The DNA binding domain

Thus far a series of deletion mutations have been introduced into glucocorticoid receptor cDNAs in the region coding for the DNA binding domain [83,84,90,104], These were tested either by in vitro transcription and translation followed by a spe- 

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Two domains, t1 and t2, exist which affect the GR post-DNA binding transcription activity (37). The major (t1) transactivation domain is 185 amino acid residues ia length with a 58-tesidue a-heUcal functional cote (38). The t1 domain is located at the N terminus of the proteia the minor (t2) trans activation domain residues on the carboxy-terminal side of the DNA binding domain. 

The x-ray structure of the DNA-binding domain of the lambda repressor is known... 

In spite of the absence of the C-terminal domains, the DNA-binding domains of lambda repressor form dimers in the crystals, as a result of interactions between the C-terminal helix number 5 of the two subunits that are somewhat analogous to the interactions of the C-terminal p strand 3 in the Cro protein (Figure 8.7). The two helices pack against each other in the normal way with an inclination of 20° between the helical axes. The structure of the C-terminal domain, which is responsible for the main subunit interactions in the intact repressor, remains unknown. 

This model of Cro binding to DNA was arrived at by intuition and clever model building. Its validity was considerably strengthened when the same features were subsequently found in the DNA-binding domains of the lambda-repressor molecule. The helix-turn-helix motif with a recognition helix is present in the repressor, and moreover the repressor DNA-binding domains dimerize in the crystals in such a way that the recognition helices are separated by 34 A as in Cro. 

Figure 8.11 The DNA-binding domain of 434 repressor. It is a dimer in its complexes with DNA fragments. Each subunit (green and brown) folds into a bundle of four a helices (1-4) that have a structure similar to the corresponding region of the lambda repressor (see Figure 8.7) including the helix-turn-helix motif (blue and red). A fifth a helix (5) is involved in the subunit interactions, details of which are different from those of the lambda repressor fragment. The structure of the 434 Cro dimer is very similar to the 434 repressor shown here.

Steitz, T.A., et al. Structural similarity in the DNA-binding domains of catabolite gene activator and Cro repressor proteins. Proc. Natl. Acad. Sci. USA 79 3097-3100,... 

Figure 9.18 Schematic digram of the structure of the DNA-binding domain of p53. (a) The DNA binding domain of p53 folds into an antiparallel p barrel with long loop regions—...

Figure 9.19 Nucleotide sequence of the 21-base pair DNA fragment cocrystalUzed with the DNA-binding domain of p53. The p53 binds in a sequence-specific manner to the shaded region.

The two zinc ions fulfill important but different functions in the DNA-binding domains. The first zinc ion is important for DNA-bindlng because it properly positions the recognition helix the last two cysteine zinc ligands are part of this helix. The second zinc ion is important for dimerization since the five-residue loop between the first two cysteine zinc ligands is the main component of the dimer interaction area. 

In summary, a DNA-supported asymmetric interface located within the DNA-binding domains of these nuclear receptors provides the molecular basis for receptor heterodimers to distinguish between closely related response elements. RXR can provide a repertoire of different dimerization surfaces, each one unique for a specific partner, allowing dimers to form that are adapted to the length of the spacer region in their corresponding response elements. 

Figure 10.17 Amino acid sequences, represented as a helical wheels with 3.5 residues per turn, of a region of 28 residues from the DNA-binding domains of the transcription factors (a) GCN4, (b) Max,...

Figure 10.24 Structure of a monomer of the DNA-binding domain of the transcription factor MyoD. The domain, which belongs to the b/HLH family, comprises two a helices joined by a loop region. The basic region (blue) and the first helix HI (red) of the helix-loop-helLx region form one continous a helix. (Adapted from P.C.M. Ma et al.. Cell 77 451-459, 1994.)...

POU regions bind to DNA by two tandemly oriented helix-turn-helix motifs Much remains to be learnt about the function of homeodomains in vivo Understanding tumorigenic mutations The monomeric p53 polypeptide chain is divided in three domains The oligomerization domain forms tetramers The DNA-binding domain of p53 is an antiparallel P barrel... 

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