Studies on solution NMR structure of brazzein——Secondary structure and molecular scaffold

Brazzein is a sweet-tasting protein isolated from the fruit of West African plantPentadiplandra brazzeana Baillon. It is the smallest and the most water-soluble sweet protein discovered so far and is highly thermostable. The proton NMR study of brazzein at 600 MHz (pH 3.5, 300 K) is presented. The complete sequence specific assignments of the individual backbone and sidechain proton resonances were achieved using through-bond and through-space connectivities obtained from standard two-dimensional NMR techniques. The secondary structure of brazzein contains one alpha-helix (residues 21-29), one short 3(10)-helix (residues 14-17), two strands of antiparallel beta-sheet (residues 34-39, 44-50) and probably a third strand (residues 5-7) near the N-terminus. A comparative analysis found that brazzein shares a so-called 'cysteine-stabilized alpha-beta' (CSalphabeta) motif with scorpion neurotoxins, insect defensins and plant gamma - thionins. The significance of this multi-function motif, the possible active sites and the structural basis of themostability were discussed.     

Solution NMR structures reveal a distinct architecture and provide first structures for protein domain family PF04536

The protein family (Pfam) PF04536 is a broadly conserved domain family of unknown function (DUF477), with more than 1,350 members in prokaryotic and eukaryotic proteins. High-quality NMR structures of the N-terminal domain comprising residues 41–180 of the 684-residue protein CG2496 from Corynebacterium glutamicum and the N-terminal domain comprising residues 35–182 of the 435-residue protein PG0361 from Porphyromonas gingivalis both exhibit an α/β fold comprised of a four-stranded β-sheet, three α-helices packed against one side of the sheet, and a fourth α-helix attached to the other side. In spite of low sequence similarity (18%) assessed by structure-based sequence alignment, the two structures are globally quite similar. However, moderate structural differences are observed for the relative orientation of two of the four helices. Comparison with known protein structures reveals that the α/β architecture of CG2496(41–180) and PG0361(35–182) has previously not been characterized. Moreover, calculation of surface charge potential and identification of surface clefts indicate that the two domains very likely have different functions.     

The cadmium binding domains in the metallothionein isoform Cd7-MT10 from Mytilus galloprovincialis revealed by NMR spectroscopy

The metal–thiolate connectivity of recombinant Cd₇-MT10 metallothionein from the sea mussel Mytilus galloprovincialis has been investigated for the first time by means of multinuclear, multidimensional NMR spectroscopy. The internal backbone dynamics of the protein have been assessed by the analysis of ¹⁵N T ₁ and T ₂ relaxation times and steady state {¹H}–¹⁵N heteronuclear NOEs. The ¹¹³Cd NMR spectrum of mussel MT10 shows unique features, with a remarkably wide dispersion (210 ppm) of ¹¹³Cd NMR signals. The complete assignment of cysteine Hα and Hβ proton resonances and the analysis of 2D ¹¹³Cd–¹¹³Cd COSY and ¹H–¹¹³Cd HMQC type spectra allowed us to identify a four metal–thiolate cluster (α-domain) and a three metal–thiolate cluster (β-domain), located at the N-terminal and the C-terminal, respectively. With respect to vertebrate MTs, the mussel MT10 displays an inversion of the α and β domains inside the chain, similar to what observed in the echinoderm MT-A. Moreover, unlike the MTs characterized so far, the α-domain of mussel Cd₇-MT10 is of the form M₄S₁₂ instead of M₄S₁₁, and has a novel topology. The β-domain has a metal–thiolate binding pattern similar to other vertebrate MTs, but it is conformationally more rigid. This feature is quite unusual for MTs, in which the β-domain displays a more disordered conformation than the α-domain. It is concluded that in mussel Cd₇-MT10, the spacing of cysteine residues and the plasticity of the protein backbone (due to the high number of glycine residues) increase the adaptability of the protein backbone towards enfolding around the metal–thiolate clusters, resulting in minimal alterations of the ideal tetrahedral geometry around the metal centres.     

