Secondary structure and dynamics of an intrinsically unstructured linker domain.

The transient secondary structure and dynamics of an intrinsically unstructured linker domain from the 70 kDa subunit of human replication protein A was investigated using solution state NMR. Stable secondary structure, inferred from large secondary chemical shifts, was observed for a segment of the intrinsically unstructured linker domain when it is attached to an N-terminal protein interaction domain. Results from NMR relaxation experiments showed the rotational diffusion for this segment of the intrinsically unstructured linker domain to be correlated with the N-terminal protein interaction domain. When the N-terminal domain is removed, the stable secondary structure is lost and faster rotational diffusion is observed. The large secondary chemical shifts were used to calculate phi and psi dihedral angles and these dihedral angles were used to build a backbone structural model. Restrained molecular dynamics were performed on this new structure using the chemical shift based dihedral angles and a single NOE distance as restraints. In the resulting family of structures a large, solvent exposed loop was observed for the segment of the intrinsically unstructured linker domain that had large secondary chemical shifts.

NMR chemical shift and relaxation measurements provide evidence for the coupled folding and binding of the p53 transactivation domain.

The interaction between the acidic transactivation domain of the human tumor suppressor protein p53 (p53TAD) and the 70 kDa subunit of human replication protein A (hRPA70) was investigated using heteronuclear magnetic resonance spectroscopy. A 1H-15N heteronuclear single quantum coherence (HSQC) titration experiment was performed on a 15N-labeled fragment of hRPA70, containing the N-terminal 168 residues (hRPA701-168) and p53TAD. HRPA701-168 residues important for binding were identified and found to be localized to a prominent basic cleft. This binding site overlapped with a previously identified single-stranded DNA-binding site, suggesting that a competitive binding mechanism may regulate the formation of p53TAD-hRPA70 complex. The amide 1H and 15N chemical shifts of an uniformly 15N-labeled sample of p53TAD were also monitored before and after the addition of unlabeled hRPA701-168. In the presence of unlabeled hRPA701-168, resonance lineshapes increased and corresponding intensity reductions were observed for specific p53TAD residues. The largest intensity reductions were observed for p53TAD residues 42-56. Minimal binding was observed between p53TAD and a mutant form of hRPA701-168, where the basic cleft residue R41 was changed to a glutamic acid (R41E), demonstrating that ionic interactions play an important role in specifying the binding interface. The region of p53TAD most affected by binding hRPA701-168 was found to have some residual alpha helical and beta strand structure; however, this structure was not stabilized by binding hRPA701-168. 15N relaxation experiments were performed to monitor changes in backbone dynamics of p53TAD when bound to hRPA701-168. Large changes in both the transverse (R2) and rotating frame (R1) relaxation rates were observed for a subset of the p53TAD residues that had 1H-15N HSQC resonance intensity reductions during the complex formation. The folding of p53TAD upon complex formation is suggested by the pattern of changes observed for both R2 and R1. A model that couples the formation of a weak encounter complex between p53TAD and hRPA701-168 to the folding of p53TAD is discussed in the context of a functional role for the p53-hRPA70 complex in DNA repair.

Reduced spectral density mapping of a partially folded fragment of E. coli thioredoxin.

The backbone dynamics of a partially folded, N-terminal fragment of E. coli thioredoxin were investigated using nuclear magnetic resonance spectroscopy (NMR). Relaxation data were collected at three temperatures and analyzed using reduced spectral density mapping. As temperature was increased, the values for the viscosity normalized J(0) and for J(omegaH) increased, while J(omegaN) decreased. The global trend observed for the viscosity normalized J(0) was consistent with an increase in the hydrodynamic volume of the fragment and suggested the presence of correlated rotational motion in the absence of long range interactions. In addition, the residue specific variation observed for the viscosity normalized J(0) suggested contributions to J(omega) from a range of correlation times that are close to the global correlation time.

Stable isotope labeling of a Group A Streptococcus virulence factor using a chemically defined growth medium.

A secreted, hypervariable virulence factor called the streptococcal inhibitor of complement (Sic) has been linked to the reemergence of epidemics due to the human pathogenic bacterium Group A Streptococcus. This paper describes a method for expressing and purifying Sic from an attenuated GAS strain using a chemically defined growth medium. This method was used to label specific amino acid residue types in Sic with forms containing the magnetically active isotope (15)N, at the amide nitrogen. The (15)N-labeling of Sic permits a detailed investigation of the structure and dynamics of the protein using nuclear magnetic resonance spectroscopy. The level of stable isotope incorporation was established using mass spectrometry and nuclear magnetic resonance spectroscopy.