Pyroglutamate-Modified Amyloid-ß(3-42) Shows α-Helical Intermediates before Amyloid Formation.

Pyroglutamate-modified amyloid-ß (pEAß) has been described as a relevant Aß species in Alzheimer's-disease-affected brains, with pEAß (3-42) as a dominant isoform. Aß (1-40) and Aß (1-42) have been well characterized under various solution conditions, including aqueous solutions containing trifluoroethanol (TFE). To characterize structural properties of pEAß (3-42) possibly underlying its drastically increased aggregation propensity compared to Aß (1-42), we started our studies in various TFE-water mixtures and found striking differences between the two Aß species. Soluble pEAß (3-42) has an increased tendency to form ß-sheet-rich structures compared to Aß (1-42), as indicated by circular dichroism spectroscopy data. Kinetic assays monitored by thioflavin-T show drastically accelerated aggregation leading to large fibrils visualized by electron microscopy of pEAß (3-42) in contrast to Aß (1-42). NMR spectroscopy was performed for backbone and side-chain chemical-shift assignments of monomeric pEAß (3-42) in 40% TFE solution. Although the difference between pEAß (3-42) and Aß (1-42) is purely N-terminal, it has a significant impact on the chemical environment of >20% of the total amino acid residues, as revealed by their NMR chemical-shift differences. Freshly dissolved pEAß (3-42) contains two α-helical regions connected by a flexible linker, whereas the N-terminus remains unstructured. We found that these α-helices act as a transient intermediate to ß-sheet and fibril formation of pEAß (3-42).

Data describing the solution structure of the WW3* domain from human Nedd4-1.

The third WW domain (WW3*) of human Nedd4-1 (Neuronal precursor cell expressed developmentally down-regulated gene 4-1) interacts with the poly-proline (PY) motifs of the human epithelial Na+ channel (hENaC) subunits at micromolar affinity. This data supplements the article (Panwalkar et al., 2015) [1]. We describe the NMR experiments used to solve the solution structure of the WW3* domain. We also present NOE network data for defining the rotameric state of side chains of peptide binding residues, and complement this data with χ 1 dihedral angles derived from (3) J couplings and molecular dynamics simulations data.

The Nedd4-1 WW Domain Recognizes the PY Motif Peptide through Coupled Folding and Binding Equilibria.

The four WW domains of human Nedd4-1 (neuronal precursor cell expressed developmentally downregulated gene 4-1) interact with the PPxY (PY) motifs of the human epithelial Na(+) channel (hENaC) subunits, with the third WW domain (WW3*) showing the highest affinity. We have shown previously that the α-hENaC PY motif binding interface of WW3* undergoes conformational exchange on the millisecond time scale, indicating that conformational sampling plays a role in peptide recognition. To further understand this role, the structure and dynamics of hNedd4-1 WW3* were investigated. The nuclear Overhauser effect-derived structure of apo-WW3* resembles the domain in complex with the α-hENaC peptide, although particular side chain conformations change upon peptide binding, which was further investigated by molecular dynamics simulations. Model-free analysis of the (15)N nuclear magnetic resonance spin relaxation data showed that the apo and peptide-bound states of WW3* have similar backbone picosecond to nanosecond time scale dynamics. However, apo-WW3* exhibits pronounced chemical exchange on the millisecond time scale that is quenched upon peptide binding. (1)HN and (15)N Carr-Purcell-Meiboom-Gill (CPMG) relaxation dispersion experiments at various temperatures revealed that apo-WW3* exists in an equilibrium between the natively folded peptide binding-competent state and a random coil-like denatured state. The thermodynamics of the folding equilibrium was determined by fitting a thermal denaturation profile monitored by circular dichroism spectroscopy in combination with the CPMG data, leading to the conclusion that the unfolded state is populated to ∼ 20% at 37 °C. These results show that the binding of the hNedd4-1 WW3* domain to α-hENaC is coupled to the folding equilibrium.

Conformational Polymorphism in Autophagy-Related Protein GATE-16.

