Third strand-mediated psoralen-induced correction of the sickle cell mutation on a plasmid transfected into COS-7 cells.

A significant level of correction of the mutation responsible for sickle cell anemia has been achieved in monkey COS-7 cells on a plasmid containing a beta-globin gene fragment. The plasmid was treated in vitro with a nucleic acid 'third strand' bearing a terminal photoreactive psoralen moiety that binds immediately adjacent to the mutant base pair. Following covalent attachment of the psoralen by monoadduct or diadduct formation to the mutant T-residue on the coding strand, the treated plasmid was transfected into the cells, which were then incubated for 48 h to allow the cellular DNA repair mechanisms to remove the photoadducts. Upon re-isolation and amplification of the transfected plasmid, sickle cell mutation correction, as determined by sequence analysis of both complementary strands, was established in a full 1%. This result encourages extension of the approach to correct the mutation directly on the chromosome.

A novel method for estimating ancestral amino acid composition and its application to proteins of the Last Universal Ancestor.

MOTIVATION: Knowledge of how proteomic amino acid composition has changed over time is important for constructing realistic models of protein evolution and increasing our understanding of molecular evolutionary history. The proteomic amino acid composition of the Last Universal Ancestor (LUA) of life is of particular interest, since that might provide insight into the early evolution of proteins and the nature of the LUA itself. RESULTS: We introduce a method to estimate ancestral amino acid composition that is based on expectation-maximization. On simulated data, the approach was found to be very effective in estimating ancestral amino acid composition, with accuracy improving as the number of residues in the dataset was increased. The method was then used to infer the amino acid composition of a set of proteins in the LUA. In general, as compared with the modern protein set, LUA proteins were found to be richer in amino acids that are believed to have been most abundant in the prebiotic environment and poorer in those believed to have been unavailable or scarce. Additionally, we found the inferred amino acid composition of this protein set in the LUA to be more similar to the observed composition of the same set in extant thermophilic species than in extant mesophilic species, supporting the idea that the LUA lived in a thermophilic environment. AVAILABILITY: The program is available at http://compbio.cs.princeton.edu/ancestralaa

Functional pleiotropy of an intramolecular triplex-forming fragment from the 3'-UTR of the rat Pigr gene.

A microsatellite-containing 359-bp restriction fragment, isolated from the rat Pigr gene (murine polymeric immunoglobulin receptor gene) 3'-untranslated region (3'-UTR) and inserted into 3'-UTR or 3' flanking positions in transcription units of supercoiled plasmids, attenuates luciferase reporter gene expression in orientation- and position-dependent ways following transient transfection of human 293 cells. The same fragment stimulates orientation-dependent gene expression in a 5' flanking position. Plasmid linearization abrogates both orientation- and position-dependent responses. Cell-free translation reveals that 5' and 3' flanking expression responses are proportional to increased and decreased luciferase mRNA levels, whereas 3'-UTR expression is associated with control mRNA levels. Hypersensitivity to nucleases S1 and P1, gel mobility differences between supercoiled plasmids carrying opposing microsatellite orientations, and anomalous melting profiles of this fragment are also observed. These results suggest that functional pleiotropy of this fragment depends on the DNA context of its purine-rich microsatellite strand and on DNA supercoiling. Intramolecular triplexes stabilized by supercoiling and secondary structures of purine repeat-rich mRNAs may also confer regulatory properties to similar genomic elements.

A search for base analogs to enhance third-strand binding to 'inverted' target base pairs of triplexes in the pyrimidine/parallel motif.

