Conformational Preferences of DNA Strands from the Promoter Region of the c-MYC Oncogene

Conformational Propensities of a DNA Hairpin with a Stem Sequence from the c-MYC Promoter

G-quadruplexes and i-motifs are four-stranded non-canonical structures of DNA. They exist in the cell, where they are implicated in the conformational regulation of cellular events, such as transcription, translation, DNA replication, telomere homeostasis, and genomic instability. Formation of the G-quadruplex and i-motif conformations in the genome is controlled by their competition with the pre-existing duplex. The fate of that competition depends upon the relative stabilities of the competing conformations, leading ultimately to a distribution of double helical, tetrahelical, and coiled conformations that coexist in dynamic equilibrium with each other. We previously developed a CD spectroscopy-based procedure to characterize the distribution of conformations adopted by equimolar mixtures of complementary G- and C-rich DNA strands from the promoter regions of the c-MYC, VEGF, and Bcl-2 oncogenes. In those bimolecular systems, duplex-to-tetraplex and duplex-to-coil transitions are accompanied by strand separation and an associated entropic cost. This situation is distinct from the pseudo-monomolecular nature of conformational transformations within the genome, where strand separation does not occur. To mimic better the situation in the genome, we here extend our studies to a monomolecular DNA construct-a hairpin-in which complementary G- and C-rich strands featuring sequences from the promoter region of the c-MYC oncogene are linked by a dT11 loop. We used our CD-based procedure to quantify the distribution of conformational states sampled by the hairpin at pH 5.0 and 7.0 as a function of temperature and the concentration of KCl. The data were analyzed according to a thermodynamic model based on equilibria between the different conformational states to evaluate the thermodynamic properties of the duplex-to-coil, G-quadruplex-to-coil, and i-motif-to-coil transitions of the hairpin. The results have implications for the modulation of such transitions as a means of therapeutic intervention.

CD spectra reveal the state of G-quadruplexes and i-motifs in repeated and other DNA sequences

The B-DNA of the genome contains numerous sequences that can form various noncanonical structures including G-quadruplex (G4), formed by two or more stacks of four guanine residues in a plane, and intercalating motif (i-motif [iM]) formed by alternately arranged C-C+ pairs. One of the easy yet sensitive methods to study G4s and iMs is circular dichroism (CD) spectroscopy, which generates characteristic G4 and iM peaks. We have analyzed and compared the effects of various environmental factors including pH, buffer composition, temperature, flanking sequences, complimentary DNA strands, and single-stranded DNA binding protein (SSB) on the CD patterns of G4s and iMs generated by two groups of DNA molecules, one containing tandem repeats of GGGGCC and CCCCGG from the C9ORF72 gene associated with amyotrophic lateral sclerosis and frontotemporal dementia, and the second containing polyG/polyC clusters from oncogene promoter-proximal regions without such tandem repeats. Changes in pH caused drastic changes in CCCCGG-iM and GGGGCC-G4 and the changes were dependent on repeat numbers and G-C basepairing. In contrast, with the DNA sequences from the promoter-proximal regions of oncogenes, iMs disassembled upon pH changes with the peak slowly shifting to lower wavelength but the G4s did not show significant change. Complementary DNA strands and flanking DNA sequences also regulate G4 and iM formation. The SSB disassembled both G4s and iMs formed by almost all sequences suggesting an in vivo role for SSBs in the disassembly of G4s and iMs during DNA replication and other DNA transactions.

Higher-Order DNA Secondary Structures and Their Transformations: The Hidden Complexities of Tetrad and Quadruplex DNA Structures, Complexes, and Modulatory Interactions Induced by Strand Invasion Events

