Probe development for detection of TERRA 1 intramolecular G-quadruplex formation using a fluorescent adenosine derivative

We developed a probing system to detect the intramolecular G-quadruplex of telomeric repeat-containing RNA (TERRA 1). We used a fluorescent adenosine derivative rA^py as a fluorophore and incorporated it into the dangling position of the parallel-type G-quadruplex sequence of TERRA 1. The rA^py-modified G-quadruplex structure exhibited a strong fluorescence emission signal, while the emission signals of the single-strand and duplex structures were much lower.     

Structural insight into DNA-assembled oligochromophores: crystallographic analysis of pyrene- and phenanthrene-modified DNA in complex with BpuJI endonuclease

The use of the DNA duplex as a supramolecular scaffold is an established approach for the assembly of chromophore aggregates. In the absence of detailed structural insight, the characterization of thus assembled oligochromophores is, today, largely based on solution-phase spectroscopy. Here, we describe the crystal structures of three DNA-organized chromophore aggregates. DNA hybrids containing non-nucleosidic pyrene and phenanthrene building blocks were co-crystallized with the recently described binding domain of the restriction enzyme BpuJI. Crystal structures of these complexes were determined at 2.7, 1.9 and 1.6 Å resolutions. The structures reveal aromatic stacking interactions between pyrene and/or phenanthrene units within the framework of the B-DNA duplex. In hybrids containing a single modification in each DNA strand near the end of the duplex, the two polyaromatic hydrocarbons are engaged in a face-to-face stacking orientation. Due to crystal packing and steric effects, the terminal GC base pair is disrupted in all three crystal structures, which results in a non-perfect stacking arrangement of the aromatic chromophores in two of the structures. In a hybrid containing a total of three pyrenes, crystal lattice induced end-to-end stacking of individual DNA duplexes leads to the formation of an extended aromatic π-stack containing four co-axially arranged pyrenes. The aromatic planes of the stacked pyrenes are oriented in a parallel way. The study demonstrates the value of co-crystallization of chemically modified DNA with the recombinant binding domain of the restriction enzyme BpuJI for obtaining detailed structural insight into DNA-assembled oligochromophores.     

Structure and Stability of Human Telomeric G-Quadruplex with Preclinical 9-Amino Acridines

G-quadruplexes are higher-order DNA structures formed from guanine-rich sequences, and have been identified as attractive anticancer drug targets. Elucidating the three-dimensional structure of G-quadruplex with 9-amino acridines and the specific interactions involved in binding selectivity are the key to understanding their mechanism of action. Fluorescence titration assays, competitive dialysis and NMR studies have been used to study the binding specificity of 9-amino acridines to DNA. Structural models of the complexes with the telomeric DNA G-quadruplex based on NMR measurements were developed and further examined by molecular dynamics simulations and free energy calculations. Selective binding of 9-amino acridines for G-quadruplex sequences were observed. These compounds bind between A and G-tetrads, involving significant π-π interactions and several strong hydrogen bonds. The specific interactions between different moieties of the 9-amino acridines to the DNA were examined and shown to play a significant role in governing the overall stabilities of DNA G-quadruplex complexes. Both 9-amino acridines, with similar binding affinities to the G-quadruplex, were shown to induce different level of structural stabilization through intercalation. This unique property of altering structural stability is likely a contributing factor for affecting telomerase function and, subsequently, the observed differences in the anticancer activities between the two 9-amino acridines.     

Evidence of different G-quadruplex DNA binding with biogenic polyamines probed by electrospray ionization-quadrupole time of flight mass spectrometry,circular dichroism and atomic force microscopy