Eight base analogs were tested as third strand residues in otherwise homopyrimidine strands opposite each of the 'direct' (A.T and G.C) and 'inverted' (T.A and C.G) Watson-Crick base pairs, using UV melting profiles to assess triplex stability. The target duplexes contained 20 A.T base pairs and a central test base pair X.Y, while the third strand contained 20 T residues and a central Z test base. Z included 5-bromo-uracil, 5-propynyluracil, 5-propynylcytosine, 5-methyl-cytosine, 5-bromocytosine, hypoxanthine, 2-amino-purine and 2,6-diaminopurine. Some of the base analogs enhanced third strand binding to the target duplex with one or other 'inverted' central base pair relative to the binding afforded by any of the canonical bases. Other analogs did the same for the duplexes with the 'direct' target pairs. The increasing order of triplex stabilization by these base analogs is: opposite the 'inverted' base pairs, for T.A, A < C < 5-pC < 5-pU < T < 5-BrC < 5-meC < 5-BrU < 2-AP < 2,6-DAP < Hy < G, for C.G, 2-AP < A < Hy < G < 5-pC < 5-BrC < 5-meC < C < 2,6-DAP < T < 5-BrU < 5-pU; opposite the 'direct' base pairs, for A.T, 2-AP < A < 5-meC < C < G < Hy < 2,6-DAP < 5-pU < T = 5-BrU < 5-BrC < 5-pC, for G.C, G < 2,6-DAP < 2-AP < A < Hy < T < 5-BrU < 5-pU < 5-pC < 5-BrC < C < 5-meC.

Third-strand in situ hybridization (TISH) to non-denatured metaphase spreads and interphase nuclei.

A methodology has been developed for binding oligodeoxyribonucleotide 'third strands' to duplex DNA targets in fixed but not additionally denatured metaphase spreads and interphase nuclei under conditions found to be optimal in solution. Third-strand in situ hybridization (TISH) at pH 6.0 of a psoralen- and biotin-modified 16-nucleotide homopyrimidine third strand to a unique multicopy target sequence in human chromosome 17 alpha-satellite (D17Z1 locus) is described. UVA-photofixed third strands, rendered fluorescent by fluorescein isothiocyanate-labeled avidin, are reproducibly centromere-specific for chromosome 17, and visible without amplification of the signal in lymphocyte and somatic cell hybrid spreads and interphase nuclei. Two third-strand-specific D17Z1 haplotypes were identified. TISH has potential diagnostic, biochemical, and flow cytometric applicability to native metaphase and interphase chromatin.

Repairing the sickle cell mutation. I. Specific covalent binding of a photoreactive third strand to the mutated base pair.

A DNA third strand with a 3'-psoralen substituent was designed to form a triplex with the sequence downstream of the T.A mutant base pair of the human sickle cell beta-globin gene. Triplex-mediated psoralen modification of the mutant T residue was sought as an approach to gene repair. The 24-nucleotide purine-rich target sequence switches from one strand to the other and has four pyrimidine interruptions. Therefore, a third strand sequence favorable to two triplex motifs was used, one parallel and the other antiparallel to it. To cope with the pyrimidine interruptions, which weaken third strand binding, 5-methylcytosine and 5-propynyluracil were used in the third strand. Further, a six residue "hook" complementary to an overhang of a linear duplex target was added to the 5'-end of the third strand via a T(4) linker. In binding to the overhang by Watson-Crick pairing, the hook facilitates triplex formation. This third strand also binds specifically to the target within a supercoiled plasmid. The psoralen moiety at the 3'-end of the third strand forms photoadducts to the targeted T with high efficiency. Such monoadducts are known to preferentially trigger reversion of the mutation by DNA repair enzymes.

Identification by UV resonance Raman spectroscopy of an imino tautomer of 5-hydroxy-2'-deoxycytidine, a powerful base analog transition mutagen with a much higher unfavored tautomer frequency than that of the natural residue 2'-deoxycytidine.

UV resonance Raman spectroscopy was used to detect and estimate the frequency of the unfavored imino tautomer of the transition mutagen 5-hydroxy-2'-deoxycytidine (HO5dCyt) in its anionic form. In DNA, this 2'-deoxycytidine analog arises from the oxidation of 2'-deoxycytidine and induces C --> T transitions with 10(2) greater frequency than such spontaneous transitions. An imino tautomer marker carbonyl band (approximately 1650 cm-1) is enhanced at approximately 65 degrees C against an otherwise stable spectrum of bands associated with the favored amino tautomer. This band is similarly present in the UV resonance Raman spectra of the imino cytidine analogs N3-methylcytidine at high pH and N4-methoxy-2'-deoxycytidine at pH 7 and displays features attributable to the imino form of C residues and their derivatives. The fact that the imino tautomer of HO5dCyt occurs at a frequency consistent with its high mutagenic enhancement lends strong support to the hypothesis that unfavored base tautomers play important roles in the mispair intermediates of replication leading to substitution mutations.

