Danielle Thiele scite author profile

The subject of four-stranded nucleic acid structures is reviewed. Studies on gels formed by guanosine and its analogues have provided appropriate models for the structures of poly(I) and poly(G). The stabilizing influence of certain cations, in particular K+, on Guo-5'-P gels and poly(I) is discussed in the light of recent data on selective K+ stabilization of telomeric DNA structures. The topological possibilities these dG containing sequences could adopt are discussed. In particular the role of the glycosidic linkage (anti/syn), the polarity of the strands and the orientation of the G-tetrad stacks is highlighted.

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Poly(dG).poly(dC) at neutral and alkaline pH: the formation of triple stranded poly(dG).poly(dG). poly(dC)

Marck¹,

Thiele²

1978

Nucl Acids Res

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Alkaline titrations of different samples of poly(dG).poly(dC) and of the constituent homopolymers poly(dG) and poly(dC) have been performed in 0.15 M NaCl and their CD spectra followed. Sample I contained a slight excess of poly(dC) (52% C: 48% G) and showed a single reversible transition (pK = 11.9) due to the dissociation of double stranded poly(dG).poly(dC). Sample II, containing an excess of poly(dG) (43% C: 57% G), showed two transitions (pK1 = 11.4, PK2 = 11.9) the first one being only partially reversible. Examination of the CD spectra along the alkaline titrations indicated the presence of another hydrogen-bonded complex of higher G content. Mixing curves performed at pH 8 have confirmed the presence of a 2G: 1C complex, besides the double stranded complex. It can be formed in amounts up to 30% by mixing the two homopolymers, alkali treatment and heating. The CD spectra of the two complexes have been computed from the CD data of the mixing curves. This permitted the determination of the concentrations of both complexes and homopolymers in all samples. The ratio of triple to double stranded complex is not only dependent on the G/C ratio of the sample, but also a function of the previous physico-chemical conditions. These results explain the variability of many properties of different poly(dG).poly(dC) samples observed by other workers.

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The structures of polyinosinic acid

Thiele¹,

Guschlbauer²

1973

Biophysik

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Protonated polynucleotide structures. IX. Disproportionation of poly (G)·poly (C) in acid medium

Thiele¹,

Guschlbauer²

1971

Biopolymers

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The interaction between poly (G) and poly (C) was investigated in neutral and acid medium by optical methods. Three main points arise from this investigation. (1) The formation of poly (G)·poly (C) was complete only above an ionic strength of about 0.6M [Na+]. Lowering the ionic strength increased the amounts of free poly (G) and free poly (C) that could be detected. (2) When titrating towards acid pH values a transition took place which was characterized by potentiometry, mixing curves, and circular dichroism: a three‐stranded poly (G)·poly (C)·poly (C+) complex was formed analogous to the transition observed for the acid titration of poly (I)·poly (C). (3) Even when the poly (G)·poly (C) complex was incompletely formed (at low ionic strength) in neutral medium all poly (C) entered the triple‐stranded complex.

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Protonated polynucleotides structures - 22.CD study of the acid-base titration of poly(dG).poly(dC)

Marck

Thiele²,

Schneider

et al. 1978

Nucl Acids Res

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The acid-base titration (pH 8 --> pH 2.5 --> pH 8) of eleven mixing curve samples of the poly(dG) plus poly(dC) system has been performed in 0.15 M NaCl. Upon protonation, poly(dG).poly(dC) gives rise to an acid complex, in various amounts according to the origin of the sample. We have established that the hysteresis of the acid-base titration is due to the non-reversible formation of an acid complex, and the liberation of the homopolymers at the end of the acid titration and during the base titration: the homopolymer mixtures remain stable up to pH 7. A 1G:1C stoichiometry appears to be the most probable for the acid complex, a 1G:2C stoichiometry, as found in poly(C(+)).poly(I).poly(C) or poly(C(+)).poly(G).poly(C), cannot be rejected. In the course of this study, evidence has been found that the structural consequences of protonation could be similar for both double stranded poly(dG).poly(dC) and G-C rich DNA's: 1) protonation starts near pH 6, dissociation of the acid complex of poly(dG).poly(dC) and of protonated DNA take place at pH 3; 2) the CD spectrum computed for the acid polymer complex displays a positive peak at 255 nm as found in the acid spectra of DNA's; 3) double stranded poly(dG).poly(dC) embedded in triple-stranded poly(dG).poly(dG).poly(dC) should be in the A-form and appears to be prevented from the proton induced conformational change. The neutral triple stranded poly(dG).poly(dG).poly(dC) appears therefore responsible, although indirectly, for the complexity and variability of the acid titration of poly(dG).poly(dC) samples.

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Danielle Thiele

Four-Stranded Nucleic Acid Structures 25 Years Later: From Guanosine Gels to Telomer DNA

Poly(dG).poly(dC) at neutral and alkaline pH: the formation of triple stranded poly(dG).poly(dG). poly(dC)

The structures of polyinosinic acid

Protonated polynucleotide structures. IX. Disproportionation of poly (G)·poly (C) in acid medium

Protonated polynucleotides structures - 22.CD study of the acid-base titration of poly(dG).poly(dC)

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