Stability of human telomere quadruplexes at high DNA concentrations

For mimicking macromolecular crowding of DNA quadruplexes, various crowding agents have been used, typically PEG, with quadruplexes of micromolar strand concentrations. Thermal and thermodynamic stabilities of these quadruplexes increased with the concentration of the agents, the rise depended on the crowder used. A different phenomenon was observed, and is presented in this article, when the crowder was the quadruplex itself. With DNA strand concentrations ranging from 3 µM to 9 mM, the thermostability did not change up to ～2 mM, above which it increased, indicating that the unfolding quadruplex units were not monomolecular above ～2 mM. The results are explained by self‐association of the G‐quadruplexes above this concentration. The ΔG^o₃₇ values, evaluated only below 2 mM, did not become more negative, as with the non‐DNA crowders, instead, slightly increased. Folding topology changed from antiparallel to hybrid above 2 mM, and then to parallel quadruplexes at high, 6–9 mM strand concentrations. In this range, the concentration of the DNA phosphate anions approached the concentration of the K⁺ counterions used. Volume exclusion is assumed to promote the topological changes of quadruplexes toward the parallel, and the decreased screening of anions could affect their stability. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 428–438, 2014.     

Substitution of adenine for guanine in the quadruplex-forming human telomere DNA sequence G(3)(T(2)AG(3))(3)

We have studied the formation and structural properties of quadruplexes of the human telomeric DNA sequence G(3)(T(2)AG(3))(3) and related sequences in which each guanine base was replaced by an adenine base. None of these single base substitutions hindered the formation of antiparallel quadruplexes, as shown by circular dichroism, gel electrophoresis, and UV thermal stability measurements in NaCl solutions. Effect of substitution did differ, however, depending on the position of the substituted base. The A-for-G substitution in the middle quartet of the antiparallel basket scaffold led to the most distorted and least stable structures and these sequences preferred to form bimolecular quadruplexes. Unlike G(3)(T(2)AG(3))(3), no structural transitions were observed for the A-containing analogs of G(3)(T(2)AG(3))(3) when sodium ions were replaced by potassium ions. The basic quadruplex topology remained the same for all sequences studied 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 have biological relevance.     

Synthesis and characterization of DNA quadruplexes containing T-tetrads formed by bunch-oligonucleotides

The solid phase syntheses of the bunch oligonucleotides and based on the sequences of the natural oligodeoxynucleotides (ODNs) d(TG2TG2C) and d(CG2TG2T), respectively, attached to a non-nucleotidic tetrabranched linker, are reported. Bunch-ODNs and were shown to form more stable monomolecular parallel G-quadruplexes and when compared with their tetramolecular counterparts [d(TG2TG2C)]4 and [d(CG2TG2T)]4, respectively. The structure and stability of all the synthesized complexes have been investigated by circular dichroism (CD), CD thermal denaturation experiments, and 1H-NMR (nuclear magnetic resonance) experiments at variable temperatures. Particularly, the spectroscopic data confirmed that 1 adopts a T-tetrad containing parallel-stranded quadruplex structure as in the tetramolecular complex.     

Recognition of human telomeric G‐quadruplex DNA by berberine analogs: effect of substitution at the 9 and 13 positions of the isoquinoline moiety

G‐quadruplex forming sequences are widely distributed in human genome and serve as novel targets for regulating gene expression and chromosomal maintenance. They offer unique targets for anticancer drug development. Here, the interaction of berberine (BC) and two of its analogs bearing substitution at 9 and 13‐position with human telomeric G‐quadruplex DNA sequence has been investigated by biophysical techniques. Both the analogs exhibited several‐fold higher binding affinity than berberine. The Scatchard binding isotherms revealed non‐cooperative binding. 9‐ω‐amino hexyl ether analog (BC1) showed highest affinity (1.8 × 10⁶ M^?1) while the affinity of the 13‐phenylpropyl analog (BC2) was 1.09 × 10⁶ M^?1. Comparative fluorescence quenching and polarization anisotropy of the emission spectra gave evidence for a stronger stacking interaction of the analogs compared to berberine. The thiazole orange displacement assay has clearly established that the analogs were more effective in displacing the end stacked dye in comparison to berberine. However, the binding of the analogs did not induce any major structural perturbation in the G‐quadruplex structure, but led to higher thermal stability. Energetics of the binding indicated that the association of the analogs was exothermic and predominantly entropy driven phenomenon. Increasing the temperature resulted in weaker binding; the enthalpic contribution increased and the entropic contribution decreased. A small negative heat capacity change with significant enthalpy–entropy compensation established the involvement of multiple weak noncovalent interactions in the binding process. The 9‐ω‐amino hexyl ether analog stabilized the G‐quadruplex structure better than the 13‐phenyl alkyl analog. Copyright © 2015 John Wiley & Sons, Ltd.     

