NMR structure of the Escherichia coli type 1 pilus subunit FimF and its interactions with other pilus subunits

Type 1 pili from uropathogenic Escherichia coli strains mediate bacterial attachment to target receptors on the host tissue. They are composed of up to 3000 copies of the subunit FimA, which form the stiff, helical pilus rod, and the subunits FimF, FimG, and FimH, which form the linear tip fibrillum. All subunits in the pilus interact via donor strand complementation, in which the incomplete immunoglobulin-like fold of each subunit is complemented by insertion of an N-terminal extension from the following subunit. We determined the NMR structure of a monomeric, self-complemented variant of FimF, FimF_F, which has a second FimF donor strand segment fused to its C-terminus that enables intramolecular complementation of the FimF fold. NMR studies on bimolecular complexes between FimF_F and donor strand-depleted variants of FimF and FimG revealed that the relative orientations of neighboring domains in the tip fibrillum cover a wide range. The data provide strong support for the intrinsic flexibility of the tip fibrillum. They lend further support to the hypothesis that this flexibility would significantly increase the probability that the adhesin at the distal end of the fibrillum successfully targets host cell receptors.     

The Switch that Does Not Flip: The Blue-Light Receptor YtvA from Bacillus subtilis Adopts an Elongated Dimer Conformation Independent of the Activation State as Revealed by a Combined AUC and SAXS Study

Photoreceptors play an important role in plants and bacteria by converting extracellular stimuli into intracellular signals. One distinct class are the blue-light-sensitive phototropins harboring a light-oxygen-voltage (LOV) domain coupled to various effector domains. Photon absorption by the chromophore within the LOV domain results in an activation of the output domain via mechanisms that are hitherto not well understood. The photoreceptor YtvA from Bacillus subtilis is a bacterial analog of phototropins, consists of an LOV and a sulfate transporter/anti-sigma factor antagonist domain, and is involved in the response of the bacterium to environmental stress. We present here analytical ultracentrifugation studies and small-angle X-ray scattering experiments, showing that YtvA is a dimer. On the basis of these results, we present a low-resolution model of the dimer in the dark and the lit state of the protein. In addition, we show that YtvA does not change its oligomerization state or its overall shape upon light activation.     

Posttranslational Modifications Affect the Interaction of S100 Proteins with Tumor Suppressor p53

Proteins of the S100 family bind to the intrinsically disordered transactivation domain (TAD; residues 1-57) and C-terminus (residues 293-393) of the tumor suppressor p53. Both regions provide sites that are subject to posttranslational modifications, such as phosphorylation and acetylation, that can alter the affinity for interacting proteins such as p300 and MDM2. Here, we found that S100A1, S100A2, S100A4, S100A6, and S100B bound to two subdomains of the TAD (TAD1 and TAD2). Both subdomains were mandatory for high-affinity binding to S100 proteins. Phosphorylation of Ser and Thr residues increased the affinity for the p53 TAD. Conversely, acetylation and phosphorylation of the C-terminus of p53 decreased the affinity for S100A2 and S100B. In contrast, we found that nitrosylation of S100B caused a minor increase in binding to the p53 C-terminus, whereas binding to the TAD remained unaffected. As activation of p53 is usually accompanied by phosphorylation and acetylation at several sites, our results suggest that a shift in binding from the C-terminus in favor of the N-terminus occurs upon the modification of p53. We propose that binding to the p53 TAD might be involved in the stimulation of p53 activity by S100 proteins.     

Evidence for dynamic interplay of different oligomeric states of UDP-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase by biophysical methods

The bifunctional enzyme UDP-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase (GNE) is a key enzyme for the biosynthesis of sialic acids, the terminal sugars of glycoconjugates associated with a variety of physiological and pathological processes such as cell adhesion, development, inflammation and cancer. In this study, we characterized rat GNE by different biophysical methods, analytical ultracentrifugation, dynamic light-scattering and size-exclusion chromatography, all revealing the native hydrodynamic behavior and molar mass of the protein. We show that GNE is able to reversibly self-associate into different oligomeric states including monomers, dimers and tetramers. Additionally, it forms non-specific aggregates of high molecular mass, which cannot be unequivocally assigned a distinct size. Our results also indicate that ligands of the epimerase domain of the bifunctional enzyme, namely UDP-N-acetylglucosamine and CMP-N-acetylneuraminic acid, stabilize the protein against aggregation and are capable of modulating the quaternary structure of the protein. The presence of UDP-N-acetylglucosamine strongly favors the tetrameric state, which therefore likely represents the active state of the enzyme in cells.     

