Anomalous Migration of Short Sequences of DNA: Comparison of Theory and Experiment

Abstract A new model to replace the Ogstron and tube reptation models for gel retardation of DNA is proposed that explicitly takes into account screening of the hydrodynamic interactions and polyelectrolyte effects. At short DNA sequence lengths, significant anomalous migration is predicted whose onset is dependent on the size of polyacrylamide gel pores. Thus, a 2-residue fragment has the same electrophoretic mobility as a 12-residue fragment for a polyacrylamide gel with a mesh size of 60Å. The oligonucleotide length at which anomalous migration is observed also depends on pore size. Experimental measurement of gel mobility for DNA fragments of the form N(pN)(n), where n = 1-11, 14 and 19 substantiate this phenomenon.

Engineering specific cross-links in nucleic acids using glycol linkers

One of the most convenient methods for generating oligonucleotides possessing intra- or interstrand cross-links is through incorporation of oligoethylene glycol bridges by solid-phase synthesis. The reagents are commercially available or can be synthesized in a few easy synthetic steps. Unlike many other DNA and RNA cross-links, aspects of the structural and thermodynamic impact of modifying nucleic acids with oligoethylene glycols have been studied. This unit covers protection, phosphitylation, and preparation of the glycol linker for oligonucleotide synthesis.

Synthesis of a dA-dT base pair analogue and its effects on DNA-ligand binding

Two nucleoside derivatives containing the base analogues 3-deazaadenine and 3-methyl-2-pyridone have been prepared as analogues of dA and dT, respectively. After conversion into the appropriately protected phosphoramidites, DNA sequences were prepared with site-specifically placed analogues. When present in a duplex DNA sequence, the analogues result in the deletion of one or both of the hydrogen bonding functional groups (the N3-nitrogen of dA and the O2-carbonyl of dT) present in the minor groove. Binding by two ligands, 4',6-diamidine-2-phenyl indole (DAPI) and Hoechst 33258 in the minor groove has been probed using a variety of DNA sequences. These sequences contain a d(GAATTC)2 core with analogue nucleosides substituted for one or more of the dA and dT residues. DAPI bound strongly to any sequence that contained both O2-carbonyls of the central two dT residues. The presence of a dc3A residue did in some cases enhance binding. With one of the central O2-carbonyls deleted, the binding was noticeably reduced, and with both absent, no significant binding could be detected. Similar although less dramatic results were observed with Hoechst 33258 binding to analogue sequences.

Tethered naphthalene diimide intercalators enhance DNA triplex stability

Naphthalene diimides function as effective intercalators and when tethered to the 5'-terminus of a pyrimidine-rich oligonucleotide can contribute significantly to the overall stabilization of DNA triplexes. This stabilization can be further enhanced by alterations to the linker tethering the DNA sequence and the intercalator. Less flexible linkers, and particularly one with a phenyl ring present, appear to permit the stabilization afforded by the bound intercalator to be transferred more effectively to the three-stranded complex. The conjugate containing the phenyl linker exhibits a T(M) value that is increased by 28 degrees C relative to the unconjugated triplex. That the linker itself contributes to the observed stabilization is clear since introduction of the phenyl linker increases the observed T(M) by 11 degrees C relative to a simple flexible linker.

Minor groove functional groups are critical for the B-form conformation of duplex DNA

Two analogue bases are described: 3-deazaadenine is a derivative of adenine from which N3 has been deleted and 3-methyl-2-pyridone is a C-nucleoside that mimics thymine but lacks the O2 carbonyl. The dc(3)A-dm(3)2P base pair is similar to dA-dT but eliminates the polar functional groups in the minor groove. The presence of this base pair in dA-dT rich sequences results in destabilized duplexes or conformational preferences for monomolecular hairpins rather than bimolecular duplexes. When present in dG-dC rich sequences, no significant differences in helix stability are observed. These differences are explained on the basis of hydration effects, most notably, the elimination of the minor groove spine of hydration normally present in dA-dT rich sequences. CD spectra suggest that sequences with a fully modified core (four analogue base pairs) are more A-like helices than B-like helices. Sequences containing two analogue base pairs can be transformed to A-like helices under conditions of high salt, or 65% trifluoroethanol. These conformational changes are also explained in terms of a loss of hydration in the minor groove that normally stabilizes the B-form conformation. In the absence of such hydration, the helices are conformationally mobile and adopt a more A-like helix form.

Use of pK(a) differences to enhance the formation of base triplets involving C-G and G-C base pairs

Two C-nucleosides are employed for the recognition of dC-dG base pairs. Both derivatives are related to dC but lack the O2-carbonyl. The absence of the carbonyl should eliminate any unfavorable steric interactions at this site. One of the derivatives contains a 2-aminopyridine heterocycle (d2APy) while the second contains a 2-aminopyrimidine heterocycle (d2APm). The former with a pK(a) of 6. 8 functions better for the recognition of dG-dC base pairs than it does in the binding to dC-dG base pairs. The d2APm derivative with a pK(a) of 3.3 functions better to form base triplets with dC-dG base pairs than with dG-dC targets. Triplex T(m)'s in both cases are compared with the sequence containing the native dC residue. The dC analogues appear to make two hydrogen bonds to a target dG base residue, one of which requires protonation of the ring nitrogen. Recognition of a target dC residue appears to require the formation of a single hydrogen bond to the C-nucleoside and having that nitrogen largely in the unprotonated state facilitates its formation.

Expanding the structural and functional diversity of RNA: analog uridine triphosphates as candidates for in vitro selection of nucleic acids

Two analog uridine triphosphates tethering additional functionality, one a primary amino group and the second a mercapto group, were prepared and tested for their compatibility with in vitro RNA selection procedures. 5-(3-Aminopropyl)uridine triphosphate (UNH(2)) as a uridine substitute was a more effective substrate for T7 RNA polymerase than 5-(2-mercaptoethyl)uridine triphosphate (USH). However, both functioned in transcription assays of 100 nt templates to generate RNA transcripts in quantities sufficient to initiate RNA selection procedures. Transcription of RNA pools with T7 RNA polymerase and UNH(2) or USH occurred with efficiencies of 43 and 29%, respectively, of the values obtained for native UTP transcription. In addition, the transcribed RNA containing roughly 25% UNH(2) residues exhibited better substrate properties for SuperScript(TM) II RNase H reverse transcriptase than did RNA transcripts containing approximately 25% of the USH analog. With either analog, both transcription and reverse transcription proceeded with high fidelity for insertion of the analog residue.

