Interaction of G-rich GT oligonucleotides with nuclear-associated eEF1A is correlated with their antiproliferative effect in haematopoietic human cancer cell lines

G-rich GT oligonucleotides with a different content of G clusters have been evaluated for their ability to exert cytotoxicity and to bind to nuclear-associated proteins in T-lymphoblast CCRF-CEM cells. Only the oligomers that did not form G-based structures or had a poor structure, under physiological conditions, were able to exert significant cellular growth inhibition effect. The cytotoxicity of these oligomers was related to their binding to the nuclear-associated eEF1A protein, but not to the recognition of nucleolin or other proteins. In particular, GT oligomers adopting a conformation compatible with G-quadruplex, did not exert cytotoxicity and did not bind to eEF1A. The overall results suggest that the ability of oligomers to adopt a G-quadruplex-type secondary structure in a physiological buffer containing 150 mM NaCl is not a prerequisite for antiproliferative effect in haematopoietic cancer cells. The cytotoxicity of G-rich GT oligomers was shown to be tightly related to their binding affinity for eEF1A protein.     

Conformational features of benzo‐homologated yDNA duplexes by molecular dynamics simulation

yDNA is a base‐modified nucleic acid duplex containing size‐expanded nucleobases. Base‐modified nucleic acids could expand the genetic alphabet and thereby enhance the functional potential of DNA. Unrestrained 100 ns MD simulations were performed in explicit solvent on the yDNA NMR sequence [5′(yA T yA yA T yA T T yA T)₂] and two modeled yDNA duplexes, [5′(yC yC G yC yC G G yC G G)₂] and [(yT5′ G yT A yC yG C yA yG T3′)?(yA5′ C T C yG C G yT A yC A3′)]. The force field parameters for the yDNA bases were derived in consistent with the well‐established AMBER force field. Our results show that DNA backbone can withstand the stretched size of the bases retaining the Watson‐Crick base pairing in the duplexes. The duplexes retained their double helical structure throughout the simulations accommodating the strain due to expanded bases in the backbone torsion angles, sugar pucker and helical parameters. The effect of the benzo‐expansion is clearly reflected in the extended C1′‐C1′ distances and enlarged groove widths. The size expanded base modification leads to reduction in base pair twist resulting in larger overlapping area between the stacked bases, enhancing inter and intra strand stacking interactions in yDNA in comparison with BDNA. This geometry could favour enhanced interactions with the groove binders and DNA binding proteins., 2016. © 2015 Wiley Periodicals, Inc. Biopolymers 105: 55–64, 2016     

Functional identification of an 8-oxoguanine specific endonuclease from Thermotoga maritima

To date, no 8-oxoguanine-specific endonuclease-coding gene has been identified in Thermotoga maritima of the order Thermotogales, although its entire genome has been deciphered. However, the hypothetical protein Tm1821 from T. maritima, has a helix-hairpin-helix motif that is considered to be important for DNA binding and catalytic activity. Here, Tm1821 was overexpressed in Escherichia coli and purified using Ni-NTA affinity chromatography, protease digestion, and gel filtration. Tm1821 protein was found to efficiently cleave an oligonucleotide duplex containing 8-oxoguanine, but Tm1821 had little effect on other substrates containing modified bases. Moreover, Tm1821 strongly preferred DNA duplexes containing an 8-oxoguanine:C pair among oligonucleotide duplexes containing 8-oxoguanine paired with four different bases (A, C, G, or T). Furthermore, Tm1821 showed AP lyase activity and Schiff base formation with 8-oxoguanine in the presence of NaBH4, which suggests that it is a bifunctional DNA glycosylase. Tm1821 protein shares unique conserved amino acids and substrate specificity with an 8-oxoguanine DNA glycosylase from the hyperthermophilic archaeon. Thus, the DNA recognition and catalytic mechanisms of Tm1821 protein are likely to be similar to archaeal repair protein, although T. maritima is an eubacterium.     

General Cell-Binding Activity of Intramolecular G-Quadruplexes with Parallel Structure

G-quadruplexes (G4s) are four-stranded nucleic acid structures adopted by some repetitive guanine-rich sequences. Putative G-quadruplex-forming sequences (PQSs) are highly prevalent in human genome. Recently some G4s have been reported to have cancer-selective antiproliferative activity. A G4 DNA, AS1411, is currently in phase II clinical trials as an anticancer agent, which is reported to bind tumor cells by targeting surface nucleolin. AS1411 also has been extensively investigated as a target-recognition element for cancer cell specific drug delivery or cancer cell imaging. Here we show that, in addition to AS1411, intramolecular G4s with parallel structure (including PQSs in genes) have general binding activity to many cell lines with different affinity. The binding of these G4s compete with each other, and their targets are certain cellular surface proteins. The tested G4s exhibit enhanced cellular uptake than non-G4 sequences. This uptake may be through the endosome/lysosome pathway, but it is independent of cellular binding of the G4s. The tested G4s also show selective antiproliferative activity that is independent of their cellular binding. Our findings provide new insight into the molecular recognition of G4s by cells; offer new clues for understanding the functions of G4s in vivo, and may extend the potential applications of G4s.     

