Double-resonance experiments at 500 MHz on gene-5 protein and its complex with octadeoxyriboadenylic acid

Alma, N. C. M.; Harmsen, B.J.M.; Hull, William E.; Marel, Gijs van der; Boom, J. H. van; Hilbers, C.W.

doi:10.1021/bi00518a029

Cited by 54 publications

(68 citation statements)

References 21 publications

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“…Exact temperatures were determined from the chemical shift value of the water peak relative to Me4NC1 as described earlier [l I] '. One-dimensional selective-saturation transfer experiments were carried out at 300 MHz: a l-s selective saturation pulse was employed in the one-dimensional NOEdifference pulse sequence proposed by Alma et al [12].…”

Section: Methodsmentioning

confidence: 99%

Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

Rinkel¹,

Marel²,

Boom³

et al. 1987

European Journal of Biochemistry

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The solution conformations of the oligonucleotides d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) and d(C‐C‐G‐A‐m6A‐T‐T‐C‐G‐G) as a function of temperature and sample concentration were investigated by means of 1H‐NMR spectroscopy. The NMR spectra revealed that, at certain combinations of temperature and low sample and salt concentration, both compounds exist as a B‐DNA‐type duplex slowly (on the 1H‐NMR time scale) interconverting with a monomeric species. From chemical shift data and imino‐proton spectra, it is concluded that the monomeric species consists of a mixture of a hairpin form in rapid equilibrium with the random‐coil form. The double‐helical stem of the hairpin is formed by the six terminal cytidine and guanine residues, whereas the four core residues, ‐A‐(m6)A‐T‐T‐, partake in the loop. Thermodynamic analysis of the chemical shift of the resonances of the monomeric species vs temperature profiles of the two decamers and mutual comparison of these profiles indicate the following: (a) the influence of N6‐methylation of residue A(5) upon the local structure of the hairpin must be small; (b) methylation decreases the stability of the duplex relative to the monomeric species: the temperature at which the fraction duplex equals 0.5 was found to be 312 K for the parent compound and 305 K for the methylated decamer at 2 mM sample concentration; (c) methylation does not significantly alter the stability of the hairpin form relative to the random coil form: the Tm of the hairpin ⇌ random‐coil equilibrium is 308 K for the parent compound and 306 K for the methylated decamer. A higher fraction hairpin‐like structure for the N6‐methylated compound is observed under identical conditions of temperature and sample concentration: at 300 K, 2 mM sample concentration, the fraction hairpin form is 0.12 for d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) and 0.20 for d(C‐C‐G‐A‐m6A‐T‐T‐C‐G‐G). This finding appears to be a consequence of the reduced stability of the methylated dimeric species relative to the monomeric species, and to depend upon the sodium‐ion concentration: it becomes more pronounced under low‐salt conditions.

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Section: Methodsmentioning

confidence: 99%

Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

Rinkel¹,

Marel²,

Boom³

et al. 1987

European Journal of Biochemistry

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“…The isolation and purification of the gene-5 protein were essentially as in [12] in the aromatic part of the spectrum (8.1-6.4 ppm downfield from DSS) to the protons of the single histidyl the 5 tyrosyl and the 3 phenylalanyl residues in the protein [ 10]. The resonances of 2 tyrosyl and 1 phenylalanyl residues also undergo large shifts upon binding of oligonucleotides to the protein [10,11 ] and ~>2 of these residues are located close to the DNA, in the protein-DNA complex.…”

Section: Methodsmentioning

confidence: 99%

“…There is a wealth of spectroscopic evidence that aromatic residues are involved in the interaction with DNA [4,8,9]. The molecular surroundings of 2 tyrosines and 1 phenylalanine are influenced by binding of DNA [10,11]. This phenylalanine and i>1 of these tyrosines are located in close proximity to the DNA [10].…”

Section: Introductionmentioning

confidence: 99%

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500 MHz ¹H NMR study of the role of lysines and arginines in the binding of gene‐5 protein to oligoadenylic acids

et al. 1981

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“…The timedomain signals were apodized with Gaussian windows, zerofilled to 32 K and Fourier transformed. 500-MHz NOE difference spectra were recorded at 0°C following Alma et al [15]. A selective preirradiation pulse of 0.5 s was used.…”

Section: Nmr Measurementsmentioning

confidence: 99%

Conformational analysis of the dinucleotides 5′‐methylphospho‐N⁶‐dimethyladenylyl‐uridine (mpm⁶₂A‐U) and 5′methylphospho‐uridylyl‐N⁶‐dimethyladenosine (mpU‐m⁶₂A) and of the trinucleotide U‐m⁶₂A‐U