Solution conformation of brazzein by H nuclear magnetic resonance: resonance assignment and secondary structure

Brazzein is a sweet-tasting protein isolated from the fruit of the West African plant Pentadiplandra brazzeana Baillon. It is the smallest and the most water-soluble sweet protein discovered so far, it is also highly thermostable. The proton NMR study of brazzein at 600 MHz (pH 3.5, 300K) is presented. Complete sequence specific assignment of the individual backbone and sidechain proton resonances were achieved using through-bond and through-space connectivities obtained from standard two-dimensional NMR techniques. The secondary structure of brazzein contains one -helix (residues 21–29), one short 3₁₀-helix (residues 14–17), two strands of antiparallel β-sheet (residues 34–39, 44–50) and probably a third strand (residues 5–7) near the N-terminus.     

Predicted secondary structure of maltodextrin Phosphorylase fromEscherichia coli as deduced using Chou-Fasman model

Secondary structure of maltodextrin Phosphorylase fromEscherichia coli has been predicted using Chou-Fasman model. The enzyme protein contains 28% α-helix, 27% β-pleated sheets and 20% reverse β-turns. The secondary structure predicted 4 regions showing Rossman-fold super secondary structure. Two regions, one from residue 268–361 and the another from residue 606–684, having 4 consecutive strands of parallel β-pleated sheets and 3 joining α-helix, are predicted. Two regions, one from residue 379–434 and the another from residue 496–573, having 3 consecutive strands of parallel β-pleated sheets and two joining α-helix, are predicted.     

Dioxygenases Without Requirement for Cofactors: Identification of Amino Acid Residues Involved in Substrate Binding and Catalysis, and Testing for Rate-Limiting Steps in the Reaction of 1H-3-Hydroxy-4-oxoquinaldine 2,4-dioxygenase

1H-3-Hydroxy-4-oxoquinaldine 2,4-dioxygenase (Hod), catalyzing cleavage of its heteroaromatic substrate to form carbon monoxide and N-acetylanthranilate, belongs to the α/β hydrolase fold family of enzymes. Analysis of protein variants suggested that Hod has adapted active-site residues of the α/β hydrolase fold for the dioxygenolytic reaction. H251 was recently shown to act as a general base to abstract a proton from the organic substrate. Residue S101, which corresponds to the nucleophile of the catalytic triad of α/β-hydrolases, presumably participates in binding the heteroaromatic substrate. H102 and residues located in the topological region of the triad’s acidic residue appear to influence O₂ binding and reactivity. A tyrosine residue might be involved in the turnover of the ternary complex [HodH⁺–3,4-dioxyquinaldine dianion–O₂]. Absence of viscosity effects and kinetic solvent isotope effects suggests that turnover of the ternary complex, rather than substrate binding, product release, or proton movements, involves the rate-determining step in the reaction catalyzed by Hod.     

Non-erythroid beta spectrin interacting proteins and their effects on spectrin tetramerization

With yeast two-hybrid methods, we used a C-terminal fragment (residues 1697–2145) of non-erythroid beta spectrin (βII-C), including the region involved in the association with alpha spectrin to form tetramers, as the bait to screen a human brain cDNA library to identify proteins interacting with βII-C. We applied stringent selection steps to eliminate false positives and identified 17 proteins that interacted with βII-C (IP_βII-C s). The proteins include a fragment (residues 38–284) of “THAP domain containing, apoptosis associated protein 3, isoform CRA g”, “glioma tumor suppressor candidate region gene 2” (residues 1-478), a fragment (residues 74–442) of septin 8 isoform c, a fragment (residues 704–953) of “coatomer protein complex, subunit beta 1, a fragment (residues 146–614) of zinc-finger protein 251, and a fragment (residues 284–435) of syntaxin binding protein 1. We used yeast three-hybrid system to determine the effects of these βII-C interacting proteins as well as of 7 proteins previously identified to interact with the tetramerization region of non-erythroid alpha spectrin (IP_αII-N s) [1] on spectrin tetramer formation. The results showed that 3 IP_βII-C s were able to bind βII-C even in the presence of αII-N, and 4 IP_αII-N s were able to bind αII-N in the presence of βII-C. We also found that the syntaxin binding protein 1 fragment abolished αII-N and βII-C interaction, suggesting that this protein may inhibit or regulate non-erythroid spectrin tetramer formation.     