Long-range guanine oxidation in DNA restriction fragments by a triplex-directed naphthalene diimide intercalator

Naphthalene diimide (NDI), a powerful oxidant that binds avidly to DNA by intercalation, is seen to damage the 5' guanine of 5'-GG-3' sites by photoactivated charge transport through DNA. When covalently tethered to the center of a triplex-forming oligonucleotide and delivered by triplex formation within a pyrimidine.purine-pyrimidine motif to a specific site on a restriction fragment, NDI can photooxidize guanine over at least 25-38 bp in each direction from the site of binding. Charge migration occurs in both directions from the NDI intercalator and on both DNA strands of the target, but the oxidation is significantly more efficient to the 3' side of the triplex. NDI and octahedral rhodium intercalators, when tethered directly to the 5' terminus of the triplex-forming strand as opposed to the center, generate significant amounts of oxidative damage only in the immediate vicinity of the intercalation site. Given that long-range charge transport depends on DNA stacking, these results suggest that the base stack is distorted at the 5' end of the triplex region in the duplex-triplex junction. Targeting of photooxidative damage by triplex formation extends our previous studies of long-range charge transport to significantly longer DNA sequences through a strategy that does not require covalent attachment of the photooxidant to the DNA being probed. Moreover, triplex targeting of oxidative damage provides for the first time a typical distance distribution for genomic charge transport of approximately 200 A around the oxidant.

Tethered naphthalene diimide-based intercalators for DNA triplex stabilization

The synthesis and triplex stabilizing properties of oligodeoxyribonucleotides functionalized at the 5'- and/or 3'-termini with a naphthalene diimide-based (NDI) intercalator is described. The NDI intercalator was prepared in a single step from the corresponding dianhydride and was attached to the 5'-terminus of an oligodeoxyribonucleotide following a reverse coupling procedure. The DMT protecting group was removed and the sequence phosphitylated to generate the phosphoramidite derivative on the 5'-terminus of the support-bound oligodeoxyribonucleotide. The NDI intercalator with a free hydroxyl was then added in the presence of tetrazole. Attachment of the NDI to the 3'-terminus relied upon a tethered amino group that could be functionalized first with the naphthalene dianhydride, which was subsequently converted to the diimide. Using both procedures, an oligonucleo-tide conjugate was prepared having the NDI intercalator at both the 5'- and 3'-termini. Thermal denaturation studies were used to determine the remarkable gain in stability for triplexes formed when the NDI-conjugated oligonucleotide was present as the third strand in the complex.

Nucleoside analogue substitutions in the trinucleotide DNA template recognition sequence 3'-(CTG)-5' and their effects on the activity of bacteriophage T7 primase

Bacteriophage T7 primase catalyzes the synthesis of the oligoribonucleotides pppACC(C/A) and pppACAC from the single-stranded DNA template sites 3'-d[CTGG(G/T)]-5' and 3'-(CTGTG)-5', respectively. The 3'-terminal deoxycytidine residue is conserved but noncoding. A series of nucleoside analogues have been prepared and incorporated into the conserved 3'-d(CTG)-5' site, and the effects of these analogue templates on T7 primase activity have been examined. The nucleosides employed include a novel pyrimidine derivative, 2-amino-5-(beta-2-deoxy-D-erythro-pentofuranosyl)pyridine (d2APy), whose synthesis is described. Template sites containing d2APy in place of the cryptic dC support oligoribonucleotide synthesis whereas those containing 3-deaza-2'-deoxycytidine (dc(3)C) and 5-methyl-6-oxo-2'-deoxycytidine (dm(5ox)C) substitutions do not, suggesting that the N3 nitrogen of cytidine is used for a critical interaction by the enzyme. Recognition sites containing 4-amino-1-(beta-2-deoxy-D-erythro-pentofuranosyl)-5-methyl-2,6[1H, 3H]-pyrimidione (dm(3)2P) or 2'-deoxyuridine (dU) substitutions for dT support oligoribonucleotide synthesis whereas those containing 5-methyl-4-pyrimidinone 2'-deoxyriboside (d(2H)T) substitutions do not, suggesting the importance of Watson-Crick interactions at this template residue. Template sites containing 7-deaza-2'-deoxyguanosine (dc(7)G) or 2'-deoxyinosine (dI) in place of dG support oligoribonucleotide synthesis. The reduced extent to which dc(7)G is successful within the template suggests a primase-DNA interaction. Inhibition studies suggest that the primase enzyme binds "null" substrates but cannot initiate RNA synthesis.

Synthesis and triplex forming properties of pyrimidine derivative containing extended functionality

Two pyrimidine nucleosides have been synthesized containing extended hydrogen bonding functionality. In one case the side chain is based upon semicarbazide and in the second monoacetylated carbohydrazide was employed. DNA sequences could be prepared using both analogue nucleosides in a reverse coupling protocol, and provided that the normal capping step was eliminated and that the iodine-based oxidizing solution was replaced with one based upon 10-camphorsulfonyl oxaziridine. Both derivatives exhibited moderate effects in targeting selectively C-G base pairs embedded within a polypurine target sequence.

Critical nature of a specific uridine O2-carbonyl for cleavage by the hammerhead ribozyme

Three modified hammerhead ribozyme/substrate complexes have been prepared in which individual uridine O2-carbonyls have been eliminated. The modified complexes were chemically synthesized with the substitution of a single 2-pyridone (2P) base analogue for residues U4, U7, and U16.1. Steady-state kinetic analyses indicate that the cleavage efficiencies for the U7 and U16.1 complexes were not significantly reduced relative to the native complex as measured by kcat/KM. The cleavage efficiency for the 2P4 complex, with the analogue present within the uridine loop, was reduced by greater than 2 orders of magnitude. This significant reduction in catalytic efficiency was due primarily to a decrease in kcat. The pH vs cleavage rate profile suggests that the O2-carbonyl of the U4 residue of the hammerhead complex is critical for transition state stabilization and efficient cleavage activity. The results of a Mg2+ rescue assay do not implicate the O2-carbonyl of U4 in an interaction with a divalent metal ion. In addition, the results of a ribozyme folding assay suggest that the presence of the 2P4 within the uridine loop does not alter the folding pathway (relative to the native sequence) both in the absence and in the presence of Mg2+. The O2-carbonyl of U4 appears oriented toward the interior of the catalytic pocket where it may be involved in a critical hydrogen bonding interaction necessary for transition state stabilization.

A 2,2"-bipyridine ligand for incorporation into oligodeoxynucleotides: synthesis, stability and fluorescence properties of ruthenium-DNA complexes

A non-nucleoside linker based upon the ligand 2,2'-bipyridine and ethylene glycol is prepared and placed into the backbone of a number of oligonucleo-tides. The bipyridine ligand is reacted with cis -dichloro bis(2,2'-bipyridyl) Ru(II) to generate the relatively substitutionally inert complex based upon the well-characterized tris -2,2'-bipyridyl Ru(II). The ruthenium-containing DNA complexes exhibited UV and fluorescence characteristics that are consistent with those previously observed for simple tris -2,2'-bipyridyl Ru(II) complexes. Oligonucleotides containing the ruthenium complex will form both DNA duplexes and triplexes with stabilities that are slightly better than those formed from simple tethered oligonucleotide probes in which the two hybridizing sequences are tethered by simple tri(ethylene glycol) or hexa(ethylene glycol) linkers.

