David F. Lowry

Solution structure of the C-terminal X domain of the measles virus phosphoprotein and interaction with the intrinsically disordered C-terminal domain of the nucleoprotein

In this report, the solution structure of the nucleocapsid‐binding domain of the measles virus phosphoprotein (XD, aa 459–507) is described. A dynamic description of the interaction between XD and the disordered C‐terminal domain of the nucleocapsid protein, (NTAIL, aa 401–525), is also presented. XD is an all α protein consisting of a three‐helix bundle with an up‐down‐up arrangement of the helices. The solution structure of XD is very similar to the crystal structures of both the free and bound form of XD. One exception is the presence of a highly dynamic loop encompassing XD residues 489–491, which is involved in the embedding of the α‐helical XD‐binding region of NTAIL. Secondary chemical shift values for full‐length NTAIL were used to define the precise boundaries of a transient helical segment that coincides with the XD‐binding domain, thus shedding light on the pre‐recognition state of NTAIL. Titration experiments with unlabeled XD showed that the transient α‐helical conformation of NTAIL is stabilized upon binding. Lineshape analysis of NMR resonances revealed that residues 483–506 of NTAIL are in intermediate exchange with XD, while the 475–482 and 507–525 regions are in fast exchange. The NTAIL resonance behavior in the titration experiments is consistent with a complex binding model with more than two states. Copyright

Modeling the accessible conformations of the intrinsically unstructured transactivation domain of p53.

Internuclear distances derived from paramagnetic relaxation enhancement (PRE) data were used to restrain molecular dynamics simulations of the intrinsically unstructured transactivation domain of the tumor suppressor protein, p53. About 1000 structures were simulated using ensemble averaging of replicate molecules to compensate for the inherent bias in the PRE‐derived distances. Gyration radii measurements on these structures show that the p53 transactivation domain (p53TAD) is statistically predominantly in a partially collapsed state that is unlike the open structure that is found for p53TAD bound to either the E3 ubiquitin ligase, MDM2, or the 70 kDa subunit of replication protein A, RPA70. Contact regions that potentially mediate the collapse were identified and found to consist of mostly hydrophobic residues. The identified contact regions preferentially place the MDM2 and RPA70 binding regions in close proximity. We show that our simulations thoroughly sample the available range of conformations and that a fraction of the molecules are in an open state that would be competent for binding either MDM2 or RPA70. We also show that the Stokes radius estimated from the average gyration radius of the ensemble is in good agreement with the value determined using size exclusion chromatography. Finally, the presence of a persistent loop localized to a PXP motif was identified. Serine residues flanking the PXP motif become phosphorylated in response to DNA damage, and we postulate that this will perturb the equilibrium population to more open conformations. Proteins 2008.

Identifying long-range structure in the intrinsically unstructured transactivation domain of p53

Paramagnetic relaxation enhancement (PRE) was used to identify a compact dynamic structure for the intrinsically unstructured transactivation domain of the tumor suppressor protein, p53. Our results show that p53 residues essential for binding to the ubiquitin ligase, MDM2, and the 70 kDa subunit of replication protein A, RPA70, are separated by an average distance of 10–15 Å. This result suggests that a more extended member of the ensemble must be populated prior to binding either MDM2 or RPA70. We also show that PRE can be used to detect intermolecular distances between p53 and RPA70. Proteins 2007.

Investigation of the role of the histidine-aspartate pair in the human exonuclease III-like abasic endonuclease, Ape1

Hydrogen bonded histidine-aspartate (His-Asp) pairs are critical constituents in several key enzymatic reactions. To date, the role that these pairs play in catalysis is best understood in serine and trypsin-like proteases, where structural and biochemical NMR studies have revealed important pK(a) values and hydrogen bonding patterns within the catalytic pocket. However, the role of the His-Asp pair in metal-assisted catalysis is less clear. Here, we apply liquid-state NMR to investigate the role of a critical histidine residue of apurinic endonuclease 1 (Ape1), a human DNA repair enzyme that cleaves adjacent to abasic sites in DNA using one or more divalent cations and an active-site His-Asp pair. The results of these studies suggest that the Ape1 His-Asp pair does not function as either a general base catalyst or a metal ligand. Rather, the pair likely stabilizes the pentavalent transition state necessary for phospho-transfer.