Classification and Phylogenetic Analysis of the cAMP-Dependent Protein Kinase Regulatory Subunit Family

The members of the PKA regulatory subunit family (PKA-R family) were analyzed by multiple sequence alignment and clustering based on phylogenetic tree construction. According to the phylogenetic trees generated from multiple sequence alignment of the complete sequences, the PKA-R family was divided into four subfamilies (types I to IV). Members of each subfamily were exclusively from animals (types I and II), fungi (type III), and alveolates (type IV). Application of the same methodology to the cAMP-binding domains, and subsequently to the region delimited by β-strands 6 and 7 of the crystal structures of bovine RIα and rat RIIβ (the phosphate-binding cassette; PBC), proved that this highly conserved region was enough to classify unequivocally the members of the PKA-R family. A single signature sequence, F–G–E–[LIV]–A–L–[LIMV]–x(3)–[PV]–R–[ANQV]–A, corresponding to the PBC was identified which is characteristic of the PKA-R family and is sufficient to distinguish it from other members of the cyclic nucleotide-binding protein superfamily. Specific determinants for the A and B domains of each R-subunit type were also identified. Conserved residues defining the signature motif are important for interaction with cAMP or for positioning the residues that directly interact with cAMP. Conversely, residues that define subfamilies or domain types are not conserved and are mostly located on the loop that connects α-helix B′ and β strand 7. Received: 2 November 2000/Accepted: 14 June 2001     

Novel oligosaccharide has suppressive activity against human leukemia cell proliferation

Various oligosaccharides containing galactose(s) and one glucosamine (or N-acetylglucosamine) residues with β1–4, α1–6 and β1–6 glycosidic bond were synthesized; Galβ1–4GlcNH₂, Galα1–6GlcNH₂, Galα1–6GlcNAc, Galβ1–6GlcNH₂, Galβ1–4Galβ1–4GlcNH₂ and Galβ1–4Galβ1–4GlcNAc. Galα1–6GlcNH₂ (MelNH₂) and glucosamine (GlcNH₂) had a suppressive effect on the proliferation of K562 cells, but none of the other saccharides tested containing GlcNAc showed this effect. On the other hand, the proliferation of the human normal umbilical cord fibroblast was suppressed by none of the saccharides other than GlcNH₂. Adding Galα1–6GlcNH₂ or glucosamine to the culture of K562 cell, the cell number decreased strikingly after 72 h. Staining the remaining cells with Cellstain Hoechst 33258, chromatin aggregation was found in many cells, indicating the occurrence of cell death. Furthermore, all of the cells were stained with Galα1–6GlcNH-FITC (MelNH-FITC). Neither the control cells nor the cells incubated with glucosamine were stained. On the other hand, when GlcNH-FITC was also added to cell cultures, some of them incubated with Galα1–6GlcNH₂ were stained. The difference in the stainability of the K562 cells by Galα1–6GlcNH-FITC and GlcNH-FITC suggests that the intake of Galα1–6GlcNH₂ and the cell death induced by this saccharide is not same as those of glucosamine. The isolation of the Galα1–6GlcNH₂ binding protein was performed by affinity chromatography (melibiose-agarose) and LC-MS/MS, and we identified the human heterogeneous ribonucleoprotein (hnRNP) A1 (34.3 kDa) isoform protein (30.8 kDa). The hnRNP A1 protein was also detected from the eluate(s) of the MelNH-agarose column by the immunological method (anti-hnRNP-A1 and HRP-labeled anti-mouse IgG (γ) antibodies).     

