The effects of thioketo substitution upon uracil-adenine interactions in polyribonucleotides. Synthesis and properties of the alternating polynucleotides poly(r(A-s2U)) and poly(r(A-s2s4U)).

The polynucleotides poly[r(A-s-2U)] and poly]r(A-s2s4U)] have been synthesized and characterized by nearest-neighbour analysis, sedimentation analysis as well as spectroscopic techniques. Absorption-temperature profile and absorption-pH profile of poly[r(A-s-2U)] did not reveal a structural transition between 10 and 95 degrees C even at low ionic strength, although a variety of properties indicated a helical structure of poly[r(A-s-2U)]: remarkable hyperchromicity of the absorption spectrum, circular dichroic spectrum displaying extrema of large amplitudes, resistance against hydrolysis by ribonuclease and interaction with ethidium bromide in a manner which is characteristic of helical polynucleotides. Our results show that interactions of the type A-s-2U and A-s-2s-4U do in fact exist in helical polynucleotides. The properties of poly]r(As-2U)] furthermore demonstrate the general stabilizing effect of 2-thioketopyrimidine bases in helical polynucleotides by virtue of vertical stacking interactions with neighbouring pyrimiding and purine bases.     

Microcalorimetric investigation of dilute and concentrated solutions and films of the polydeoxynucleotide poly(d(A-T)-d(A-T))

Microcalorimetric heat capacity measurements on dilute and concentrated solutions and films of poly[d(A-T)·d(A-T)] in 2 M sodium chloride have been carried out. Values for enthalpy, entropy, and temperature of the helix–coil transition have been found to depend on the polymer concentration, and to have maxima near 20% (w/w) of polymer. The results are discussed in terms of polynucleotide hydration as one of the structure stabilizing factors.     

Conformational changes of nucleic acids and poly (d(A-T)-d(A-T)) caused by photoaddition of furocoumarins.

DNA's of various AT content, poly[d(A-T)-d(A-T)], and double-stranded RNA were irradiated with UV light at 365 nm in the presence of linear (xanthotoxin) or angular (angelicin) furocoumarins. The covalent photobinding is strongly dependent on the spatial arrangement of furocoumarin molecules at the polymer conformation. CD measurements demonstrate that the bifunctional photochemical binding of xanthotoxin with double-stranded DNA's and poly[d(A-T)-d(A-T)] is accompanied by conformational changes which involve probably decreasing helical twisting of the double helix. This effect is greatly enhanced with increasing AT content. The formation of A-like structures is very unlikely since the B leads to A transition induced by ethanol addition was found to be strongly suppressed in xanthotoxin photoreacted DNA. The B-type helix appears to be the most sensitive conformation with minor restriction to produce photochemically induced cross-links.     

Structure of the beta-form of poly d(A).poly d(U)

The crystalline beta-form of the sodium salt of poly d(A).poly d(U) trapped in oriented fibers forms a Watson-Crick base-paired, 10(1) double-helix of pitch 3.2 nm. Two molecules are present in a monoclinic unit cell apparently isomorphous with beta-poly d(A).poly d(T). The two chains in each molecule both carry C2'-endo puckered furanose rings but are conformationally not identical. The orientations of the A:U base-pairs relative to the helix-axis are distinctly different from those in classical B-DNA and the overall morphology of the duplex in which they reside resembles that of the alpha-forms of poly (purine).poly (pyrimidine) DNA duplexes previously reported.     

Structure of poly d(A).poly d(T).

On the basis of the x-ray data from polycrystalline and well oriented fibers of the sodium salt of poly d(A).poly d(T) (Arnott et al, Nucl. Acids Res. 11, 4141-4155 (1983), a revised B'-DNA model incorporating B-like adenine and thymine strands is shown to give a much better x-ray agreement (R = 0.25) than the previously assigned model consisting of mixed sugar conformations in the two strands. The narrowing of the minor and the widening of the major grooves are promiscuous features of B'-DNA, which are common to all poly d(purine).poly d(pyrimidine) duplexes with two hydrogen bonded base-pairs and are in marked contrast with classical B-DNA. Due to modest propeller (-15 degrees), the cross strand diagonal hydrogen bonds (0.37 nm) in this duplex are not as strong as those in A,T-rich oligonucleotide crystal structures.     