Autophagy is a fundamental homeostatic process in eukaryotic organisms, fulfilling essential roles in development and adaptation to stress. Among other factors, formation of autophagosomes critically depends on proteins of the Atg8 (autophagy-related protein 8) family, which are reversibly conjugated to membrane lipids. We have applied X-ray crystallography, nuclear magnetic resonance spectroscopy, and molecular dynamics simulations to study the conformational dynamics of Atg8-type proteins, using GATE-16 (Golgi-associated ATPase enhancer of 16 kDa), also known as GABARAPL2, as a model system. This combination of complementary approaches provides new insight into a structural transition centered on the C-terminus, which is crucial for the biological activity of these proteins.

Resonance assignment of the ligand-free cyclic nucleotide-binding domain from the murine ion channel HCN2.

Hyperpolarization activated and cyclic nucleotide-gated (HCN) ion channels as well as cyclic nucleotide-gated (CNG) ion channels are essential for the regulation of cardiac cells, neuronal excitability, and signaling in sensory cells. Both classes are composed of four subunits. Each subunit comprises a transmembrane region, intracellular N- and C-termini, and a C-terminal cyclic nucleotide-binding domain (CNBD). Binding of cyclic nucleotides to the CNBD promotes opening of both CNG and HCN channels. In case of CNG channels, binding of cyclic nucleotides to the CNBD is sufficient to open the channel. In contrast, HCN channels open upon membrane hyperpolarization and their activity is modulated by binding of cyclic nucleotides shifting the activation potential to more positive values. Although several high-resolution structures of CNBDs from HCN and CNG channels are available, the gating mechanism for murine HCN2 channel, which leads to the opening of the channel pore, is still poorly understood. As part of a structural investigation, here, we report the complete backbone and side chain resonance assignments of the murine HCN2 CNBD with part of the C-linker.

Sequestration of a ß-hairpin for control of α-synuclein aggregation.

The misfolding and aggregation of the protein α-synuclein (α-syn), which results in the formation of amyloid fibrils, is involved in the pathogenesis of Parkinson's disease and other synucleinopathies. The emergence of amyloid toxicity is associated with the formation of partially folded aggregation intermediates. Here, we engineered a class of binding proteins termed ß-wrapins (ß-wrap proteins) with affinity for α-synuclein (α-syn). The NMR structure of an α-syn:ß-wrapin complex reveals a ß-hairpin of α-syn comprising the sequence region α-syn(37-54). The ß-wrapin inhibits α-syn aggregation and toxicity at substoichiometric concentrations, demonstrating that it interferes with the nucleation of aggregation.

Conservation of dark recovery kinetic parameters and structural features in the pseudomonadaceae "short" light, oxygen, voltage (LOV) protein family: implications for the design of LOV-based optogenetic tools.

In bacteria and fungi, various light, oxygen, voltage (LOV) sensory systems that lack a fused effector domain but instead contain only short N- and C-terminal extensions flanking the LOV core exist. In the prokaryotic kingdom, this so-called "short" LOV protein family represents the third largest LOV photoreceptor family. This observation prompted us to study their distribution and phylogeny as well as their photochemical and structural properties in more detail. We recently described the slow and fast reverting "short" LOV proteins PpSB1-LOV and PpSB2-LOV from Pseudomonas putida KT2440 whose adduct state lifetimes varied by 3 orders of magnitude [Jentzsch, K., Wirtz, A., Circolone, F., Drepper, T., Losi, A., Gärtner, W., Jaeger, K. E., and Krauss, U. (2009) Biochemistry 48, 10321-10333]. We now present evidence of the conservation of similar fast and slow-reverting "short" LOV proteins in different Pseudomonas species. Truncation studies conducted with PpSB1-LOV and PpSB2-LOV suggested that the short N- and C-terminal extensions outside of the LOV core domain are essential for the structural integrity and folding of the two proteins. While circular dichroism and solution nuclear magnetic resonance experiments verify that the two short C-terminal extensions of PpSB1-LOV and PpSB2-LOV form independently folding helical structures in solution, bioinformatic analyses imply the formation of coiled coils of the respective structural elements in the context of the dimeric full-length proteins. Given their prototypic architecture, conserved in most more complex LOV photoreceptor systems, "short" LOV proteins could represent ideally suited building blocks for the design of genetically encoded photoswitches (i.e., LOV-based optogenetic tools).