Positioning of the Alzheimer Aβ(1–40) peptide in SDS micelles using NMR and paramagnetic probes

NMR spectroscopy combined with paramagnetic relaxation agents was used to study the positioning of the 40-residue Alzheimer Amyloid β-peptide Aβ(1–40) in SDS micelles. 5-Doxyl stearic acid incorporated into the micelle or Mn²⁺ ions in the aqueous solvent were used to determine the position of the peptide relative to the micelle geometry. In SDS solvent, the two α-helices induced in Aβ(1–40), comprising residues 15–24, and 29–35, respectively, are surrounded by flexible unstructured regions. NMR signals from these unstructured regions are strongly attenuated in the presence of Mn²⁺ showing that these regions are positioned mostly outside the micelle. The central helix (residues 15–24) is significantly affected by 5-doxyl stearic acid however somewhat less for residues 16, 20, 22 and 23. This α-helix therefore resides in the SDS headgroup region with the face with residues 16, 20, 22 and 23 directed away from the hydrophobic interior of the micelle. The C-terminal helix is protected both from 5-doxyl stearic acid and Mn²⁺, and should be buried in the hydrophobic interior of the micelle. The SDS micelles were characterized by diffusion and ¹⁵N-relaxation measurements. Comparison of experimentally determined translational diffusion coefficients for SDS and Aβ(1–40) show that the size of SDS micelle is not significantly changed by interaction with Aβ(1–40). Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Hypothetical protein AF2241 from Archaeoglobus fulgidus adopts a cyclophilin-like fold

AF2241 is a hypothetical protein from Archaeoglobus fulgidus and it belongs to the PFam domain of unknown function 369 (DUF369). NMR structural determination reveals that AF2241 adopts a cyclophilin-like fold, with a β-barrel core composed of eight β-strands, one α-helix, and one 3₁₀ helix located at each end of the barrel. The protein displays a high structural similarity to TM1367, another member of DUF369 whose structure has been determined recently by X-ray crystallography. Structural similarity search shows that AF2241 also has a high similarity to human cyclophilin A, however, sequence alignment and electrostatic potential analysis reveal that the residues in the PPIase catalytic site of human cyclophilin A are not conserved in AF2241 or TM1367. Instead, a putative active site of AF2241 maps to a negatively charged pocket composed of 9 conserved residues. Our results suggest that although AF2241 adopts the same fold as the human cyclophilin A, it may have distinct biological function. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

NMR structural elucidation of myelin basic protein epitope 83–99 implicated in multiple sclerosis

Myelin basic protein peptide 83–99 (MBP83–99) is the most immunodominant epitope playing a significant role in the multiple sclerosis (MS), an autoimmune disease of the central nervous system. Many peptide analogues, linear or cyclic have been designed and synthesized based on this segment in order to inhibit the experimental autoimmune encephalomyelitis, the best well-known animal model of MS. In this study, the solution structural motif of MBP_83–99 has been performed using 2D ¹H-NMR spectroscopy in dimethyl sulfoxide. A rather extended conformation, along with the formation of a well defined α-helix spanning residues Val⁸⁷–Phe⁹⁰ is proposed, as no long-range NOE are presented. Moreover, the residues of MBP peptide that are important for T-cell receptor recognition are solvent exposed. The spatial arrangement of the side chain all over the sequence of our NMR based model exhibits great similarity with the solid state model, while both TCR contacts occupy the same region in space.     