The synthetic DNA duplex of poly d(Abr5U).poly d(Abr5U) adopts an A-DNA-like structure

An X-ray fiber diffraction study of the synthetic DNA duplex poly d(Abr5U).poly d(Abr5U) shows that its sodium salt adopts an unexceptional A-DNA-like structure. Similar to A-DNA, two molecules are packed in a monoclinic unit cell (a = 2.23 nm, b = 4.14 nm, c = 5.61 nm and alpha = beta = gamma = 90 degrees) of space group C2. Because of its dinucleotide chemical motif, the c-repeat is twice that in A-DNA but, notably, corresponding backbone conformation angles of adjacent nucleotides are almost identical. This is in marked contrast to many B-like conformations of polydinucleotides.     

On the structure of poly d(A-S4T).

The helical twist of poly d(A-s4T) was determined from the periodicity of the cleavage patterns of the double stranded polydeoxynucleotide adsorbed on calcium phosphate and found to be 14 bp per turn. Both cleavage patterns and 31P NMR spectra indicate a mononucleotide structure rather than an alternating B DNA like poly d(A-T). The failure of nucleosome formation excludes a B type structure. The discrepancy of the mononucleotide structure found in 31P NMR spectra and the dinucleotide structure given by X ray fiber diffraction is explained by an alternating tilt of the planes of the base pairs (base roll) as a consequence of a strong propeller twist. The importance of interstrand stacking interactions of adjacent 4-thiothymidines for the helical stability is discussed.     

Circular dichroism and thermal melting differentiation of Hoechst 33258 binding to the curved (A(4)T(4)) and straight (T(4)A(4)) DNA sequences

The ability of the B-DNA minor groove ligand Hoechst 33258 to discriminate between prototype curved and straight duplex DNA sequences was investigated by circular dichroism (CD) titrations at the wavelengths of absorbance of the ligand. The sequences were studied either within the framework of the ligated decamers (CA(4)T(4)G)(n) and (CT(4)A(4)G)(n), or within that of the single dodecamers GCA(4)T(4)GC and GCT(4)A(4)GC, to confirm and extend our earlier results based on fluorescence titrations of ligated decamers. A unique, strong binding site is invariantly present in both sequence units. The binding affinity of the drug for the site in the curved A(4)T(4) sequence was found 3- to 4-fold higher compared to the straight sequence. All these features hold true irrespective of the sequence framework, thus confirming that they reflect specific properties of the binding to the two sequences. Ligand binding increases the thermal stability of straight and curved duplex dodecamers to the same extent, thus maintaining the melting temperature differential between the two sequences. However, the different melting patterns and the difference between [total ligand]:[site] ratios needed for site saturation in the two duplexes are in agreement with the difference between binding constants derived from CD measurements.     

RecA independent recombination of poly[d(GT)-d(CA)] in pBR322.

Short sequence tracts composed of alternating guanosine and thymidine nucleotide residues poly[d(GT)-d(CA)] carried in a derivative of pBR322 were recombinogenic in a recA host. Recombination brought about by poly[d(GT)-d(CA)] tracts displayed two interesting properties: (i) the reaction was quasi-sequence-specific in that while recombination usually occurred between two poly[d(GT)-d(CA)] tracts, recombination also occurred between sequences bordering the dinucleotide repeats. (ii) recombination was enhanced when two poly[d(GT)-d(CA)] tracts were clustered within 250 base pairs of each other, but not when the repeats were separated by 3 kilobase pairs. The mechanism by which poly[d(GT)-d(CA)] stimulated recombination remains to be determined, but the behavior of these sequences is consistent with the idea that general recombination in E. coli may involve formation of Z-DNA.     

Energetics of Z-DNA formation in poly d(A-T), poly d(G-C), and poly d(A-C) poly d(G-T).

The conformational change for the alternating purine-pyrimidine polydeoxyribonucleotides i.e. poly d(A-T), poly d(G-C), and poly d(A-C) poly d(G-T) from a right-handed conformation at room temperature to the left-handed Z-DNA like double helix at elevated temperatures has been studied by UV spectroscopy, Raman spectroscopy, and by adiabatic differential scanning microcalorimetry (DSC) in the presence of Na+ and Mg2+ or Ni2+ respectively as counterions. The differential UV spectra reveal through a hyperchromic shift at around 280nm and a hypochromic shift at 260nm that a conformational change to the left-handed conformation occurs. The Raman spectra clearly show characteristic changes, a drastic decrease of the band at 680cm-1 and the appearance of a new band at 628cm-1, due to the change of the purine bases to the syn conformation upon inversion of the helix-handedness. The course of the transition as function of temperature can be followed quantitatively by plotting the change in the excess heat capacity vs. temperature. The transition enthalpy delta H for the B- to Z-DNA transition per mole base pairs (mbp) amounts to 2.0 +/- 0.2kcal for poly d(G-C), to 4.0 +/- 0.4kcal for poly d(A-T), and to 3.1 +/- 0.3kcal for poly d(A-C) poly d(G-T). The enthalpy change due to the Z-DNA to coil transitions (per mole base pairs) amounts to 11kcal for poly d(G-C), 10.5kcal for poly d(A-T) and 11.3kcal for poly d(A-C) poly d(G-T).     

