Leucine-rich hydrophobic clusters promote folding of the N-terminus of the intrinsically disordered transactivation domain of p53

Molecular dynamics simulations have been performed on the intrinsically disordered 39-residue N-terminal transactivation domain of p53 (p53_1-39). Simulations not only revealed that p53_1-39 is natively compact, but also possesses a folded structure. Furthermore, leucine-rich hydrophobic clusters were found to play a crucial role in the formation and stabilization of the folded structure of p53_1-39. Collapsing in the sub-microsecond timescale might allow for rapid conformational turnovers of p53_1-39, necessary for its efficient transactivation activity and modulation. Fast collapsing might be the result of unique conformational landscapes, featuring several energy minima separated by small energy barriers. It is suggested that IDPs with highly specialized functions in the cell, such as transactivation, possibly display more ordered patterns than their less specialized counterparts.     

Insights into the dynamic interactions at chemokine-receptor interfaces and mechanistic models of chemokine binding

Chemokine receptors are the central signaling hubs of several processes such as cell migration, chemotaxis and cell positioning. In this graphical review, we provide an overview of the structural and mechanistic principles governing chemokine recognition that are currently emerging. Structural models of chemokine-receptor co-complexes with endogenous chemokines, viral chemokines and therapeutics have been resolved that highlight multiple interaction sites, termed as CRS1, CRS1.5 etc. The first site of interaction has been shown to be the N-terminal domain of the receptors (CRS1 site). A large structural flexibility of the N-terminal domain has been reported that was supported by both experimental and simulation studies. Upon chemokine binding, the N-terminal domain appears to show constricted dynamics and opens up to interact with the chemokine via a large interface. The subsequent sites such as CRS1.5 and CRS2 sites have been structurally well resolved although differences arise such as the localization of the N-terminus of the ligand to a major or minor pocket of the orthosteric binding site. Several computational studies have highlighted the dynamic protein-protein interface at the CRS1 site that seemingly appears to resolve the differences in NMR and mutagenesis studies. Interestingly, the differential dynamics at the CRS1 site suggests a mixed model of binding with complex signatures of both conformational selection and induced fit models. Integrative experimental and computational approaches could help unravel the structural basis of promiscuity and specificity in chemokine-receptor binding and open up new avenues of therapeutic design.     

How phosphorylation activates the protein phosphatase-1 • inhibitor-2 complex

Phosphorylation regulates activity of many proteins; however, atomic level details are known for very few examples. Inhibitor-2 (I2) squelches the ubiquitous protein phosphatase-1 (PP1) enzyme activity by blocking access to the metal-containing active site. I2 Thr74 phosphorylation results in PP1 activation without I2 dissociation from the PP1–I2 complex. The dynamic disordered structure of the 73-residue segment of I2 containing Thr74, prevented visualization by X-ray crystallography of PP1–I2. In this work, I generated structures of this segment using simulated annealing to NMR restraints, fused them to the crystallographic PP1–I2 coordinates, and used molecular dynamics to study the impact of Thr74 phosphorylation on structural alterations leading to PP1 activation. Frequencies of I2 Tyr149 displacement from the PP1 active site, rotation of the phenolic Tyr149 side chain to prevent its reinsertion, and repositioning the I2 inhibitory helix to expose the PP1 active site to solvent and substrates significantly increased upon I2 Thr74 phosphorylation. After these steps, a second metal bound to produce PP1–Mn₂–I2, which held the phosphorylated form of I2 to its active site less tightly than it held dephosphorylated I2. I2 Thr74 lies on the edge of variable dynamic communities of residues where it forms various allosteric pathways that induce motions at the PP1 active site 20 Å away. These molecular dynamics simulations show how an unstructured region of I2 can harness enhanced rapid movements around phosphorylated Thr74 to pry I2 residues away from the PP1 active site in early steps of PP1–I2 activation.     

1H, 13C, and 15N resonance assignment of the cAMP-regulated phosphoprotein endosulfine-alpha in free and micelle-bound states

¹³C, ¹⁵N, and ¹H chemical shift assignments are presented for the cAMP-regulated phosphoprotein endosulfine-alpha in its free and micelle-bound states. Secondary chemical shift analysis demonstrates formation of four helices in the micelle-bound state, which are not present in the absence of detergent.     

Structural and functional analysis of the Josephin domain of the polyglutamine protein ataxin-3

Ataxin-3 belongs to the family of polyglutamine proteins, which are associated with nine different neurodegenerative disorders. Relatively little is known about the structural and functional properties of ataxin-3, and only recently have these aspects of the protein begun to be explored. We have performed a preliminary investigation into the conserved N-terminal domain of ataxin-3, termed Josephin. We show that Josephin is a monomeric domain which folds into a globular conformation and possesses ubiquitin protease activity. In addition, we demonstrate that the presence of the polyglutamine region of the protein does not alter the structure of the protein. However, its presence destabilizes the Josephin domain. The implications of these data in the pathogenesis of polyglutamine repeat proteins are discussed.     

