Flanking sequence effects within the pyrimidine triple-helix motif characterized by affinity cleaving.

Nearest neighbor interactions affect the stabilities of triple-helical complexes. Within a pyrimidine triple-helical motif, the relative stabilities of natural base triplets T.AT, C + GC, and G.TA, as well as triplets, D3.TA and D3.CG, containing the nonnatural deoxyribonucleoside 1-(2-deoxy-beta-D-ribofuranosyl)-4-(3-benzamido)phenylimidazole (D3) were characterized by the affinity cleaving method in the context of different flanking triplets (T.AT, T.AT: T.AT, C + GC: C + GC, T.AT: G + GC, C + GC). The to be insensitive to substitutions in either the 3' or 5' directions, while the relative stabilities of triple helices containing C + GC triplets decreased as the number of adjacent C + GC triplets increased. Triple helices incorporating a G.TA interaction were most stable when this triplet was flanked by two T.AT triplets and were adversely affected when a C + GC triplet was placed in the adjacent 5' direction. Similarly, complexes containing D3.TA or D3.CG triplets were most stable when the triplet was flanked by two T.AT triplets but were destabilized when the adjacent 3' neighbor position was occupied with a C + GC triplet. This information regarding sequence composition effects in triple-helix formation establishes a set of guidelines for targeting sequences of double-helical DNA by the pyrimidine triple-helix motif.     

DNA triple helix formation at oligopurine sites containing multiple contiguous pyrimidines.

We have used DNase I footprinting to assess the formation of triple helices at 15mer oligopurine target sites which are interrupted by several (up to four) adjacent central pyrimidine residues. Third strand oligonucleotides were designed to generate complexes containing central (X.TA)nor (X.CG)n triplets (X = each base in turn) surrounded by C+.GC and T.AT triplets. It has previously been shown that G.TA and T.CG are the most stable triplets for recognition of single TA and CG interruptions. We show that these triplets are the most useful for recognizing consecutive pyrimidine interruptions and find that addition of each pyrimidine residue leads to a 30-fold decrease in third strand affinity. The addition of 10 microM naphthylquinoline triplex-binding ligand stabilizes each complex so that all the oligonucleotides produce footprints at similar concentrations (0.3 microM). Targets containing two pyrimidines are only bound by oligonucleotides generating (G.TA)2 and (T.CG)2 with a further 30-fold decrease in affinity. (G.TA)2 is slightly more stable than (T.CG)2. In the presence of the triplex-binding ligand the order of stability is (G.TA)2 > (C.TA)2 > (T.TA)2 > (A.TA)2 and (T.CG)2 > (C.CG)2 > (G.CG)2 = (A.CG)2. No oligonucleotide footprints are generated at target sites containing three consecutive pyrimidines, though addition of 10 microM triplex-binding ligand produces stable complexes with oligonucleotides generating (G.TA)3, (T.CG)3 and (C.CG)3, with a further 30-fold reduction in affinity. No footprints are generated at targets containing four Ts, though the ligand induces a weak interaction with the oligonucleotide generating (T.CG)4.     

DNA triple helix formation at target sites containing several pyrimidine interruptions: stabilization by protonated cytosine or 5-(1-propargylamino)dU.