The binding properties of five G-quadruplex oligonucleotides (humtel24, k-ras32, c-myc22, c-kit1 and c-kit2) with polyamines have been investigated by electrospray ionization-quadrupole time of flight mass spectrometry, circular dichroism, melting temperature, atomic force microscopy (AFM) and molecular simulation. The MS results demonstrated that the polyamines and G-quadruplex DNA can form complexes with high affinity, and one molecule of G-quadruplex DNA can combine several molecules (1–5) of polyamines. The binding affinities of the polyamines to DNA were in the order of spermine > spermidine > putrescine. After binding with polyamines, the conformations of the G-quadruplex DNA were significantly changed, and spermine can induce the configurations of k-ras32 and c-kit1 to deviate from their G-quadruplex structures at high concentrations. In the presence of K⁺, the conformations of G-quadruplex DNA were stabilized, while polyamines can also induced alterations of their configurations. Melting temperature experiments suggested that the T_m of the DNA–polyamine complexes obviously increased both in the absence and presence of K⁺. The AFM results indicated that polyamines can induce aggregation of G-quadruplex DNA. Above results illustrated that the polyamines bound with the phosphate backbone and the base-pairs of G-quadruplex structures. Combining with the molecular simulation, the binding mode of the G-quadruplex DNA and polyamines were discussed. The results obtained would be beneficial for understanding the biological and physiological functions of polyamines and provide useful information for development of antitumor drugs.     

G-rich VEGF aptamer with locked and unlocked nucleic acid modifications exhibits a unique G-quadruplex fold

The formation of a single G-quadruplex structure adopted by a promising 25 nt G-rich vascular endothelial growth factor aptamer in a K⁺ rich environment was facilitated by locked nucleic acid modifications. An unprecedented all parallel-stranded monomeric G-quadruplex with three G-quartet planes exhibits several unique structural features. Five consecutive guanine residues are all involved in G-quartet formation and occupy positions in adjacent DNA strands, which are bridged with a no-residue propeller-type loop. A two-residue D-shaped loop facilitates inclusion of an isolated guanine residue into the vacant spot within the G-quartet. The remaining two G-rich tracts of three residues each adopt parallel orientation and are linked with edgewise and propeller loops. Both 5′ with 3 nt and 3′ with 4 nt overhangs display well-defined conformations, with latter adopting a basket handle topology. Locked residues contribute to thermal stabilization of the adopted structure and formation of structurally pre-organized intermediates that facilitate folding into a single G-quadruplex. Understanding the impact of chemical modifications on folding, thermal stability and structural polymorphism of G-quadruplexes provides means for the improvement of vascular endothelial growth factor aptamers and advances our insights into driving nucleic acid structure by locking or unlocking the conformation of sugar moieties of nucleotides in general.     

Preferential binding of a G-quadruplex ligand to human chromosome ends

The G-overhangs of telomeres are thought to adopt particular conformations, such as T-loops or G-quadruplexes. It has been suggested that G-quadruplex structures could be stabilized by specific ligands in a new approach to cancer treatment consisting in inhibition of telomerase, an enzyme involved in telomere maintenance and cell immortality. Although the formation of G-quadruplexes was demonstrated in vitro many years ago, it has not been definitively demonstrated in living human cells. We therefore investigated the chromosomal binding of a tritiated G-quadruplex ligand, ³H-360A (2,6-N,N′-methyl-quinolinio-3-yl)-pyridine dicarboxamide [methyl-³H]. We verified the in vitro selectivity of ³H-360A for G-quadruplex structures by equilibrium dialysis. We then showed by binding experiments with human genomic DNA that ³H-360A has a very potent selectivity toward G-quadruplex structures of the telomeric 3′-overhang. Finally, we performed autoradiography of metaphase spreads from cells cultured with ³H-360A. We found that ³H-360A was preferentially bound to chromosome terminal regions of both human normal (peripheral blood lymphocytes) and tumor cells (T98G and CEM1301). In conclusion, our results provide evidence that a specific G-quadruplex ligand interacts with the terminal ends of human chromosomes. They support the hypothesis that G-quadruplex ligands induce and/or stabilize G-quadruplex structures at telomeres of human cells.     