Effect of the 1-(2'-deoxy-beta-D-ribofuranosyl)-3-nitropyrrole residue on the stability of DNA duplexes and triplexes.

3-Nitropyrrole (M) was introduced as a non-discriminating 'universal' base in nucleic acid duplexes by virtue of small size and a presumed tendency to stack but not hydrogen bond with canonical bases. However, the absence of thermally-induced hyperchromic changes by single-stranded deoxyoligomers in which M alternates with A or C residues shows that M does not stack strongly with A or C nearest neighbors. Yet, the insertion of a centrally located M opposite any canonical base in a duplex is sometimes even less destabilizing than that of some mismatches, and the variation in duplex stability is small. In triplexes, on the other hand, an M residue centrally located in the third strand reduces triplex stability drastically even when the X.Y target base pair is A.T or G. C in a homopurine. homopyrimidine segment. But, when the target duplex opposition is M-T and the third strand residue is T, the presence of M in the test triplet has little effect on triplex stability. Therefore, a lack of hydrogen bonding in an otherwise helix-compatible test triplet cannot be responsible for triplex destabilization when M is the third strand residue. Thus, M is non-discriminating and none-too-destabilizing in a duplex, but in a triplex it is extremely destabilizing when in the third strand.

Parallel-stranded linear homoduplexes of d(A+-G)n > 10 and d(A-G)n > 10 manifesting the contrasting ionic strength sensitivities of poly(A+.A+) and DNA.

In contrast to shorter homologs which only form a single-stranded nucleic acid alpha-helix in acid solution at [Na+]/=0.2 M) the protonated base-backbone interactions are so weakened that duplex stability becomes increasingly dependent upon H-bonded base pairing and stacking and almost independent of pH. Between pH 6 and 8 this duplex structure is devoid of protonated dA residues and shows positive dependence of T m on ionic strength similar to that of DNA.

Duplex-tetraplex equilibrium between a hairpin and two interacting hairpins of d(A-G)10 at neutral pH.

d(A-G)10 forms two helical structures at neutrality, at low ionic strength a single-hairpin duplex, and at higher ionic strength a double-hairpin tetraplex. An ionic strength-dependent equilibrium between these forms is indicated by native PAGE, which also reveals additional single-stranded species below 0.3 M Na+, probably corresponding to partially denatured states. The equilibrium also depends upon oligomer concentration: at very low concentrations, d(A-G)10 migrates faster than the random coil d(C-T)10, probably because it is a more compact single hairpin; at high concentrations, it co-migrates with the linear duplex d(A-G)10 x d(C-T)10, probably because it is a two-hairpin tetraplex. Molecular weights measured by equilibrium sedimentation in 0.1 M Na+, pH 7, reveal a mixture of monomer and dimer species at 1 degree C, but only a monomer at 40 degrees C; in 0.6 M Na+, pH 7, only a dimer species is observed at 4 degrees C. That the single- and double-stranded species are hairpin helices, is indicated by preferential S1 nuclease cleavage at the center of the oligomer(s), i.e., the loop of the hairpin(s). The UV melting transition below 0.3 M Na+ or K+, exhibits a dTm/dlog[Na+/K+] of 33 or 36 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex to a single-hairpin duplex with extrahelical residues. When [Na+/K+] > or = 0.3 M, dTm/dlog [Na+/K+] is 19 or 17 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex directly to single strands. A two-hairpin structure stabilized by G-tetrads is indicated by differential scanning calorimetry in 0.15 M Na+/5 mM Mg2+, with deltaH of formation per mole of the two-hairpin tetraplex of -116.9 kcal or -29.2 kcal/mol of G-tetrad.

