TERRA mimicking ssRNAs prevail over the DNA substrate for telomerase in vitro due to interactions with the alternative binding site

Telomerase is a key component of the telomere length maintenance system in the majority of eukaryotes. Telomerase displays maximal activity in stem and cancer cells with high proliferative potential. In humans, telomerase activity is regulated by various mechanisms, including the interaction with telomere ssDNA overhangs that contain a repetitive G‐rich sequence, and with noncoding RNA, Telomeric repeat‐containing RNA (TERRA), that contains the same sequence. So these nucleic acids can compete for telomerase RNA templates in the cell. In this study, we have investigated the ability of different model substrates mimicking telomere DNA overhangs and TERRA RNA to compete for telomerase in vitro through a previously developed telomerase inhibitor assay. We have shown in this study that RNA oligonucleotides are better competitors for telomerase that DNA ones as RNA also use an alternative binding site on telomerase, and the presence of 2′‐OH groups is significant in these interactions. In contrast to DNA, the possibility of forming intramolecular G‐quadruplex structures has a minor effect for RNA binding to telomerase. Taking together our data, we propose that TERRA RNA binds better to telomerase compared with its native substrate – the 3′‐end of telomere DNA overhang. As a result, some specific factor may exist that participates in switching telomerase from TERRA to the 3′‐end of DNA for telomere elongation at the distinct period of a cell cycle in vivo. Copyright © 2015 John Wiley & Sons, Ltd.     

Yeast flocculation: competition between nonspecific repulsion and specific bonding in cell adhesion

Yeast flocculation is governed by the competition between electrostatic repulsion (nonspecific interaction) and polysaccharide-protein bonds (specific interaction). The electrical surface potential, which is mainly due to phosphodiester linkages (of the cell wall phosphomannan), maintains the cells dispersed. Polysaccharides and proteins of the cell surface can readily penetrate the potential barrier and may establish specific bonds. The specific inhibition of flocculation by various mannosyl derivatives suggested that the protein receptor binds to the group Man alpha----3 Man alpha----PO4- ----6 Man alpha----2 Man alpha... of phosphomannan. Calcium, which is required for flocculation, could act as a bridge between the negatively charged groups of phosphomannan and those of the protein receptor. The role of calcium, however, cannot be restricted only to charge neutralization because other divalent cations inhibit flocculation; our results show that cation binding is governed by strong stereochemical constraints. Studies on protein-polysaccharide interactions have shown that electrical charges may remain uncompensated at short distance, but can be stabilized by hydrogen bonds. Calcium could induce a "locked" conformation of the receptor; this conformation is the only one capable of binding phosphomannan strongly enough to make cell adhesion possible.     

Telomeric repeat-containing RNA/G-quadruplex-forming sequences cause genome-wide alteration of gene expression in human cancer cells in vivo

Telomere erosion causes cell mortality, suggesting that longer telomeres enable more cell divisions. In telomerase-positive human cancer cells, however, telomeres are often kept shorter than those of surrounding normal tissues. Recently, we showed that cancer cell telomere elongation represses innate immune genes and promotes their differentiation in vivo. This implies that short telomeres contribute to cancer malignancy, but it is unclear how such genetic repression is caused by elongated telomeres. Here, we report that telomeric repeat-containing RNA (TERRA) induces a genome-wide alteration of gene expression in telomere-elongated cancer cells. Using three different cell lines, we found that telomere elongation up-regulates TERRA signal and down-regulates innate immune genes such as STAT1, ISG15 and OAS3 in vivo. Ectopic TERRA oligonucleotides repressed these genes even in cells with short telomeres under three-dimensional culture conditions. This appeared to occur from the action of G-quadruplexes (G4) in TERRA, because control oligonucleotides had no effect and a nontelomeric G4-forming oligonucleotide phenocopied the TERRA oligonucleotide. Telomere elongation and G4-forming oligonucleotides showed similar gene expression signatures. Most of the commonly suppressed genes were involved in the innate immune system and were up-regulated in various cancers. We propose that TERRA G4 counteracts cancer malignancy by suppressing innate immune genes.     

