Experimental evidence for the role of domain swapping in the evolution of the histone fold.

The histone fold forms the fundamental endoskeleton of the protein core of the nucleosome and is also found in several transcription factors. We have investigated the evolutionary origins of this ubiquitous protein motif, which is found soluble exclusively as an antiparallel (handshake motif) dimer. We introduced a three amino acid insertion into the middle of a homodimeric archaeal histone fold motif. The engineered molecule was found to be a soluble and stable monomer with properties consistent with a four-helix-bundle protein. The experimental evidence presented here support the hypothesis that the handshake association motif characteristic of present-day histone dimers is the evolutionary product of domain swapping between two four-helix bundle domains, each of which derived from the tandem duplication of a primitive helix-strand-helix unit.

Influence of ions, hydration, and the transcriptional inhibitor P4N on the conformations of the Sp1 binding site.

Three crystal structures containing the entire Sp1 consensus sequence d(GGGGCGGGG) with two or three additional base-pairs on either the 5' or 3' ends and overhangs have been determined. Despite the different lengths of DNA in the pseudo-dodecamers and pseudo-tridecamer, all three structures form A-DNA duplexes that share a common set of crystal contacts, including a T*(G.C) base triplet and a 5'-overhang that flips out and away from the helical axes to form a Hoogsteen base-pair with the 3'-overhang of a symmetry mate. The global conformations of the three structures differ, however, in the widths of their respective major grooves, the lengths of the molecules, and the extent of crystal packing. The structures were determined from crystals grown in an unusual precipitant for A-DNA, polyethylene glycol (PEG) 400, in combination with polyamines or ions; cobalt hexamine for the pseudo-tridecamer, and spermidine for the pseudo-dodecamers. As the Sp1 binding site is a target for antiviral and anticancer drugs, pseudo-dodecamer crystals were soaked with one such antiviral and anticancer compound, P4N. Although P4N was not visualized unambiguously in the electron density maps, the effect of the drug is evident from significant differences in the lattice constants, crystal packing, and overall conformation of the structure.

The histone octamer is invisible when NF-kappaB binds to the nucleosome.

The transcription factor NF-kappaB is involved in the transcriptional control of more than 150 genes, but the way it acts at the level of nucleosomal templates is not known. Here we report on a study examining the interaction of NF-kappaB p50 with its DNA recognition sequence in a positioned nucleosome. We demonstrate that NF-kappaB p50 was able to bind to the nucleosome with an apparent association constant close to that for free DNA. In agreement with this, the affinity of NF-kappaB p50 binding does not depend on the localization of its recognition sequence relative to the nucleosome dyad axis. In addition, the binding of NF-kappaB p50 does not induce eviction of histones and does not perturb the overall structure of the nucleosome. The NF-kappaB p50-nucleosome complex exhibits, however, local structural alterations within the NF-kappaB p50 recognition site. Importantly, these alterations were very similar to those found in the NF-kappaB p50-DNA complex. Our data suggest that NF-kappaB p50 can accommodate the distorted, bent DNA within the nucleosome. This peculiar property of NF-kappaB p50 might have evolved to meet the requirements for its function as a central switch for stress responses.