An RTX transporter tethers its unfolded substrate during secretion via a unique N-terminal domain.

Type 1 secretion systems (T1SS) catalyze the one step protein transport across the membranes of Gram-negative bacteria and are composed of an outer membrane protein, a membrane fusion protein and an ABC transporter. The ABC transporter consists of the canonical nucleotide binding and transmembrane domains. For the toxin hemolysin A (HlyA), the ABC transporter HlyB carries an additional, N-terminal domain sharing about 40% homology to C39 peptidases, but this "C39-like domain" (CLD) is suggested to feature another, yet unknown function. Our functional and structural analysis demonstrates that the CLD is essential for secretion and that it specifically interacts with the unfolded state of HlyA. We determined the nuclear magnetic resonance structure of the CLD as well as the substrate-binding region within the CLD. This mode of action, represents a mechanism within T1SS and answers the question, how a large and unfolded substrate is protected inside the cells during secretion.

Structural analysis of the pyroglutamate-modified isoform of the Alzheimer's disease-related amyloid-ß using NMR spectroscopy.

The aggregation of the Aß plays a fundamental role in the pathology of AD. Recently, N-terminally modified Aß species, pE-Aß, have been described as major constituents of Aß deposits in the brains of AD patients. pE-Aß has an increased aggregation propensity and shows increased toxicity compared with Aß1-40 and Aß1-42. In the present work, high-resolution NMR spectroscopy was performed to study pE-Aß3-40 in aqueous TFE-containing solution. Two-dimensional TOCSY and NOESY experiments were performed. On the basis of NOE and chemical shift data, pE-Aß3-40 was shown to contain two helical regions formed by residues 14-22 and 30-36. This is similar as previously described for Aß1-40. However, the secondary chemical shift data indicate decreased helical propensity in pE-Aß3-40 when compared with Aß1-40 under exactly the same conditions. This is in agreement with the observation that pE-Aß3-40 shows a drastically increased tendency to form ß-sheet-rich structures under more physiologic conditions. Structural studies of pE-Aß are crucial for better understanding the structural basis of amyloid fibril formation in the brain during development of AD, especially because an increasing number of reports indicate a decisive role of pE-Aß for the pathogenesis of AD.

Crystallization and preliminary X-ray crystallographic studies of an oligomeric species of a refolded C39 peptidase-like domain of the Escherichia coli ABC transporter haemolysin B.

The ABC transporter haemolysin B (HlyB) from Escherichia coli is part of a type I secretion system that translocates a 110 kDa toxin in one step across both membranes of this Gram-negative bacterium in an ATP-dependent manner. Sequence analysis indicates that HlyB contains a C39 peptidase-like domain at its N-terminus. C39 domains are thiol-dependent peptidases that cleave their substrates after a GG motif. Interestingly, the catalytically invariant cysteine is replaced by a tyrosine in the C39-like domain of HlyB. Here, the overexpression, purification and crystallization of the isolated C39-like domain are described as a first step towards obtaining structural insights into this domain and eventually answering the question concerning the function of a degenerated C39 domain in the ABC transporter HlyB.

Structural insights into conformational changes of a cyclic nucleotide-binding domain in solution from Mesorhizobium loti K1 channel.

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels, are activated by binding of ligands to a domain (CNBD) located on the cytoplasmic side of the channel. The underlying mechanisms are not well understood. To elucidate the gating mechanism, structures of both the ligand-free and -bound CNBD are required. Several crystal structures of the CNBD from HCN2 and a bacterial CNG channel (MloK1) have been solved. However, for HCN2, the cAMP-free and -bound state did not reveal substantial structural rearrangements. For MloK1, structural information for the cAMP-free state has only been gained from mutant CNBDs. Moreover, in the crystal, the CNBD molecules form an interface between dimers, proposed to be important for allosteric channel gating. Here, we have determined the solution structure by NMR spectroscopy of the cAMP-free wild-type CNBD of MloK1. A comparison of the solution structure of cAMP-free and -bound states reveals large conformational rearrangement on ligand binding. The two structures provide insights on a unique set of conformational events that accompany gating within the ligand-binding site.

1H, 15N and 13C resonance assignment of the N-terminal C39 peptidase-like domain of the ABC transporter Haemolysin B (HlyB).