Synthesis and triplex forming properties of an acyclic N7-glycosylated guanine nucleoside

A chiral acyclic nucleoside, one in which the ribose carbohydrate has been replaced with a glycerol-based linker, is prepared by glycosylating guanine at the N7-nitrogen. The stereochemically pure derivative is converted to a DMT-protected phosphoramidite for incorporation into DNA sequences. Sequence containing the acyclic N7-dG nucleoside are capable of forming DNA triplexes in which it is likely that the N1-H and N2-amino groups of the N7-dG are involved in recognition of the guanine base in G-C base pairs.

Inhibition of DNA polymerase reactions by pyrimidine nucleotide analogues lacking the 2-keto group

To investigate the influence of the pyrimidine 2-keto group on selection of nucleotides for incorporation into DNA by polymerases, we have prepared two C nucleoside triphosphates that are analogues of dCTP and dTTP, namely 2-amino-5-(2'-deoxy-beta-d-ribofuranosyl)pyridine-5'-triphosphate (d*CTP) and 5-(2'-deoxy- beta-d-ribofuranosyl)-3-methyl-2-pyridone-5'-triphosphate (d*TTP) respectively. Both proved strongly inhibitory to PCR catalysed by Taq polymerase; d*TTP rather more so than d*CTP. In primer extension experiments conducted with either Taq polymerase or the Klenow fragment of Escherichia coli DNA polymerase I, both nucleotides failed to substitute for their natural pyrimidine counterparts. Neither derivative was incorporated as a chain terminator. Their capacity to inhibit DNA polymerase activity may well result from incompatibility with the correctly folded form of the polymerase enzyme needed to stabilize the transition state and catalyse phosphodiester bond formation.

Functional group substitutions of the branchpoint adenosine in a nuclear pre-mRNA and a group II intron

Splicing of nuclear mRNA precursors (pre-mRNAs) takes place in the spliceosome, a large and complex ribonucleoprotein. Nuclear pre-mRNA splicing and group II intron self-splicing occur by a chemically identical pathway involving recognition of a specific branchpoint adenosine and nucleophilic activation of its 2'-hydroxyl group. The chemical similarity between these two splicing reactions, as well as other considerations, have suggested that the catalytic core of the spliceosome and group II introns may be related. Here we test this hypothesis by analyzing splicing and RNA branch formation of a pre-mRNA and a group II intron in which the branchpoint adenosine was substituted with purine base analogues. We find that replacement of the branchpoint adenosine with either of two modified adenosine analogues or guanosine leads to remarkably similar patterns of splicing and RNA branch formation in the two systems.

Application of a 5'-bridging phosphorothioate to probe divalent metal and hammerhead ribozyme mediated RNA cleavage

This paper describes the preparation and application of a chimeric DNA/RNA oligonucleotide that contains a single 5'-bridging phosphorothioate linkage adjacent to a ribonucleotide and embedded in an otherwise all-DNA sequence. The influence of pH, divalent metal cation, hybridization, and secondary structure on the susceptibility of the thio linkage towards transesterification is investigated in an effort to better understand the metal-phosphorothioate interactions and the basis for catalysis. In addition to the chemical cleavage, we have examined the hammerhead ribozyme mediated cleavage of the 5'-bridging phosphorothioate linkage specifically to test the hypothesis that the ribozyme employs a second metal cofactor, which functions as a Lewis acid, to catalyze transesterification. The results of our kinetics experiments do not support this double-metal model.

Probing contacts to the DNA backbone in the trp repressor-operator sequence-specific protein-nucleic acid complex using diastereomeric methylphosphonate analogues

Fourteen analogue DNA sequences containing the trp operator sequence and a single diastereomeric methylphosphonate linkage are each prepared from the stereochemically pure nucleoside methylphosphonate dimer building block, prepared as a phosphoramidite. The analogue sequences are shown to be single diastereomers on the basis of HPLC analysis of the digestion mixture; in each case, only a single diastereomeric dimer is present. These analogue sequences can be used effectively to probe for interactions to either of the prochiral phosphate oxygens as illustrated by their use to identify critical interactions in the trp repressor-operator complex. In a number of cases, the pairs of diastereomeric analogue sequences exhibit variable binding affinities that can be used to identify one of the prochiral phosphate oxygens as a critical site for complex-stabilizing interactions. Upon the basis of dissociation constants, apparent incremental binding energies are assigned to specific interactions. In all but one example, these identified sites for interactions to the phosphate backbone can be correlated with contacts implicated by the crystal structure analysis of the trp repressor-operator complex.

Oligonucleotides tethering Hoechst 33258 derivatives: effect of the conjugation site on duplex stabilization and fluorescence properties

A series of DNA conjugates have been prepared in which two different derivatives of Hoechst 33258 have been tethered to a sequence containing a 5'-GAATTC-3' target site. The two derivatives differ only in the length of the tether between the DNA and the Hoechst fluorophore. By using a DNA backbone labeling protocol, one in which the Hoechst dye is tethered to an internucleotide phosphoramidate residue, it was possible to easily vary the site of attachment with respect to the A-T rich binding site. When tethered outside the GAATTC sequence, little if any helix stabilization results upon hybridization of the conjugate to its complementary sequence. As the site of conjugation is moved to one end of the target sequence and finally within the AATT sequence, more effective helix stabilization results. When tethered between the two A residues, or between the A and T residue, a delta Tm of at least +20 degrees C is observed. Upon hybridization and formation of the B-form DNA, binding by the tethered Hoechst dye results, and the bound dye becomes brightly fluorescent. Upon a simple titration of the single-stranded conjugate with the complementary target sequence the quantum yield enhancement for hybridization only appears to be 5-7-fold at best. These fluorescence effects, generally less dramatic than those observed with other sequences, result from an increase in quantum yield for the single-stranded conjugate relative to the free Hoechst 33258. Heating the single-stranded conjugate reduces the inherent fluorescence of the single-stranded conjugate to a level comparable with that of the free Hoechst dye. In experiments monitoring absorbance vs temperature, a cooperative transition is observed for the single-stranded conjugate. Both the high quantum yield observed for the single-stranded conjugate and the observed thermally induced transition suggest that the single-stranded conjugate can dimerize (at the GAATTC site), mediated by the groove-binding fluorophore.

[125I/127I]iodoHoechst 33342: synthesis, DNA binding, and biodistribution

An iodinated analog of the DNA-minor-groove-binding agent Hoechst 33342 has been synthesized and evaluated for DNA binding and tumor targeting. The bis-benzimidazole ring system of the title compound was constructed from the piperazinyl terminus via a Pinner-type cyclization followed by oxidative cyclization of the diamine Schiff base. To synthesize radioiodoHoechst 33342, (trimethylstannyl)Hoechst 33342 was prepared by the same strategy and subjected to mild radioiododestannylation in the presence of lactoperoxidase. After purification by HPLC, the radiochemical was separated in carrier-free form with > 85% radiochemical yield and > 99% chemical and radiochemical purity. Fluorescence spectrometric analysis of the binding of iodoHoechst 33342 to calf thymus DNA gave an equilibrium association constant (Ka) of 2.57 x 10(7) M-1 comparable to the Ka value of Hoechst 33342. Fluorescence microscopy of viable V79 cells demonstrated that the iodinated dye stained the nuclei with avidity similar to that of the noniodinated dye. The biodistribution of [125I]-iodoHoechst 33342 in LS174T tumor-bearing athymic mice 4 h postadministration showed a tumor uptake of 3-4% injected dose per gram (ID/g), tumor/blood ratio of 6-8, and tumor/ nontumor ratios above unity for most organs. A low thyroid uptake (approximately 2% ID/g) indicated that the radiochemical did not deiodinate and was stable in vivo.

