable equilibrium conformations at 300 K. The entropic preference of these configurations is explained by strong water ordering effects due to the present number of hydrogen bonds. We observe a full unfolding at higher temperatures in good agreement with experimental results.

Coexistence of an ILPR i-motif and a partially folded structure with comparable mechanical stability revealed at the single-molecule level

Investigation of i-motif is of high importance to fully understand the biological functions of G quadruplexes in the context of double-stranded DNA. Whereas single-molecule approaches have profiled G quadruplexes from a perspective unavailable by bulk techniques, there is a lack of similar literature on the i-motif in the cytosine (C)-rich region complementary to G quadruplex-forming sequences. Here, we have used laser tweezers to investigate the structures formed in 5'-(TGTCCCCACACCCC)(2), a predominate variant in the insulin-linked polymorphic region (ILPR). We have observed two species with the change in contour length (DeltaL) of 10.4 (+/-0.1) and 5.1 (+/-0.5) nm, respectively. Since DeltaL of 10.4 nm is located within the expected range for an i-motif structure, we assign this species to the i-motif. The formation of the i-motif in the same sequence has been corroborated by bulk experiments such as Br(2) footprinting, circular dichroism, and thermal denaturation. The assignment of the i-motif is further confirmed by decreased formation of this structure (23% to 1.3%) with pH 5.5 --> 7.0, which is a well-established behavior for i-motifs. In contrast to that of the i-motif, the formation of the second species with DeltaL of 5.1 nm remains unchanged (6.1 +/- 1.6%) in the same pH range, implying that pH-sensitive C:CH(+) pairs may not contribute to the structure as significantly as those to the i-motif. Compared to the DeltaG(unfold) of an i-motif (16.0 +/- 0.8 kcal/mol), the decreased free energy in the partially folded structure (DeltaG(unfold) 10.4 +/- 0.7 kcal/mol) may reflect a weakened structure with reduced C:CH(+) pairs. Both DeltaL and DeltaG(unfold) argue for the intermediate nature of the partially folded structure in comparison to the i-motif. In line with this argument, we have directly observed the unfolding of an i-motif through the partially folded structure. The i-motif and the partially folded structure share similar rupture forces of 22-26 pN, which are higher than those that can stall transcription catalyzed by RNA polymerases. This suggests, from a mechanical perspective alone, that either of the structures can stop RNA transcription.

Sole and stable RNA duplexes of G-rich sequences located in the 5'-untranslated region of protooncogenes

Guanine- (G-) rich nucleic acid sequences can form four-stranded structures called G-quadruplexes. It is widely held that the formation of a G-quadruplex in RNA is more feasible than in DNA because of the lack of a complementary strand in mRNA. Here, we analyzed sequences of 5'-untranslated regions of protooncogenes and surprisingly found that these regions showed an enrichment of not only guanine (G) but also cytosine (C) nucleotides. Since neighboring cytosine- (C-) rich regions can affect the formation and stability of a G-quadruplex structure, we further investigated the properties of DNA and RNA structures of G-rich and GC-rich regions. We selected typical GC-rich RNA sequences from protooncogenes and corresponding DNA sequences and investigated their structures. It was found that the GC-rich RNA sequences formed stable A-form duplexes as their major structure independent of the surrounding conditions, including the presence of different cations (Na(+), K(+), or Li(+)) or molecular crowding with 40 wt % poly(ethylene glycol) with an average molecular mass of 200 Da although there are a few exceptions in which only a combination of K(+) and molecular crowding induced a G-quadruplex structure of an extremely G-rich RNA sequence. In contrast, structural polymorphisms involving duplexes, G-quadruplexes, and i-motifs were observed for GC-rich DNA sequences depending on the surrounding factors. These results demonstrate the considerable structural and functional differences in GC-rich sequences of the genome (DNA) and transcriptosome (mRNA) with respect to the nucleic acid backbone. Moreover, it was suggested that structural study for a G-rich RNA sequence should be carried out under cell-mimicking condition where K(+) and crowding cosolutes exist.

The i-motif in the bcl-2 P1 promoter forms an unexpectedly stable structure with a unique 8:5:7 loop folding pattern