DNase I footprinting has been used to study the formation of parallel triplexes at oligopurine target sequences which are interrupted by pyrimidines at regular intervals. TA interruptions are targeted with third strand oligonucleotides containing guanine, generating G x TA triplets, while CG base pairs are targeted with thymine, forming T x CG triplets. We have attempted to optimize the stability of these complexes by varying the base composition and sequence arrangement of the target sites, and by replacing the third strand thymines with the positively charged analogue 5-(1-propargylamino)dU (U(P)). For the target sequence (AAAT)(5)AA, in which pyrimidines are positioned at every fourth residue, triplex formation with TG-containing oligonucleotides is only detected in the presence of a triplex-binding ligand, though stable triplexes were detected at the target site (AAAAAT)(3)AAAA. Triplex stability at targets containing pyrimidines at every fourth residue is increased by introducing guanines into the duplex repeat unit using the targets (AGAT)(5)AA and (ATGA)(5)AA. In contrast, placing C(+) x GC triplets on the 5'-side of G x TA, using the target (AGTA)(5)TT, produces complexes of lower stability. We have attempted further to increase the stability of these complexes by using the positively charged thymine base analogue U(P), and have shown that (TU(P)TG)(5)TT forms a more stable complex with target (AAAT)(5)AA than the unmodified third strand, generating a footprint in the absence of a triplex-binding ligand. Triplex formation at (AGTA)(5)AA is improved by using the modified oligonucleotide (TCGU(P))(5)TT, generating a complex in which the charged triplets C(+) x GC and U(P) x AT alternate with uncharged triplets. In contrast, placing U(P) x AT triplets adjacent to C(+) x GC, using the third strand oligonucleotide (U(P)CGT)(5)TT, reduces triplex formation, while the third strand with both substitutions, (U(P)CGU(P))(5)TT, produces a complex with intermediate stability. It appears that, although adjacent U(P) x AT triplets form stable triplexes, placing U(P) x AT adjacent to C(+) x GC is unfavorable. Similar results were obtained with fragments containing CG inversions within the oligopurine tract, though triplexes at (AAAAAC)(3)AA were only detected in the presence of a triplex-binding ligand. Placing C(+) x GC on the 5'-side of T x CG triplets also reduces triplex formation, while a 3'-C(+) x GC produces complexes with increased stability.     

The influence of single base triplet changes on the stability of a pur.pur.pyr triple helix determined by affinity cleaving.

The influence of sixteen base triplet changes at a single position within a pur.pur.pyr triple helix was examined by affinity cleaving. For the 15 base pair target site studied here, G.GC, A.AT and T.AT triplets stabilize a triple helix to a greater extent than the other 13 natural triplets (pH = 7.4, 25 degrees C). Weaker interactions were detected for the C.AT, A.GC and T.CG triplets. The absence of specific, highly stabilizing interactions between third strand bases and the CG or TA base pairs demonstrates a current sequence limitation to formation of this structure. Models for the two dimensional base triplet interactions for all possible 16 natural triplets are presented.     

Triple helix formation at (AT)n adjacent to an oligopurine tract.

We have used DNase I footprinting to investigate the recognition of (AT) n tracts in duplex DNA using GT-containing oligonucleotides designed to form alternating G.TA and T.AT triplets. Previous studies have shown that the formation of these complexes is facilitated by anchoring the triplex with a block of adjacent T.AT triplets, i.e. using T11(TG)6to recognize the target A11(AT)6. (AT)6T11. In the present study we have examined how the stability of these complexes is affected by the length of either the T.AT tract or the region of alternating G.TA and T.AT triplets, using oligonucleotides of type T x (TG) y to recognize the sequence A11(AT)11. We find that successful triplex formation at (AT)n (n = 3, 6 or 11) can be achieved with a stabilizing tail of 11xT.AT triplets. The affinity of the third strand increases with the length of the (GT) n tract, suggesting that the alternating G.TA and T.AT triplets are making a positive contribution to stability. These complexes are stabilized by the presence of manganese or a triplex-specific binding ligand. Shorter oligo-nucleotides, such as T7(TG)5, bind less tightly and require the addition of a triplex-binding ligand. T4(GT)5showed no binding under any conditions. Oligo-nucleotides forming a 3'-terminal T.AT are marginally more stable that those with a terminal G.TA. The stability of these complexes was further increased by replacing two of the T.AT triplets in the T n tail region with two C+.GC triplets.     

Mutagenic target for hydroxyl radicals generated in Escherichia coli mutant deficient in Mn- and Fe- superoxide dismutases and Fur,a repressor for iron-uptake systems