Importance of specific adenosine N3-nitrogens for efficient cleavage by a hammerhead ribozyme

Five modified hammerhead ribozyme/substrate complexes have been prepared in which individual adenosine N3-nitrogens have been excised and replaced with carbon. The modified complexes were chemically synthesized with the substitution of a single 3-deazzaadenosine (c3A) base analogue for residues A6, A9, A13, A14, or A15.1. Steady-state kinetic analyses indicate that the cleavage efficiencies, as measured by kcat/K(M), for the c3A6, c3A9, and c3A14 complexes were only marginally reduced (< or = 5-fold) relative to the native complex. By comparison, the cleavage efficiencies for the c3A13 and c315.1 complexes were reduced by 9-fold and 55-fold, respectively. these reductions in cleavage efficiency are primarily a result of lower kcat values. Profiles of pH and cleavage rate suggest that the chemical cleavage step is the rate-limiting reaction for these complexes. These results suggest that the N3-nitrogen of the A13 residue and particularly the A15.1 residue in the hammerhead ribozyme/substrate complex are critical for transition state stabilization and efficient cleavage activity. We have additionally compared the locations of these critical functional groups, as well as those identified from other studies, with recent crystallographic analyses. In some cases, the critical functional groups are clustered around proposed metal binding sites and may reflect functional groups critical for binding the metal cofactor. In other cases, clusters of functional groups may form a network of hydrogen bonds necessary for transition state stabilization.

Use of a pyrimidine nucleoside that functions as a bidentate hydrogen bond donor for the recognition of isolated or contiguous G-C base pairs by oligonucleotide-directed triplex formation

Synthesis of the nucleoside building block of the 6-keto derivative of 2'-deoxy-5-methylcytidine (m5oxC) as an analog of an N3-protonated cytosine derivative is described. A series of 15mer oligonucleotides containing either four or six m5oxC residues has been prepared by chemical synthesis. Complexation of the 15 residue oligonucleotides with target 25mer duplexes results in DNA triplexes containing T-A-T and m5oxC-G-C base triplets. When the m5oxC-G-C base triplets are present in sequence positions that alternate with TAT base triplets, DNA triplexes are formed with Tm values that are pH independent in the range 6.4-8.5. A 25mer DNA duplex containing a series of five contiguous G-C base pairs cannot be effectively targeted with either m5C or M5oxC in the third strand. In the former case charge-charge repulsion effects likely lead to destabilization of the complex, while in the latter case ineffective base stacking may be to blame. However, if the m5C and M5oxC residues are present in the third strand in alternate sequence positions, then DNA triplexes can be formed with contiguous G-C targets even at pH 8.0.

Ribozyme-mediated cleavage of a substrate analogue containing an internucleotide-bridging 5'-phosphorothioate: evidence for the single-metal model

An oligonucleotide substrate containing a 5'-bridging phosphorothioate linkage adjacent to a ribonucleotide has been used to investigate the cleavage mechanisms of the hammerhead ribozyme and to probe the catalytic role of the metal cofactor(s). Specifically, we tested the hypothesis that a second metal interacts with the 5'-leaving group to facilitate the cleavage event. To this end, we have examined the ribozyme-mediated cleavage activity of the phosphorothioate substrate at pH 7.5 with a series of divalent metal in both the presence and absence of the polycation spermine. The cleavage products are found to be the same as for the native sequence under a variety of reaction conditions. The influence of divalent metal ion concentration, temperature, and pH on the cleavage rate also has been examined for both the oxo linkage and the thio analogue. Spermine (but not spermidine or NaCl) is shown to support efficient cleavage of the thio analogue in the absence [5 mM ethylenediaminetetraacetic acid (EDTA)] of a divalent metal cofactor. The cleavage of the oxo linkage exhibits a solvent deuterium isotope effect of 3.6, but a similar effect is not observed with the thio analogue. The pseudo-first-order rate constants for cleavage of the thio analogue in the presence of 10 mM Mg2+ or Mn2+ at pH 7.5 are 65 and 82 x 10(-3) min-1, respectively. The native oxo linkage is cleaved at essentially the same rate as the thio analogue (35 and 97 x 10(-3) min-1 for Mg2+ and Mn2+, respectively). The absence of an appreciable thio effect and the lack of a preference for either Mg2+ or Mn2+ provides compelling evidence that the metal cofactor does not interact with the 5'-thioanion (or oxyanion) leaving group in the transition state. These rate comparisons additionally reveal the the departure of the 5'-leaving group is not the rate-limiting step of the cleavage reaction catalyzed by the hammerhead ribozyme.

Cleavage properties of an oligonucleotide containing a bridged internucleotide 5'-phosphorothioate RNA linkage

An oligonucleotide has been synthesized that contains a single bridging 5'-phosphorothioate at an RNA linkage (5'-ApCpGpGpTpCpTprCpsApCpGpApGpC-3'). This new phosphodiester linkage is found to be particularly susceptible to cleavage when compared with the corresponding oxo, deoxy and thiodeoxy derivatives. Divalent metal cations were observed to dramatically increase the cleavage rate. The products of the cleavage under a variety of conditions are a 5'-thiol-containing fragment (6mer) and a 2',3'-cyclic phosphate-containing fragment (8mer). The pseudo-first order rate constant, kobs, for cleavage at pH 7.5 (50 mM Tris-HCI) in the presence of 5 mM EDTA is 1.5 x 10(-4)/min. In the presence of 5 mM metal dichloride and 50 mM Tris-HCI, pH 7.5, the relative cleavage rate enhancements are 10, 24, 71, 98, 370 and 3400 for Mg2+, Ca2+, Mn2+, Co2+, Zn2+ and Cd2+ respectively. The rate enhancements correlate well with Pearson's HSAB principle, suggesting that cleavage is mediated in part by coordination of the metal to the 5'-mercapto leaving group. RNA linkages containing bridging 5'-phosphorothioates should prove valuable for studying the mechanistic details of a variety of RNA cleaving agents, such as ribozymes.