Transcriptional regulation of the bcl-2 proto-oncogene is highly complex, with the majority of transcription driven by the P1 promoter site and the interaction of multiple regulatory proteins. A guanine- and cytosine-rich (GC-rich) region directly upstream of the P1 site has been shown to be integral to bcl-2 promoter activity, as deletion or mutation of this region significantly increases transcription. This GC-rich element consists of six contiguous runs of guanines and cytosines that have the potential to adopt DNA secondary structures, the G-quadruplex and i-motif, respectively. Our laboratory has previously demonstrated that the polypurine-rich strand of the bcl-2 promoter can form a mixture of three different G-quadruplex structures. In this current study, we demonstrate that the complementary polypyrimidine-rich strand is capable of forming one major intramolecular i-motif DNA secondary structure with a transition pH of 6.6. Characterization of the i-motif folding pattern using mutational studies coupled with circular dichroic spectra and thermal stability analyses revealed an 8:5:7 loop conformation as the predominant structure at pH 6.1. The folding pattern was further supported by chemical footprinting with bromine. In addition, a novel assay involving the sequential incorporation of a fluorescent thymine analog at each thymine position provided evidence of a capping structure within the top loop region of the i-motif. The potential of the GC-rich element within the bcl-2 promoter region to form DNA secondary structures suggests that the transition from the B-DNA to non-B-DNA conformation may play an important role in bcl-2 transcriptional regulation. Furthermore, the two adjacent large lateral loops in the i-motif structure provide an unexpected opportunity for protein and small molecule recognition.

Intramolecularly folded G-quadruplex and i-motif structures in the proximal promoter of the vascular endothelial growth factor gene

A polyguanine/polycytosine (polyG/polyC) tract in the proximal promoter of the vascular endothelial growth factor (VEGF) gene is essential for transcriptional activation. The guanine-rich (G-rich) and cytosine-rich (C-rich) strands on this tract are shown to form specific secondary structures, characterized as G-quadruplexes and i-motifs, respectively. Mutational analysis of the G-rich strand combined with dimethyl sulfate (DMS) footprinting, a polymerase stop assay, and circular dichroism (CD) spectroscopy revealed that the G-quadruplex containing a 1:4:1 double-chain reversal loop is the most thermodynamically stable conformation that this strand readily adopts. These studies provide strong evidence that the size of loop regions plays a critical role in determining the most favored folding pattern of a G-quadruplex. The secondary structure formed on the complementary C-rich strand was also determined by mutational analysis combined with Br(2) footprinting and CD spectroscopy. Our results reveal that at a pH of 5.9 this strand is able to form an intramolecular i-motif structure that involves six C-C(+) base pairs and a 2:3:2 loop configuration. Taken together, our results demonstrate that the G-quadruplex and i-motif structures are able to form on the G- and C-rich strands, respectively, of the polyG/polyC tract in the VEGF proximal promoter under conditions that favor the transition from B-DNA to non-B-DNA conformations.

Oligo(dT) is not a correct native PAGE marker for single-stranded DNA

Polyacrylamide gel electrophoresis is a widely used method to study short DNA fragments in solution. It is, however, a relative method requiring length markers to assess mobility, shape, flexibility, and molecularity of the DNA structures of interest. In recent literature we have encountered the use of oligo(dT) fragments as the native PAGE length markers. We show here that this practice is inadequate because oligo(dT) migration is strongly retarded in native polyacrylamide gels. This conclusion is qualitatively true irrespective of the conditions of electrophoresis, oligo(dT) length, and gel concentration. Depending on their length, oligo(dT) fragments migrate 2--4 times slower than that would correspond to their nucleotide number. This leads to erroneous conclusions, e.g., determination of the number of associated molecules in guanine quadruplexes or other DNA complexes.

Formation of the G-quadruplex and i-motif structures in retinoblastoma susceptibility genes (Rb)

The formation of G-quadruplex and i-motif structures in the 5′ end of the retinoblastoma (Rb) gene was examined using chemical modifications, circular dichroism (CD) and fluorescence spectroscopy. It was found that substitutions of 8-methylguanine at positions that show syn conformations in antiparallel G-quadruplexes stabilize the structure in the G-rich strand. The complementary C-rich 18mer forms an i-motif structure, as suggested by CD spectroscopy. Based on the C to T mutation experiments, C bases participated in the C–C⁺ base pair of the i-motif structure were determined. Experiments of 2-aminopurine (2-AP) substitution reveal that an increase of fluorescence in the G-quadruplex relative to duplex is attributed to unstacked 2-AP within the loop of G-quadruplex. The fluorescence experiments suggest that formation of the G-quadruplex and i-motif can compete with duplex formation. Furthermore, a polymerase arrest assay indicated that formation the G-quadruplex structure in the Rb gene acts as a barrier in DNA synthesis.

Guanine-rich DNA nanocircles for the synthesis and characterization of long cytosine-rich telomeric DNAs

Short synthetic oligonucleotides derived from the human telomeric repeat have been studied recently for their ability to fold into four-stranded structures that are thought to be important to their biological function. Because telomeric DNAs are several kilobases in length, however, their folding might well be affected by cooperative or high-order interactions in these long sequences. Here, we present a new molecular system that allows for easy synthesis of very long stretches of the cytosine-rich strand of human telomeric DNA. Small circular DNAs composed of the G-rich sequence of human telomeres were prepared and used as templates in a rolling-circle replication mechanism. To facilitate the synthesis of the repetitive G-rich circles, an orthogonal base-protection strategy that made use of dimethylformamidine-protected guanine nucleobases was developed. Nanometer-scale circles ranging in size from 42 to 54 nucleotides were prepared. Subsequently, we tested the action of various DNA polymerases on these circular templates, and identified DNA Pol I (Klenow fragment) and T7 DNA polymerase as enzymes that are able to generate very long, C-rich telomeric DNA strands. Purification and initial structural examination of these C-rich polymeric products revealed evidence of a folded structure in the polymer.

