Walter Gehring

The structure of the antennapedia homeodomain determined by nmr spectroscopy in solution comparison with prokaryotic repressors

The structure of the Antennapedia homeodomain from Drosophila melanogaster was determined by nuclear magnetic resonance spectroscopy in solution. It includes three well-defined helices (residues 10-21, 28-38, and 42-52) and a more flexible fourth helix (residues 53-59). Residues 30-50 form a helix-turn-helix motif virtually identical to those observed in various prokaryotic repressors. Further comparisons of the homeodomain with prokaryotic repressors showed that there are also significant differences in the molecular architectures. Overall, these studies support the view that the third helix of the homeodomain may function as the DNA recognition site. The elongation of the third helix by the fourth helix is a structured element that so far appears to be unique to the Antennapedia homeodomain.

Protein - DNA contacts in the structure of a homeodomain - DNA complex determined by nuclear magnetic resonance spectroscopy in solution

The 1:1 complex of the mutant Antp(C39––S) homeodomain with a 14 bp DNA fragment corresponding to the BS2 binding site was studied by nuclear magnetic resonance (NMR) spectroscopy in aqueous solution. The complex has a molecular weight of 17,800 and its lifetime is long compared with the NMR chemical shift time scale. Investigations of the three‐dimensional structure were based on the use of the fully 15N‐labelled protein, two‐dimensional homonuclear proton NOESY with 15N(omega 2) half‐filter, and heteronuclear three‐dimensional NMR experiments. Based on nearly complete sequence‐specific resonance assignments, both the protein and the DNA were found to have similar conformations in the free form and in the complex. A sufficient number of intermolecular 1H‐1H Overhauser effects (NOE) could be identified to enable a unique docking of the protein on the DNA, which was achieved with the use of an ellipsoid algorithm. In the complex there are intermolecular NOEs between the elongated second helix in the helix‐turn‐helix motif of the homeodomain and the major groove of the DNA. Additional NOE contacts with the DNA involve the polypeptide loop immediately preceding the helix‐turn‐helix segment, and Arg5. This latter contact is of special interest, both because Arg5 reaches into the minor groove and because in the free Antp(C39––S) homeodomain no defined spatial structure could be found for the apparently flexible N‐terminal segment comprising residues 0‐6.

Isolation and sequence-specific DNA binding of the Antennapedia homeodomain.

The homeodomain encoded by the Antennapedia (Antp) gene of Drosophila was overproduced in a T7 expression vector in Escherichia coli. The corresponding polypeptide of 68 amino acids was purified to homogeneity. The homeodomain was analysed by ultracentrifugation and assayed for DNA binding. The secondary structure of the isolated homeodomain was determined by nuclear magnetic resonance spectroscopy. DNA‐binding studies indicate that the isolated homeodomain binds to DNA in vitro. It selectively binds to the same sites as a longer Antp polypeptide and a full‐length fushi tarazu (ftz) protein. Therefore, the homeodomain represents the DNA‐binding domain of the homeotic proteins.

Structure determination of the Antp (C39----S) homeodomain from nuclear magnetic resonance data in solution using a novel strategy for the structure calculation with the programs DIANA, CALIBA, HABAS and GLOMSA.

The structure of a mutant Antennapedia homeodomain, Antp(C39----S), from Drosophila melanogaster was determined using a set of new programs introduced in the accompanying paper. An input dataset of 957 distance constraints and 171 dihedral angle constraints was collected using two-dimensional n.m.r. experiments with the 15N-labeled protein. The resulting high quality structure for Antp(C39----S), with an average root-mean-square deviation of 0.53 A between the backbone atoms of residues 7 to 59 in 20 energy-refined distance geometry structures and the mean structure, is nearly identical to the previously reported structure of the wild-type Antp homeodomain. The only significant difference is in the connection between helices III and IV, which was found to be less kinked than was indicated by the structure determination for Antp. The main emphasis of the presentation in this paper is on a detailed account of the practical use of a novel strategy for the computation of nuclear magnetic resonance structures of proteins with the combined use of the programs DIANA, CALIBA, HABAS and GLOMSA.