We previously reported that mutations in Mn- and Fe-superoxide dismutases and Fur, a repressor for iron uptake systems, simulated generation of hydroxyl radicals, and caused hypermutability in Escherichia coli. The predominant type of spontaneous mutation was GC --> TA, followed by AT --> CG, suggesting the involvement of 7,8-dihydro-8-oxoguanine (8-oxoG) and 1,2-dihydro-2-oxoadenine (2-oxoA) in DNA as well as 7,8-dihydro-8-oxodeoxyguanosine triphosphate (8-oxodGTP) and 1,2-dihydro-2-oxodeoxyadenosine triphosphate (2-oxodATP) in the nucleotide pool. To determine the targets contributing to oxidative mutagenesis, DNA or nucleotides, we characterized spontaneous mutations and compared the distribution to those in mutMY and mutT strains, in which GC --> TA and AT --> CG were predominantly induced, respectively. The hotspots and sequence contexts where AT --> CG occurred frequently in sodAB fur strain were almost identical to those in mutT strain,whereas, those where GC --> TA occurred frequently in sodAB fur strain were quite different from those in mutMY strain. These observations suggested that AT --> CG is due to 8-oxodGTP, while GC --> TA is produced by some other lesion(s). The 2-oxodATP is also a major oxidative lesion in nucleotides, and strongly induces GC --> TA. The expression of cDNA for MTH1, which can hydrolyze 2-oxodATP as well as 8-oxodGTP, partially but significantly, suppressed the GC --> TA mutator phenotype of the sodAB fur strain, whereas, it did not for the mutMY strain. Additionally, the sequence contextby 2-oxodATP in E. coli was similar to that in sodAB fur strain. These results suggested that the targets contributing to oxidative mutagenesis in sodAB fur strain are nucleotides such as dGTP and dATP, rather than DNA.     

Stable recognition of TA interruptions by triplex forming oligonucleotides containing a novel nucleoside

We have prepared the 2'-aminoethoxy derivative of the S nucleoside ((2AE)S) and incorporated it into triplex-forming oligonucleotides for recognition of TA interruptions within a target oligopurine tract. Fluorescence melting, UV melting, and DNase I footprinting experiments show that (2AE)S has greater affinity than G or S for a single TA interruption. Stable triplexes are formed at pH 6.0 at an 18-mer target site containing two TA interruptions, even though this contains eight C(+).GC triplets. Although (2AE)S and S produce stable triplexes at TA interruptions, they also interact with other base pairs, in particular, CG, although the selectivity for TA improves with increased pH.( 2AE)S is the best nucleoside described so far for recognition of TA within a triple-helix target.     

Actions of three human alpha-amylases expressed in yeast on modified substrates and the amino acid residues causing their different actions

The mode of action of an alpha-amylase (yHXA) which was the gene product of a newly found human alpha-amylase gene expressed in yeast on synthetic substrates was compared with those of the gene products (yHSA and yHPA) of human salivary and pancreatic alpha-amylase gene in yeast. The substrates used were phenyl alpha-maltopentaoside (G5 phi) and its derivatives in which the CH2OH groups of the non-reducing-end glucose residues were converted to CH2NH2 (AG5 phi), COOH (CG5 phi), or CH2I (IG5 phi). The digests were subjected to HPLC to determine the amounts of products. The HPLC analysis revealed that yHXA and yHSA bound G5 phi to their active sites in similar manners to give the same products, while yHPA hydrolyzed it in a different way. Modifications of the non-reducing-end glucose of G5 phi caused change of the binding mode to the active sites of the enzymes. AG5 phi and CG5 phi were hydrolyzed by the enzymes to give more phenyl alpha-glucoside (G phi) and less phenyl alpha-maltoside (G2 phi), while IG5 phi gave more G2 phi and less G phi, compared with G5 phi. The substrate binding mode of yHXA changed more extensively than that of yHSA. The results suggested that there exists an amino acid replacement between yHXA and yHSA. The amino acid residues replaced are neither acidic nor basic, are located in subsite S3, and interact with the CH2OH residue of the non-reducing-end glucose residue of G5 phi.(ABSTRACT TRUNCATED AT 250 WORDS)     

Association between mutation spectra and stable and unstable DNA adduct profiles in Salmonella for benzo[a]pyrene and dibenzo[a,l]pyrene