Double-stranded flanking ends affect the folding kinetics and conformational equilibrium of G-quadruplexes forming sequences within the promoter of KIT oncogene

G-quadruplexes embedded within promoters play a crucial role in regulating the gene expression. KIT is a widely studied oncogene, whose promoter contains three G-quadruplex forming sequences, c-kit1, c-kit2 and c-kit*. For these sequences available studies cover ensemble and single-molecule analyses, although for kit* the latter were limited to a study on a promoter domain comprising all of them. Recently, c-kit2 has been reported to fold according to a multi-step process involving folding intermediates. Here, by exploiting fluorescence resonance energy transfer, both in ensemble and at the single molecule level, we investigated the folding of expressly designed constructs in which, alike in the physiological context, either c-kit2 or c-kit* are flanked by double stranded DNA segments. To assess whether the presence of flanking ends at the borders of the G-quadruplex affects the folding, we studied under the same protocols oligonucleotides corresponding to the minimal G-quadruplex forming sequences. Data suggest that addition of flanking ends results in biasing both the final equilibrium state and the folding kinetics. A previously unconsidered aspect is thereby unravelled, which ought to be taken into account to achieve a deeper insight of the complex relationships underlying the fine tuning of the gene-regulatory properties of these fascinating DNA structures.     

Functional importance of Ψ38 and Ψ39 in distinct tRNAs,amplified for tRNAGln(UUG) by unexpected temperature sensitivity of the s2U modification in yeast

The numerous modifications of tRNA play central roles in controlling tRNA structure and translation. Modifications in and around the anticodon loop often have critical roles in decoding mRNA and in maintaining its reading frame. Residues U₃₈ and U₃₉ in the anticodon stem–loop are frequently modified to pseudouridine (Ψ) by members of the widely conserved TruA/Pus3 family of pseudouridylases. We investigate here the cause of the temperature sensitivity of pus3Δ mutants of the yeast Saccharomyces cerevisiae and find that, although Ψ₃₈ or Ψ₃₉ is found on at least 19 characterized cytoplasmic tRNA species, the temperature sensitivity is primarily due to poor function of tRNA^Gln(UUG), which normally has Ψ₃₈. Further investigation reveals that at elevated temperatures there are substantially reduced levels of the s²U moiety of mcm⁵s²U₃₄ of tRNA^Gln(UUG) and the other two cytoplasmic species with mcm⁵s²U₃₄, that the reduced s²U levels occur in the parent strain BY4741 and in the widely used strain W303, and that reduced levels of the s²U moiety are detectable in BY4741 at temperatures as low as 33°C. Additional examination of the role of Ψ_38,39 provides evidence that Ψ₃₈ is important for function of tRNA^Gln(UUG) at permissive temperature, and indicates that Ψ₃₉ is important for the function of tRNA^Trp(CCA) in trm10Δ pus3Δ mutants and of tRNA^Leu(CAA) as a UAG nonsense suppressor. These results provide evidence for important roles of both Ψ₃₈ and Ψ₃₉ in specific tRNAs, and establish that modification of the wobble position is subject to change under relatively mild growth conditions.     

G-quadruplex preferentially forms at the very 3' end of vertebrate telomeric DNA

Human chromosome ends are protected with kilobases repeats of TTAGGG. Telomere DNA shortens at replication. This shortening in most tumor cells is compensated by telomerase that adds telomere repeats to the 3′ end of the G-rich telomere strand. Four TTAGGG repeats can fold into G-quadruplex that is a poor substrate for telomerase. This property has been suggested to regulate telomerase activity in vivo and telomerase inhibition via G-quadruplex stabilization is considered a therapeutic strategy against cancer. Theoretically G-quadruplex can form anywhere along the long G-rich strand. Where G-quadruplex forms determines whether the 3′ telomere end is accessible to telomerase and may have implications in other functions telomere plays. We investigated G-quadruplex formation at different positions by DMS footprinting and exonuclease hydrolysis. We show that G-quadruplex preferentially forms at the very 3′ end than at internal positions. This property provides a molecular basis for telomerase inhibition by G-quadruplex formation. Moreover, it may also regulate those processes that depend on the structure of the very 3′ telomere end, for instance, the alternative lengthening of telomere mechanism, telomere T-loop formation, telomere end protection and the replication of bulky telomere DNA. Therefore, targeting telomere G-quadruplex may influence more telomere functions than simply inhibiting telomerase.     