A UV resonance Raman study of hairpin dimer helices of d(A-G)10 at neutral pH containing intercalated dA residues and alternating dG tetrads.

The structure of the oligonucleotide d(A-G)10 in 0.6 M Na+, pH 7.0 has been investigated with UV resonance Raman (UVRR) spectroscopy. Variable wavelength excitation was used to distinguish the spectral contributions of dG and dA residues. Both classes of residues show UVRR hyperchromism with increasing temperature, reflecting unstacking of the bases. The dG residues melt relatively cooperatively with a Tm of approximately 42 degrees C. Unstacking is non-cooperative for the dA residues, increasing linearly between 4 and 80 degrees C. G-tetrads at low temperature are indicated by UVRR frequency shifts of modes associated with C6=O and C2-NH2 of the dG residues, and of vibrations involving N7, all sites of H-bonding. However, there are no indications of interbase H-bonds for the dA residues, showing they do not form H-bonded tetrads. Most of the bases are oriented anti about the glycosyl bond, but at 4 degrees C a fraction of the residues are syn. These results, together with the findings by Shiber et al. [Shiber,M.C., Braswell,E.H., Klump,H. and Fresco,J.R. (1996) Nucleic Acids Res. 24, 5004-5012] that d(A-G)10 under comparable conditions has the molecular weight of a dimer, support a model in which two hairpins interact to form a helical structure with G-tetrads and intercalated dA residues.

Alpha-DNA, a single-stranded secondary structure stabilized by ionic and hydrogen bonds: d(A(+)-G)n.

A novel nucleic acid secondary structure, exemplified by d(A(+)-G)10, is formed by an intramolecular, cooperative, acid-induced, coil-->helix transition. The helix is apparently left-handed, lacks base stacking and pairing, and is maintained by hydrogen and ionic bonds between dA+ "side-chain" residues (with electropositive hydrogens -N6H2, -N1+H) and the phosphodiester backbone. Modeling indicates that those dA+ residues lie approximately parallel to the helix axis, interacting with the n-1 backbone phosphates (with electronegative oxygens), somewhat like the -C=O...H-N- longitudinal interactions in a protein alpha-helix. Moreover, the intervening dG side-chain residues are extrahelical, as are amino acid side chains of an alpha-helix.

A UV resonance Raman study of d(A(+)-G)10, a single-stranded helix without stacked or paired bases.

UV resonance Raman spectroscopy has been utilized to directly observe structural features of the recently described nucleic acid single-stranded helix d(A(+)-G)10. An absence of base stacking is confirmed by invariant hypochromic ratios of dominant vibrational modes for the oligomer relative to its constituent monomers as the structure is thermally denatured. The N1 of dA residues is protonated, as determined by similarity to the ring-stretching vibrations for protonated adenine and its derivatives. Selective resonance enhancement of Raman vibrational modes from dA and dG residues shows frequency shifts upon thermal denaturation that confirm the participation of the exocyclic amino of dA but not dG residues in H-bonding. Conformationally sensitive glycosyl bond modes suggest anti residue conformations.

UV spectroscopic identification and thermodynamic analysis of protonated third strand deoxycytidine residues at neutrality in the triplex d(C(+)-T)6:[d(A-G)6.d(C-T)6]; evidence for a proton switch.