Benzo[a]pyrene (BP) and dibenzo[a,l]pyrene (DBP) are two polycyclic aromatic hydrocarbons (PAHs) that exhibit distinctly different mutagenicity and carcinogenicity profiles. Although some studies show that these PAHs produce unstable DNA adducts, conflicting data and arguments have been presented regarding the relative roles of these unstable adducts versus stable adducts, as well as oxidative damage, in the mutagenesis and tumor-mutation spectra of these PAHs. However, no study has determined the mutation spectra along with the stable and unstable DNA adducts in the same system with both PAHs. Thus, we determined the mutagenic potencies and mutation spectra of BP and DBP in strains TA98, TA100 and TA104 of Salmonella, and we also measured the levels of abasic sites (aldehydic-site assay) and characterized the stable DNA adducts ((32)P-postlabeling/HPLC) induced by these PAHs in TA104. Our results for the mutation spectra and site specificity of stable adducts were consistent with those from other systems, showing that DBP was more mutagenic than BP in TA98 and TA100. The mutation spectra of DBP and BP were significantly different in TA98 and TA104, with 24% of the mutations induced by BP in TA98 being complex frameshifts, whereas DBP produced hardly any of these mutations. In TA104, BP produced primarily GC to TA transversions, whereas DBP produced primarily AT to TA transversions. The majority (96%) of stable adducts induced by BP were at guanine, whereas the majority (80%) induced by DBP were at adenine. Although BP induced abasic sites, DBP did not. Most importantly, the proportion of mutations induced by DBP at adenine and guanine paralleled the proportion of stable DNA adducts induced by DBP at adenine and guanine; however, this was not the case for BP. Our results leave open a possible role for unstable DNA adducts in the mutational specificity of BP but not for DBP.     

Comparison of antiparallel A.AT and T.AT triplets within an alternate strand DNA triple helix.

We have examined the formation of alternate strand triple-helices at the target sequence A11(TC)6.(GA)6T11 using the oligonucleotides T11(AG)6 and T11(TG)6, by DNase I footprinting. These third strands were designed so as to form parallel T.AT triplets together with antiparallel G.GC and A.AT or T.AT triplets. We find that, although both oligonucleotides yield clear footprints at similar concentrations (0.3 microM) in the presence of manganese, only T11(TG)6 forms a stable complex in magnesium-containing buffers, albeit at a higher concentration (10-30 microM). Examination of the interaction of (AG)6 and (TG)6 with half the target site confirmed that the complex containing A.AT triplets was only stable in the presence of manganese. In contrast no binding of (TG)6 was detected in the presence of either metal ion, suggesting that the reverse-Hoogsteen T.AT triplet is less stable that G.GC. We suggest that, within the context of G.GC triplets, the rank order of antiparallel triplet stability is A.AT (Mn2+) > T.AT (Mn2+) > T.AT (Mg2+) > A.AT (Mg2+). Third strands containing a single base substitution in the centre of either the parallel or antiparallel portion showed a (10-fold) weaker interaction in manganese-containing buffers, and no interaction in the presence of magnesium.     

Studies of base pair sequence effects on DNA solvation based on all-atom molecular dynamics simulations

Detailed analyses of the sequence-dependent solvation and ion atmosphere of DNA are presented based on molecular dynamics (MD) simulations on all the 136 unique tetranucleotide steps obtained by the ABC consortium using the AMBER suite of programs. Significant sequence effects on solvation and ion localization were observed in these simulations. The results were compared to essentially all known experimental data on the subject. Proximity analysis was employed to highlight the sequence dependent differences in solvation and ion localization properties in the grooves of DNA. Comparison of the MD-calculated DNA structure with canonical A- and B-forms supports the idea that the G/C-rich sequences are closer to canonical A- than B-form structures, while the reverse is true for the poly A sequences, with the exception of the alternating ATAT sequence. Analysis of hydration density maps reveals that the flexibility of solute molecule has a significant effect on the nature of observed hydration. Energetic analysis of solute-solvent interactions based on proximity analysis of solvent reveals that the GC or CG base pairs interact more strongly with water molecules in the minor groove of DNA that the AT or TA base pairs, while the interactions of the AT or TA pairs in the major groove are stronger than those of the GC or CG pairs. Computation of solvent-accessible surface area of the nucleotide units in the simulated trajectories reveals that the similarity with results derived from analysis of a database of crystallographic structures is excellent. The MD trajectories tend to follow Manning's counterion condensation theory, presenting a region of condensed counterions within a radius of about 17 A from the DNA surface independent of sequence. The GC and CG pairs tend to associate with cations in the major groove of the DNA structure to a greater extent than the AT and TA pairs. Cation association is more frequent in the minor groove of AT than the GC pairs. In general, the observed water and ion atmosphere around the DNA sequences is the MD simulation is in good agreement with experimental observations.     

