Marcel J. J. Blommers scite author profile

In the version of this caption initially published, the cover artwork was credited to Erin Dewalt, based on imagery from the author, rather than stating that it was created by Michael B. Battles and the design was by Erin Dewalt. The error has been corrected in the HTML and PDF versions of the caption. ERRATUM In the version of this article initially published, the genus name 'Mycoplasma' was incorrectly used in place of the correct 'Mycobacterium'. The error has been corrected in the HTML and PDF versions of the article. ERRATUM npg

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Discovery of Potent Antagonists of the Interaction between Human Double Minute 2 and Tumor Suppressor p53

García‐Echeverría

et al. 2000

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Effects of base sequence on the loop folding in DNA hairpins

Blommers

Walters²,

Haasnoot³

et al. 1989

Biochemistry

140

128

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High-resolution NMR and UV-melting experiments have been used to study the hairpin formation of partly self-complementary DNA fragments in an attempt to derive rules that describe the folding in these molecules. Earlier experiments on the hexadecanucleotide d(ATCCTA-TTTT-TAGGAT) had indicated that within the loop of four thymidines a wobble T-T pair is formed (Blommers et al., 1987). In the present paper it is shown that if the first and the last thymines of the intervening sequence are replaced by complementary bases, sometimes base pairs can be formed. Thus for the intervening sequences -CTTG- and -TTTA- with the pyrimidine in the 5'-position and the purine in the 3'-position, a base pair is formed leading to a loop consisting of two residues. For the intervening sequences -GTTC- and -ATTT- with the purine in the 5'-position and the pyrimidine in the 3'-position, this turns out not to be the case. It was found that it made no difference when the four-membered sequence was closed by a G-C base pair or an A-T base pair. Replacement of the two central thymidine residues by the more bulky adenine residues limits the hairpin to a four-membered loop scheme. Very surprisingly, it was found from 2D NOE experiments that the T-A base pair, formed in the loop consisting of the -TTTA- sequence, is a Hoogsteen pair. It is argued that the pairing of the bases in this scheme may facilitate the formation of a loop of two residues, since the distance of the C1' atoms in this base pair is 8.6 A instead of 10.4 A found in the canonical Watson-Crick base pair. Combination of the data obtained for the series of DNA fragments studied shows that the results can be explained by a simple, earlier proposed, loop folding principle which assumes that the folding of the four-membered loop is dictated by the stacking of the double-helical stem of the hairpin.

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A New Class of HIV-1 Tat Antagonist Acting through Tat−TAR Inhibition

et al. 1998

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The main transcriptional regulator of the human immunodeficiency virus, the Tat protein, recognizes and binds to a small structured RNA element at the 5' end of every viral mRNA, termed TAR. On the basis of published structural data of the molecular interactions between TAR and Tat-related peptides, we defined requirements for potential low-molecular weight inhibitors of TAR recognition by the Tat protein. In accordance with the resulting concept, a series of compounds was synthesized. In vitro evaluation of their potential to directly interfere with Tat-TAR interaction was used to define a new chemical class of potent Tat antagonistic substances. The most active compound competed with Tat-TAR complexation with a competition dose CD50 of 22 nM in vitro and blocked HIV expression in a cellular Tat transactivation system with an IC50 of 1.2 microM. The close relation between structural features of the interaction between TAR and a new type of inhibitory agent, "In-PRiNts" (for inhibitor of protein-ribonucleotide sequences), such as CGP 40336A and those of the Tat-TAR complex was confirmed by RNase A footprinting and by two-dimensional NMR. Structural implications for the complex between this class of compounds and TAR RNA will be presented.

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The three‐dimensional structure of a DNA hairpin in solution

Blommers¹,

Ven²,

Marel

et al. 1991

European Journal of Biochemistry

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The hairpin formed by d(ATCCTATTTATAGGAT) was studied by means of two-dimensional NMR spectroscopy and conformational analysis. Almost all 'H resonances of the stem region could be assigned, while the 'H and 31P spectra of the loop region were interpreted completely; this includes the stereospecific assignment of the H5' and H5" resonances. The derivation of the detailed loop structure was carried out in a stepwise fashion including some improved and new methods for structure determination from NMR data. In the first step, the mononucleotide structures were examined. The conformational space available to the mononucleotide was scanned systematically by varying the glycosidic torsion angle and pseudorotational parameters. Each generated conformer was tested against the experimental J coupling constants and NOE parameters. In the following stage, the structures of dinucleotides and longer fragments were derived. Inter-residue distances between protons were calculated by means of a procedure in which the simulated NOEs, obtained via a relaxation-matrix approach, were fitted to the experimental NOEs without the introduction of a molecular model. In addition, the backbone torsion angles fl, y and c were deduced from homocoupling and heterocoupling constants. These data served as constraints in the next step, in which the loop sequence was subjected to a multi-conformer generation procedure. The resulting structures were tested against the mentioned constraints and disregarded if these constraints were violated. This yielded a family of structures for the loop region, confined to a relatively narrow conformational space. A representative conformation was subsequently docked on a B-type stem which fulfilled the structural constraints (derived from the NMR experiments for the stem region) to yield the hairpin structure. Results obtained from subsequent restrained-molecular-mechanics as well as free-molecular-mechanics calculations are in accordance with those obtained by means of the analysis described above.The structure of the hairpin loop is a compactly folded conformation and the first base of the central TTTA region forms a Hoogsteen T-A pair with the fourth base. This Hoogsteen base pair is stacked upon the sixth base pair of the B-type double-helical stem. The second base of the loop is folded into the minor groove, whereas the third base of the loop is partly stacked on the first and fourth bases. The phosphate backbone exhibits a sharp turn between the third and fourth nucleotides of the loop. The peculiar structure of this hairpin loop is discussed in relation to loop folding in DNA and RNA hairpins and in relation to a general model for loop folding.Loop structures in RNA and DNA hairpins have been the subject of numerous studies. We have been interested in these structures because they may serve as models for the folding which occurs in RNA and DNA molecules in the cell, and also because they may provide insight into the mechanism underlying the folding. Our initial studies were concerned with the hairpin fo...

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