Mechanism of kappa B DNA binding by Rel/NF-kappa B dimers

The DNA binding of three different NF-kappaB dimers, the p50 and p65 homodimers and the p50/p65 heterodimer, has been examined using a combination of gel mobility shift and fluorescence anisotropy assays. The NF-kappaB p50/p65 heterodimer is shown here to bind the kappaB DNA target site of the immunoglobulin kappa enhancer (Ig-kappaB) with an affinity of approximately 10 nm. The p50 and p65 homodimers bind to the same site with roughly 5- and 15-fold lower affinity, respectively. The nature of the binding isotherms indicates a cooperative mode of binding for all three dimers to the DNA targets. We have further characterized the role of pH, salt, and temperature on the formation of the p50/p65 heterodimer-Ig-kappaB complex. The heterodimer binds to the Ig-kappaB DNA target in a pH-dependent manner, with the highest affinity between pH 7.0 and 7.5. A strong salt-dependent interaction between Ig-kappaB and the p50/p65 heterodimer is observed, with optimum binding occurring at monovalent salt concentrations below 75 mm, with binding becoming virtually nonspecific at a salt concentration of 200 mm. Binding of the heterodimer to DNA was unchanged across a temperature range between 4 degrees C and 42 degrees C. The sensitivity to ionic environment and insensitivity to temperature indicate that NF-kappaB p50/p65 heterodimers form complexes with specific DNA in an entropically driven manner.     

Analysis of p53 "latency" and "activation" by fluorescence correlation spectroscopy. Evidence for different modes of high affinity DNA binding

The concept that the tumor suppressor p53 is a latent DNA-binding protein that must become activated for sequence-specific DNA binding recently has been challenged, although the "activation" phenomenon has been well established in in vitro DNA binding assays. Using electrophoretic mobility shift assays and fluorescence correlation spectroscopy, we analyzed the binding of "latent" and "activated" p53 to double-stranded DNA oligonucleotides containing or not containing a p53 consensus binding site (DNAspec or DNAunspec, respectively). In the absence of competitor DNA, latent p53 bound DNAspec and DNAunspec with high affinity in a sequence-independent manner. Activation of p53 by the addition of the C-terminal antibody PAb421 significantly decreased the binding affinity for DNAunspec and concomitantly increased the binding affinity for DNAspec. The net result of this dual effect is a significant difference in the affinity of activated p53 for DNAspec and DNAunspec, which explains the activation of p53. High affinity nonspecific DNA binding of latent p53 required both the p53 core domain and the p53 C terminus, whereas high affinity sequence-specific DNA binding of activated p53 was mediated by the p53 core domain alone. The data suggest that high affinity nonspecific DNA binding of latent and high affinity sequence-specific binding of activated p53 to double-stranded DNA differ in their requirement for the C terminus and involve different structural features of the core domain. Because high affinity nonspecific DNA binding of latent p53 is restricted to wild type p53, we propose that it relates to its tumor suppressor functions.     

Insights on the acetylated NF-κB transcription factor complex with DNA from molecular dynamics simulations

The nuclear factor-κB (NF-κB) is a DNA sequence-specific regulator of many important biological processes, whose activity is modulated by enzymatic acetylation. In one of the best functionally characterized NF-κB complexes, the p50/p65 heterodimer, acetylation of K221 at p65 causes a decrease of DNA dissociation rate, whilst the acetylation of K122 and K123, also at p65, markedly decreases the binding affinity for DNA. By means of molecular dynamics simulations based on the X-ray structure of the p50/p65 complex with DNA, we provide insights on the structural determinants of the acetylated complexes in aqueous solution. Lysine acetylation involves the loss of favorable electrostatic interactions between DNA and NF-κB, which is partially compensated by the reduction of the desolvation free-energy of the two binding partners. Acetylation at both positions K122 and K123 is associated with a decrease of the electrostatic potential at the p65/DNA interface, which is only partially counterbalanced by an increase of the local Na(+) concentration. It induces the disruption of base-specific and nonspecific interactions between DNA and NF-κB and it is consistent with the observed decrease of binding affinity. In contrast, acetylation at position K221 results in the loss of nonspecific protein-DNA interactions, but the DNA recognition sites are not affected. In addition, the loss of protein-DNA interactions is likely to be counterbalanced by an increase of the configurational entropy of the complex, which provides, at a speculative level, a justification for the observed decrease of NF-κB/DNA dissociation rate.     

Mutations in DNA Binding and Transactivation Domains Affect the Dynamics of Parvovirus NS1 Protein

The multifunctional replication protein of autonomous parvoviruses, NS1, is vital for viral genome replication and for the control of viral protein production. Two DNA-interacting domains of NS1, the N-terminal and helicase domains, are necessary for these functions. In addition, the N and C termini of NS1 are required for activation of viral promoter P38. By comparison with the structural and biochemical data from other parvoviruses, we identified potential DNA-interacting amino acid residues from canine parvovirus NS1. The role of the identified amino acids in NS1 binding dynamics was studied by mutagenesis, fluorescence recovery after photobleaching, and computer simulations. Mutations in the predicted DNA-interacting amino acids of the N-terminal and helicase domains increased the intranuclear binding dynamics of NS1 dramatically. A substantial increase in binding dynamics was also observed for NS1 mutants that targeted the metal ion coordination site in the N terminus. Interestingly, contrary to other mutants, deletion of the C terminus resulted in slower binding dynamics of NS1. P38 transactivation was severely reduced in both N-terminal DNA recognition and in C-terminal deletion mutants. These data suggest that the intranuclear dynamics of NS1 are largely characterized by its sequence-specific and -nonspecific binding to double-stranded DNA. Moreover, binding of NS1 is equally dependent on the N-terminal domain and conserved β-loop of the helicase domain.     

Role of cysteine62 in DNA recognition by the P50 subunit of NF-kappa B.

A powerful chemical modification procedure has been developed to define determinants of DNA recognition by the p50 subunit of NF-kappa B. Differential labelling with [14C] iodoacetate has identified a conserved cysteine residue, Cys62, that was protected from modification by the presence of an oligonucleotide containing the specific recognition site of the protein. To determine the importance of this cysteine residue, each of the conserved cysteines in p50 was changed to serine and the DNA binding properties of the mutant proteins determined. Scatchard analysis indicated that the C62S mutant bound to its DNA recognition site with a 10-fold larger dissociation constant than the wild type protein, while the other two mutants bound with an intermediate affinity. Dissociation rate constant measurements correlated well with the dissociation constants for the wild type, C119S, and C273S p50 proteins, whereas the p50 C62S-DNA complex dissociated anomalously quickly. Competition analyses with oligonucleotide variants of the DNA recognition site and nonspecific E. coli DNA revealed that the C62S p50 mutant had an altered DNA binding site specificity and was impaired in its ability to discriminate between specific and non-specific DNA. Thus the sulphydryl group of Cys62 is an important determinant of DNA recognition by the p50 subunit of NF-kappa B.