Effects of base analog substitutions in the noncoding dC of the 3'-d(CTG)-5' template recognition site of the bacteriophage T7 primase

The 63-kDa gene 4 protein (DNA primase) of bacteriophage T7 catalyzes the synthesis of the oligoribonucleotides pppACC(C/A) and pppACAC at single-stranded DNA recognition sites 3'-d[CTGG-(G/T)]-5' and 3'-d(CTGTG)-5', respectively. At these sites, the 3'-terminal deoxycytidine residue is conserved but noncoding; the 3'-dC residue is required to initiate catalytic synthesis of oligoribonucleotides, yet it is not used as a template residue for the synthesis of a complementary G residue in the RNA primer. We have examined the interactions between T7 primase and the functional groups of the 3'-dC residue by measuring the ability of the primase to catalyze the synthesis of oligoribonucleotides on synthetic single-stranded 20-mer templates [e.g., 3'-d(GCTATGGTGACTGGTAGTCG)-5'] that contain analogs of dC in the conserved pentanucleotide recognition site. Recognition sites containing 5-methyldeoxycytidine (m5dC) or 1-(beta-D-2'-deoxyribosyl)-2-pyrimidinone (dH4C) substitutions for dC support oligoribonucleotide synthesis whereas those containing deoxythymidine (dT) and deoxyuridine (dU) substitutions do not. Oligoribonucleotide synthesis on the native template (containing dC) is inhibited competitively by the template containing a dT residue in the primase recognition site, 3'-[(N10)TTGGT(N5)]-5', with an apparent Ki of 1.30 +/- 0.04 microM. Templates containing dU residues, 3'-[(N10)UTGGT(N5)]-5' and 3'-[(N9)UTTGGT-(N5)]-5', affect both the apparent Km and Vmax parameters for oligoribonucleotide synthesis on the 3'-[(N10)CTGGT(N5)]-5' template.

Synthesis and properties of a Hoechst-like minor-groove binding agent tethered to an oligodeoxynucleotide

A small Hoechst-like DNA groove-binding fluorophore carrying a terminal bromoacetimido linker has been synthesized. Individual diastereomeric oligodeoxynucleotide dodecamers containing a thiol-based linker attached to an internucleotide phosphoramidate within a sequence of dA-dT residues were each covalently labeled with the new fluorophore. One isomer of the DNA-fluorophore conjugate (Isomer B) hybridizes to the complementary single-stranded target DNA and the presence of the tethered fluorophore results in both increased duplex stability and an enhanced fluorescent signal, presumably due to the fluorophore binding in the dA-dT rich minor groove. Duplex stability is increased by 2-3 degrees C and the fluorescence quantum yield for the fluorophore increases four-fold. In contrast, the other diastereomer (Isomer A) exhibits reduced helix stability (approximately 2 degrees C) and only slight changes in fluorescence intensity upon hybridization.

Activity of the hammerhead ribozyme upon inversion of the stereocenters for the guanosine 2'-hydroxyls

Two guanosine 2'-hydroxyls in the hammerhead RNA complex at positions G5 and G8 are critical for efficient cleavage by this RNA catalyst. These two functional groups are likely involved in the binding of the metal cofactor, or they are involved in specific interresidue hydrogen-bonding interactions. The importance of the stereochemical positioning of both critical 2'-hydroxyls was investigated by comparing the cleavage rates of three arabinosylguanine-substituted complexes (in which the positions of specific guanosine 2'-hydroxyls were stereochemically altered by inverting the C2' stereocenter) with that of the native complex, as well as with the rates of the dG- and dFG-substituted complexes [in which the 2'-hydroxyls are absent as the result of substitution by 2'-deoxyguanosine (dG) or 2'-deoxy-2'-fluoroguanosine (dFG)]. The G5araG and G8araG complexes exhibit dramatically different cleavage rates. The G5araG complex is essentially inactive, at least 10(5)-fold slower than the native complex. RNA cleavage by this analogue ribozyme is also 1000-fold slower than cleavage by either the G5dG or the G5dFG ribozyme, both of which lack the 2'-hydroxyl at G5. By comparison, catlytic efficiency of the G8araG complex as expressed by kcat/Km is comparable with that of the native complex and some 2 orders of magnitude more active than either the G8dG or the G8dFG complex.

Specific purine N7-nitrogens are critical for high affinity binding by the trp repressor

We have analysed the interaction of the trp repressor with the trpEDCBA operator using a series of modified trp operator sequences incorporating two isosteric purine analogues that lack N7-nitrogens. Our results suggest that as well as the direct contact between Arg69 and G-9, three additional purine N7-nitrogens, implicated in specific, water-mediated contacts to the repressor, are critical for formation of the high-affinity repressor-operator complex. We conclude that the crystal structure obtained by Otwinowski et al. reflects high-affinity sequence-specific binding of the trp repressor to the trp operator, and that in some cases proteins can use water molecules to extend amino acid side chains in order to derive favorable binding energy in complex formation.

Importance of specific guanosine N7-nitrogens and purine amino groups for efficient cleavage by a hammerhead ribozyme

Seven modified hammerhead ribozyme/substrate complexes have been prepared in which individual purine nitrogens, the guanine N7-, the guanine N2-, or the adenine N6-nitrogen, have been excised. The modified complexes were chemically synthesized with the substitution of a single 7-deazaguanosine (c7G), inosine (I), or nebularine (purine riboside, P) base analogue as appropriate for residues G5, G8, G12, A13, A14, or A15. Two of the base analogues, c7G5 and C7G8, occur in a 19-mer ribozyme, while the remaining three residues are present in a 24-mer substrate. Under stoichiometric conditions, four of the complexes, G5c7G, G8c7G, G12c7G, and A14P, are cleaved with relatively little change in rate when compared with the native complex. Two complexes, A13P and A15P, are cleaved some 6-8-fold slower than the native complex, while the G12I complex is reduced in rate by 50-fold. Steady-state kinetic analyses indicate that the cleavage efficiencies, as measured by kcat/KM values, for the G5c7G, G8c7G, and G12c7G complexes are only marginally reduced relative to the native complex. The values for the A13P, A14P, and A15P complexes are reduced by 25-, 15-, and 60-fold, respectively. These reductions in cleavage efficiency are primarily a result of lower kcat values. By comparison, the kcat/KM value for the G12I complex is decreased 450-fold relative to the native complex and is characterized by an 8-fold increase in KM and a kcat value that is reduced nearly 60-fold. These results indicate that the N2-amino group of G12 in the hammerhead ribozyme/substrate complex is critical for efficient cleavage activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Importance of specific adenosine N7-nitrogens for efficient cleavage by a hammerhead ribozyme. A model for magnesium binding

Five modified hammerhead ribozyme/substrate complexes have been prepared in which individual adenosine N7-nitrogens have been excised. The modified complexes were chemically synthesized with the substitution of a single 7-deazaadenosine (c7A) base analogue for residues A11, A14, A26, A27, or A28. Two of the base analogues, c7A11 and c7A14, occur in a 19-mer ribozyme, while the remaining three residues, c7A26, c7A27, and c7A28, are present in a 24-mer substrate. Under stoichiometric conditions, four of the complexes are cleaved with relatively little change in rate when compared with that of the native complex. However, the relative rate for the c7A11 complex is some 35-fold slower than that of the native complex. Steady-state kinetic analyses indicate that the cleavage efficiencies, as measured by kcat/KM, for the c7A14, c7A26, c7A27, and c7A28 complexes are reduced 18-fold, 10-fold, 34-fold, and 16-fold, respectively. These reductions in cleavage efficiency are primarily a result of lower kcat values. By comparison, the cleavage efficiency of the c7A11 complex is reduced more than 200-fold relative to that of the native complex, again primarily as a result of a lower kcat value. The results suggest that the N7-nitrogen of A11 in the hammerhead ribozyme/substrate complex is critical for efficient cleavage activity. The results of the present work, in combination with those from previous reports, indicate that five critical functional groups are located within the tetrameric sequence G10A11U12G13. A preliminary model for the binding of a single magnesium cofactor to this portion of the sequence is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)