The Baseplate Wedges of Bacteriophage T4 Spontaneously Assemble into Hubless Baseplate-Like Structure In Vitro

The baseplate of phage T4 is an important model system in viral supramolecular assembly. The baseplate consists of six wedges surrounding the central hub. We report the first successful attempt at complete wedge assembly using an in vitro approach based on recombinant proteins. The cells expressing the individual wedge proteins were mixed in a combinatorial manner and then lysed. Using this approach, we could both reliably isolate the complete wedge along with a series of intermediate complexes as well as determine the exact sequence of assembly. The individual proteins and intermediate complexes at each step of the wedge assembly were successfully purified and characterized by sedimentation velocity and electron microscopy. Although our results mostly confirmed the hypothesized sequential wedge assembly pathway as established using phage mutants, interestingly, we also detected some protein interactions not following the specified order. It was found that association of gene product 53 to the immediate precursor complex induces spontaneous association of the wedges to form a six-fold star-shaped baseplate-like structure in the absence of the hub. The formation of the baseplate-like structure was facilitated by the addition of gene product 25. The complete wedge in the star-shaped supramolecular complex has a structure similar to the baseplate in the expanded “star” conformation found after infection. Based on the results of the present and previous studies, we assume that the strict order of wedge assembly is due to the induced conformational change caused by every new binding event. The significance of a 40-S star-shaped baseplate structure, which was previously reported and was also found in this study, is discussed in the light of a new paradigm for T4 baseplate assembly involving the star-shaped wedge ring and the central hub. Importantly, the methods described in this article suggest a novel methodology for future structural characterization of supramolecular protein assemblies.     

Dynamic Interactions between Clathrin and Locally Structured Elements in a Disordered Protein Mediate Clathrin Lattice Assembly

Assembly of clathrin lattices is mediated by assembly/adaptor proteins that contain domains that bind lipids or membrane-bound cargo proteins and clathrin binding domains (CBDs) that recruit clathrin. Here, we characterize the interaction between clathrin and a large fragment of the CBD of the clathrin assembly protein AP180. Mutational, NMR chemical shift, and analytical ultracentrifugation analyses allowed us to precisely define two clathrin binding sites within this fragment, each of which is found to bind weakly to the N-terminal domain of the clathrin heavy chain (TD). The locations of the two clathrin binding sites are consistent with predictions from sequence alignments of previously identified clathrin binding elements and, by extension, indicate that the complete AP180 CBD contains ∼ 12 degenerate repeats, each containing a single clathrin binding site. Sequence and circular dichroism analyses have indicated that the AP180 CBD is predominantly unstructured and our NMR analyses confirm that this is largely the case for the AP180 fragment characterized here. Unexpectedly, unlike the many proteins that undergo binding-coupled folding upon interaction with their binding partners, the AP180 fragment is similarly unstructured in its bound and free states. Instead, we find that this fragment exhibits localized β-turn-like structures at the two clathrin binding sites both when free and when bound to clathrin. These observations are incorporated into a model in which weak binding by multiple, pre-structured clathrin binding elements regularly dispersed throughout a largely unstructured CBD allows efficient recruitment of clathrin to endocytic sites and dynamic assembly of the clathrin lattice.     