NMR assignments for the Sinorhizobium meliloti response regulator Sma0114

Response regulators are terminal ends of bacterial two-component systems that undergo extensive structural reorganization in response to phosphoryl transfer from their cognate histidine kinases. The response regulator encoded by the gene sma0114 of Sinorhizobium meliloti is a part of a unique class of two-component systems that employ HWE histidine kinases. The distinct features of Sma0114 include a PFxFATGY motif that houses the conserved threonine in the “Y–T coupling” conformational switch which mediates output response through downstream protein–protein interactions, and the replacement of the conserved phenylalanine/tyrosine in Y–T coupling by a leucine. Here we present ¹H, ¹⁵N, and ¹³C NMR assignments for Sma0114. We identify the secondary structure of the protein based on TALOS chemical shift analysis, ³J_HNHα coupling constants and hydrogen–deuterium exchange. The secondary structure determined by NMR is in good agreement with that predicted from the sequence. Both methods suggest that Sma0114 differs from standard CheY-like folds by missing the fourth α-helix. Our initial NMR characterization of Sma0114 paves the way to a full investigation of the structure and dynamics of this response regulator.     

High resolution <Superscript>13</Superscript>C-detected solid-state NMR spectroscopy of a deuterated protein

High resolution ¹³C-detected solid-state NMR spectra of the deuterated beta-1 immunoglobulin binding domain of the protein G (GB1) have been collected to show that all ¹⁵N, ¹³C′, ¹³Cα and ¹³Cβ sites are resolved in ¹³C–¹³C and ¹⁵N–¹³C spectra, with significant improvement in T ₂ relaxation times and resolution at high magnetic field (750 MHz). The comparison of echo T ₂ values between deuterated and protonated GB1 at various spinning rates and under different decoupling schemes indicates that ¹³Cα T ₂′ times increase by almost a factor of two upon deuteration at all spinning rates and under moderate decoupling strength, and thus the deuteration enables application of scalar-based correlation experiments that are challenging from the standpoint of transverse relaxation, with moderate proton decoupling. Additionally, deuteration in large proteins is a useful strategy to selectively detect polar residues that are often important for protein function and protein–protein interactions.     

Structural elements of the C-terminal domain of subunit E (E<Subscript>133-222</Subscript>) from the <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> V<Subscript>1</Subscript>V<Subscript>O</Subscript> ATPase determined by solution NMR spectroscopy

Subunit E of the vacuolar ATPase (V-ATPase) contains an N-terminal extended α helix (Rishikesan et al. J Bioenerg Biomembr 43:187–193, 2011) and a globular C-terminal part that is predicted to consist of a mixture of α-helices and β-sheets (Grüber et al. Biochem Biophys Res Comm 298:383–391, 2002). Here we describe the production, purification and 2D structure of the C-terminal segment E_133-222 of subunit E from Saccharamyces cerevisiae V-ATPase in solution based on the secondary structure calculation from NMR spectroscopy studies. E_133-222 consists of four β-strands, formed by the amino acids from K136-V139, E170-V173, G186-V189, D195-E198 and two α-helices, composed of the residues from R144-A164 and T202-I218. The sheets and helices are arranged as β1:α1:β2:β3:β4:α2, which are connected by flexible loop regions. These new structural details of subunit E are discussed in the light of the structural arrangements of this subunit inside the V₁- and V₁V_O ATPase.     

Top-down approach in protein RDC data analysis: <Emphasis Type="Italic">de novo</Emphasis> estimation of the alignment tensor

In solution NMR spectroscopy the residual dipolar coupling (RDC) is invaluable in improving both the precision and accuracy of NMR structures during their structural refinement. The RDC also provides a potential to determine protein structure de novo. These procedures are only effective when an accurate estimate of the alignment tensor has already been made. Here we present a top–down approach, starting from the secondary structure elements and finishing at the residue level, for RDC data analysis in order to obtain a better estimate of the alignment tensor. Using only the RDCs from N–H bonds of residues in α-helices and CA–CO bonds in β-strands, we are able to determine the offset and the approximate amplitude of the RDC modulation-curve for each secondary structure element, which are subsequently used as targets for global minimization. The alignment order parameters and the orientation of the major principal axis of individual helix or strand, with respect to the alignment frame, can be determined in each of the eight quadrants of a sphere. The following minimization against RDC of all residues within the helix or strand segment can be carried out with fixed alignment order parameters to improve the accuracy of the orientation. For a helical protein Bax, the three components A _xx , A _yy and A _zz , of the alignment order can be determined with this method in average to within 2.3% deviation from the values calculated with the available atomic coordinates. Similarly for β-sheet protein Ubiquitin they agree in average to within 8.5%. The larger discrepancy in β-strand parameters comes from both the diversity of the β-sheet structure and the lower precision of CA–CO RDCs. This top-down approach is a robust method for alignment tensor estimation and also holds a promise for providing a protein topological fold using limited sets of RDCs.     