Affinity maturation of a computationally designed binding protein affords a functional but disordered polypeptide

Computational methods have been recently applied to the design of protein–protein interfaces. Using this approach, a 61 amino acid long protein called Spider Roll was engineered to recognize the kinase domain of the human p21-activated kinase 1 (PAK1) with good specificity but modest affinity (K_D = 100 μM). Here we show that this artificial protein can be optimized by yeast surface display and fluorescence-activated cell sorting. After three rounds of mutagenesis and screening, a diverse set of tighter binding variants was obtained. A representative binder, MSR7, has a >10²-fold higher affinity for PAK1 when displayed on yeast and a 6 to 11-fold advantage when produced free in solution. In contrast to the starting Spider Roll protein, however, MSR7 unexpectedly exhibits characteristics typical of partially disordered proteins, including lower α-helical content, non-cooperative thermal denaturation, and NMR data showing peak broadening and poor signal dispersion. Although conformational disorder is increasingly recognized as an important property of proteins involved in cellular signaling and regulation, it is poorly modeled by current computational methods. Explicit consideration of structural flexibility may improve future protein designs and provide deeper insight into molecular events at protein–protein interfaces.     

Thermodynamics and kinetics of non-native interactions in protein folding: a single point mutant significantly stabilizes the N-terminal domain of L9 by modulating non-native interactions in the denatured state

Comparatively little is known about the role of non-native interactions in protein folding and their role in both folding and stability is controversial. We demonstrate that non-native electrostatic interactions involving specific residues in the denatured state can have a significant effect upon protein stability and can persist in the transition state for folding. Mutation of a single surface exposed residue, Lys12 to Met, in the N-terminal domain of the ribosomal protein L9 (NTL9), significantly increased the stability of the protein and led to faster folding. Structural and energetic studies of the wild-type and K12M mutant show that the 1.9 kcal mol(-1) increase in stability is not due to native state effects, but rather is caused by modulation of specific non-native electrostatic interactions in the denatured state. pH dependent stability measurements confirm that the increased stability of the K12M is due to the elimination of favorable non-native interactions in the denatured state. Kinetic studies show that the non-native electrostatic interactions involving K12 persist in the transition state. The analysis demonstrates that canonical Phi-values can arise from the disruption of non-native interactions as well as from the development of native interactions.     

Folded-unfolded cross-predictions and protein evolution: The case study of coiled-coils

Here we report a thorough analysis of cross-predictions between coiled-coil and disordered protein segments using various prediction algorithms for both sequence classes. Coiled-coils are often predicted to be unstructured, consistent with their obligate multimeric nature, whereas reverse cross-predictions are rare due to the regularity of coiled-coil sequences. We propose the simultaneous use of the programs Coils and IUPred to achieve acceptable prediction accuracy and minimize the extent of cross-predictions. The relevance of observed cross-predictions might be that disordered sequences can adopt coiled-coil conformation relatively easily during protein evolution.     

Intrinsic disorder of Drosophila melanogaster hormone receptor 38 N-terminal domain

Drosophila hormone receptor 38 (dHR38), an ortholog of the vertebrate NR4A subclass of nuclear receptors, responds to ecdysteroids, which mediate developmental transitions during the Drosophila life cycle. However, this response is independent of the ecdysteroid receptor, and it does not involve binding of ecdysteroids to dHR38. It has been suggested that ecdysteroids may indirectly activate dHR38, perhaps by recruiting specific proteins. There have been recent reports pointing out the decisive role that nuclear receptor N-terminal domains (NTDs) have in protein-protein interactions that are important for regulation of gene expression. It is reasonable to assume that dHR38-NTD may also be involved in some protein-protein interactions that are critical for the ecdysteroid signaling pathway. To facilitate the exploration of the molecular basis of these interactions, we developed and optimized a protocol for the efficient expression and purification of the recombinant dHR38-NTD. Using a diverse array of biochemical and biophysical methods, we carried out the first structural characterization of dHR38-NTD. The results of our study indicate that dHR38-NTD exhibits a characteristic reminiscent of pre-molten globule-like intrinsically disordered proteins existing in a partially unfolded conformation with regions of secondary structures. The dHR38-NTD structure, which apparently comprises some local, ordered, tertiary structure clusters, is pliable and can adopt more ordered conformations in response to changes in environmental conditions. Thus, dHR38-NTD, which exhibits the structural and functional characteristic of a pre-molten globule-like intrinsically disordered protein, could serve as a platform for multiple protein-protein interactions, possibly including interactions with proteins involved in an unusual ecdysteroid signaling pathway.     