Insight into the molecular recognition of spermine by DNA quadruplexes from an NMR study of the association of spermine with the thrombin‐binding aptamer

The preferred residence sites and the conformation of DNA‐bound polyamines are central to understanding the regulatory roles of polyamines. To this end, we have used a series of selective ¹³C‐edited and selective total correlation spectroscopy‐edited one‐dimensional (1D) nuclear Overhauser effect spectroscopy NMR experiments to determine a number of intramolecular ¹H nuclear Overhauser effect (NOE) connectivities in ¹³C‐labelled spermine bound to the thrombin‐binding aptamer. The results provide evidence that the aptamer‐bound spermine adopts a conformation that optimizes electrostatic and hydrogen bond contacts with the aptamer backbone. The distance between the nitrogen atoms of the central aminobutyl is reduced by an increase in the population of gauche conformers at the C6–C7 bonds, which results in either a curved or S‐shaped spermine conformation. Molecular modelling contributes insight toward the mode of spermine binding of these spermine structures within the narrow grooves of DNA quadruplexes. In each case, the N5 ammonium group makes hydrogen bonds with two nearby phosphates across the narrow groove. Our results have implications for the understanding of chromatin structure and the rational design of quadruplex‐binding drugs. Copyright © 2013 John Wiley & Sons, Ltd.     

Formation of G‐wires,bimolecular and tetramolecular quadruplex: Cation‐induced structural polymorphs of G‐rich DNA sequence of human SYTX gene

An exceptional property of auto‐folding into a range of intra‐ as well as intermolecular quadruplexes by guanine‐rich oligomers (GROs) of promoters, telomeres and various other genomic locations is still one of the most attractive areas of research at present times. The main reason for this attention is due to their established in vivo existence and biological relevance. Herein, the structural status of a 20‐nt long G‐rich sequence with two G5 stretches (SG20) is investigated using various biophysical and biochemical techniques. Bioinformatics analysis suggested the presence of a 17‐nt stretch of this SG20 sequence in the intronic region of human SYTX (Synaptotagmin 10) gene. The SYTX gene helps in sensing out the Ca²⁺ ion, causing its intake in the pre‐synaptic neuron. A range of various topologies like bimolecular, tetramolecular and guanine‐wires (nano‐wires) was exhibited by the studied sequence, as a function of cations (Na⁺/K⁺) concentration. UV‐thermal denaturation, gel electrophoresis, and circular dichroism (CD) spectroscopy showed correlations and established a cation‐dependent structural switch. The G‐wire formation, in the presence of K⁺, may further be explored for its possible relevance in nano‐biotechnological applications.     

Towards a better understanding of the unusual conformations of the alternating guanine-adenine repeat strands of DNA

Alternating guanine-adenine strands of DNA are known to self-associate into a parallel-stranded homoduplex at neutral pH, fold into an ordered single-stranded structure at acid pH, and adopt yet another ordered single-stranded conformer in aqueous ethanol. The unusual conformers melt cooperatively and exhibit distinct circular dichroism spectra suggestive of a substantial conformational order, but their molecular structures are not known yet. Here, we have probed the molecular structures using guanine and adenine analogs lacking the N7 atom, and thus unable of Hoogsteen pairing, or those restrained in the less-frequent syn glycosidic orientation. The studies showed that the syn glycosidic orientation of dA residues promoted the neutral homoduplex, whereas the syn orientation of dG was incompatible with the homoduplex. In addition, Hoogsteen pairing of dA seemed to be a crucial property of the homoduplex whereas dG did not pair in this way. The situation was the same in both single-stranded conformers with the dG residues. On the other hand, the presence of N7 was important with dA but its syn geometry was not favorable. The present data can be used as restraints to model the unusual molecular structures of the alternating guanine-adenine strands of DNA.     