The estimation of distances between specific backbone-labeled sites in DNA using fluorescence resonance energy transfer

A series DNA helices of twenty-four base pairs has been prepared for the study of fluorescence resonance energy transfer. Each of the DNA helices contains two phosphorothioate diesters (one in each strand) at pre-selected sites for introduction of the desired donor and acceptor fluorophores. The phosphorothioate-containing oligodeoxynucleotides have been prepared as pure Rp or Sp derivatives or as deastereomeric mixtures. Fluorescein and eosin are employed as the respective donor and acceptor fluorophores. A series of donor-acceptor pairs was generated by labeling of the appropriate phosphorothioate diester with the desired fluorophore and annealing the two complementary DNA strands (one containing the acceptor and one containing the donor fluorophore) to form the double-stranded helix. The 24-mer helices containing two covalently attached fluorophores exhibited some thermal destabilization and the extent of this destabilization was dependent upon the stereochemical orientation of the fluorophore. The Sp derivatives direct the fluorophore out, away from the the DNA helix, while the Rp derivatives direct the fluorophore toward the major groove. As expected, the Sp labeled duplexes were more stable than the corresponding Rp labeled sequences. However, all of the duplex structures formed were stable under the conditions used to measure energy transfer. Energy transfer could be observed with these complexes from the quenching of the donor fluorescence in the presence of the acceptor fluorophore. Using Förster's theories, distances separating the fluorophores could be calculated that were generally in reasonable agreement with the distances expected in an idealized B-form DNA helix. However anomalous results were obtained for one donor/acceptor pair where the expected distance was less than 20 A. Fluorescence anisotropy values determined in solutions of varying viscosity were quite high suggesting that the fluorophores did not experience complete freedom of movement when attached to the DNA helix.

Interactions between the trp repressor and its operator sequence as studied by base analogue substitution

A series of modified trp operator sequences has been prepared by the incorporation of seven different base analogues. Four of the analogues allow the site-specific deletion of functional groups present on the dA-dT and dT-dA base pairs at positions -4/+4 and -5/+5 in the trp operator. The remaining three analogues permit the incorporation of structural analogues of the native dA-dT or dG-dC base pairs. The duplex operator sequences all exhibit Tm values well above ambient temperature (48-70 degrees C), and these values generally correlate very well with the number of interstrand hydrogen bonds present. The affinity between the trp repressor and 14 modified operator sequences was examined using a recently developed alkaline phosphatase protection assay. The results from the analogue sequences used in this study suggest that the structure of the dA-dT or dT-dA base pairs at positions -4/+4 and -5/+5, respectively, has relatively little effect upon the solution binding by the trp repressor, but the protein is very sensitive to the orientation of the amino and carbonyl functional groups at the -4/+4 positions, which are involved in the formation of an interbase hydrogen bond present in the major groove. (The term structure in this case refers to the hydrogen bonding structure of the base pairs. We recognize that the introduction of conservative functional group deletions or reversals may affect other structural criteria such as hydration.) The deletion of individual functional groups from the operator sequence suggests that the carbonyl at dT+4 is critical for formation of the high-affinity sequence-specific complex. Additionally, the thymine methyl group at dT+4 and the N7 nitrogen of dA+5 appear to be critical contacts necessary for high-affinity binding by the repressor. The thymine carbonyl and the adenine N7 nitrogen are each responsible for approximately -1.5 kcal/mol of apparent free energy of binding. The thymine methyl provides a somewhat smaller contribution of -0.7 kcal/mol. Deletion of either of the adenine amino groups at dA-4 or dA+5 results in a sequence that binds to the repressor with a higher affinity than observed with the native sequence; this can be explained in that the functional groups lost are not critical for binding, and the resulting increased flexibility of the operator, or the creation of a more hydrophobic surface at these sites, enhances van der Waals contacts between the protein and the nucleic acid.

DNA curvature does not require bifurcated hydrogen bonds or pyrimidine methyl groups

Short tracts of the homopolymer dA.dT confer intrinsic curvature on the axis of the DNA double helix. This phenomenon is assumed to be a consequence of such tracts adopting a stable B'-DNA conformation that is distinct from B-form structure normally assumed by other DNA sequences. The more stable B' structure of dA.dT tracts has been attributed to several possible stabilizing factors: (1) optimal base stacking interactions consequent upon the high propeller twist, (2) bifurcated hydrogen bonds between adjacent dA.dT base-pairs, (3) stacking interactions involving the dT methyl groups, and finally (4) a putative spine of ordered water molecules in the minor groove. DNA oligodeoxynucleotides have been synthesized that enable these hypotheses to be tested; of particular interest is the combination of effects due to bifurcation (2) and methylation of the pyrimidines nucleotides (3). The data indicate that neither bifurcated hydrogen bonds nor pyrimidine methyl groups nor both are essential for DNA curvature. The data further suggest that the influence of the minor groove spine of hydration on the B'-formation is small. The experiments favor the hypothesis that base stacking interactions are the dominant force in stabilizing the B'-form structure.

Importance of specific purine amino and hydroxyl groups for efficient cleavage by a hammerhead ribozyme

Eight modified ribozymes of 19 residues have been prepared with individual purine amino or hydroxyl groups excised. The modified ribozymes were chemically synthesized with the substitution of a single 2'-deoxyadenosine, 2'-deoxyguanosine, inosine, or purine riboside for residues G10, A11, G13, or A14. Five of the modified ribozymes cleaved the 24-mer substrate with little change in rate as monitored by simple first-order kinetics. However, deletion of the 2-amino group at G10 (replacement with inosine) or deletion of either of the 2'-hydroxyls at G10 or G13 (replacement with 2'-deoxyguanosine) resulted in ribozymes with a drastic decrease in cleavage efficiency. Increasing the concentration of the Mg2+ cofactor from 10 mM to 50 mM significantly enhanced cleavage efficiency by these three derivatives. Steady-state kinetic assays for these three ribozymes indicated that the modifications result in both an increase in Km and a decrease in kcat. These results suggest that the exocyclic amino group at-G10 and the hydroxyls at G10 and G13 are important both for ribozyme-substrate binding and for the Mg(2+)-catalyzed cleavage reaction.

Properties of pseudouridine N1 imino protons located in the major groove of an A-form RNA duplex

The exchangeable N1 imino protons of two pseudouridine (psi) bases located at adjacent internal positions within an undecamer RNA duplex (5'AUAC psi psi ACCUG/3'UAUGAAUGGUC) can report on the environment of the major groove of an A-form double-stranded nucleic acid. The psi N1 imino protons of these residues (which are not involved in interstrand Watson-Crick hydrogen bonding) are protected from chemical exchange with the solvent water and thus are observable in the proton NMR spectrum in H2O (1). These protons will exchange readily at increased pH values or upon thermal denaturation of the duplex. The longitudinal (T1) relaxation times of the psi N1 imino protons in 100 mM NaCl or in 10 mM MgCl2 and 100 mM NaCl are approximately two-fold faster than those of the psi N3 imino protons which are involved in Watson-Crick base pairing. With the addition of spermidine, the psi N1 imino protons become readily exchangeable at a temperature some 20 degrees C below the melting temperature of the duplex.