We demonstrate that a short oligonucleotide complementary to a G-quadruplex domain can invade this iconic, noncanonical DNA secondary structure in ways that profoundly influence the properties and differential occupancies of the resulting DNA polymorphic products. Our spectroscopic mapping of the conformational space of the associated reactants and products, both before and after strand invasion, yield unanticipated outcomes which reveal several overarching features. First, strand invasion induces the disruption of DNA secondary structural elements in both the invading strand (which can assume an iDNA tetrad structure) and the invaded species (a G-quadruplex). The resultant cascade of coupled alterations represents a potential pathway for the controlled unfolding of kinetically trapped DNA states, a feature that may be characteristic of biological regulatory mechanisms. Furthermore, the addition of selectively designed, exogenous invading oligonucleotides can enable the manipulation of noncanonical DNA conformations for biomedical applications. Secondly, our results highlight the importance of metastability, including the interplay between slower and faster kinetic processes in determining preferentially populated DNA states. Collectively, our data reveal the importance of sample history in defining state populations, which, in turn, determine preferred pathways for further folding steps, irrespective of the position of the thermodynamic equilibrium. Finally, our spectroscopic data reveal the impact of topological constraints on the differential stabilities of base-paired domains. We discuss how our collective observations yield insights into the coupled and uncoupled cascade of strand-invasion-induced transformations between noncanonical DNA forms, potentially as components of molecular wiring diagrams that regulate biological processes.

Structural Transitions in Complementary G-Rich and C-Rich Strands and Their Mixture at Various pH Conditions

We used circular dichroism spectroscopy, UV spectrophotometry, and differential scanning calorimetry to investigate pH-dependent structural transitions in an equimolar mixture of complementary G-rich d[5'-A(GGGTTA)3GGG-3'] (TelG) and C-rich d[3'-T(CCCAAT)3CCC-5'] (TelC) human telomeric DNA strands. Our studies were conducted at neutral (pH 7.0) and slightly acidic (pH 5.5 and 6.5) pH. We analyzed the melting thermodynamics of TelG and TelC and their equimolar mixture. Our analysis revealed that the preferred conformation of an equimolar mixture of TelG and TelC is the duplex. At pH 5.5, however, in addition to the duplex state, we observed a significant population of the i-motif state formed by TelC. Our results are consistent with the picture in which an increase in pH from 5.5 to 7.0 has little effect on the melting enthalpy of an isolated G-quadruplex while causing a strong reduction in the melting enthalpy of an isolated i-motif (the latter diminishes to 0 at pH 7.0). These effects summarily lead to a decrease in the contribution of the i-motif to the melting enthalpy of the mixture and, hence, an increase in the apparent melting enthalpy and overall stability of the duplex state.

Probing the Competition between Duplex, G-Quadruplex and i-Motif Structures of the Oncogenic c-Myc DNA Promoter Region

Development of probe systems that provide unique spectral signatures for duplex, G-quadruplex (GQ) and i-motif (iM) structures is very important to understand the relative propensity of a G-rich-C-rich promoter region to form these structures. Here, we devise a platform using a combination of two environment-sensitive nucleoside analogs namely, 5-fluorobenzofuran-modified 2'-deoxyuridine (FBF-dU) and 5-fluoro-2'-deoxyuridine (F-dU) to study the structures adopted by a promoter region of the c-Myc oncogene. FBF-dU serves as a dual-purpose probe containing a fluorescent and 19 F NMR label. When incorporated into the C-rich sequence, it reports the formation of different iMs via changes in its fluorescence properties and 19 F signal. F-dU incorporated into the G-rich ON reports the formation of a GQ structure whose 19 F signal is clearly different from the signals obtained for iMs. Rewardingly, the labeled ONs when mixed with respective complementary strands allows us to determine the relative population of different structures formed by the c-Myc promoter by the virtue of the probe's ability to produce distinct and resolved 19 F signatures for different structures. Our results indicate that at physiological pH and temperature the c-Myc promoter forms duplex, random coil and GQ structures, and does not form an iM. Whereas at acidic pH, the mixture largely forms iM and GQ structures. Taken together, our system will complement existing tools and provide unprecedented insights on the population equilibrium and dynamics of nucleic acid structures under different conditions.