Triple-helix mediated excimer and exciplex formation

The synthesis and properties of triple-helical hybrids containing non-nucleosidic polyaromatic building blocks are described. Clamp-type oligonucleotides containing a non-nucleosidic pyrene linker form stable triple helices with a polypurine target strand containing a terminal pyrene or phenanthrene moiety. Stacking interactions between the unnatural building blocks enhance triplex stability and lead to strong excimer or exciplex formation, which is monitored by fluorescence spectroscopy.     

Solution structure of psi32-modified anticodon stem-loop of Escherichia coli tRNAPhe

Nucleoside base modifications can alter the structures and dynamics of RNA molecules and are important in tRNAs for maintaining translational fidelity and efficiency. The unmodified anticodon stem–loop from Escherichia coli tRNA^Phe forms a trinucleotide loop in solution, but Mg²⁺ and dimethylallyl modification of A₃₇ N6 destabilize the loop-proximal base pairs and increase the mobility of the loop nucleotides. The anticodon arm has three additional modifications, ψ₃₂, ψ₃₉, and A₃₇ C2-thiomethyl. We have used NMR spectroscopy to investigate the structural and dynamical effects of ψ₃₂ on the anticodon stem-loop from E.coli tRNA^Phe. The ψ₃₂ modification does not significantly alter the structure of the anticodon stem–loop relative to the unmodified parent molecule. The stem of the RNA molecule includes base pairs ψ₃₂-A₃₈ and U₃₃–A₃₇ and the base of ψ₃₂ stacks between U₃₃ and A₃₁. The glycosidic bond of ψ₃₂ is in the anti configuration and is paired with A₃₈ in a Watson–Crick geometry, unlike residue 32 in most crystal structures of tRNA. The ψ₃₂ modification increases the melting temperature of the stem by ~3.5°C, although the ψ₃₂ and U₃₃ imino resonances are exchange broadened. The results suggest that ψ₃₂ functions to preserve the stem integrity in the presence of additional loop modifications or after reorganization of the loop into a translationally functional conformation.     

Structural basis for uracil DNA glycosylase interaction with uracil: NMR study

Two dimensional (2D) NMR and molecular dynamics simulations have been used to determine the three dimensional (3D) structure of a hairpin DNA, d-CTA-GAGGATCC-TUTT-GGATCCT (22mer; abbreviated as U2-hairpin), which has uracil at the second position from the 5′ end of the tetraloop. The ¹H resonances of this hairpin have been assigned almost completely. NMR restrained molecular dynamics and energy minimization procedures have been used to describe the 3D structure of U2-hairpin. This study establishes that the stem of the hairpin adopts a right-handed B-DNA conformation, while the T₁₂ and T₁₅ nucleotides stack upon 3′ and 5′ ends of the stem, respectively. Further, T₁₄ stacks upon both T₁₂ and T₁₅. Though U₁₃ partially stacks upon T₁₄, no stacking interaction is observed between U₁₃ and T₁₂. All the individual nucleotide bases belonging to the stem and T₁₂ and T₁₅ of the loop adopt ‘anti’ conformation with respect to their sugar moiety, while the U₁₃ and T₁₄ of the loop are in ‘syn’ conformation. The turning phosphate in the loop is located between T₁₃ and T₁₄. This study and a concurrent NMR structural study on yet another hairpin DNA d-CTAGAGGAATAA-TTTU-GGATCCT (22mer; abbreviated as U4-hairpin), with uracil at the fourth position from the 5′ end of the tetraloop throw light upon various interactions which have been reported between Escherichia coli uracil DNA glycosylase (UDG) and uracil containing DNA. The of T₁₂ and α, β, γ, and ζ of U₁₃ and γ of T₁₄, which partially influence the local conformation of U₁₃ in U2-hairpin are all locked in ‘trans’ conformation. Such stretched out backbone conformation in the vicinity of U₁₃ could be the reason as to why the U2-hairpin is found to be the poor substrate for its interaction with UDG compared to the other substrates in which the uracil is at first, third and fourth positions of the tetraloop from its 5′ end, as reported earlier by Vinay and Varshney. This study shows that UDG actively promotes the flipping of uracil from a stacked conformation and rules out the possibility of UDG recognizing the flipped out uracil bases.     