Secondary Structure and Dynamics of an Intrinsically Unstructured Linker Domain

Abstract 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 psidihedral 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.

Helix A Stabilization Precedes Amino-Terminal Lobe Activation upon Calcium Binding to Calmodulin†

The structural coupling between opposing domains of CaM was investigated using the conformationally sensitive biarsenical probe 4,5-bis(1,3,2-dithioarsolan-2-yl)resorufin (ReAsH), which upon binding to an engineered tetracysteine motif near the end of helix A (Thr-5 to Phe-19) becomes highly fluorescent. Changes in conformation and dynamics are reflective of the native CaM structure, as there is no change in the (1)H- (15)N HSQC NMR spectrum in comparison to wild-type CaM. We find evidence of a conformational intermediate associated with CaM activation, where calcium occupancy of sites in the amino-terminal and carboxyl-terminal lobes of CaM differentially affect the fluorescence intensity of bound ReAsH. Insight into the structure of the conformational intermediate is possible from a consideration of calcium-dependent changes in rates of ReAsH binding and helix A mobility, which respectively distinguish secondary structural changes associated with helix A stabilization from the tertiary structural reorganization of the amino-terminal lobe of CaM necessary for high-affinity binding to target proteins. Helix A stabilization is associated with calcium occupancy of sites in the carboxyl-terminal lobe ( K d = 0.36 +/- 0.04 microM), which results in a reduction in the rate of ReAsH binding from 4900 M (-1) s (-1) to 370 M (-1) s (-1). In comparison, tertiary structural changes involving helix A and other structural elements in the amino-terminal lobe require calcium occupancy of amino-terminal sites (K d = 18 +/- 3 microM). Observed secondary and tertiary structural changes involving helix A in response to the sequential calcium occupancy of carboxyl- and amino-terminal lobe calcium binding sites suggest an important involvement of helix A in mediating the structural coupling between the opposing domains of CaM. These results are discussed in terms of a model in which carboxyl-terminal lobe calcium activation induces secondary structural changes within the interdomain linker that release helix A, thereby facilitating the formation of calcium binding sites in the amino-terminal lobe and linked tertiary structural rearrangements to form a high-affinity binding cleft that can associate with target proteins.

A robust approach for analyzing a heterogeneous structural ensemble.

Intrinsically unstructured proteins (IUP) are widespread in eukaryotes and participate in numerous cellular processes, but a structural explanation of the mechanisms they use to recognize and bind their diverse targets has proved elusive. Transcriptional activator domains are one class of IUP that function by recruiting other factors into basal transcription complexes. Transcriptional activator domains are known to use electrostatic interactions for recognition, but it is unclear how this could be accomplished by a structurally heterogeneous ensemble. To investigate this question, we performed principal component analysis on the atomic contact maps of an experimentally restrained ensemble of the human p53 transcriptional activator domain. This analysis revealed that the ensemble is conspicuously nonrandom and permitted a straightforward identification of persistent structural features and their relative probabilities. It was observed that six predominant long‐range contacts are combinatorially arranged in 13 clusters of structures. Potential surfaces of the aligned clusters showed that these contacts uniformly organize the negative charges of the highly acidic p53 transcriptional activator domain on one face of the clusters. This observation provides a structural basis for the recruitment of other factors into basal transcription complexes and further supports the hypothesis that the structural ensembles of IUPs are not random and instead have evolved under selection to maintain specific structural features. Proteins 2008.

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

Abstract 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(ωH) increased, while J(ωN) 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(ω) from a range of correlation times that are close to the global correlation time.