Structural Characterization of the Natively Unfolded N-Terminal Domain of Human c-Src Kinase: Insights into the Role of Phosphorylation of the Unique Domain

The N-terminal regions of the members of Src family of non-receptor protein tyrosine kinases are intrinsically unfolded and contain the maximum sequence divergence among them. In this study, we have addressed the structural characterization by nuclear magnetic resonance of this region of 84 residues that encompasses the SH4 and the unique domains (USrc) of the human c-Src. With this aim, the backbone assignment was performed using ¹³C-detected experiments that overcome the spectral resolution problems and the large number of prolines that are typical for intrinsically unfolded proteins. The analysis of the residual dipolar couplings measured for the USrc indicates the presence of a low populated helical structure in the 60-75 region. No long-range contacts between remote fragments of the chain were detected with paramagnetic relaxation enhancement experiments. The structural characterization was extended to two different phosphorylation states of USrc that encompassed three different phosphorylated sites, Ser17, Thr37, and Ser75. The structural and conformational changes upon phosphorylation were monitored through chemical shift perturbations and residual dipolar couplings, indicating that modifications occur at local level and no global rearrangements were apparent. These results suggest a scenario where phosphorylation induces a global electrostatic perturbation that could be involved in the membrane unbinding of c-Src and that could be related with the localization of the enzyme. These observations suggest the unique domain of Src kinases as a source of selectivity and reinforce the relevant role of intrinsically disordered proteins in biological processes.     

Role of intrinsic flexibility in signal transduction mediated by the cell cycle regulator, p27 Kip1

p27^Kip1 (p27), which controls eukaryotic cell division through interactions with cyclin-dependent kinases (Cdks), integrates and transduces promitogenic signals from various nonreceptor tyrosine kinases by orchestrating its own phosphorylation, ubiquitination and degradation. Intrinsic flexibility allows p27 to act as a “conduit” for sequential signaling mediated by tyrosine and threonine phosphorylation and ubiquitination. While the structural features of the Cdk/cyclin-binding domain of p27 are understood, how the C-terminal regulatory domain coordinates multistep signaling leading to p27 degradation is poorly understood. We show that the 100-residue p27 C-terminal domain is extended and flexible when p27 is bound to Cdk2/cyclin A. We propose that the intrinsic flexibility of p27 provides a molecular basis for the sequential signal transduction conduit that regulates p27 degradation and cell division. Other intrinsically unstructured proteins possessing multiple sites of posttranslational modification may participate in similar signaling conduits.     

The Solution Structure of the Regulatory Domain of Tyrosine Hydroxylase

Tyrosine hydroxylase (TyrH) catalyzes the hydroxylation of tyrosine to form 3,4-dihydroxyphenylalanine in the biosynthesis of the catecholamine neurotransmitters. The activity of the enzyme is regulated by phosphorylation of serine residues in a regulatory domain and by binding of catecholamines to the active site. Available structures of TyrH lack the regulatory domain, limiting the understanding of the effect of regulation on structure. We report the use of NMR spectroscopy to analyze the solution structure of the isolated regulatory domain of rat TyrH. The protein is composed of a largely unstructured N-terminal region (residues 1–71) and a well-folded C-terminal portion (residues 72–159). The structure of a truncated version of the regulatory domain containing residues 65–159 has been determined and establishes that it is an ACT domain. The isolated domain is a homodimer in solution, with the structure of each monomer very similar to that of the core of the regulatory domain of phenylalanine hydroxylase. Two TyrH regulatory domain monomers form an ACT domain dimer composed of a sheet of eight strands with four α-helices on one side of the sheet. Backbone dynamic analyses were carried out to characterize the conformational flexibility of TyrH_65–159. The results provide molecular details critical for understanding the regulatory mechanism of TyrH.     

Intrinsically unstructured domains of Arf and Hdm2 form bimolecular oligomeric structures in vitro and in vivo

Arf, Hdm2, and p53 regulate the tumor-suppressor pathway that is most frequently disrupted in human cancer. In the absence of tumorigenic stress, Hdm2 actively attenuates p53-dependent cell cycle arrest and apoptosis by mediating ubiquitination-dependent degradation of p53. Mitogenic stress activates Arf, which indirectly activates p53 by binding to and nullifying the anti-p53 activities of Hdm2. Small conserved domains within Arf and Hdm2 mediate their direct interaction. Individually, these domains are intrinsically unstructured and, when combined in vitro, cofold into bimolecular oligomeric structures that resemble amyloid fibrils in some features. Detailed structural characterization of Hdm2/Arf complexes has previously been hampered by their heterogeneity and large size. Here, we report that a nine-residue fragment of the N-terminus of mouse Arf (termed "A1-mini") cofolds specifically with the Arf-binding domain of Hdm2 to form bimolecular oligomers. We characterized these unprecedented structures using analytical ultracentrifugation and NMR spectroscopy, providing insights into their structural organization. The A1-mini peptide not only binds specifically to Hdm2 in vitro but also recapitulates the nucleolar localization features of full-length Arf in cells. Furthermore, larger fragments of Arf that contain the A1-mini segment have previously been shown to activate p53 in mouse and human cells. Our studies provide the first insights into the molecular basis through which Arf nullifies the p53-inhibiting activity of Hdm2, indirectly activating the tumor-suppressor function of p53 in mammalian cells.     