Near-UV difference spectral analysis of the triplex formed from d(C-T)6 and d(A-G)6.d(C-T)6 in neutral and acidic solution shows that the third strand dC residues are protonated at pH 7.0, far above their intrinsic pKa. Additional support for ion-dipole interactions between the third strand dC residues and the G.C target base pairs comes from reduced positive dependence of triplet stability on ionic strength below 0.9 M Na+, inverse dependence above 0.9 M Na+ and strong positive dependence on hydrogen ion concentration. Molecular modeling (AMBER) of C:G.C and C+:G.C base triplets with the third strand base bound in the Hoogsteen geometry shows that only the C+:G.C triplet is energetically feasible. van't Hoff analysis of the melting of the triplex and target duplex shows that between pH 5.0 and 8.5 in 0.15 M NaCl/0.005 M MgCl2 the enthalpy of melting (delta H degree obs) varies from 5.7 to 6.6 kcal.mol-1 for the duplex in a duplex mixture and from 7.3 to 9.7 kcal.mol-1 for third strand dissociation in the triplex mixture. We have extended the condensation-screening theory of Manning to pH-dependent third strand binding. In this development we explicitly include the H+ contribution to the electrostatic free energy and obtain [formula: see text]. The number of protons released in the dissociation of the third strand from the target duplex at pH 7.0, delta n2, is thereby calculated to be 5.5, in good agreement with approximately six third strand dc residues per mole of triplex. This work shows that when third strand binding requires protonated residues that would otherwise be neutral, triplex formation and dissociation are mediated by proton uptake and release, i.e., a proton switch. As a by-product of this study, we have found that at low pH the Watson-Crick duplex d(A-G)6.d(C-T)6 undergoes a transition to a parallel Hoogsteen duplex d(A-G)6.d(C(+)-T)6.

Relative specificities in binding of Watson-Crick base pairs by third strand residues in a DNA pyrimidine triplex motif.

The specificity of binding of Watson-Crick base pairs by third strand nucleic acid residues via triple helix formation was investigated in a DNA pyrimidine triplex motif by thermal melting experiments. The host duplex was of the type A10-X-A10: T10-Y-T10, and the third strand T10-Z-T10, giving rise to 16 possible triplexes with Z:XY inserts, 4 duplexes with the Watson-Crick base pairs (XY) and 12 duplexes with mismatch pairs (XZ), all of whose stabilities were compared. Two Z:XY combinations confirm the primary binding of AT and GC target pairs in homopurine.homopyrimidine sequences by T and C residues, respectively. All other Z:XY combinations in the T:AT environment result in triplex destabilization. While some related observations have been reported, the present experiments differ importantly in that they were performed in a T:AT nearest neighbor environment and at physiological ionic strength and pH, all of which were previously untested. The conclusions now drawn also differ substantially from those in previous studies. Thus, by evaluating the depression in Tm due to base triplet mismatches strictly in terms of third strand residue affinity and specificity for the target base pair, it is shown that none of the triplet combinations that destabilize qualify for inclusion in the third strand binding code for the pyrimidine triplex motif. Hence, none of the mismatch triplets afford a general way of circumventing the requirement for homopurine.homopyrimidine targets when third strands are predominated by pyrimidines, as others have suggested. At the same time, the applicability of third strand binding is emphasized by the finding that triplexes are equally or much more sensitive to base triplet mismatches than are Watson-Crick duplexes to base pair mismatches.

Molecular and thermodynamic properties of d(A(+)-G)10, a single-stranded nucleic acid helix without paired or stacked bases.

Previously (Dolinnaya & Fresco, 1992), on the basis of an analysis of UV absorption and CD properties as a function of temperature and pH, the secondary structure of the deoxyoligonucleotide d(A(+)-G)10 was hypothesized to be helical and intramolecular in origin, being stabilized not by stacked bases or hydrogen-bonded base pairs but instead by ionic bonds between positively charged adenine residues and distal negatively charged phosphates. Several other properties are now shown to be consistent with this unusual type of structure. The molecular weight determined for d(A(+)-G)10 by sedimentation equilibrium is that of the single strand, and consistent with this, there is no molecular weight change on helix disruption. Formation of the d(A(+)-G)10 helix is accompanied by cooperative uptake of nine protons, corresponding to nine adenine residues that can form ionic bonds with all the available distal phosphates, i.e., the n+1 or the n+2 phosphates. The thermodynamic parameters of this helical structure obtained from both van't Hoff analysis of the melting of the structure and calorimetric measurements are in keeping with the ionic properties of the proposed structure. So are the dependence of its stability on pH and ionic strength, and also on oligomer length when compared with the behavior of d(A(+)-G)6. The possible role of this type of secondary structure in protein recognition of the single-stranded homopurine element of H-DNA is evaluated.

Single-stranded nucleic acid helical secondary structure stabilized by ionic bonds: d(A(+)-G)10.

