Formation of AraC-DNA sandwiches.

With the use of special DNA binding sites, but not the natural aral binding site, the dimeric AraC protein can be forced to make sandwich structures in which two DNA molecules are joined by two AraC protein dimers. Apparently one subunit from each dimer contacts each DNA molecule in an extended structure. These sandwich structures form only in the absence of arabinose. This behavior is consistent with the protein's ability to form DNA loops by binding to separated half sites in the absence of arabinose and its preference for binding to adjacent half-sites in the presence of arabinose.     

Novel mode of deoxyribonucleic acid recognition by thyroid hormone receptors: thyroid hormone receptor beta-isoforms can bind as trimers to natural response elements comprised of reiterated half-sites

Thyroid hormone receptors (TRs) regulate gene expression by binding to specific DNA sequences, denoted thyroid hormone response elements (TREs). The accepted paradigm for TRs proposes that they bind as homo- or heterodimers to TREs comprised of two AGGTCA half-site sequences. In the prototypic TRE, these half-sites are arranged as direct repeats separated by a four-base spacer. This dimeric model of TR binding, derived from analysis of artificial DNA sequences, fails to explain why many natural TREs contain more than two half-sites. Therefore, we investigated the ability of different TR isoforms to bind to TREs possessing three or more half-sites. We report that the TRbeta isoforms (TRbeta0, TRbeta1, TRbeta2), but not TRalpha1, can bind to reiterated DNA elements, such as the rat GH-TRE, as complexes trimeric or greater in size. The TRbeta0 isoform, in particular, formed homo- and heterotrimers (with the retinoid X receptor) with high efficiency and cooperativity, and TRbeta0 preferentially used reporters containing these reiterated elements to drive gene expression in vivo. Our data demonstrate that TRbeta isoforms can form multimeric receptor complexes on appropriately reiterated DNA response elements, providing a functional distinction between the TR isoforms and an explanation for TREs possessing three or more half-sites.     

Biochemical and physiological properties of the DNA binding domain of AraC protein

Intact AraC protein is poorly soluble and difficult to purify, whereas its dimerization domain is the opposite. Unexpectedly, the DNA binding domain of AraC proved also to be soluble in cells when overproduced and is easily purified to homogeneity. The DNA binding affinity of the DNA binding domain for its binding site could not be measured by electrophoretic mobility shift because of its rapid association and dissociation rates, but its affinity could be measured with a fluorescence assay and was found to have a dissociation constant of 1 x 10(-8)M in 100 mM KCl. The binding of monomers of the DNA binding domain to adjacent half-sites occurs without substantial positive or negative cooperativity. A simple analysis relates the DNA binding affinities of monomers of DNA binding domain and normal dimeric AraC protein.     

DNA binding of Escherichia coli arginine repressor mutants altered in oligomeric state

The Escherichia coli arginine repressor (ArgR) controls expression of the arginine biosynthetic genes and acts as an accessory protein in Xer site-specific recombination at cer and related plasmid recombination sites. The hexameric wild-type protein shows L -arginine-dependent DNA binding. In this work, ArgR mutants that are defective in trimer–trimer interactions and bind DNA as trimers in an L -arginine-independent manner are isolated and characterized. Whereas the wild-type ArgR hexamer exhibits high-affinity binding to two repeated ARG boxes separated by 3 bp (each ARG box containing two identical dyad symmetrical 9 bp half-sites), the trimeric mutants bind to and footprint three adjacent half-sites of this 'idealized' substrate. Trimeric ArgR is impaired in its ability to repress the arginine biosynthetic genes and in Xer site-specific recombination. In the absence of L -arginine, residual wild-type ArgR-binding occurs as trimers. The binding of an N-terminal 77-amino-acid DNA-binding domain to idealized ARG boxes is also characterized.     

Half-site spacing and orientation determines whether thyroid hormone and retinoic acid receptors and related factors bind to DNA response elements as monomers, homodimers, or heterodimers.