Epigenetic Regulation of Cardiac Progenitor Cells Marker c-kit by Stromal Cell Derived Factor-1α

Background

Cardiac progenitor cells (CPCs) have been proven suitable for stem cell therapy after myocardial infarction, especially c-kit(+)CPCs. CPCs marker c-kit and its ligand, the stem cell factor (SCF), are linked as c-kit/SCF axis, which is associated with the functions of proliferation and differentiation. In our previous study, we found that stromal cell-derived factor-1α (SDF-1α) could enhance the expression of c-kit. However, the mechanism is unknown.

Methods and Results

CPCs were isolated from adult mouse hearts, c-kit(+) and c-kit(−) CPCs were separated by magnetic beads. The cells were cultured with SDF-1α and CXCR4-selective antagonist AMD3100, and c-kit expression was measured by qPCR and Western blotting. Results showed that SDF-1α could enhance c-kit expression of c-kit(+)CPCs, made c-kit(−)CPCs expressing c-kit, and AMD3100 could inhibit the function of SDF-1α. After the intervention of SDF-1α and AMD3100, proliferation and migration of CPCs were measured by CCK-8 and transwell assay. Results showed that SDF-1α could enhance the proliferation and migration of both c-kit(+) and c-kit(−) CPCs, and AMD3100 could inhibit these functions. DNA methyltransferase (DNMT) mRNA were measured by qPCR, DNMT activity was measured using the DNMT activity assay kit, and DNA methylation was analyzed using Sequenom''s MassARRAY platform, after the CPCs were cultured with SDF-1α. The results showed that SDF-1α stimulation inhibited the expression of DNMT1 and DNMT3β, which are critical for the maintenance of regional DNA methylation. Global DNMT activity was also inhibited by SDF-1α. Lastly, SDF-1α treatment led to significant demethylation in both c-kit(+) and c-kit(−) CPCs.

Conclusions

SDF-1α combined with CXCR4 could up-regulate c-kit expression of c-kit(+)CPCs and make c-kit(−)CPCs expressing c-kit, which result in the CPCs proliferation and migration ability improvement, through the inhibition of DNMT1 and DNMT3β expression and global DNMT activity, as well as the subsequent demethylation of the c-kit gene.     

Sugar-modified G-quadruplexes: effects of LNA-, 2′F-RNA– and 2′F-ANA-guanosine chemistries on G-quadruplex structure and stability

G-quadruplex-forming oligonucleotides containing modified nucleotide chemistries have demonstrated promising pharmaceutical potential. In this work, we systematically investigate the effects of sugar-modified guanosines on the structure and stability of a (4+0) parallel and a (3+1) hybrid G-quadruplex using over 60 modified sequences containing a single-position substitution of 2′-O-4′-C-methylene-guanosine (^LNAG), 2′-deoxy-2′-fluoro-riboguanosine (^FG) or 2′-deoxy-2′-fluoro-arabinoguanosine (^FANAG). Our results are summarized in two parts: (I) Generally, ^LNAG substitutions into ‘anti’ position guanines within a guanine-tetrad lead to a more stable G-quadruplex, while substitutions into ‘syn’ positions disrupt the native G-quadruplex conformation. However, some interesting exceptions to this trend are observed. We discover that a ^LNAG modification upstream of a short propeller loop hinders G-quadruplex formation. (II) A single substitution of either ^FG or ^FANAG into a ‘syn’ position is powerful enough to perturb the (3+1) G-quadruplex. Substitution of either ^FG or ^FANAG into any ‘anti’ position is well tolerated in the two G-quadruplex scaffolds. ^FANAG substitutions to ‘anti’ positions are better tolerated than their ^FG counterparts. In both scaffolds, ^FANAG substitutions to the central tetrad layer are observed to be the most stabilizing. The observations reported herein on the effects of ^LNAG, ^FG and ^FANAG modifications on G-quadruplex structure and stability will enable the future design of pharmaceutically relevant oligonucleotides.     