Quadruplex-coupled kinetics distinguishes ligand binding between G4 DNA motifs

G-quadruplex (or G4 DNA) specific ligands are important potential anticancer molecules as telomerase inhibitors. On the other hand, emerging evidence implicates G4 DNA in regulation of several oncogenes making telomerase inhibitors amenable to undesired effects (Borman, S. (2007) Chem. Eng. News 85 (22), 12-17). Therefore molecules which can discriminate between G4 DNA are of interest, both as telomerase inhibitors and for selective intervention of gene expression. Design of selective molecules requires resolution of the coupled equilibria between intramolecular quadruplex-formation and bimolecular ligand-binding. Several previous studies have reported G4-ligand binding kinetics, however the primary equilibrium of intramolecular G4 DNA folding/unfolding was not considered. Here, we quantitatively assess the linked equilibrium in G4-ligand complexes using a novel real time surface plasmon resonance-based technique. Kinetic constants for G4 folding/unfolding and ligand binding were simultaneously determined, for the first time, from a single reaction by resolving the coupled equilibrium. We demonstrate the coupled model by showing that affinity of TMPyP4 (a well-established anticancer telomerase inhibitor) for the human telomere quadruplex is only 3-fold more than the c-MYC promoter G4, which is known to repress c-MYC. This provides quantitative rationale to poor selectivity of TMPyP4 in recently observed cell-based assays. In the light of recent advances indicating G4's regulatory potential in several important genes, quantitative evaluation of selectivity vis-à-vis affinity as presented here will augment design and preliminary screening of new molecules.     

Thermodynamic fingerprints of ligand binding to human telomeric G-quadruplexes

Thermodynamic studies of ligand binding to human telomere (ht) DNA quadruplexes, as a rule, neglect the involvement of various ht-DNA conformations in the binding process. Therefore, the thermodynamic driving forces and the mechanisms of ht-DNA G-quadruplex-ligand recognition remain poorly understood. In this work we characterize thermodynamically and structurally binding of netropsin (Net), dibenzotetraaza[14]annulene derivatives (DP77, DP78), cationic porphyrin (TMPyP4) and two bisquinolinium ligands (Phen-DC3, 360A-Br) to the ht-DNA fragment (Tel22) AGGG(TTAGGG)₃ using isothermal titration calorimetry, CD and fluorescence spectroscopy, gel electrophoresis and molecular modeling. By global thermodynamic analysis of experimental data we show that the driving forces characterized by contributions of specific interactions, changes in solvation and conformation differ significantly for binding of ligands with low quadruplex selectivity over duplexes (Net, DP77, DP78, TMPyP4; K_Tel22 ≈ <K_dsDNA) and for highly selective quadruplex-specific ligands (Phen-DC3, 360A-Br; K_Tel22 > K_dsDNA). These contributions are in accordance with the observed structural features (changes) and suggest that upon binding Net, DP77, DP78 and TMPyP4 select hybrid-1 and/or hybrid-2 conformation while Phen-DC3 and 360A-Br induce the transition of hybrid-1 and hybrid-2 to the structure with characteristics of antiparallel or hybrid-3 type conformation.     

Spectroscopic study on the binding of a cationic porphyrin to DNA G-quadruplex under different K+ concentrations

We have performed systematic spectroscopic titrations to characterize the binding reaction of cationic meso-tetrakis(4-(N-methylpyridiumyl))porphyrin (TMPyP4) with the G-quadruplex (G4) of human telomeric single-strand oligonucleotide d[TAGGG(TTAGGG)3T] (S24), for which special effort was made to examine the TMPyP4-G4 binding stoichiometry, the binding modes, and the conformational conversion of the G4 structure under different potassium ion (K+) concentration. It is found that, in the presence of 0, 10 mM, and 100 mM K+, TMPyP4 forms a complex with the anti-parallel G4 in a TMPyP4-to-G4 molar ratio of 5, 5 and 3, respectively, and the increase of K+ concentration would reduce the binding affinity of TMPyP4 to G4. For the TMPyP4-G4 complex, the end-stacking mode and groove binding mode were presumed mainly by the results of time-resolved fluorescence spectroscopy in the three cases. Most importantly, it is found that TMPyP4 can directly induce the formation of the anti-parallel G4 structure from the single-strand oligonucleotide S24 in the absence of K+, and that it can preferentially induce the conformational conversion of the G4 structure from the hybrid-type to the anti-parallel one in the presence of K+.     

An unexpected major groove binding of netropsin and distamycin A to tRNA(phe)

Crystalline complexes of yeast tRNA(phe) and the oligopeptide antibiotics netropsin and distamycin A were prepared by diffusing drugs into crystals of tRNA. X-ray structure analyses of these complexes reveal a single common binding site for both drugs which is located in the major or deep groove of the tRNA T-stem. The netropsin-tRNA complex is stabilized by specific hydrogen bonds between the amide groups of the drug and the tRNA bases G51 O(6), U52 O(4) and G53 N(7) on one strand, and is further stabilized by electrostatic interactions between the positively charges guanidino side chain of the drug and the tRNA phosphate P53 on the same strand and the positively charged amidino propyl side chain and the phosphates P61, P62 and P63 on the opposite strand of the double helix. These results are in contrast to the implicated minor groove binding of these drugs to non-guanine sequences in DNA. The binding to the GUG sequence in tRNA implies that major groove binding to certain DNA sequences is possible.     