Four base recognition by triplex-forming oligonucleotides at physiological pH

We have achieved recognition of all 4 bp by triple helix formation at physiological pH, using triplex-forming oligonucleotides that contain four different synthetic nucleotides. BAU [2′-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine] recognizes AT base pairs with high affinity, ^MeP (3-methyl-2 aminopyridine) binds to GC at higher pHs than cytosine, while ^APP (6-(3-aminopropyl)-7-methyl-3H-pyrrolo[2,3-d]pyrimidin-2(7H)-one) and S [N-(4-(3-acetamidophenyl)thiazol-2-yl-acetamide)] bind to CG and TA base pairs, respectively. Fluorescence melting and DNase I footprinting demonstrate successful triplex formation at a 19mer oligopurine sequence that contains two CG and two TA interruptions. The complexes are pH dependent, but are still stable at pH 7.0. BAU, ^MeP and ^APP retain considerable selectivity, and single base pair changes opposite these residues cause a large reduction in affinity. In contrast, S is less selective and tolerates CG pairs as well as TA.     

Intramolecular triple-helix formation at (PunPyn).(PunPyn) tracts: recognition of alternate strands via Pu.PuPy and Py.PuPy base triplets.

Triple-helical DNA shows increasing potential for applications in the control of gene expression (including therapeutics) and the development of sequence-specific DNA-cleaving agents. The major limitation in this technology has been the requirement of homopurine sequences for triplex formation. We describe a simple approach that relaxes this requirement, by utilizing both Pu.PuPy and Py.PuPy base triplets to form a continuous DNA triple helix at tandem oligopurine and oligopyrimidine tracts. [Triplex formation at such a sequence has been previously demonstrated only with the use of a special 3'-3' linkage in the third strand [Horne, D. A., & Dervan, P. B. (1990) J. Am. Chem. Soc. 112, 2435-2437].] Supporting evidence is from chemical probing experiments performed on several oligonucleotides designed to form 3-stranded fold-back structures. The third strand, consisting of both purine and pyrimidine blocks, pairs with purines in the Watson-Crick duplex, switching strands at the junction between the oligopurine and oligopyrimidine blocks but maintaining the required strand polarity without any special linkage. Although Mg2+ ions are not required for the formation of Pu.PuPy base triplets, they show enhanced stability in the presence of Mg2+. In the sequences observed. A.AT triplets appear to be more stable than G.GC triplets. As expected, triplex formation is largely independent of pH unless C+.GC base triplets are required.     

Selectivity and affinity of triplex-forming oligonucleotides containing 2'-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine for recognizing AT base pairs in duplex DNA

We have used DNase I footprinting, fluorescence and ultraviolet (UV) melting experiments and circular dichroism to demonstrate that, in the parallel triplex binding motif, 2′-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine (bis-amino-U, BAU) has very high affinity for AT relative to all other Watson–Crick base pairs in DNA. Complexes containing two or more substitutions with this nucleotide analogue are stable at pH 7.0, even though they contain several C.GC base triplets. These modified triplex-forming oligonucleotides retain exquisite sequence specificity, with enhanced discrimination against YR base pairs (especially CG). These properties make BAU a useful base analogue for the sequence-specific creation of stable triple helices at pH 7.0.     