Quadruplex-duplex competition in the nuclease hypersensitive element of human c-myc promoter: C to T mutation in C-rich strand enhances duplex association

The nuclease hypersensitive element NHE III(I) is an important anti-cancer target as the transcription of oncogene c-myc is largely regulated by it. It has been postulated that regulatory control is mediated by G-quadruplex formation in the NHE anti-sense strand through a competition between the duplex and the quadruplex states. A mutation in the NHE has been implicated in cancer. In this study, the reported mutation has been characterized vis-a-vis the kinetics of i-tetraplex formation (in the sense strand) and its effect on duplex formation. We found that i-tetraplex formation was destabilized by approximately 1.4 kcal/mol (DeltaDeltaG at 20 degrees C, pH 5.8). Observed hysteresis allowed us to analyze the kinetics of folding for the mutant (M3). Though we observed higher association (DeltaEon approximately -23.4 kcal/mol) and dissociation (DeltaEoff approximately 22.1 kcal/mol) activation energies (at pH 5.3) for the wild-type (P1) tetraplex folding, the kinetics of folding and unfolding for M3 was somewhat faster at pH 5.3 and 5.8. Interestingly, Surface plasmon resonance (BIAcore) analysis of hybridization at pH 6.6 indicated a higher association constant for M3 (approximately 22.5 x 10(4)M(-1)s(-1)) than P1 (approximately 3.2 x 10(4)M(-1)s(-1)). The equilibrium dissociation constants also indicated favorable duplex association for M3 (approximately 22.2 and approximately 190.6 nM for M3 and P1, respectively). We envisage that the increased affinity for the duplex state due to the mutation could play a functional role in the aberrant regulation of c-myc.

Small circular DNAs for synthesis of the human telomere repeat: varied sizes, structures and telomere-encoding activities

We describe the construction, structural properties and enzymatic substrate abilities of a series of circular DNA oligonucleotides that are entirely composed of the C-rich human telomere repeat, (CCCTAA)n. The nanometer-sized circles range in length from 36 to 60 nt, and act as templates for synthesis of human telomere repeats in vitro. The circles were constructed successfully by the application of a recently developed adenine-protection strategy, which allows for cyclization/ligation with T4 DNA ligase. Thermal denaturation studies showed that at pH 5.0, all five circles form folded structures with similar stability, while at pH 7.0 no melting transitions were seen. Circular dichroism spectra at the two pH conditions showed evidence for i-motif structures at the lower pH value. The series was tested as rolling circle templates for a number of DNA polymerases at pH = 7.3-8.5, using 18mer telomeric primers. Results showed that surprisingly small circles were active, although the optimum size varied from enzyme to enzyme. Telomeric repeats >>1000 nt in length could be synthesized in 1 h by the Klenow (exo-) DNA polymerase. The results establish a convenient way to make long human telomeric repeats for in vitro study of their folding and interactions, and establish optimum molecules for carrying this out.

Thermodynamics of i-tetraplex formation in the nuclease hypersensitive element of human c-myc promoter

More than 85% of c-myc transcription is controlled by the nuclease hypersensitive element III(1) upstream of the P1 promoter of this oncogene. The purine-rich sequence in the anti-sense strand forms a G-quadruplex, which has been recently implicated in colorectal cancer, and is proposed as a silencer element [Proc. Natl. Acad. Sci. USA 101 (2004) 6140]. This prompted us to characterize the thermodynamics and proton/counterion effect of the complementary pyrimidine-rich sequence, which forms a C-tetraplex. We report the thermodynamic parameters for folding of the pyrimidine-rich DNA fragment from this region into a C-tetraplex. At 20 degrees C, we observed a DeltaG of -10.36+/-0.13kcalmol(-1) with favorable enthalpy (DeltaH=75.99+/-0.99kcalmol(-1)) and unfavorable entropy (TDeltaS=65.63+/-0.88 kcalmol(-1)) at pH 5.3 in 20mM NaCl for tetraplex folding. Similar characteristic stabilizing enthalpy and destabilizing entropy were observed at other pH and ionic strengths. Folding was induced by uptake of about two to three protons per mole of tetraplex while a marginal (0.5-1mol/mol) counterion uptake was observed. In the context of current understanding of c-myc transcription we envisage a role of the i-motif in remodeling the G-quadruplex silencer.