Ethanol is a better inducer of DNA guanine tetraplexes than potassium cations

Guanine tetraplexes are a biologically relevant alternative of the Watson and Crick duplex of DNA. It is thought that potassium or other cations present in the cavity between consecutive guanine tetrads are an integral part of the tetraplexes. Here we show using CD spectroscopy that ethanol induces the guanine tetraplexes like or even better than potassium cations. We present examples of ethanol stabilizing guanine tetraplexes even in cases when potassium cations fail to do so. Hence, besides the A-form or Z-form, ethanol stabilizes another conformation of DNA, i.e., the guanine tetraplexes. We discuss the mechanism of the stabilization. Use of ethanol will permit studies of guanine tetraplexes that cannot be induced by potassium cations or other tetraplex-promoting agents. This work demonstrates that a still broader spectrum of nucleotide sequences can fold into guanine tetraplexes than has previously been thought. Aqueous ethanol may better simulate conditions existing in vivo than the aqueous solutions.     

Sequence specificity of inter- and intramolecular G-quadruplex formation by human telomeric DNA

Human telomeric DNA consists of tandem repeats of the sequence 5'-d(TTAGGG)-3'. Guanine-rich DNA, such as that seen at telomeres, forms G-quadruplex secondary structures. Alternative forms of G-quadruplex structures can have differential effects on activities involved in telomere maintenance. With this in mind, we analyzed the effect of sequence and length of human telomeric DNA on G-quadruplex structures by native polyacrylamide gel electrophoresis and circular dichroism. Telomeric oligonucleotides shorter than four, 5'-d(TTAGGG)-3' repeats formed intermolecular G-quadruplexes. However, longer telomeric repeats formed intramolecular structures. Altering the 5'-d(TTAGGG)-3' to 5'-d(TTAGAG)-3' in any one of the repeats of 5'-d(TTAGGG)(4)-3' converted an intramolecular structure to intermolecular G-quadruplexes with varying degrees of parallel or anti-parallel-stranded character, depending on the length of incubation time and DNA sequence. These structures were most abundant in K(+)-containing buffers. Higher-order structures that exhibited ladders on polyacrylamide gels were observed only for oligonucleotides with the first telomeric repeat altered. Altering the sequence of 5'-d(TTAGGG)(8)-3' did not result in the substantial formation of intermolecular structures even when the oligonucleotide lacked four consecutive telomeric repeats. However, many of these intramolecular structures shared common features with intermolecular structures formed by the shorter oligonucleotides. The wide variability in structure formed by human telomeric sequence suggests that telomeric DNA structure can be easily modulated by proteins, oxidative damage, or point mutations resulting in conversion from one form of G-quadruplex to another.     

Sequence effects of single base loops in intramolecular quadruplex DNA

We have examined the properties of intramolecular G-quadruplexes in which the G3 tracts are separated by single base loops. The most stable complex contained 1',2'-dideoxyribose in all three loops, while loops containing T and C were slightly less stable (by about 2 degrees C). Quadruplexes containing loops with single A residues were less stable by 8 degrees C for each T to A substitution. These folded sequences display similar CD spectra, which are consistent with the formation of parallel stranded complexes with double-chain reversal loops. These results demonstrate that loop sequence, and not just length, affects quadruplex stability.     

Biophysical properties of quadruple helices of modified human telomeric DNA

Telomeric DNA of a variety of vertebrates including humans contains the tandem repeat d(TTAGGG)n. The guanine rich strand can fold into four-stranded G-quadruplex structures, which have recently become attractive for biomedical research. Indeed, the aptamers based on the quadruplex motif may prove useful as tools aimed at binding and inhibiting particular proteins, catalyzing various biochemical reactions, or even serving as pharmaceutically active agents. The incorporation of modified bases into oligonucleotides can have profound effects on their folding and may produce useful changes in physical and biological properties of the resulting DNA fragments. In this work, the adenines of the human telomeric repeat oligonucleotide d(TAGGGT) and d(AGGGT) were substituted by 2'-deoxy-8-(propyn-1-yl)adenosine (A-->APr) or by 8-bromodeoxyadenosine (A-->ABr). The biophysical properties of the resulting quadruplex structures were compared with the unmodified quadruplexes. NMR and CD spectra of the studied sequences were characteristic of parallel-stranded, tetramolecular quadruplexes. The analysis of the equilibrium melting curves reveals that the modifications stabilize the quadruplex structure. The results are useful when considering the design of novel aptameric nucleic acids with diverse molecular recognition capabilities that would not be present using native RNA/DNA sequences.     

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.     