ATP-binding cassette (ABC) transporters are ubiquitous integral membrane proteins, which catalyze the translocation of molecules across biological membranes in an ATP-dependent manner. Despite the diversity in the transported substrates, they all share the same architecture, comprised of two transmembrane (TMD) and two nucleotide-binding domains (NBD). Members of the bacteriocin ABC transporter subfamily feature a special domain, belonging to the C39 (cystein protease family 39) peptidase protein family. These domains are assumed to cleave a C-terminal signal sequence from the protein or peptide substrate before or during the transport process. Although the C39 peptidase-like domain of the ABC transporter haemolysin B from E. coli shows no proteolytic activity, it is essential for the function of this transporter. In order to elucidate the contribution of the isolated C39 peptidase-like domain in the whole transport process, the backbone and side chain (1)H, (15)N and (13)C-NMR chemical shifts have been assigned.

Resonance assignments of the nucleotide-free wildtype MloK1 cyclic nucleotide-binding domain.

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels play crucial roles in neuronal excitability and signal transduction of sensory cells. These channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide-binding domain (CNBD). A comparison of the structures of wildtype ligand-free and ligand-bound CNBD is essential to elucidate the mechanism underlying nucleotide-dependent activation of CNBDs. We recently reported the solution structure of the Mesorhizobium loti K1 (MloK1) channel CNBD in complex with cAMP. We have now extended these studies and achieved nearly complete assignments of (1)H, (13)C and (15)N resonances of the nucleotide-free CNBD. A completely new assignment of the nucleotide-free wildtype CNBD was necessary due to the sizable chemical shift differences as compared to the cAMP bound CNBD and the slow exchange behaviour between both forms. Scattering of these chemical shift differences over the complete CNBD suggests that nucleotide binding induces significant overall conformational changes.

The crystal structure of UehA in complex with ectoine-A comparison with other TRAP-T binding proteins.

Substrate-binding proteins or extracellular solute receptors (ESRs) are components of both ABC (ATP binding cassette) and TRAP-T (tripartite ATP-independent periplasmic transporter). The TRAP-T system UehABC from Silicibacter pomeroyi DSS-3 imports the compatible solutes ectoine and 5-hydroxyectoine as nutrients. UehA, the ESR of the UehABC operon, binds both ectoine and 5-hydroxyectoine with high affinity (K(d) values of 1.4+/-0.1 and 1.1+/-0.1 microM, respectively) and delivers them to the TRAP-T complex. The crystal structure of UehA in complex with ectoine was determined at 2.9-A resolution and revealed an overall fold common for all ESR proteins from TRAP systems determined so far. A comparison of the recently described structure of TeaA from Halomonas elongata and an ectoine-binding protein (EhuB) from an ABC transporter revealed a conserved ligand binding mode that involves both directed and cation-pi interactions. Furthermore, a comparison with other known TRAP-T ESRs revealed a helix that might act as a selectivity filter imposing restraints on the ESRs that fine-tune ligand recognition and binding and finally might determine the selection of the cognate substrate.

The compatible-solute-binding protein OpuAC from Bacillus subtilis: ligand binding, site-directed mutagenesis, and crystallographic studies.

In the soil bacterium Bacillus subtilis, five transport systems work in concert to mediate the import of various compatible solutes that counteract the deleterious effects of increases in the osmolarity of the environment. Among these five systems, the ABC transporter OpuA, which catalyzes the import of glycine betaine and proline betaine, has been studied in detail in the past. Here, we demonstrate that OpuA is capable of importing the sulfobetaine dimethylsulfonioacetate (DMSA). Since OpuA is a classic ABC importer that relies on a substrate-binding protein priming the transporter with specificity and selectivity, we analyzed the OpuA-binding protein OpuAC by structural and mutational means with respect to DMSA binding. The determined crystal structure of OpuAC in complex with DMSA at a 2.8-A resolution and a detailed mutational analysis of these residues revealed a hierarchy within the amino acids participating in substrate binding. This finding is different from those for other binding proteins that recognize compatible solutes. Furthermore, important principles that enable OpuAC to specifically bind various compatible solutes were uncovered.