Thermodynamic and kinetic stability of intermolecular triple helices containing different proportions of C+*GC and T*AT triplets

We have used oligonucleotides containing appropriately placed fluorophores and quenchers to measure the stability of 15mer intermolecular triplexes with third strands consisting of repeats of TTT, TTC, TCC and TCTC. In the presence of 200 mM sodium (pH 5.0) triplexes that contain only T·AT triplets are unstable and melt below 30°C. In contrast, triplets with repeats of TTC, TCC and CTCT melt at 67, 72 and 76°C, respectively. The most stable complex is generated by the sequence containing alternating C⁺·GC and T·AT triplets. All four triplexes are stabilised by increasing the ionic strength or by the addition of magnesium, although triplexes with a higher proportion of C⁺·GC triplets are much less sensitive to changes in the ionic conditions. The enthalpies of formation of these triplexes were estimated by examining the concentration dependence of the melting profiles and show that, in the presence of 200 mM sodium at pH 5.0, each C⁺·GC triplet contributes about 30 kJ mol^–1, while each T·AT contributes only 11 kJ mol^–1. Kinetic experiments with these oligonucleotides show that in 200 mM sodium (pH 5.0) repeats of TCC and TTC have half-lives of ~20 min, while the triplex with alternating C⁺·GC and T·AT triplets has a half-life of ~3 days. In contrast, the dissociation kinetics of the triplex containing only T·AT are too fast to measure.     

Reduction of GC --> TA transversion mutation by overexpression of MutS in Escherichia coli K-12

Overexpression of the MutS repair protein significantly decreased the rate of lacZ GC --> TA transversion mutation in stationary-phase and exponentially growing bacteria and in mutY and mutM mutants, which accumulate mismatches between 8-oxoguanine (8-oxoG) and adenine residues in DNA. Conversely, GC --> TA transversion increased in mutL or mutS mutants in stationary phase. In contrast, overexpression of MutS did not appreciably reduce lacZ AT --> CG transversion mutation in a mutT mutant. These results suggest that MutS-dependent repair can correct 8-oxoG:A mismatches in Escherichia coli cells but may not be able to compete with mutation fixation by MutY in mutT mutants.     

Mutational specificities of 1′-acetoxysafrole,N-benzoyloxy-N-methyl-4-aminoazobenzene,and ethyl methanesulfonate in human cells

We have used an oriP-tk shuttle vector t determine the types of mutations induced in human cells by ethyl methanesulfonate (EMS), 1'-acetoxysafrole (AcOS), and N-benzoyloxy-N-methyl-4-aminoazobenzene (BzOMAB). Plasmid DNA was treated in vitro with mutagen and electroporated into human lymphoblastoid cells. After replication of the vector in human cells, plasmids were analyzed for mutations in the herpes simplex virus type 1 thymidine kinase gene. Ethyl methanesulfonate induced predominantly GC → AT transition mutations. Treatment of the shuttle vector with AcOS induced 5 of the 6 possible base substitution mutations, including GC → AT (32%) and AT → GC (14%) transition mutations, GC → TA (%), GC → CG (18%), and AT → TA (14%) transversion mutations, as well as a low frequency (9%) of −1 frameshift mutations at GC base pairs. Replication in human cells of DNA modified with BzOMAB yielded a significant increase (17-fold) in the frequency of deletion mutations relative to solvent-treated DNA. A majority (94%) of the point mutations induced by BzOMAB occurred at GC base pairs and were predomianntly GC → AT transitions (33%) and −1 frameshift (22%) mutations, with the remainder consisting mainly of transversions at GC base pairs (28%). The broad spectrum of base substitution mutations observed for AcOS and BzOMAB may indicate the frequent insertion of a variety of bases during replicative bypass of aralkylated bases in human cells.     

Nuclear magnetic resonance structural studies of intramolecular purine.purine.pyrimidine DNA triplexes in solution. Base triple pairing alignments and strand direction