Fractionation of chick oviduct chromatin. Nuclease-resistant deoxyribonucleic acid.

Chromatin isolated from several chick tissues was treated with micrococcal nuclease. A limited degree of tissue specificity of chromatin DNA resistance to nuclease digestion was observed. No difference in the extent of nuclease resistance of chromatin DNA was detected during oestrogen-induced oviduct differentiation. This suggested that the amount of non-histone chromosomal protein does not play an important role in the sensitivity of chromatin DNA to nuclease digestion. Studies of nuclease resistance of chromatin DNA after dissociation and reconstitution of chromatin proteins and ethanol extraction of chromatin indicate that the histones protect the DNA from nuclease attack. Slow thermal denaturation of nuclease-resistant DNA suggests that the protected DNA sequences may be (A+T)-rich, and the (G+C)-rich satellites present in total chick DNA are sensitive to nuclease.     

Purification and RNA binding properties of a C-type hnRNP protein from HeLa cells

A protein of the C group, most likely C3 (Mr approximately 42,000, pI approximately 6, corresponding to IEF 48m,n of the HeLa protein catalogue (Celis, J. E., Bravo, R., Arenstorf, H. P., and LeStourgeon, W. M. (1986) FEBS Lett. 194, 101-109)), a minor hnRNP protein was purified to near homogeneity under nondenaturing conditions from 40 S heterogeneous nuclear ribonucleoprotein particles. Type C protein stoichiometrically disrupts the residual secondary structure of natural and synthetic RNAs, e.g. HeLa hnRNA, coliphage MS2 RNA, and poly(rU)-spermine, and decreases the Tm of duplex structures, e.g. poly[r(A + U)], by about 30 degrees C. Binding of the protein to polynucleotides is not highly cooperative and has a stoichiometry of one protein per about 10 nucleotides. Binding experiments with a variety of synthetic and natural poly- and oligonucleotides, including those containing consensus splice site sequences, indicate that the protein has a high affinity for G-rich and U-rich regions, G-rich regions being preferred. Base analogs I and T have affinities for the protein that are similar to G and U. There is little or no affinity for A- and C-rich regions. The presence of A residues in a G- or U-rich sequence does not interfere with binding while C-rich regions decrease or prevent the binding of the protein. The nucleotide specificity of type C protein, e.g. selective binding to an oligonucleotide from the 3' end of an intron, is discussed in relationship to the abundance of G and U and the relative scarcity of C residues in the processing signals in pre-mRNA.     

A Trypanosoma brucei protein complex that binds G-overhangs and co-purifies with telomerase activity.

The chromosomal ends of Trypanosoma brucei, like those of most eukaryotes, contain conserved 5'-TTAGGG-3' repeated sequences and are maintained by the action of telomerase. Fractionated T. brucei cell extracts with telomerase activity were used as a source of potential regulatory factors or telomerase-associated components that might interact with T. brucei telomeres. Electrophoretic mobility shift assays and UV cross-linking were used to detect possible single-stranded telomeric protein.DNA complexes and to estimate the approximate size of the protein constituents. Three single-stranded telomeric protein.DNA complexes were observed. Complex C3 was highly specific for the G-strand telomeric repeat sequence and shares biochemical characteristics with G-rich, single-stranded telomeric binding proteins and with components of the telomerase holoenzyme described in yeast, ciliates, and humans. Susceptibility to RNase A or chemical nuclease (hydroxyl radical) pre-treatment showed that complex C3 was tightly associated with an RNA component. Matrix-assisted laser desorption/ionization-time of flight mass spectrometry was used to estimate the molecular mass of the peptides obtained by in-gel Lys-C digestion of low abundance C3-associated proteins. The molecular masses of the peptides showed no homologies with other proteins from trypanosomes or with any protein in the data bases screened.     