Thermodynamics of interaction of a fluorescent DNA oligomer with the anti-tumour drug netropsin

Fluorescence spectroscopy was used to study the interaction between the minor-groove-binding drug netropsin and the self-complementary oligonucleotide d(CTGAnPTTCAG)2 containing the fluorescent base analogue 2-aminopurine (nP). The binding of netropsin to this oligonucleotide causes strong quenching of the 2-aminopurine fluorescence, observed by steady-state as well as time-resolved spectroscopy. From fluorescence titrations, binding isotherms were recorded and evaluated. The parameters showed one netropsin binding site/oligonucleotide duplex and an association constant of about 10(5) M-1 at 25 degrees C, 3-4 orders of magnitude weaker than for an exclusive adenine/thymine host sequence. From the temperature dependence of the association constant the thermodynamic parameters were obtained as delta G = -29 kJ/mol, delta H = -12 kJ/mol and delta S = +55 J.mol-1.K-1 at 25 degrees C. These parameters resemble those of the interaction of poly[(dG-dC).(dG-dC)] with netropsin, indicating a mainly entropy-driven reaction. The amino group of 2-aminopurine, like that of guanine, resides in the minor groove of DNA. Therefore the relatively weak binding of netropsin to d(CTGAnPTTCAG)2 is probably related to partial blockage of the tight fit of netropsin into the preferred minor groove of an exclusive adenine/thymine host sequence.

Thermodynamic and structural properties of pentamer DNA.DNA, RNA.RNA, and DNA.RNA duplexes of identical sequence

Four pentamers with the general sequence 5'CU(T)GU(T)G/5'CACAG have been prepared by chemical synthesis in order to generate duplex structures with common sequences. The four duplexes studied include the DNA.DNA duplex (5'dCACAG/5'dCTGTG) and the RNA.RNA duplex (5'rCUGUG/5'rCACAG) as well as the two corresponding DNA.RNA heteroduplexes (5'rCUGUG/5'dCACAG and 5'CACAG/5'dCTGTG). The measured entropy, enthalpy, and free energy changes upon melting are reported for each pentamer and compared to the predicted values where possible. Results show that the two DNA.RNA heteroduplexes are destabilized (delta G degrees 25 = -4.2 +/- 0.4 kcal/mol) relative to either the DNA.DNA duplex (delta G degrees 25 = -4.8 +/- 0.5 kcal/mol) or the RNA.RNA duplex (delta G degrees 25 = -5.8 +/- 0.6 kcal/mol). Circular dichroism spectra indicate that the RNA and the two heteroduplexes adopt an A-form conformation, while the DNA conformation is B-form. Imino proton NMR spectra also show that the heteroduplex structures resemble the RNA.RNA duplex.

The covalent attachment of multiple fluorophores to DNA containing phosphorothioate diesters results in highly sensitive detection of single-stranded DNA

DNA fragments containing multiple internucleotidic phosphorothioate diesters, prepared by either chemical or enzymatic syntheses, are amenable to labeling with the fluorophore monobromobimane. With the incorporation of phosphorothioate diesters at each internucleotidic site, multiple fluorophores, ideally one for each nucleotide residue, can be covalently attached to the DNA fragment. The presence of multiple labels can be expected to interfere with analysis techniques, such as polyacrylamide gel electrophoresis. To avoid such problems, the fluorophores are introduced in a "postassay" fashion, that is, while the fragments are still embedded within the gel matrix. The detection limit (to the naked eye) for multiply labeled single-stranded DNA containing hundreds of base residues is in the low femtomole range. DNA containing greater than 1000 base residues can be visualized in some cases in the subfemtomole range without the use of sophisticated electronic instrumentation.

The highly homologous isoschizomers RsrI endonuclease and EcoRI endonuclease do not recognize their target sequence identically

Using a series of decadeoxyribonucleotides containing base analogues as substrates we measured the steady-state kinetic parameters for the reaction catalyzed by RsrI endonuclease and compared the results to those with its isoschizomer EcoRI. The kinetics of RsrI cleavage are affected by each substitution, with the effects being generally more deleterious than with EcoRI, as shown by the greater reduction in the specificity constant kcat/KM. The magnitudes of the effects of several substitutions are consistent with the formation of direct enzyme-nucleobase contacts at the indicated positions. With substrates containing 2-amino-purine or 2,6-diaminopurine at the central adenine or uracil at the outermost thymine in the recognition sequence, cleavage by RsrI was very slow, less than one-tenth the rate of the corresponding EcoRI-catalyzed reaction. The lower tolerance of RsrI endonuclease for functional group changes in its recognition site may reflect differences in the mechanisms of DNA recognition by the two enzymes. Although RsrI and EcoRI endonucleases bind with similar affinities to specific and nonspecific DNA sequences and appear to introduce similar structural distortions in DNA upon binding, the use of substrate analogues reveals significant differences at the level of catalysis in the mechanisms by which these two endonucleases recognize the duplex sequence GAATTC.

Properties of a U1/mRNA 5' splice site duplex containing pseudouridine as measured by thermodynamic and NMR methods

Three RNA undecamers, 5'AUAC psi psi ACCUG (psi = pseudouridine), 5'AUACUUACCUG, and their complementary 11-mer 5'CAGGUAAGUAU, have been chemically synthesized by phosphite triester chemistry on a controlled-pore glass (CPG) support. The two duplexes formed with these molecules, 5'AUAC psi psi ACCUG/5'CAGGUAAGUAU and 5'AUACUUACCUG/5'CAGGUAAGUAU, represent the 5' end of human U1 snRNA paired to the mRNA consensus 5' splice site. In one undecamer, pseudouridines are incorporated at those positions corresponding to the native in vivo U1 snRNA, while the other (control) undecamer contains only uridine. Surprisingly, the NMR data show that the extra imino proton of the pseudouridines, which is found in the major groove and is presumably not hydrogen bonded, is clearly visible in the imino proton NMR spectrum at pH 6. This result suggests that the structure of the RNA restricts access of solvent to the major groove, slowing the exchange of the pseudouridine NH1 imino proton. A comparison of the thermodynamic properties of the two duplexes show that the free energy of duplex formation is unchanged by the substitution of pseudouridine for uridine.