Structural characterization of the intrinsically unfolded protein beta-synuclein, a natural negative regulator of alpha-synuclein aggregation

The synuclein family of intrinsically unfolded proteins is composed of three highly homologous members, alpha-synuclein (alphaS), beta-synuclein (betaS) and gamma-synuclein (gammaS), which are linked to neurodegenerative disorders and cancer. alphaS has been studied intensively after its identification as the major protein component of amyloid-like deposits in Parkinson's disease and dementia with Lewy bodies. betaS, on the other hand, was found to act as a potent inhibitor of alphaS amyloid formation, and it is proposed as a natural regulator of its neurotoxicity. It is then of particular interest to elucidate the structural and dynamic features of the soluble state of betaS as a first step to understand the molecular basis of its anti-amyloidogenic effect on alphaS. We present here the characterization of natively unstructured betaS by high resolution heteronuclear NMR techniques. A combination of pulse-field gradient, three-dimensional heteronuclear correlation, residual dipolar couplings, paramagnetic relaxation enhancement and backbone relaxation experiments were employed to characterize the ensemble of conformations populated by the protein. The results indicate that betaS adopts extended conformations in its native state, characterized by the lack of the long-range contacts as previously reported for alphaS. Despite the lack of defined secondary structure, we found evidence for transient polyproline II conformations clustered at the C-terminal region. The structuring of the backbone at the C terminus is locally encoded, stabilized by the presence of eight proline residues embedded in a polypeptide stretch rich in hydrophilic and negatively charged amino acids. The structural and functional implications of these findings are analyzed via a thorough comparison with its neurotoxic homolog alphaS.     

Structural Reorganization of α-Synuclein at Low pH Observed by NMR and REMD Simulations

α-Synuclein is an intrinsically disordered protein that appears in aggregated forms in the brains of patients with Parkinson's disease. The conversion from monomer to aggregate is complex, and aggregation rates are sensitive to changes in amino acid sequence and environmental conditions. It has previously been observed that α-synuclein aggregates faster at low pH than at neutral pH. Here, we combine NMR spectroscopy and molecular simulations to characterize α-synuclein conformational ensembles at both neutral and low pH in order to understand how the altered charge distribution at low pH changes the structural properties of these ensembles and leads to an increase in aggregation rate. The N-terminus, which has a small positive charge at neutral pH due to a balance of positively and negatively charged amino acid residues, is very positively charged at low pH. Conversely, the acidic C-terminus is highly negatively charged at neutral pH and becomes essentially neutral and hydrophobic at low pH. Our NMR experiments and replica exchange molecular dynamics simulations indicate that there is a significant structural reorganization within the low-pH ensemble relative to that at neutral pH in terms of long-range contacts, hydrodynamic radius, and the amount of heterogeneity within the conformational ensembles. At neutral pH, there is a very heterogeneous ensemble with transient contacts between the N-terminus and the non-amyloid β component (NAC); however, at low pH, there is a more homogeneous ensemble that exhibits strong contacts between the NAC and the C-terminus. At both pH values, transient contacts between the N- and C-termini are observed, the NAC region shows similar exposure to solvent, and the entire protein shows similar propensities to secondary structure. Based on the comparison of the neutral- and low-pH conformational ensembles, we propose that exposure of the NAC region to solvent and the secondary-structure propensity are not factors that account for differences in propensity to aggregate in this context. Instead, the comparison of the neutral- and low-pH ensembles suggests that the change in long-range interactions between the low- and neutral-pH ensembles, the compaction of the C-terminal region at low pH, and the uneven distribution of charges across the sequence are key to faster aggregation.     