Binding of actinomycin D to single-stranded DNA of sequence motifs d(TGTCT(n)G) and d(TGT(n)GTCT)

Our recent binding studies with oligomers derived from base replacements on d(CGTCGTCG) had led to the finding that actinomycin D (ACTD) binds strongly to d(TGTCATTG) of apparent single-stranded conformation without GpC sequence. A fold-back binding model was speculated in which the planar phenoxazone inserts at the GTC site with a loop-out T base whereas the G base at the 3'-terminus folds back to form a basepair with the internal C and stacks on the opposite face of the chromophore. To provide a more concrete support for such a model, ACTD equilibrium binding studies were carried out and the results are reported herein on oligomers of sequence motifs d(TGTCT(n)G) and d(TGT(n)GTC). These oligomers are not expected to form dimeric duplexes and contain no canonical GpC sequences. It was found that ACTD binds strongly to d(TGTCTTTTG), d(TGTTTTGTC), and d(TGTTTTTGTC), all exhibiting 1:1 drug/strand binding stoichiometry. The fold-back binding model with displaced T base is further supported by the finding that appending TC and TCA at the 3'-terminus of d(TGTCTTTTG) results in oligomers that exhibit enhanced ACTD affinities, consequence of the added basepairing to facilitate the hairpin formation of d(TGTCTTTTGTC) and d(TGTCTTTTGTCA) in stabilizing the GTC/GTC binding site for juxtaposing the two G bases for easy stacking on both faces of the phenoxazone chromophore. Further support comes from the observation of considerable reduction in ACTD affinity when GTC is replaced by GTTC in an oligomer, in line with the reasoning that displacing two T bases to form a bulge for ACTD binding is more difficult than displacing a single base. Based on the elucidated binding principle of phenoxazone ring requiring its opposite faces to be stacked by the 3'-sides of two G bases for tight ACTD binding, several oligonucleotide sequences have been designed and found to bind well.     

鼠伤寒沙门氏菌嘌呤生物合成调控研究XI.PUR box的突变分析

为研究１６ｂｐ ＰＵＲ ｂｏｘ中除第３位的Ｇ与第１４位的Ｃ外,余下６个完全保守碱基的４个在与ＰｕｒＲ阻遏蛋白结合中的功能,对它们分别做了定点突变,使其分别从Ｃ、Ａ、Ａ和Ｔ突变为Ｇ、Ｇ、Ｇ和Ｃ。凝胶阻滞实验结果表明,含上述指定突变的：ＰＵＲｂｏｘ均不能与ＰｒｕＲ阻遏蛋白结合。由此证明,这４个保守碱基对维持ＰＵＲ ｂｏｘ的功能是必须的,其中任一改变都导致ＰＵＲｂｏｘ功能的夹失。     

Simultaneous recognition of nucleobase and sites of DNA damage: effect of tethered cation on the binding affinity

BACKGROUND: The 3,5-diamino-N-(3-aminopropyl)-6-chloropyrazine-2-carboxamide (DCPC-NH(2)) has been synthesized and characterized by Mass and (1)H NMR. The selective binding of the ligand to thymine (T) target base is investigated by the melting temperature (T(m)) and fluorescence measurements. METHODS: Thermal denaturation study of DNA duplex containing T target base revealed the DeltaT(m) of 5.1 degrees C, while least influence was observed for other target bases. The fluorescence of the ligand DCPC-NH(2) is quenched only upon adding the DNA containing T target base. RESULTS: The binding constant for the interaction of the ligand to T target base containing DNA duplex was determined to be 4.7 (+/-0.3)x10(6) M(-1). The tethered cation in the ligand is found to enhance the binding constant. The ligand binds to both a target nucleotide and an AP site on the complimentary strand for the target strand in a DNA duplex. GENERAL SIGNIFICANCE: Interestingly, the electronic behavior of the ligand depends on the bases flanking the AP site. Its fluorescence is quenched with guanine flanking bases, while it is enhanced with DNA duplex containing T bases flanking an AP site. Finally, the binding modes were visualized by molecular modeling.     

The trinucleotide repeat sequence d(GTC)15 adopts a hairpin conformation.

The structure of a single-stranded (ss) oligonucleotide containing (GTC)15 [ss(GTC)15] was examined. As a control, parallel studies were performed with ss(CTG)15, an oligonucleotide that forms a hairpin. Electrophoretic mobility, KMnO4 oxidation and P1 nuclease studies demonstrate that, similar to ss(CTG)15, ss(GTC)15 forms a hairpin containing base paired and/or stacked thymines in the stem. Electrophoretic mobility melting profiles performed in approximately 1 mM Na+ revealed that the melting temperature of ss(GTC)15 and ss(CTG)15 were 38 and 48 degrees C respectively. The loop regions of ss(GTC)15 and ss(CTG)15 were cleaved by single-strand-specific P1 nuclease at the T25-C29 and G26-C27 phosphodiester bonds respectively (where the loop apex of the DNAs is T28). Molecular dynamics simulations suggested that in ss(GTC)15 the loop was bent towards the major groove of the stem, apparently causing an increased exposure of the T25-C29 region to solvent. In ss(CTG)15 guanine--guanine stacking caused a separation of the G26 and C27 bases, resulting in exposure of the intervening phosphodiester to solvent. The results suggest that ss(GTC)15 and ss(CTG)15 form similar, but distinguishable, hairpin structures.     