Binding of Hoechst 33258 and 4',6'-diamidino-2-phenylindole to self-complementary decadeoxynucleotides with modified exocyclic base substituents

Fluorescence titrations have been carried out to determine the association constants (Ka) for binding of the dyes Hoechst 33258 and DAPI to the self-complementary decamer d(CTGAATTCAG) and nine duplex derivatives with exocyclic substituent changes in the six central base pairs. Many Ka values are in the range (2-5) x 10(8) (duplex M)-1 at 5.5 degrees C. Replacement of the leftmost adenine by 2-aminopurine in the sequence decreases Ka for Hoechst 33258 by a factor of 170. When the centermost adenine is replaced by 2-aminopurine, Ka for Hoechst 33258 and DAPI is too small to be evaluated. When the centermost adenine is replaced by purine, Ka for both dyes increases, but this very stable duplex-Hoechst 33258 complex is nonfluorescent. The measured affinities are compared to expectations derived from X-ray studies with dodecamer-dye complexes having an identical central binding sequence (Pjura et al., 1987; Teng et al., 1988; Larsen et al., 1989).

Base stacking and unstacking as determined from a DNA decamer containing a fluorescent base

Time-resolved fluorescence decay of a single-stranded DNA decamer d(CTGAAT5CAG), where d5 is the fluorescent base 1-(beta-D-2'-deoxyribosyl)-5-methyl-2-pyrimidinone, was measured and analyzed at several temperatures. The d5 base in the decamer is resolved into three states according to their fluorescence decay lifetime characteristics and temperature dependence of their associated amplitudes: fully extended and completely unstacked state, loosely associated state, and fully stacked state. These states are in slow exchange compared to their fluorescence decay rates. The population of the fully extended and completely unstacked state is small and decreases further with increasing temperature. The loosely associated state, whose fluorescence can still be efficiently quenched by other DNA bases, occupies a large portion of the conventionally defined unstacked state. Stacking enthalpy and entropy for the d5 base with thymine or cytosine bases in the DNA decamer are calculated to be -6.6 kcal/mol and -22 cal/mol.K, respectively. This work shows that fluorescent bases in DNA can be useful to the study of local conformations of bases.

A demonstration of the intrinsic importance of stabilizing hydrophobic binding and non-covalent van der Waals contacts dominant in the non-covalent CC-1065/B-DNA binding

The comparative DNA binding properties and cytotoxic activity of CDPIn methyl esters (n = 1-5) vs. PDE-In methyl esters (n = 1-3) are detailed in studies which provide experimental evidence for the intrinsic importance of stabilizing hydrophobic binding and non-covalent van der Waals contacts dominant in the CC-1065/B-DNA minor groove binding. High affinity minor groove binding to DNA was established through: (1) the observation of CDPI3 binding (UV) but not unwinding of supercoiled DNA (phi 174 RFI DNA) thus excluding intercalative binding; (2) the observation of CDPI3 binding to T4 phage DNA (UV, delta Tm) in which the major groove is occluded by glycosylation thus excluding major groove binding; (3) the observation of salt (Na+) concentration independent high affinity CDPI3 binding to poly(dA . poly(dT) thus excluding simple electrostatic binding to the DNA phosphate backbone; and further inferred through (4) the observation of an intense induced dichroism (ICD, poly(dA) . poly(dT) and poly(dG) . poly(dC) [phi]23(358) = 24,000 and 23,500). This high affinity minor groove binding is sufficient to produce a potent cytotoxic effect.(ABSTRACT TRUNCATED AT 400 WORDS)

Structure and dynamics of a fluorescent DNA oligomer containing the EcoRI recognition sequence: fluorescence, molecular dynamics, and NMR studies

The self-complementary DNA decamer duplex d(CTGAATTCAG)2 and its modified counterpart d(CTGA[2AP]TTCAG)2, where the innermost adenine (6-aminopurine) has been replaced with the fluorescent analogue 2-aminopurine (2AP), have been studied by fluorescence and NMR spectroscopy and simulated by molecular dynamics. Both decamers are recognized and cleaved by the EcoRI restriction endonuclease. 2D NMR results show that both decamers have a standard B-type conformation below 20 degrees C, though a disturbance exists to the 5' side of the 2AP site which may originate from increased local mobility. The fluorescence and fluorescence anisotropy decays of both decamers, as well as the one containing 2AP in only one chain, were studied as a function of temperature. The data show that the 2AP base exists in a temperature-dependent distribution of states and shows rapid motions, suggesting interconversion among these states on a time scale of about 10(-10) s. The integrated fluorescence of the decamer with 2AP in both chains shows a large increase around the helix melting temperature whereas the decamer with one 2AP shows only a mild increase, showing that the mixed helix has a different structural transition as sensed by the 2AP base. The data suggest a model of conformational states which have distinct fluorescence decay times. The various states may differ in the degree of base stacking. Fluctuations in the degree of stacking of the A or 2AP base are supported by molecular dynamics simulations, which additionally show that the 2AP-T or A-T base pair hydrogen bonds remain intact during these large motions.

Effects of functional group changes in the EcoRV recognition site on the cleavage reaction catalyzed by the endonuclease

Oligodeoxynucleotides have been prepared which contain changes in the functional group pattern present in the EcoRV recognition site d(GATATC). These modifications involve the deletion of specific functional groups or the reversal of the relative positions of functional groups within the canonical six base pair recognition site. The duplex stability of these modified oligodeoxynucleotides has been assessed by determining the thermodynamic parameters characterizing helix formation. Steady-state kinetic parameters have been used to characterize the interaction of the modified oligodeoxynucleotides with the EcoRV endonuclease. The enzyme is very sensitive to the deletion of either of the adenine amino or thymine methyl groups, or the reversal of the relative positions of the adenine amino group and thymine carboxy group which form an interstrand hydrogen bond in the major groove of the B-DNA helix. Conversely, deletion of the guanine amino group had only minimal effects upon the measured kinetic parameters. Deletion of the exocyclic amino group from the "inner" dA-dT base pair resulted in the fragment which interacted with the enzyme on the basis of observed inhibition experiments but was not cleaved. The results suggest that the endonuclease interacts with its recognition sequence via contacts in the major groove of the B-DNA helix and that both hydrogen bonding to the adenine amino groups and also hydrophobic interactions with the thymine methyl groups are involved.

The synthesis of 2-pyrimidinone nucleosides and their incorporation into oligodeoxynucleotides

The synthesis of 1-(beta-D-2'-deoxyribosyl)-2-pyrimidinone (dK) and its 5-methyl derivative (d5) from 2'-deoxycytidine or 2'-deoxythymidine, respectively, via silver oxide oxidation of 4-hydrazinopyrimidines is described. The necessary hydrazine substituted pyrimidine nucleosides have been prepared by transamination of a protected cytidine derivative or by addition/elimination reactions to an O4-sulfonated thymidine derivative. Oxidation of the 4-hydrazino pyrimidines was complicated by a competing hydrolytic reaction which generated 2'-deoxyuridine or 2'-deoxythymidine. However, in the presence of an organic base such as triethylamine, oxidation became the predominant reaction. After suitable protection and formation of the 3'-phosphoramidite derivatives, these modified nucleosides were incorporated into seven self-complementary oligodeoxynucleotides by chemical synthesis using phosphite triester methodology. Oligodeoxynucleotides were prepared such that dA-dT and dG-dC base pairs were substituted by dA-d5 or dG-dK base pairs, respectively. Both circular dichroism spectra and thermal denaturation studies were used to characterize the modified oligodeoxynucleotides.