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.     

Structural Basis Underlying the Binding Preference of Human Galectins-1, -3 and -7 for Galβ1-3/4GlcNAc

Galectins represent β-galactoside-binding proteins and are known to bind Galβ1-3/4GlcNAc disaccharides (abbreviated as LN1 and LN2, respectively). Despite high sequence and structural homology shared by the carbohydrate recognition domain (CRD) of all galectin members, how each galectin displays different sugar-binding specificity still remains ambiguous. Herein we provided the first structural evidence of human galectins-1, 3-CRD and 7 in complex with LN1. Galectins-1 and 3 were shown to have higher affinity for LN2 than for LN1, while galectin-7 displayed the reversed specificity. In comparison with the previous LN2-complexed structures, the results indicated that the average glycosidic torsion angle of galectin-bound LN1 (ψ^LN1 ≈ 135°) was significantly differed from that of galectin-bound LN2 (ψ^LN2 ≈ -108°), i.e. the GlcNAc moiety adopted a different orientation to maintain essential interactions. Furthermore, we also identified an Arg-Asp/Glu-Glu-Arg salt-bridge network and the corresponding loop (to position the second Asp/Glu residue) critical for the LN1/2-binding preference.     

Annular Anionic Lipids Stabilize the Integrin αIIbβ3 Transmembrane Complex

Cationic membrane-proximal amino acids determine the topology of membrane proteins by interacting with anionic lipids that are restricted to the intracellular membrane leaflet. This mechanism implies that anionic lipids interfere with electrostatic interactions of membrane proteins. The integrin αIIbβ3 transmembrane (TM) complex is stabilized by a membrane-proximal αIIb(Arg⁹⁹⁵)-β3(Asp⁷²³) interaction; here, we examine the influence of anionic lipids on this complex. Anionic lipids compete for αIIb(Arg⁹⁹⁵) contacts with β3(Asp⁷²³) but paradoxically do not diminish the contribution of αIIb(Arg⁹⁹⁵)-β3(Asp⁷²³) to TM complex stability. Overall, anionic lipids in annular positions stabilize the αIIbβ3 TM complex by up to 0.50 ± 0.02 kcal/mol relative to zwitterionic lipids in a headgroup structure-dependent manner. Comparatively, integrin receptor activation requires TM complex destabilization of 1.5 ± 0.2 kcal/mol, revealing a sizeable influence of lipid composition on TM complex stability. We implicate changes in lipid headgroup accessibility to small molecules (physical membrane characteristics) and specific but dynamic protein-lipid contacts in this TM helix-helix stabilization. Thus, anionic lipids in ubiquitous annular positions can benefit the stability of membrane proteins while leaving membrane-proximal electrostatic interactions intact.     

Completing the family of human Eps15 homology domains: Solution structure of the internal Eps15 homology domain of γ‐synergin

Eps15 homology (EH) domains are universal interaction domains to establish networks of protein–protein interactions in the cell. These networks mainly coordinate cellular functions including endocytosis, actin remodeling, and other intracellular signaling pathways. They are well characterized in structural terms, except for the internal EH domain from human γ‐synergin (EHγ). Here, we complete the family of EH domain structures by determining the solution structure of the EHγ domain. The structural ensemble follows the canonical EH domain fold and the identified binding site is similar to other known EH domains. But EHγ differs significantly in the N‐ and C‐terminal regions. The N‐terminal α‐helix is shortened compared to known homologues, while the C‐terminal one is fully formed. A significant proportion of the remaining N‐ and C‐terminal regions are well structured, a feature not seen in other EH domains. Single mutations in both the N‐terminal and the C‐terminal structured extensions lead to the loss of the distinct three‐dimensional fold and turn EHγ into a molten globule like state. Therefore, we propose that the structural extensions in EHγ function as a clamp and are undoubtedly required to maintain its tertiary fold.