The receptors for thyroid hormone (T3R) and retinoic acid (RAR) are members of a nuclear receptor subfamily that are capable of recognizing similar DNA sequences. Native response elements for T3R and RAR consist of two or more putative half-site binding motifs organized as imperfect direct or inverted repeats separated by different sized nucleotide gaps. To clarify how T3R, RAR, and related factors recognize DNA response elements, we analyzed the interaction of purified receptors with a series of inverted and direct repeats of an idealized AGGTCA half-site separated by different sized nucleotide gaps. Our results indicate that RAR and T3R can bind to half-sites as monomers and, depending on the orientation and distance between half-sites, also bind as homodimers or T3R-RAR heterodimers. T3R also binds to certain DNA elements as a heterodimer with one or more nuclear factors from eucaryotic cells. Thus, the orientation and spacing of half-sites play a central role in determining which configuration of receptors and nuclear factors will interact with a specific DNA element. This along with the ability of these factors to participate in reversible protein-protein interactions serve to broaden and diversify the responses mediated by T3R, RAR, and related members of this nuclear receptor subfamily.     

How p53 binds DNA as a tetramer.

The p53 tumor suppressor protein is a tetramer that binds sequence-specifically to a DNA consensus sequence consisting of two consecutive half-sites, with each half-site being formed by two head-to-head quarter-sites (--><-- --><--). Each p53 subunit binds to one quarter-site, resulting in all four DNA quarter-sites being occupied by one p53 tetramer. The tetramerization domain forms a symmetric dimer of dimers, and two contrasting models have the two DNA-binding domains of each dimer bound to either consecutive or alternating quarter-sites. We show here that the two monomers within a dimer bind to a half-site (two consecutive quarter-sites), but not to separated (alternating) quarter-sites. Tetramers bind similarly, with the two dimers within each tetramer binding to pairs of half-sites. Although one dimer within the tetramer is sufficient for binding to one half-site in DNA, concurrent interaction of the second dimer with a second half-site in DNA drastically enhances binding affinity (at least 50-fold). This cooperative dimer-dimer interaction occurs independently of tetramerization and is a primary mechanism responsible for the stabilization of p53 DNA binding. Based on these findings, we present a model of p53 binding to the consensus sequence, with the tetramer binding DNA as a pair of clamps.     

Studies on the domain structure of the Salmonella typhimurium AraC protein

The Salmonella typhimurium araC gene product is known to be susceptible to proteolytic degradation. Limited cleavage by trypsin, kallikrein, elastase and pronase E yields stable fragments comprising approximately the N-terminal two thirds of the AraC protein. These fragments have in common the ability to dimerize in solution and to bind L-arabinose and D-fucose. Under appropriate conditions, hydrolysis of the AraC protein with Staphylococcus aureus V8 protease leads to a small C-terminal fragment which is able to bind specifically to a synthetic ara consensus sequence. These results indicate that, as with several other prokaryotic gene regulatory proteins, the basic functions of effector binding, subunit interaction and specific DNA binding are segregated into distinct domains of the AraC protein.     

Purification and properties of RhaR, the positive regulator of the L-rhamnose operons of Escherichia coli

The product of the rhaR gene, which regulates the level of mRNA produced from the four L-rhamnose-inducible promoters of the rhamnose operon, has been hypersynthesized and purified by a two-column procedure. The purified protein is a 33 kDa DNA-binding protein that binds to an inverted repeat structure located within the psr promoter, the promoter for the rhaS and rhaR genes. The equilibrium binding constants and kinetic constants have been determined under a variety of solution conditions. The protein binds with high affinity and its binding is sensitive to salt concentration and the presence of L-rhamnose. The nucleotides and phosphate residues contacted by RhaR were identified by chemical interference assays. All of the contacts are made to one face of the DNA and the symmetrical pattern matches the inverted repeat sequence proposed for the binding site. An unusual property of the binding site is that the two half-sites of the inverted repeat are separated from one another by 17 base-pairs of uncontacted DNA. Significant binding is retained if the 17 base-pairs are extended by insertions of integral turns of DNA, but not by half-integral turns. The complex of RhaR-DNA appears to be sharply bent, approximately 160 degrees.