TbTRF suppresses the TERRA level and regulates the cell cycle-dependent TERRA foci number with a TERRA binding activity in its C-terminal Myb domain

Telomere repeat-containing RNA (TERRA) has been identified in multiple organisms including Trypanosoma brucei, a protozoan parasite that causes human African trypanosomiasis. T. brucei regularly switches its major surface antigen, VSG, to evade the host immune response. VSG is expressed exclusively from subtelomeric expression sites, and we have shown that telomere proteins play important roles in the regulation of VSG silencing and switching. In this study, we identify several unique features of TERRA and telomere biology in T. brucei. First, the number of TERRA foci is cell cycle-regulated and influenced by TbTRF, the duplex telomere DNA binding factor in T. brucei. Second, TERRA is transcribed by RNA polymerase I mainly from a single telomere downstream of the active VSG. Third, TbTRF binds TERRA through its C-terminal Myb domain, which also has the duplex DNA binding activity, in a sequence-specific manner and suppresses the TERRA level without affecting its half-life. Finally, levels of the telomeric R-loop and telomere DNA damage were increased upon TbTRF depletion. Overexpression of an ectopic allele of RNase H1 that resolves the R-loop structure in TbTRF RNAi cells can partially suppress these phenotypes, revealing an underlying mechanism of how TbTRF helps maintain telomere integrity.     

Induced chirality of binary aggregates of oppositely charged water-soluble porphyrins on DNA matrix

The induced chirality of achiral binary aggregates of meso-tetrakis(4-N-methylpyridyl)porphyrine (TMPyP) and meso-tetrakis(4-sulfonatophenyl)porphyrine (TPPS) on a deoxyribonucleic acid (DNA) matrix was investigated. Although the negatively charged TPPS did not show induced chirality in DNA solution due to the electrostatic repulsion, induced chirality was obtained through the addition of a positively charged TMPyP. It was confirmed that the induced chirality was due to the binary complex formation between TPPS and TMPyP on the DNA matrix. Moreover, the induced chirality depended on the relative molar ratio of TPPS to TMPyP (r) and the binding modes of the complex to DNA. When r<1, induced circular dichroism (CD) spectrum of the ternary complex was similar to that of intercalated TMPyP into DNA. For r=1, the induced CD spectrum showed a reversed biphasic signal due to the complex of TMPyP and TPPS stacking along the DNA surface. At a higher r value (>1), there was an induced CD signal at 482 nm attributed to a lateral shifted arrangement of heteroaggregate of TPPS and TMPyP on DNA matrix where TMPyP acted as a spacer to mediate the growth of heteroaggregates. Increasing the concentration of sodium chloride in the solution would favor the formation of the lateral shifted arrangement of heteroaggregate of TPPS and TMPyP. The resonance light scattering (RLS) spectra confirmed the above results. Analysis of the CD spectral changes in DNA conformation showed that during the binary complex formation of TPPS and TMPyP, the intercalated TMPyP could be 'pulled out' from the base pairs of DNA, which might be useful in gene therapy. A model was proposed to account for these observations.     

Guanine residues in d(T2AG3) and d(T2G4) form parallel-stranded potassium cation stabilized G-quadruplexes with anti glycosidic torsion angles in solution.

We report below on proton NMR studies of the G-quadruplex structure formed by the human telomere sequence d(T2AG3) and the tetrahymena telomere sequence d(T2G4) in K cation containing solution. We observe well-resolved proton NMR spectra corresponding to a G-quadruplex monomer conformation predominant at 50 mM K cation concentration and a G-quadruplex dimer conformation predominant at 300 mM K cation concentration. By contrast, d(T2AG3T) and d(T2G4T) form only the G-quadruplex monomer structures independent of K cation concentration as reported previously [Sen, D., & Gilbert, W. (1992) Biochemistry 31, 65-70]. We detect well-resolved resonances for the exchangeable guanine imino and amino protons involved in G-tetrad formation with the hydrogen-bonded and exposed amino protons separated by up to 3.5 ppm. The observed NOEs between the amino and H8 protons on adjacent guanines within individual G-tetrads support the Hoogsteen pairing alignment around the tetrad. The imino protons of the internal G-tetrads exchange very slowly with solvent H2O in the d(T2AG3) and d(T2G4) quadruplexes. The nature and intensity of the observed NOE patterns establish formation of parallel-stranded right-handed G-quadruplexes with all anti guanine glycosidic torsion angles. A model for the parallel-stranded G-quadruplex is proposed which is consistent with the experimental NOE data on the d(T2AG3) and d(T2G4) quadruplexes in solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

