Sequence specific DNA binding of Ets-1 transcription factor: molecular dynamics study on the Ets domain--DNA complexes

Molecular dynamics (MD) simulations for Ets-1 ETS domain-DNA complexes were performed to investigate the mechanism of sequence-specific recognition of the GGAA DNA core by the ETS domain. Employing the crystal structure of the Ets-1 ETS domain-DNA complex as a starting structure we carried out MD simulations of: (i). the complex between Ets-1 ETS domain and a 14 base-pair DNA containing GGAA core sequence (ETS-GGAA); (ii). the complex between the ETS domain and a DNA having single base-pair mutation, GGAG sequence (ETS-GGAG); and (iii). the 14 base-pair DNA alone (GGAA). Comparative analyses of the MD structures of ETS-GGAA and ETS-GGAG reveal that the DNA bending angles and the ETS domain-DNA phosphate interactions are similar in these complexes. These results support that the GGAA core sequence is distinguished from the mutated GGAG sequence by a direct readout mechanism in the Ets-1 ETS domain-DNA complex. Further analyses of the direct contacts in the interface between the helix-3 region of Ets-1 and the major groove of the core DNA sequence clearly show that the highly conserved arginine residues, Arg391 and Arg394, play a critical role in binding to the GGAA core sequence. These arginine residues make bidentate contacts with the nucleobases of GG dinucleotides in GGAA core sequence. In ETS-GGAA, the hydroxyl group of Tyr395 is hydrogen bonded to N7 nitrogen of A(3) (the third adenosine in the GGAA core), while the hydroxyl group makes a contact with N4 nitrogen of C(4') (the complementary nucleotide of the fourth guanosine G(4) in the GGAG sequence) in the ETS-GGAG complex. We have found that this difference in behavior of Tyr395 results in the relatively large motion of helix-3 in the ETS-GGAG complex, causing the collapse of bidentate contacts between Arg391/Arg394 and the GG dinucleotides in the GGAG sequence.     

Determination of DNA cooperativity factor.

The paper presents measurements of the difference in the melting temperature of a colE1 DNA region when it is located inside the DNA helix and at its end. A direct comparison of calculations based on the rigorous theory of helix-coil transition with experimental data for .2 M Na+ (the conditions for fully reversible melting) yielded the value of 2.5-5x10(-5) for the cooperatively factor sigma. We discuss the reversibility of DNA melting and the possibility of applying the "all-or-nothing" concept to the melting of DNA regions.     

a1 protein alters the DNA binding specificity of alpha 2 repressor

The alpha 2 protein of S. cerevisiae, the product of the MAT alpha 2 gene, represses a set of cell-type-specific genes (the a-specific genes) by binding to an operator sequence upstream of each gene. We demonstrate that a second yeast regulatory protein, a1, the product of the MATa1 gene, can alter the binding specificity of alpha 2 so that it no longer recognizes the a-specific gene operator, but instead acquires the ability to recognize a different operator sequence found upstream of haploid-specific genes. Thus, under the influence of a1, alpha 2 can repress haploid-specific genes. An alpha cell expresses alpha 2 but not a1, so that alpha 2 turns off only the a-specific genes. An a/alpha cell makes both a1 and alpha 2, in a ratio that ensures that alpha 2 is distributed between two distinct binding modes: the alpha 2 binding mode and the a1-alpha 2 binding mode. Thus in an a/alpha cell, alpha 2 represses two distinct classes of genes.     

Differential binding of a CCAAT DNA binding factor to the promoters of the mouse alpha 2(I) and alpha 1(III) collagen genes

An exonuclease III assay (Wu, C. (1985) Nature 317, 84-87) was used to identify in nuclear extracts of NIH 3T3 cells a factor which binds to the CCAAT segment of the alpha 2(I) collagen promoter between -80 and -84. This sequence is located on the coding strand in the alpha 2(I) collagen promoter. Binding is specific since only promoter fragments which contain the CCAAT box sequences on one or the other DNA strand inhibit binding to the alpha 2(I) collagen CCAAT box. The CCAAT binding factor protects approximately 26 base pairs of the alpha 2(I) collagen promoter from exonuclease III digestion. Binding to the alpha 2(I) collagen promoter CCAAT box is not inhibited by a fragment of the alpha 1(III) collagen promoter (from -396 to +16), which does not contain a CCAAT sequence on either one or the other strand. Our data suggest that two genes such as the alpha 2(I) and alpha 1(III) collagen genes, which are coordinately expressed in many tissues, are not necessarily regulated by the same trans-acting DNA binding proteins.     

E1 initiator DNA binding specificity is unmasked by selective inhibition of non-specific DNA binding

Initiator proteins are critical components of the DNA replication machinery and mark the site of initiation. This activity probably requires highly selective DNA binding; however, many initiators display modest specificity in vitro. We demonstrate that low specificity of the papillomavirus E1 initiator results from the presence of a non-specific DNA-binding activity, involved in melting, which masks the specificity intrinsic to the E1 DNA-binding domain. The viral factor E2 restores specificity through a physical interaction with E1 that suppresses non-specific binding. We propose that this arrangement, where one DNA-binding activity tethers the initiator to ori while another alters DNA structure, is a characteristic of other viral and cellular initiator proteins. This arrangement would provide an explanation for the low selectivity observed for DNA binding by initiator proteins.