Secondary structure determination for the Antennapedia homeodomain by nuclear magnetic resonance and evidence for a helix-turn-helix motif.

The homeodomain encoded by the Antennapedia (Antp) gene of Drosophila was studied in aqueous solution by nuclear magnetic resonance (NMR). Sequence‐specific resonance assignments have been obtained for the complete polypeptide chain of 68 amino acid residues. The secondary structure determined from nuclear Overhauser effects (NOE) and information about slowly exchanging amide protons includes three helical segments consisting of the residues 10‐21, 28‐38 and 42‐52, respectively. Combination of the presently available NMR data with computer modeling provided preliminary evidence for the presence of a helix‐turn‐helix motif in the homeodomain. Near the turn, this supersecondary structure appears to be very similar to the DNA binding site in the 434 and P22 c2 repressors, but both helices in the homeodomain include 2‐3 additional residues when compared with these prokaryotic DNA‐binding proteins.

The interaction with DNA of wild-type and mutant fushi tarazu homeodomains.

The in vitro DNA binding properties of wild‐type and mutant fushi tarazu homeodomains (ftz HD) have been analysed. The DNA binding properties of the ftz HD are very similar to those of the Antp HD. In interference experiments with mutant ftz HDs, close approaches between specific portions of the ftz HD peptide and specific regions of the binding site DNA were mapped. A methylation interference, G7 on the beta strand of BS2, is absent from the interference pattern with a mutant ftz HD [ftz (R43A) HD] in which the Arg43 at the second position of helix III (the recognition helix) is replaced by an Ala. This indicated that Arg43 of the ftz HD is in close proximity to the N7 of G7 of the beta strand of BS2 in the major groove. The methylation and ethylation interference patterns with the ftz (NTD) HD, in which the first six amino acids of the homeodomain were deleted, were extensively altered relative to the ftz HD patterns. Methylation of A11 and G12 of the alpha strand and ethylation of the phosphate of nucleotide A12 of the alpha strand no longer interfere with binding. This indicated that the first six amino acids of the homeodomain of ftz interact with A11 of the alpha strand in the minor groove, the phosphate of the nucleotide A13 on the alpha strand and G12 of the alpha strand in the adjacent major groove of BS2. In a binding study using a change of specificity mutation [ftz (Q50K) HD], in which the Gln50 at the ninth position of the third helix is exchanged for a Lys (as in the bicoid HD), and variant binding sites, we concluded that position 50 of the ftz HD and the ftz (Q50K) HD peptides interacts with base pairs at positions 6 and 7 of BS2. These three points of contact allowed us to propose a crude orientation of the ftz HD within the protein‐DNA complex. We find that the ftz HD and the Antp HD peptides contact DNA in a similar way.

Distamycin-induced inhibition of homeodomain-DNA complexes.

The mobility shift assay was used to study the competition of the minor groove binder distamycin A with either an Antennapedia homeodomain (Antp HD) peptide or derivatives of a fushi tarazu homeodomain (ftz HD) peptide for their AT‐rich DNA binding site. The results show that distamycin and the homeodomain peptides compete under the conditions: (i) preincubation of DNA with distamycin and subsequent addition of HD peptide; (ii) simultaneous incubation of DNA with distamycin and HD peptide; and (iii) preincubation of DNA with HD peptide and subsequent addition of distamycin. There is also competition when using a peptide which lacks the N‐terminal arm of ftz HD that is involved in contacts in the minor groove. It is proposed that the proteins binding affinity is diminished by distamycin‐induced conformational changes of the DNA. The feasibility of the propagation of conformational changes upon binding in the minor groove is also shown for the inhibition of restriction endonucleases differing in the AT content of their recognition site and of their flanking DNA sequences. Thus, it is demonstrated that minor groove binders can compete with the binding of proteins in the major groove, providing an experimental indication for the influence of biological activities exerted by DNA ligands binding in the minor groove.