The C-Terminal Domain of SRA1p Has a Fold More Similar to PRP18 than to an RRM and Does Not Directly Bind to the SRA1 RNA STR7 Region

Steroid receptor activator RNA protein (SRA1p) is the translation product of the bi-functional long non-coding RNA steroid receptor activator RNA 1 (SRA1) that is part of the steroid receptor coactivator-1 acetyltransferase complex and is indicated to be an epigenetic regulatory component. Previously, the SRA1p protein was suggested to contain an RNA recognition motif (RRM) domain. We have determined the solution structure of the C-terminal domain of human SRA1p by NMR spectroscopy. Our structure along with sequence comparisons among SRA1p orthologs and against authentic RRM proteins indicates that it is not an RRM domain but rather an all-helical protein with a fold more similar to the PRP18 splicing factor. NMR spectroscopy on the full SRA1p protein suggests that this structure is relevant to the native full-length context. Furthermore, molecular modeling indicates that this fold is well conserved among vertebrates. Amino acid variations in this protein seen across sequenced human genomes, including those in tumor cells, indicate that mutations that disrupt the fold occur vary rarely and highlight that its function is well conserved. SRA1p had previously been suggested to bind to the SRA1 RNA, but NMR spectra of SRA1p in the presence of its 80-nt RNA target suggest otherwise and indicate that this protein must be part of a multi-protein complex in order to recognize its proposed RNA recognition element.     

Tail-Mediated Collapse of HMGB1 Is Dynamic and Occurs via Differential Binding of the Acidic Tail to the A and B Domains

The architectural DNA-binding protein HMGB1 consists of two tandem HMG-box domains joined by a basic linker to a C-terminal acidic tail, which negatively regulates HMGB1-DNA interactions by binding intramolecularly to the DNA-binding faces of both basic HMG boxes. Here we demonstrate, using NMR chemical-shift mapping at different salt concentrations, that the tail has a higher affinity for the B box and that A box-tail interactions are preferentially disrupted. Previously, we proposed a model in which the boxes are brought together in a collapsed, tail-mediated assembly, which is in dynamic equilibrium with a more extended form. Small-angle X-ray scattering data are consistent with such a dynamic equilibrium between collapsed and extended structures and are best represented by an ensemble. The ensembles contain a significantly higher proportion of collapsed structures when the tail is present. ¹⁵N NMR relaxation measurements show that full-length HMGB1 has a significantly lower rate of rotational diffusion than the tail-less protein, consistent with the loss of independent domain motions in an assembled complex. Mapping studies using the paramagnetic spin label MTSL [(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidin-3-yl)methyl methanethiosulfonate] placed at three locations in the tail confirm our previous findings that the tail binds to both boxes with some degree of specificity. The end of the tail lies further from the body of the protein and is therefore potentially free to interact with other proteins. MTSL labelling at a single site in the A domain (C44) causes detectable relaxation enhancements of B domain residues, suggesting the existence of a “sandwich”-like collapsed structure in which the tail enables the close approach of the basic domains. These intramolecular interactions are presumably important for the dynamic association of HMGB1 with chromatin and provide a mechanism by which protein-protein interactions or posttranslational modifications might regulate the function of the protein at particular sites, or at particular stages in the cell cycle.     

Solution Structure and Characterisation of the Human Pyruvate Dehydrogenase Complex Core Assembly