Circular dichroism spectra of DNA quadruplexes [d(G(5)T(5))](4) as formed with G(4) and T(4) tetrads and [d(G(5)T(5)). d(A(5)C(5))]2 as formed with Watson-Crick-like (G-C)(2) and (T-A)(2) tetrads

We utilize electrophoresis and find that a thermally treated equimolar mixture of the oligonucleotide d(G(5)T(5)) and its complementary oligonucleotide d(A(5)C(5)) exhibits either two bands or a single band in one lane, depending on the conditions of the incubation solutions. The thermally treated d(G(5)T(5)) solution loaded in a different lane exhibits a single band of the parallel quadruplex [d(G(5)T(5))](4), which is composed of homocyclic hydrogen-bonded G(4) and T(4) tetrads previously proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(A(5)C(5)), the fast band is assigned to a Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex, so that the slow band with the same low mobility as that of [d(G(5)T(5))](4) may be assigned to either [d(G(5)T(5))](4) itself or a [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex. If the latter compound is true, this may be the antiparallel quadruplex composed of the heterocyclic hydrogen-bonded G-C-G-C and T-A-T-A tetrads proposed previously. After removing these three bands for the duplex and two kinds of hypothetical quadruplexes, we electrophoretically elute the corresponding compounds in the same electrophoresis buffer using an electroeluter. The eluted compounds are ascertained to be stable by electrophoresis. The circular dichroism (CD) and UV absorption spectra measured for the three isolated compounds are found to be clearly different. For the electrophoretic elution of the hypothetical [d(G(5)T(5))](4) quadruplex, the result of the molecularity of n = 4 obtained from the CD melting curve analysis provides further support for the formation of the parallel [d(G(5)T(5))](4) quadruplex already proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(C(5)A(5)), the fast band with a molecularity of n = 2 corresponds to the Watson-Crick duplex, d(G(5)T(5)). d(A(5)C(5)). The slow band with a molecularity of n = 4 indicates the antiparallel quadruplex [d(G(5)T(5)). d(A(5)C(5))](2), whose observed CD and UV spectra are different from those of [d(G(5)T(5))](4). By electrophoresis, after reannealing the eluted compound [d(G(5)T(5)). d(A(5)C(5))](2), a distinct photograph showing the band splitting of this quadruplex band into the lower duplex and upper quadruplex bands is not possible; but by a transilluminator, we occasionally observe this band splitting with the naked eye. The linear response polarizability tensor calculations for the thus determined structures of the [d(G(5)T(5))](4) quadruplex, the McGavin-like [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex, and the Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex are found to qualitatively predict the observed CD and UV spectra.     

DNA G-quadruplexes are uniquely stable in the presence of denaturants and monovalent cations

Ions in the Hofmeister series exhibit varied effects on biopolymers. Those classed as kosmotropes generally stabilize secondary structure, and those classed as chaotropes generally destabilize secondary structure. Here, we report that several anionic chaotropes exhibit unique effects on one DNA secondary structure - a G quadruplex. These chaotropes exhibit the expected behaviour (destabilization of secondary structure) in two other structural contexts: a DNA duplex and i-Motifs. Uniquely among secondary structures, we observe that G quadruplexes are comparatively insensitive to the presence of anionic chaotropes, but not other denaturants. Further, the presence of equimolar NaCl provided greater mitigation of the destabilization caused by other non-anionic denaturants. These results are consistent with the presence of monovalent cations providing an especially pronounced stabilizing effect to G quadruplexes when studied in denaturing solution conditions.     

Comparison of intramolecular and intermolecular reactions in protein folding

The intrinsic component of the standard free energy change for the formation of a disulfide bond in a protein molecule is compared to that for an analogous chemical reaction. The former reaction, which represents theintramolecular formation of a disulfide bond in a protein molecule from a cysteine group containing a mixed disulfide bond with glutathione, and a free cysteine residue, is a unimolecular reaction. In contrast, its chemical analogue is a bimolecular reaction, and corresponds to theintermolecular disulfide interchange between a mixed disulfide-bonded compound between a cysteine residue and glutathione, and a free cysteine molecule. The difference in the intrinsic free energy of the above two reactions is estimated by two different approaches. First, a theoretical estimate of the magnitude of the difference in free energy of the two reactions (for a standard state of 1 M) is obtained using a gas-phase statistical thermodynamic approach, which indicates that the intramolecular reaction is energetically favored over its intermolecular counterpart by as much as 15.6 kcal/mole. For comparison, an experimentally derived value is also obtained, using experimental data from a study by Konishi et al. of the regeneration of the protein ribonuclease A (RNase A) from its reduced form by reduced and oxidized glutathiones. The intrinsic component of the free energy change of the intramolecular reaction, as it occurs in the protein molecule, is obtained from such experimental data by accounting explicitly for the free energy change (assumed to be solely an entropy change) pertaining to the conformational changes (ring closure) that the protein molecule undergoes in the course of the reaction. On the basis of the value derived from such an experimental approach, the intramolecular reaction is also energetically more favorable as compared to its intermolecular analogue, but only by a difference of 2.3 kcal/mole (for a standard state of 1 M). The large apparent discrepancy between the two values estimated from the theoretical and experimental approaches is rationalized by the postulation of several additional factors not inherent in the gas-phase theoretical estimate, such as dehydration and intramolecular hydrogen-bonding effects, which can largely compensate for the otherwise favorable energetics of the intramolecular reaction.     