Structural and functional studies on the N-terminal domain of the Shigella type III secretion protein MxiG

MxiG is a single-pass membrane protein that oligomerizes within the inner membrane ring of the Shigella flexneri type III secretion system (T3SS). The MxiG N-terminal domain (MxiG-N) is the predominant cytoplasmic structure; however, its role in T3SS assembly and secretion is largely uncharacterized. We have determined the solution structure of MxiG-N residues 6-112 (MxiG-N(6-112)), representing the first published structure of this T3SS domain. The structure shows strong structural homology to forkhead-associated (FHA) domains. Canonically, these cell-signaling modules bind phosphothreonine (Thr(P)) via highly conserved residues. However, the putative phosphate-binding pocket of MxiG-N(6-112) does not align with other FHA domain structures or interact with Thr(P). Furthermore, mutagenesis of potential phosphate-binding residues has no effect on S. flexneri T3SS assembly and function. Therefore, MxiG-N has a novel function for an FHA domain. Positioning of MxiG-N(6-112) within the EM density of the S. flexneri needle complex gives insight into the ambiguous stoichiometry of the T3SS, supporting models with 24 MxiG subunits in the inner membrane ring.     

A maize FK506-sensitive immunophilin, mzFKBP-66, is a peptidylproline cis-trans-isomerase that interacts with calmodulin and a 36-kDa cytoplasmic protein

A member of a eukaryotic gene superfamily, encoding a peptidylproline cis-trans-isomerase (rotamase) has been isolated from a maize (Zea mays L. A69Y+) endosperm cDNA library. The maize sequence (mzFKBP-66) encodes a 66-kDa polypeptide most closely related to the subclass of rotamases which bind an immunosuppressive drug, FK506, (termed FK506-binding proteins, FKBPs), and possesses four tandem copies of the FKBP-like binding domain. The sequence mzFKBP-66 is expressed ubiquitously in the maize plant, and the protein encoded is present in both cytosolic and nuclear compartments within the cell. Both the native mzFKBP-66 and a recombinant protein overexpressed in Escherichia coli showed peptidylproline␣cis-trans-isomerase (PPIase) activity at rates comparable to those reported for mammalian immunophilins. This activity was also sensitive to inhibition by FK506. Immunoaffinity chromatography using anti-mzFKBP66 demonstrated an association of the protein with an unknown 36-kDa polypeptide, and affinity chromatography of mzFKBP-66 on calmodulin-agarose beads indicated the presence of a calmodulin-binding site. The existence of mzFKBP-66-associated proteins suggests that plant immunophilins may act as part of multicomponent complexes, as has been shown for other representatives of this class of enzyme. Received: 9 June 1997 / Accepted: 19 August 1997     

Steroid hormone biotransformation and xenobiotic induction of hepatic steroid metabolizing enzymes

Normal reproductive development depends on the interplay of steroid hormones with their receptors at specific tissue sites. The concentrations of hormone ligands in the circulation and at target sites are maintained through coordinated regulation on steroid biosynthesis and degradation. Changed bioavailability of steroids, through alteration of steroidogenesis or biotransformation rates, leads to changes in endocrine function. Steroid hormones lose their receptor reactivity in most cases when they are bound to binding proteins, while metabolic conversion can result in either active or inactive metabolites. Hydroxylation by cytochrome P450 (CYP) enzymes and conjugation with glucuronide and sulfate are among the major hepatic pathways of steroid inactivation. The expression of these biotransformation enzymes can be induced by many xenobiotics. The barbiturate phenobarbital and the environmental toxicant 1,1-dichloro-2,2-bis(p-chlorophenyl)ethylene (DDE) are among the well characterized inducers for the CYP 2B and 3A enzymes and selected conjugation enzymes. The induction of the steroid biotransformation enzymes is partly mediated through the activation of a group of nuclear receptors including the glucocorticoid receptor, the constitutive androstane receptor (CAR), the pregnane X receptor (PXR), and the peroxisome proliferator activated receptors (PPAR). Drug or chemical-induced increases in hepatic enzyme activities are often a basis for drug-drug interactions that lead to enhanced elimination and reduced therapeutic efficacy of steroidal drugs. The effects of enzyme induction on endogenous steroid clearance, along with its possible consequence, are less well understood. While enzyme induction by xenobiotics may increase clearance of the endogenous steroid, regulatory mechanisms for steroid homeostasis may adapt and compensate for altered clearance.