We have identified a type of secondary structure for the homopurine oligomer d(A-G)10 below pH 6 in 0.01 M Na+ that is characterized by intense CD but only minor hypochromicity. The stability of this helix, designated d(A(+)-G)10, does not depend on oligomer concentration and increases sharply as ionic strength or pH drops, reaching a maximum at 4.0 (melting temperature, 37 degrees C). The pKa for the transition, 5.3 at 25 degrees C and even higher with decreasing temperature and [Na+], is much higher than the intrinsic pKa values for dA or dG residues. While the dA residues are protonated in the helix, further protonation of the dG residues disrupts it. When observed at 280 nm, melting of the helix first results in hypochromicity due to stacking of extrahelical dG residues with neighboring dA residues. The character and temperature dependence of the CD spectra of the constituent dinucleoside monophosphates indicate minimal chirality and base overlap for the A+pG sequences in d(A(+)-G)10 but left-handed twist with some base overlap for the GpA+ sequences. The observed properties are best satisfied by a model for an intramolecular helix with limited base overlap, stabilized by ionic bonds between dA residues protonated at N-1 and downstream negatively charged phosphates brought close due to the backbone helical twist, while Gsyn residues lie external to the helix. This structure could provide additional stabilizing energy for biologically relevant protonated non-B-DNA structures adopted by homopurine.homopyrimidine sequences due to topological stress or specific protein binding.

Specificity in formation of triple-stranded nucleic acid helical complexes: studies with agarose-linked polyribonucleotide affinity columns.

The binding of a variety of deoxyribo and ribo homo- and copolynucleotide complementary duplexes to agarose-linked homopolynucleotide affinity columns has been studied. The results provide information concerning the specificity of recognition of complementary base pairs of nucleic acids through a mechanism that involves triple-helix formation under physiological conditions of ionic strength, pH, and temperature. The method employed made it possible, for the first time, to survey the full range of base triplets conceivable from the canonical nucleic acid bases and, in addition, hypoxanthine and thereby to differentiate between those triplets which can and cannot form. Certain previously observed features of the stereochemistry of double-helical targets for third-strand binding are confirmed, and some unrecognized features are elaborated. These include a general requirement for clusters of purine residues in one strand, protonation of third-strand C residues, the ability of natural third-strand residues to distinguish between A.T/U and G.C base pairs, and a capacity of third-strand (unnatural) I residues to recognize all base pairs within such clusters. Thus, the basis for a third-strand binding code is demonstrated.

Formation of the triple-stranded polynucleotide helix, poly(A.A.U).

A polynucleotide helical structure containing two strands of poly(A) and one of poly(U) is reported. As shown by spectroscopic observations, the complex only forms when the poly(A) strands are of Mr between 9000 and 50,000 (degree of polymerization congruent to 28-150), whereas the size of the poly(U) strand has no effect. This limitation may explain why poly(A.A.U) was not seen in previous investigations. The potential of the poly(A) tails of mRNA for formation of this triple helix and of A.A.U or/and A.A.T triplet formation to contribute to the binding of specific RNA strands to gene-encoding nucleic acid double helices are noted.

Ultraviolet-induced 8,8-adenine dehydrodimers in oligo- and polynucleotides.

Characteristic fluorescence excitation and emission is induced by either acetone-sensitized 313 nm irradiation of mixtures of 8-bromoadenosine and adenosine or 254 nm irradiation of oligo- and polynucleotides containing adenine neighbors. The acetone-sensitized reaction involves cleavage of bromine from 8-bromoadenosine with activation of C-8, leading to formation of an 8,8-adenosine dehydrodimer. Comparable fluorescence properties arise in the unsensitized photoreaction of dApdA, pdApdA, ApA, poly(dA), poly(A), poly(dA.dT), and poly(dA.U). The previously unidentified adenine ultraviolet photoproduct described by Porschke has been isolated as several variants from solutions of pdApdA and poly(dA) irradiated at 254 nm. Based upon fluorescence spectra and mass spectra, these variants are shown to contain the 8,8-adenine dehydrodimer moiety.