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.     

The effect of temperature on DNA structural transitions under the action of Cu2+ and Ca2+ ions in aqueous solutions

The work examines the structural transitions of DNA under the action of Cu2+ and Ca2+ ions in aqueous solution at temperatures of 29 and 45 degrees C by ir spectroscopy. Upon binding to the divalent ions studied, DNA transits into the compact state both at 29 and 45 degrees C. In the compact state DNA remains in B-form limits. The compaction process is of high positive cooperativity. As temperature increases the divalent metal ion concentration required to induce DNA compaction decreases in the case of Cu(2+)-induced compaction and increases in the case of Ca(2+)-induced compaction. It is suggested that the mechanism of the temperature effect on DNA compaction in the presence of Cu2+ ions possessing higher affinity for DNA bases differs from that of the temperature influence on Ca(2+)-induced DNA compaction. In the case of copper ions the determining factor is the increase of binding constants of the Cu2+ ions interacting with the denatured parts formed on DNA while in the case of calcium ions it is the decreased screening action of counterions upon the increase of their hydration with temperature. The efficiency of divalent metal ions studied in inducing DNA compaction depends on hydration of counterions. DNA compaction occurs in a narrow interval of Cu2+ concentrations. As the Cu2+ ion concentration increases, DNA compaction is replaced with Cu(2+)-induced DNA aggregation. At elevated temperatures Cu(2+)-induced DNA compaction could acquire a phase transition character.     

Diverse modes of 5′‐[4‐(aminoiminomethyl)phenyl]‐[2,2′‐bifuran]‐5‐carboximidamide (DB832) interaction with multi‐stranded DNA structures

The modes of binding of 5′‐[4‐(aminoiminomethyl)phenyl]‐[2,2′‐Bifuran]‐5‐carboximidamide (DB832) to multi‐stranded DNAs: human telomere quadruplex, monomolecular R‐triplex, pyr/pur/pyr triplex consisting of 12 T*(T·A) triplets, and DNA double helical hairpin were studied. The optical adsorption of the ligand was used for monitoring the binding and for determination of the association constants and the numbers of binding sites. CD spectra of DB832 complexes with the oligonucleotides and the data on the energy transfer from DNA bases to the bound DB832 assisted in elucidating the binding modes. The affinity of DB832 to the studied multi‐stranded DNAs was found to be greater (K_ass ≈ 10⁷M^?1) than to the duplex DNA (K_ass ≈ 2 × 10⁵M^?1). A considerable stabilizing effect of DB832 binding on R‐triplex conformation was detected. The nature of the ligand tight binding differed for the studied multi‐stranded DNA depending on their specific conformational features: recombination‐type R‐triplex demonstrated the highest affinity for DB832 groove binding, while pyr/pur/pyr TTA triplex favored DB832 intercalation at the end stacking contacts and the human telomere quadruplex d[AG₃(T₂AG₃)₃] accommodated the ligand in a capping mode. Additionally, the pyr/pur/pyr TTA triplex and d[AG₃(T₂AG₃)₃] quadruplex bound DB832 into their grooves, though with a markedly lesser affinity. DB832 may be useful for discrimination of the multi‐sranded DNA conformations and for R‐triplex stabilization. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 8–20, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

G4 motifs affect origin positioning and efficiency in two vertebrate replicators

DNA replication ensures the accurate duplication of the genome at each cell cycle. It begins at specific sites called replication origins. Genome‐wide studies in vertebrates have recently identified a consensus G‐rich motif potentially able to form G‐quadruplexes (G4) in most replication origins. However, there is no experimental evidence to demonstrate that G4 are actually required for replication initiation. We show here, with two model origins, that G4 motifs are required for replication initiation. Two G4 motifs cooperate in one of our model origins. The other contains only one critical G4, and its orientation determines the precise position of the replication start site. Point mutations affecting the stability of this G4 in vitro also impair origin function. Finally, this G4 is not sufficient for origin activity and must cooperate with a 200‐bp cis‐regulatory element. In conclusion, our study strongly supports the predicted essential role of G4 in replication initiation.