Interaction of YOYO-1 with guanine-rich DNA

The oxazole homodimer YOYO-1 has served as a valuable tool for the detection and quantification of nucleic acids. While the base specificity and selectivity of binding of YOYO-1 has been researched to some extent, the effect of unorthodox nucleic acid conformations on dye binding has received relatively less attention. In this work, we attempt to correlate the quadruplex-forming ability of G-rich sequences with binding of YOYO-1. Oligonucleotides differing in the number of tandem G repeats, total length, and length of loop sequence were evaluated for their ability to form quadruplexes in presence of sodium (Na⁺) or potassium (K⁺) ions. The fluorescence behavior of YOYO-1 upon binding such G-rich sequences was also ascertained. A distinct correlation was observed between the strength and propensity of quadruplex formation, and the affinity of YOYO-1 to bind such sequences. Specifically, as exemplified by the oligonucleotides 5′-G4T2G4-3′ and 5′-G3TG3TG3-3′, sequences possessing longer G-rich regions and shorter loop sequences formed stronger quadruplexes in presence of K⁺ which translated to weaker binding of YOYO-1. The dependence of binding of YOYO-1 on sequence and structural features of G-rich DNA has not been explored previously and such studies are expected to aid in more effective interpretation of applications involving the fluorophore.     

Increased potency of an aptameric G-rich oligonucleotide is associated with novel functional properties of phosphorothioate linkages.

We previously showed that inhibition of the expression of CD28 (an essential immune receptor on T cells) mediated by a phosphorothioate (PS)-modified aptameric oligodeoxynucleotide (ODN) sequence, GR1, resulted in reduced T cell responses in vitro and in vivo. Using GR1 sequences differing only in the amount of terminal PS linkages (chimeric SO-ODN), the present study demonstrated that even after a substantial reduction in PS linkages, this 18-mer ODN sequence could still confer functionality in the ODN-mediated inhibition of CD28 expression. We showed that secondary structure and full retention of the ability to form a specific protein-ODN complex and to increase cellular uptake in activated Jurkat T cells were critical parameters in the determination of the magnitude of bioactivity of chimeric SO-ODN. We report that a chimeric SO-ODN with terminal PS linkages that total 9 (ICN 17221) or 12 (ICN 17263) was sufficient to inhibit CD28 expression and suppress in vivo inflammatory ear responses to contact allergen in mice with similar potency to the 17-thioate S-ODN (ICN 16064). Interestingly, all chimeric SO-ODN showed similar in vitro nuclease resistance. These data suggest alternate functional properties for PS linkages, unrelated to nuclease resistance, in enhancing the bioactivity of a G-rich aptamer.     

Effects of bulge composition and flanking sequence on the kinking of DNA by bulged bases

We recently showed that bulged bases kink duplex DNA, with the degree of kinking increasing in roughly equal increments as the number of bases in the bulge increases from one to four [Hsieh, C.-H., & Griffith, J.D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 4833-4837]. Here we have examined the kinking of DNA by single A, C, G, or T bulges with different neighboring base pairs. Synthetic 30 base pair (bp) duplex DNAs containing 2 single-base bulges spaced by 10 bp were ligated head to tail, and their electrophoretic behavior in highly cross-linked gels was examined. All bulge-containing DNAs showed marked electrophoretic retardations as compared to non-bulge-containing DNA. Regardless of the sequence of the flanking base pairs, purine bulges produced greater retardations than pyrimidine bulges. Furthermore, C and T bulges produced the same retardations as did G and A bulges. Bulged DNA containing different flanking base pairs showed marked differences in electrophoretic mobility. For C-bulged DNA, the greatest retardations were observed with G.C neighbors, the least with T.A neighbors, and an intermediate amount with a mixture of neighboring base pairs. For A-bulged DNA, the retardations were greatest with G.C neighbors, less with T.A neighbors, even less with a mixture of neighboring base pairs, and finally least with C.G neighbors. Thus flanking base pairs affect C-bulged DNA and A-bulged DNA differently, and G.C and C.G flanking base pairs were seen to have very different effects. These results imply an important role of base stacking in determining how neighboring base pairs influence the kinking of DNA by a single-base bulge.     

DNA structural variations produced by actinomycin and distamycin as revealed by DNAase I footprinting.

The technique of DNAase I footprinting has been used to investigate preferred binding sites for actinomycin D and distamycin on a 160-base-pair DNA fragment from E. coli containing the tyr T promoter sequence. Only sites containing the dinucleotide step GpC are protected by binding of actinomycin, and all such sites are protected. Distamycin recognizes four major regions rich in A + T residues. Both antibiotics induce enhanced rates of cleavage at certain regions flanking their binding sites. These effects are not restricted to any particular base sequence since they are produced in runs of A and T by actinomycin and in GC-rich sequences by distamycin. The observed increases in susceptibility to nuclease attack are attributed to DNA structural variations induced in the vicinity of the ligand binding site, most probably involving changes in the width of the helical minor groove.