Distribution of Conformational States Adopted by DNA from the Promoter Regions of the VEGF and Bcl-2 Oncogenes

We employed a previously described procedure, based on circular dichroism (CD) spectroscopy, to quantify the distribution of conformational states adopted by equimolar mixtures of complementary G-rich and C-rich DNA strands from the promoter regions of the VEGF and Bcl-2 oncogenes. Spectra were recorded at different pHs, concentrations of KCl, and temperatures. The temperature dependences of the fractional populations of the duplex, G-quadruplex, i-motif, and coiled conformations of each promoter were then analyzed within the framework of a thermodynamic model to obtain the enthalpy and melting temperature of each folded-to-unfolded transition involved in the equilibrium. A comparison of the conformational data on the VEGF and Bcl-2 DNA with similar results on the c-MYC DNA, which we reported previously, reveals that the distribution of conformational states depends on the specific DNA sequence and is modulated by environmental factors. Under the physiological conditions of room temperature, neutral pH, and elevated concentrations of potassium ions, the duplex conformation coexists with the G-quadruplex conformation in proportions that depend on the sequence. This observed conformational diversity has biological implications, and it further supports our previously proposed thermodynamic hypothesis of gene regulation. In that hypothesis, a specific distribution of duplex and tetraplex conformations in a promoter region is fine-tuned to maintain the healthy level of gene expression. Any deviation from a healthy distribution of conformational states may result in pathology stemming from up- or downregulation of the gene.

Volumetric Interplay between the Conformational States Adopted by Guanine-Rich DNA from the c-MYC Promoter

The kinetic and thermodynamic stabilities of G-quadruplex structures have been extensively studied. In contrast, systematic investigations of the volumetric properties of G-quadruplexes determining their pressure stability are still relatively scarce. The G-rich strand from the promoter region of the c-MYC oncogene (G-strand) is known to adopt a range of conformational states including the duplex, G-quadruplex, and coil states depending on the presence of the complementary C-rich strand (C-strand) and solution conditions. In this work, we report changes in volume, ΔV, and adiabatic compressibility, ΔK_S, accompanying interconversions of G-strand between the G-quadruplex, duplex, and coil conformations in the presence and absence of C-strand. We rationalize these volumetric characteristics in terms of the hydration and intrinsic properties of the DNA in each of the sampled conformational states. We further use our volumetric results in conjunction with the reported data on changes in expansibility, ΔE, and heat capacity, ΔC_P, associated with G-quadruplex-to-coil transitions to construct the pressure-temperature phase diagram describing the stability of the G-quadruplex. The phase diagram is elliptic in shape, resembling the classical elliptic phase diagram of a globular protein, and is distinct from the phase diagram for duplex DNA. The observed similarity of the pressure-temperature phase diagrams of G-quadruplexes and globular proteins stems from their shared structural and hydration features that, in turn, result in the similarity of their volumetric properties. To the best of our knowledge, this is the first pressure-temperature stability diagram reported for a G-quadruplex.

Opposite Effects of Potassium Ions on the Thermal Stability of i-Motif DNA in Different Buffer Systems

i-motifs are noncanonical DNA structures formed via the stack of intercalating hemi-protonated C⁺: C base pairs in C-rich DNA strands and play essential roles in the regulation of gene expression. Here, we systematically investigated the impacts of K⁺ on i-motif DNA folding using different buffer systems. We found that i-motif structures display very different T _m values at the same pH and ion strength in different buffer systems. More importantly, K⁺ disrupts the i-motif formed in the MES and Bis-Tris buffer; however, K⁺ stabilizes the i-motif in phosphate, citrate, and sodium cacodylate buffers. Next, we selected phosphate buffer and confirmed by single-molecule fluorescence resonance energy transfer that K⁺ indeed has the stabilizing effect on the folding of i-motif DNA from pH 5.8 to 8.0. Nonetheless, circular dichroism spectra further indicate that the structures formed by i-motif sequences at high K⁺ concentrations at neutral and alkaline pH are not i-motif but other types of higher-order structures and most likely C-hairpins. We finally proposed the mechanisms of how K⁺ plays the opposite roles in different buffer systems. The present study may provide new insights into our understanding of the formation and stability of i-motif DNA.