Recently, P.A. Beal and P.B. Dervan, expanding on earlier observations by others, have established the formation of purine.purine.pyrimidine triple helices stabilized by G.GC, A.AT and T.AT base triples where the purine-rich third strand was positioned in the major groove of the Watson-Crick duplex and anti-parallel to its purine strand. The present nuclear magnetic resonance (n.m.r.) study characterizes the base triple pairing alignments and strand direction in a 31-mer deoxyoligonucleotide that intramolecularly folds to generate a 7-mer (R/Y-)n.(R+)n(Y-)n triplex with the strands linked by two T5 loops and stabilized by potential T.AT and G.GC base triples. (R and Y stand for purine and pyrimidine, respectively, while the signs establish the strand direction.) This intramolecular triplex gives well-resolved exchangeable and non-exchangeable proton spectra with Li+ as counterion in aqueous solution. These studies establish that the T1 to C7 pyrimidine and the G8 to A14 purine strands are anti-parallel to each other and align through Watson-Crick A.T and G.C pair formation. The T15 to G21 purine-rich third strand is positioned in the major groove of this duplex and pairs through Hoogsteen alignment with the purine strand to generate T.AT and G.GC triples. Several lines of evidence establish that the thymidine and guanosine bases in the T15 to G21 purine-rich third strand adopt anti glycosidic torsion angles under conditions where this strand is aligned anti-parallel to the G8 to A14 purine strand. We have also recorded imino proton n.m.r. spectra for an (R-)n.(R+)n(Y-)n triplex stabilized by G.GC and A.AT triples through intramolecular folding of a related 31-mer deoxyoligonucleotide with Li+ as counterion. The intramolecular purine.purine.pyrimidine triplexes containing unprotonated G.GC, A.AT and T.AT triples are stable at basic pH in contrast to pyrimidine.purine.pyrimidine triplexes containing protonated C+.GC and T.AT triples, which are only stable at acidic pH.     

Formation of DNA triple helices incorporating blocks of G.GC and T.AT triplets using short acridine-linked oligonucleotides.

We have used DNase I footprinting to assess triple helix formation at target sites containing the sequences A6G6.C6T6 and G6A6.T6C6. These sequences can be recognized by the acridine-linked oligopyrimidines Acr-T5C5 and Acr-C5T5 respectively at low pH, using well-characterised T.AT and C+.GC triplets. At pH 7.5 A6G6.C6T6 is specifically bound by Acr-G5T5, utilising G.GC and T.AT triplets in which the third strand runs antiparallel to the purine strand of the duplex. This interaction requires the presence of magnesium ions. No interaction was detected with Acr-T5G5, an oligonucleotide designed to form parallel G.GC and T.AT triplets. In contrast neither Acr-T5G5 nor Acr-G5T5 produced DNase I footprints with the target sequence G6A6.T6C6. These results suggest that, in an antiparallel R.RY triple helix, the T.AT triplet is weaker than the G.GC triplet. We find no evidence for the formation of structures containing parallel G.GC triplets.     

Examination of aglycone-binding site of human salivary alpha-amylase by means of transglycosylation reactions

The active site of human salivary alpha-amylase is composed of tandem subsites (S3, S2, S1, S1',S2', etc.) geometrically complementary to several glucose residues, and the glycosidic linkage of the substrate is split between S1 and S1'. As a matter of convenience, the subsites to which the non-reducing-end part (glycone) and the reducing-end part (aglycone) of the substrate being hydrolyzed are bound are named the glycone-binding site (S3, S2, S1) and the aglycone-binding site (S1', S2'), respectively. The features of the aglycone-binding site of human salivary alpha-amylase were examined by means of transglycosylation reaction using phenyl alpha-maltoside (GG phi: G-G-phi) and its derivatives (GAG phi: G-AG-phi, GCG phi: G-CG-phi, AGG phi: AG-G-phi, and CGG phi: CG-G-phi) in which one of the glucose residues (G) has been converted to 6-amino-6-deoxy-glucose (AG) or glucuronic acid (CG) residue as the acceptor. A fluorogenic derivative of maltotetraose, p-nitrophenyl O-6-deoxy-6-[(2-pyridyl)amino]-alpha-D-glucopyranosyl-(1----4)-O-alpha-D -glucopyranosyl-(1----4)-O-alpha-D-glucopyranosyl-(1----4)-alpha-D- glucopyranosyl-(1----4)-alpha-D-glucopyranoside (FG4P, FG-G-G-G-P), was used as the substrate. HSA catalyzed both hydrolysis of FG4P to FG3 (FG-G-G) and p-nitrophenyl alpha-glucoside (G-P) and transfer of the FG3 residue of FG4P to the acceptors. Transfer to GAG phi occurred more effectively than to GG phi. Transfers to GCG phi and CGG phi were less than to GG phi and very little transfer to AGG phi occurred.(ABSTRACT TRUNCATED AT 250 WORDS)