Mammalian pyruvate dehydrogenase complex (PDC) is a key multi-enzyme assembly that is responsible for glucose homeostasis maintenance and conversion of pyruvate into acetyl-CoA. It comprises a central pentagonal dodecahedral core consisting of two subunit types (E2 and E3BP) to which peripheral enzymes (E1 and E3) bind tightly but non-covalently. Currently, there are two conflicting models of PDC (E2 + E3BP) core organisation: the ‘addition’ model (60 + 12) and the ‘substitution’ model (48 + 12). Here we present the first ever low-resolution structures of human recombinant full-length PDC core (rE2/E3BP), truncated PDC core (tE2/E3BP) and native bovine heart PDC core (bE2/E3BP) obtained by small-angle X-ray scattering and small-angle neutron scattering. These structures, corroborated by negative-stain and cryo electron microscopy data, clearly reveal open pentagonal core faces, favouring the ‘substitution’ model of core organisation. The native and recombinant core structures are all similar to the truncated bacterial E2 core crystal structure obtained previously. Cryo-electron microscopy reconstructions of rE2/E3BP and rE2/E3BP:E3 directly confirm that the core has open pentagonal faces, agree with scattering-derived models and show density extending outwards from their surfaces, which is much more structurally ordered in the presence of E3. Additionally, analytical ultracentrifugation characterisation of rE2/E3BP, rE2 (full-length recombinant E2-only) and tE2/E3BP supports the substitution model. Superimposition of the small-angle neutron scattering tE2/E3BP and truncated bacterial E2 crystal structures demonstrates conservation of the overall pentagonal dodecahedral morphology, despite evolutionary diversity. In addition, unfolding studies using circular dichroism and tryptophan fluorescence spectroscopy show that the rE2/E3BP is less stable than its rE2 counterpart, indicative of a role for E3BP in core destabilisation. The architectural complexity and lower stability of the E2/E3BP core may be of benefit to mammals, where sophisticated fine-tuning is required for cores with optimal catalytic and regulatory efficiencies.     

Domain Features of the Peripheral Stalk Subunit H of the Methanogenic A1AO ATP Synthase and the NMR Solution Structure of H1-47

A series of truncated forms of subunit H were generated to establish the domain features of that protein. Circular dichroism analysis demonstrated that H is divided at least into a C-terminal coiled-coil domain within residues 54-104, and an N-terminal domain formed by adjacent α-helices. With a cysteine at the C-terminus of each of the truncated proteins (H_1-47, H_1-54, H_1-59, H_1-61, H_1-67, H_1-69, H_1-71, H_1-78, H_1-80, H_1-91, and H_47-105), the residues involved in formation of the coiled-coil interface were determined. Proteins H_1-54, H_1-61, H_1-69, and H_1-80 showed strong cross-link formation, which was weaker in H_1-47, H_1-59, H_1-71, and H_1-91. A shift in disulfide formation between cysteins at positions 71 and 80 reflected an interruption in the periodicity of hydrophobic residues in the region ₇₁AEKILEETEKE₈₁. To understand how the N-terminal domain of H is formed, we determined for the first time, to our knowledge, the solution NMR structure of H_1-47, which revealed an α-helix between residues 15-42 and a flexible N-terminal stretch. The α-helix includes a kink that would bring the two helices of the C-terminus into the coiled-coil arrangement. H_1-47 revealed a strip of alanines involved in dimerization, which were tested by exchange to single cysteines in subunit H mutants.     

Point mutations in the HIV-1 matrix protein turn off the myristyl switch

During the late phase of human immunodeficiency virus type-1 (HIV-1) replication, newly synthesized retroviral Gag proteins are targeted to lipid raft regions of specific cellular membranes, where they assemble and bud to form new virus particles. Gag binds preferentially to the plasma membrane (PM) of most hematopoietic cell types, a process mediated by interactions between the cellular PM marker phosphatidylinositol-(4,5)-bisphosphate (PI(4,5)P(2)) and Gag's N-terminally myristoylated matrix (MA) domain. We recently demonstrated that PI(4,5)P(2) binds to a conserved cleft on MA and promotes myristate exposure, suggesting a role as both a direct membrane anchor and myristyl switch trigger. Here we show that PI(4,5)P(2) is also capable of binding to MA proteins containing point mutations that inhibit membrane binding in vitro, and in vivo, including V7R, L8A and L8I. However, these mutants do not exhibit PI(4,5)P(2) or concentration-dependent myristate exposure. NMR studies of V7R and L8A MA reveal minor structural changes that appear to be responsible for stabilizing the myristate-sequestered (myr(s)) species and inhibiting exposure. Unexpectedly, the myristyl group of a revertant mutant with normal PM targeting properties (V7R,L21K) is also tightly sequestered and insensitive to PI(4,5)P(2) binding. This mutant binds PI(4,5)P(2) with twofold higher affinity compared with the native protein, suggesting a potential compensatory mechanism for membrane binding.