Hoogen

Lankhorst

Gijsman

et al. 1988

European Journal of Biochemistry

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NMR and CD studies were carried out on the dinucleotides 5'-methylphospho-N 6-dimethyladenylyl-uridine (mpmf-U) and 5'-methylphospho-uridylyl-N6-dimethyladenosine (mpU-mZ A) and on the trinucleotide U-mzA-U.A detailed comparison is given of the conformational features of mpmfA-U and mpU-m$A with the corresponding 5'-nonphosphorylated dinucleotides mqA-U and U-mqA, respectively. The behaviour of the trinucleotide U-mzA-U is compared with the properties of the constituent dinucleotides U-mqA and mpmq A-U.Chemical-shift and CD data were used to determine the amount of stacking interactions. For each compound NMR spectra were recorded at two or three sample concentrations in order to separate intermolecular and intramolecular base-base interactions. The coupling constants of the ribose ring are interpreted in terms of the N/S equilibrium, and population distributions along the backbone angles fl, y and E are presented.The combined data indicate a strong similarity between mpmqA-U and m$A-U both in degree and in mode of stacking. In contrast, the existence of different types of stacking interactions in mpU-m$A and U-mzA is suggested in order to explain the NMR and CD data. It is concluded that dinucleoside bisphosphates serve better as a model for the behaviour of trinucleotides than dinucleoside monophosphates.The trinucleotide U-mqA-U adopts a regular single-stranded stacked RNA structure with preference for N-type ribose and y+ and p' backbone torsion angles. The difference in behaviour between the U-mfA-part of U-mfA-U and the dimer U-mzA is seen as a typical example of conformational transmission.The biological activity of polynucleotides is determined mainly by the three-dimensional structure of these polymers. It is well known that the vertical base-base stacking constitutes a dominant driving force in the formation of stable RNA and DNA structures. For example, in the case of the codonanticodon interaction, the stacking energies of the participant bases are crucial for the conformation of the anticodon loop and the codon-anticodon complex [l, 21. This might be an important feature for the translation activity.Seen in this light, studies of the conformational behaviour of single-stranded oligonucleotides pursued in this laboratory and elsewhere are quite useful because these yield valuable information about stacking properties. Of special interest are differences in behaviour between dinucleoside monophosphates, trinucleotides, tetranucleotides and longer oligomers.Correspondence to C. Altona, Gorlaeus Laboratories, P.O. Box 9502, NL-2300 RA Leiden, The Netherlands Note. This is part 54 of the series Nucleic Acid Constituents from this laboratory, part 53 will appear later [Orbons, L. P. M., van Such studies may provide insight into the factors important for base-base stacking, like base sequence, electrostatic repulsion between the phosphate groups, conformational preferences of the sugar ring and backbone chain, and conformational transmission effects.For example, 'H-NMR [3 -51 and CD [6] investigations c...

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Double-resonance experiments at 500 MHz on gene-5 protein and its complex with octadeoxyriboadenylic acid

Cited by 54 publications

References 21 publications

Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

500 MHz ¹H NMR study of the role of lysines and arginines in the binding of gene‐5 protein to oligoadenylic acids

Conformational analysis of the dinucleotides 5′‐methylphospho‐N⁶‐dimethyladenylyl‐uridine (mpm⁶₂A‐U) and 5′methylphospho‐uridylyl‐N⁶‐dimethyladenosine (mpU‐m⁶₂A) and of the trinucleotide U‐m⁶₂A‐U

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Double-resonance experiments at 500 MHz on gene-5 protein and its complex with octadeoxyriboadenylic acid

Cited by 54 publications

References 21 publications

Influence of N6‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by 1H‐NMR spectroscopy

Influence of N6‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by 1H‐NMR spectroscopy

500 MHz 1H NMR study of the role of lysines and arginines in the binding of gene‐5 protein to oligoadenylic acids

Conformational analysis of the dinucleotides 5′‐methylphospho‐N6‐dimethyladenylyl‐uridine (mpm62A‐U) and 5′methylphospho‐uridylyl‐N6‐dimethyladenosine (mpU‐m62A) and of the trinucleotide U‐m62A‐U

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Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

Influence of N⁶‐methylation of residue A(5) on the conformational behaviour of d(C‐C‐G‐A‐A‐T‐T‐C‐G‐G) in solution studied by ¹H‐NMR spectroscopy

500 MHz ¹H NMR study of the role of lysines and arginines in the binding of gene‐5 protein to oligoadenylic acids

Conformational analysis of the dinucleotides 5′‐methylphospho‐N⁶‐dimethyladenylyl‐uridine (mpm⁶₂A‐U) and 5′methylphospho‐uridylyl‐N⁶‐dimethyladenosine (mpU‐m⁶₂A) and of the trinucleotide U‐m⁶₂A‐U