Structure of Poly (U).poly (A).poly (U)

The molecular structure of poly (U).poly (A).poly (U) has been determined and refined using the continuous x-ray intensity data on layer lines in the diffraction pattern obtained from an oriented fiber of the RNA. The final R-value for the preferred structure is 0.24, far lower than that for the plausible alternatives. The polymer forms an 11-fold right-handed triple-helix of pitch 33.5A and each base triplet is stabilized by Crick-Watson-Hoogsteen hydrogen bonds. The ribose rings in the three strands have C3'-endo, C2'-endo and C2'-endo conformations, respectively. The helix derives additional stability through systematic interchain hydrogen bonds involving ribose hydroxyls and uracil bases. The relatively grooveless cylindrical shape of the triple-helix is consistent with the lack of lateral organization.     

Enhanced stabilization of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21) and poly r(U:AU) by water structure-making solutes

A variety of organic cations, cationic lipids, low molecular weight alcohols, sodium dodecylsulfate, trehalose, glycerol, low molecular weight polyethylene glycols, and DMSO were tested for their ability to modulate the stability of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21), poly r(U:A U) and their respective core duplexes, d(A-G)(6);d(C-T)(6), d(A)(21);d(T)(21), poly r(A-U). Very substantial enhancement of triplex stability over that in a physiological salt buffer at pH 7 is obtained with different combinations of triplex and high concentrations of these additives, e.g. trimethylammonium chloride and d(C(+)-T)(6):d(A-G)(6);d(C-T)(6); 2-propanol and d(T)(21):d(A)(21);d(T)(21); ethanol and poly r(U:A;U). Triplex formation is even observed with a 1:1 strand mixture of d(A-G)(6) and d(C-T)(6) in the presence of dimethylammonium, tetramethylammonium, and tetraethylammonium-chloride, as well as methanol, ethanol, and 2-propanol. Triplex stability follows the water structure-making ability (and in some cases the duplex unwinding ability) of the organic cations, the low molecular weight alcohols and other neutral organic compounds, whereas water structure-breaking additives decrease triplex stability. These findings are consistent with those reported in the accompanying paper that triplex formation occurs with a net uptake of water. Since the findings suggest that third strand-binding is facilitated by unwinding of the target duplex, it is inferred that triplex formation may be enhanced by nucleic acid binding proteins operating similarly.     

Circular dichroism studies of the interaction of a limited hydrolysate of T4 gene 32 protein with T4 DNA and poly[d(A-T)].poly[d(A-T)].

gp32 I is a protein with a molecular weight of 27 000. It is obtained by limited hydrolysis of T4 gene 32 coded protein, which is one of the DNA melting proteins. gp32 I itself appears to be also a melting protein. It denatures poly[d(A-T)].poly[d(A-T)] and T4 DNA at temperatures far (50-60 degrees C) below their regular melting temperatures. Under similar conditions gp32 I will denature poly[d(A-T).poly[d(A-T)] at temperatures approximately 12 degrees C lower than those measured for the intact gp32 denaturation. For T4 DNA gp32 shows no melting behavior while gp32 I shows considerable denaturation (i.e., hyperchromicity) even at 1 degree C. In this paper the denaturation of poly[d(A-T)].poly[d(A-T)] and T4 DNA by gp32 I is studied by means of circular dichroism. It appears that gp32 I forms a complex with poly[d(A-T)]. The conformation of the polynucleotide in the complex is equal to that of one strand of the double-stranded polymer in 6 M LiCl. In the gp32 I DNA complex formed upon denaturation of T4 DNA, the single-stranded DNA molecule has the same conformation as one strand of the double-strand T4 DNA molecule in the C-DNA conformation.     

A novel Z-structure for poly d(GC).poly d(GC)

A novel zig-zag (Z) structure is proposed for poly d(GC).poly d(GC). The proposed model closely resembles the crystal structure of d(CG)₃.