Remodeling of the Conformational Dynamics of Noncanonical DNA Structures by Monomeric and Aggregated α-Synuclein

Research on Parkinson's disease most often focuses on the ability of the protein α-synuclein (α-syn) to form oligomers and amyloid fibrils, and how such species promote brain death. However, there are indications that α-syn also plays a gene-regulatory role in the cell nucleus. Noncanonical tetrahelical nucleic acids, G-quadruplexes (G4Q), and i-motifs have been shown to play an important role in the control of genomic events. Using the conformation-sensitive single-molecule Förster resonance energy transfer technique we show that monomeric and oligomeric α-syn affect G4Qs and i-motifs in a different way and lead to remodeling of their conformational substates. Aggregated α-syn destabilizes the G4Q leading to unfolding. In contrast, both monomeric and aggregated α-syn enhance folding of the i-motif sequence of telomeric DNA. Importantly, macromolecular crowding is able to partially rescue G4Q from unfolding.

Duplex-tetraplex equilibria in guanine- and cytosine-rich DNA

Noncanonical four-stranded DNA structures, including G-quadruplexes and i-motifs, have been discovered in the cell and are implicated in a variety of genomic regulatory functions. The tendency of a specific guanine- and cytosine-rich region of genomic DNA to adopt a four-stranded conformation depends on its ability to overcome the constraints of duplex base-pairing by undergoing consecutive duplex-to-coil and coil-to-tetraplex transitions. The latter ability is determined by the balance between the free energies of participating ordered and disordered structures. In this review, we present an overview of the literature on the stability of G-quadruplex and i-motif structures and discuss the extent of duplex-tetraplex competition as a function of the sequence context of the DNA and environmental conditions including temperature, pH, salt, molecular crowding, and the presence of G-quadruplex-binding ligands. We outline how the results of in vitro studies can be expanded to understanding duplex-tetraplex equilibria in vivo.

Heat Capacity Changes (ΔCp) for Interconversions between Differentially-Ordered DNA States within Physiological Temperature Domains: Implications for Biological Regulatory Switches

Knowledge of differences in heat capacity changes (ΔC_p) between biopolymer states provides essential information about the temperature dependence of the thermodynamic properties of these states, while also revealing insights into the nature of the forces that drive the formation of functional and dysfunctional biopolymer "order." In contrast to proteins, for nucleic acids there is a dearth of direct experimental determination of this information-rich parameter, a deficiency that compromises interpretations of the ever-increasing thermodynamic analyses of nucleic acid properties; particularly as they relate to differential nucleic acid (meta)stability states and their potential biological functions. Here we demonstrate that such heat capacity differences, in fact, exist not only between traditionally measured native to fully unfolded (assumed "random coil") DNA states, but also between competing order-to-order transformations. We illustrate the experimental approach by measuring the heat capacity change between "native"/ordered, sequence homologous, "isomeric" DNA states that differ in conformation but not sequence. Importantly, these heat capacity differences occur within biologically relevant temperature ranges. In short, we describe a new and general method to measure the value of such heat capacity differences anywhere in experimentally accessible conformational and temperature space; in this case, between two metastable bulge loop states, implicated in DNA expansion diseases, and their competing, fully paired, thermodynamically more stable duplex states. This measurement reveals a ΔC_p of 61 ± 7 cal mol_bp ^-1 K ^-1. Such heat capacity differences between competing DNA "native" ensemble states must be considered when evaluating equilibria between different DNA "ordered" conformations, including the assessment of the differential stabilizing forces and potential biological functions of competing DNA "structured" motifs.

Influence of pH and a porphyrin ligand on the stability of a G-quadruplex structure within a duplex segment near the promoter region of the SMARCA4 gene

In a previous work, the formation of G-quadruplex structures in a 44-nucleotide long sequence found near the promoter region of the SMARCA4 gene was reported. The central 25 nucleotides were able to fold into an antiparallel G-quadruplex structure, the stability of which was pH-dependent. In the present work, the effect of the presence of lateral nucleotides and the complementary cytosine-rich strand on the stability of this G-quadruplex has been characterized. Moreover, the role of the model ligand TMPyP4 has been studied. Spectroscopic and separation techniques, as well as multivariate data analysis methods, have been used with these purposes. The results have shown that stability of the G-quadruplex as a function of pH or temperature is greatly reduced in the presence of the lateral nucleotides. The influence of the complementary strand does not prevent the formation of the G-quadruplex. Moreover, attempts to modulate the equilibria by an external ligand led us to determine the influence of the TMPyP4 porphyrin on these complex equilibria. This study could eventually help to understand the regulation of SMARCA4 expression.