An Unexpected Major Groove Binding of Netropsin and Distamycin A to tRNAphe

Abstract

Crystalline complexes of yeast tRNA^phe and the oligopeptide antibiotics netropsin and distamycin A were prepared by diffusing drugs into crystals of tRNA. X-ray structure analyses of these complexes reveal a single common binding site for both drugs which is located in the major or deep groove of the tRNA T-stem. The netropsin-tRNA complex is stabilized by specific hydrogen bonds between the amide groups of the drug and the tRNA bases G51 0(6), U52 0(4) and G53 N(7) on one strand, and is further stabilized by electrostatic interactions between the positively charges guanidino side chain of the drug and the tRNA phosphate P53 on the same strand and the positively charged amidino propyl side chain and the phosphates P61, P62 and P63 on the opposite strand of the double helix. These results are in contrast to the implicated minor groove binding of these drugs to non-guanine sequences in DNA. The binding to the GUG sequence in tRNA implies that major groove binding to certain DNA sequences is possible.     

TERRA介导的端粒维持

真核细胞线状染色体末端特殊结构被称为端粒,而端粒维持对于生命体来说具有十分重要的意义,其维持机制也十分复杂.端粒酶可以通过其具有的特殊逆转录酶特性,利用自身的RNA模板(TERC)以及具有催化功能的蛋白质亚基(TERT)延长端粒,维持其长度.本文着重综述端粒TERRA (telomeric repeat-containing RNA)对端粒维持的影响及其作用机制.首先介绍端粒维持与细胞存活老化之间的关系;其次,阐述TERRA的结构及其转录特性,TERRA依赖的DNA∶RNA杂合体和R-loop形成和结构特点,TERRA结合蛋白及其作用;进而讨论依赖于TERRA的端粒维护分子机制以及在生命过程中的意义.     

A spectroscopic study on the interactions of porphyrin with G-quadruplex DNAs

Free-base porphyrin (5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H,23H-porphine) (H(2)TMPyP4) has been shown to be an effective telomerase inhibitor by an in vitro assay. Here, we examined the interactions of the H(2)TMPyP4 with three distinct G-quadruplex DNAs, the parallel-stranded (TG(4)T)4, dimer-hairpin-folded (G(4)T(4)G(4))2, and monomer-folded AG(3)(T(2)AG(3))(3), by ultraviolet resonance Raman spectroscopy (UVRR), UV-vis absorption spectroscopy, fluorescence spectroscopy, and surface-enhanced Raman spectroscopy (SERS). The data obtained by the continuous variation titration method show that the binding stoichiometry of H(2)TMPyP4/G-quadruplex is 2:1 for (TG(4)T)4 and 4:1 for (G(4)T(4)G(4))2 or AG(3)(T(2)AG(3))(3). The results of SERS spectra, UV-vis absorption titration, and fluorescence emission spectra together with the binding stoichiometries reveal that two H(2)TMPyP4 molecules are externally stacked at two ends of the parallel (TG(4)T)4 G-quadruplex, whereas H(2)TMPyP4 molecules can intercalate within their diagonal or lateral loop regions and intervals between two G-tetrads for (G(4)T(4)G(4))2 and AG(3)(T(2)AG(3))(3) G-quadruplexes. The binding of H(2)TMPyP4 to (TG(4)T)4 G-quadruplex results in the hypochromicity of the UV Raman signal of (TG(4)T)4, indicating that the stacking effects between H(2)TMPyP4 and DNA bases are significant. The Raman hyperchromicities and shifts are observed after the binding of H(2)TMPyP4 to both (G(4)T(4)G(4))2 and AG(3)(T(2)AG(3))(3) G-quadruplexes. This indicates that the intercalative H(2)TMPyP4 can lengthen the vertical distance between adjacent G-tetrads of (G(4)T(4)G(4))2 and AG(3)(T(2)AG(3))(3) and change their conformations. The present study provides new insights into the effect of H(2)TMPyP4 binding on the structures of G-quadruplexes and also demonstrates that Raman spectroscopy is an ideal method for examining the interaction between drugs and G-quadruplexes.