The structure of GH5, the globular domain of the linker histone H5, has been solved to 2.5 A resolution by multiwavelength anomalous diffraction on crystals of the selenomethionyl protein. The structure shows a striking similarity to the DNA-binding domain of the catabolite gene activator protein CAP, thereby providing a possible model for the binding of GH5 to DNA.
The Pluronic polyol F127, PEO99PPO69PEO99 (PEO and PPO being poly(ethylene oxide) and poly(propylene oxide), respectively) has the potential to be used as an effective separation medium in capillary electrophoresis (CE) for the separation of biomacromolecules such as DNA fragments and proteins. Static light scattering (SLS), dynamic light scattering (DLS), small-angle neutron scattering (SANS), and small-angle X-ray scattering (SAXS) were used to characterize the solution properties and the microstructures of F127 in the same electrophoresis buffer used in CE. In the dilute solution region, F127 in CE buffer forms micelles similar to that in water. At high solution concentrations, micelles tend to pack into some crystalline forms with relatively well-structured PPO centers. By using a combination of SANS and SAXS results, we are able to conclusively determine the gellike structure to have a facecentered cubic lattice. The effects of solvent, polymer concentration, temperature, and sample preparation procedure on the gel structure were studied. In the gellike region the aggregation number and also the micellar size are not sensitive to both the concentration change and the temperature change. The results of DNA electrophoretic migration in F127 gels also support these findings.
ClpP is a self-compartmentalized proteolytic assembly comprised of two, stacked, heptameric rings that, when associated with its cognate hexameric ATPase (ClpA or ClpX), form the ClpAP and ClpXP ATP-dependent protease, respectively. The symmetry mismatch is an absolute feature of this large energy-dependent protease and also of the proteasome, which shares a similar barrelshaped architecture, but how it is accommodated within the complex has yet to be understood, despite recent structural investigations, due in part to the conformational lability of the N-termini. We present the structures of Escherichia coli ClpP to 1.9 Å and an inactive variant that provide some clues for how this might be achieved. In the wild type protein, the highly conserved Nterminal 20 residues can be grouped into two major structural classes. In the first, a loop formed by residues 10-15 protrudes out of the central access channel extending ∼ 12-15 Å from the surface of the oligomer resulting in the closing of the access channel observed in one ring. Similar loops are implied to be exclusively observed in human ClpP and a variant of ClpP from Streptococcus pneumoniae. In the other ring, a second class of loop is visible in the structure of wt ClpP from E. coli that forms closer to residue 16 and faces toward the interior of the molecule creating an open conformation of the access channel. In both classes, residues 18-20 provide a conserved interaction surface. In the inactive variant, a third class of N-terminal conformation is observed, which arises from a conformational change in the position of F17. We have performed a detailed functional analysis on each of the first 20 amino acid residues of ClpP. Residues that extend beyond the plane of the molecule (10-15) have a lesser effect on ATPase interaction than those lining the pore (1-7 and 16-20). Based upon our structure-function analysis, we present a model to explain the widely disparate effects of individual residues on ClpP-ATPase complex formation and also a possible functional reason for this mismatch.
The nature of the complexes of histones H1 and H5 and their globular domains (GH1 and GH5) with DNA suggested two DNA‐binding sites which are likely to be the basis of the preference of H1 and H5 for the nucleosome, compared with free DNA. More recently the X‐ray and NMR structures of GH5 and GH1, respectively, have identified two basic clusters on opposite sides of the domains as candidates for these sites. Removal of the positive charge at either location by mutagenesis impairs or abolishes the ability of GH5 to assemble cooperatively in ‘tramline’ complexes containing two DNA duplexes, suggesting impairment or loss of its ability to bind two DNA duplexes. The mutant forms of GH5 also fail to protect the additional 20 bp of nucleosomal DNA that are characteristically protected by H1, H5 and wild‐type recombinant GH5. They still bind to H1/H5‐depleted chromatin, but evidently inappropriately. These results confirm the existence of, and identify the major components of, two DNA‐binding sites on the globular domain of histone H5, and they strongly suggest that both binding sites are required to position the globular domain correctly on the nucleosome.
The antiviral activity of the interferon-induced, double-stranded RNA (dsRNA)-activated protein kinase (PKR) is mediated through dsRNA binding leading to PKR autophosphorylation and subsequent inhibition of protein synthesis. Previous biochemical studies have suggested that autophosphorylation of PKR occurs via a protein-protein interaction and that PKR can form dimers in vitro. Using four independent biophysical and biochemical methods, we have characterized the solution complex formed between PKR and trans-activating region (TAR) RNA, a 57-nucleotide RNA species with double-stranded secondary structure derived from the human immunodeficiency virus type I genome. Chemical cross-linking and gel filtration analyses of PKR⅐TAR RNA complexes reveals that TAR RNA addition increases PKR dimerization and results in the formation of a solution complex with a molecular weight of approximately 150,000. Addition of TAR RNA to PKR results in a quenching of tryptophan fluorescence, indicative of a conformational shift. Through small angle neutron scattering analysis, we show that PKR exists in solution predominantly as a dimer, and has an elongated solution structure. Addition of TAR RNA to PKR causes a significant conformational shift in the protein at a 2:1 stoichiometric ratio of protein to RNA. Taken together, these data indicate that the PKR activation complex consists of a protein dimer bound cooperatively to one dsRNA molecule.
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