Interaction between Aβ Peptide and α Synuclein: Molecular Mechanisms in Overlapping Pathology of Alzheimer’s and Parkinson’s in Dementia with Lewy Body Disease

Amyloidogenic proteins (Aβ peptide) in Alzheimer’s disease (AD) and alpha-synuclein (α-Syn) in Parkinson’s disease (PD) are typically soluble monomeric precursors, which undergo remarkable conformational changes and culminate in the form of aggregates in diseased condition. Overlap of clinical and neuropathological features of both AD and PD are observed in dementia with Lewy body (DLB) disease, the second most common form of dementia after AD. The identification of a 35-amino acid fragment of α-Syn in the amyloid plaques in DLB brain have raised the possibility that Aβ and α-Syn interact with each other. In this report, the molecular interaction of α-Syn with Aβ40 and/or Aβ42 are investigated using multidimensional NMR spectroscopy. NMR data in the membrane mimic environment indicate specific sites of interaction between membrane-bound α-Syn with Aβ peptide and vice versa. These Aβ–α-Syn interactions are demonstrated by reduced amide peak intensity or change in chemical shift of amide proton of the interacting proteins. Based on NMR results, the plausible molecular mechanism of overlapping pathocascade of AD and PD in DLB due to interactions between α-Syn and Aβ is described. To the best of our knowledge, it is the first report using multidimensional NMR spectroscopy that elucidates molecular interactions between Aβ and α-Syn which may lead to onset of DLB. An erratum to this article can be found at     

Secondary structural modifications of Aβ(1-40) induced by multiple 2-acetoxy-4-methoxybenzyl (acetylHmb) protection

Summary Modifications to secondary structure and fibril formation caused by multiple acetylHmb backbone amide protection of Alzheimer's disease Aβ(1–40) were investigated using circular dichroism spectroscopy and electron microscopy. Penta(acetylHmb) Aβ(1–40) was observed to have a reduced ability to form α-helix and β-sheet structures under the same solution conditions as the native peptide, with α-helical propensity being reduced more significantly than β-sheet propensity. Further, acetylHmb backbone protection was found to alter Aβ(1–40) interaction with SDS-micelles by preventing α-helix formation. Aβ fibril formation, a characteristic property of this peptide, was also not observed for penta(acetylHmb) Aβ(1–40).     

Structural studies of arabinogalactan and pectin from Silene vulgaris (M.) G. callus

Arabinogalactan and pectin (named silenan) were isolated from Silene vulgaris (M.) G. callus. Fractionation by ion-exchange chromatography on DEAE-cellulose and digestion with pectinase demonstrated that silenan from S. vulgaris callus (80% of D-galacturonic acid) and silenan from the aerial part of the campion S. vulgaris are similar: both pectins contain a high quantity of homogalacturonan segments. The NMR spectral data and mass spectrometry of the purified polysaccharide and its fragment obtained by Smith degradation confirmed that the core of the arabinogalactan consisted of the different segments of β-1,3-D-galactopyranan. Some of the β-galactopyranose residues of the backbone are branched at O-6. The side chains of the arabinogalactan were shown to contain residues of terminal and 3-O-substituted β-galactopyranose, terminal α-arabinofuranose and α-rhamnopyranose, and 2-O-substituted α-rhamnopyranose. The α-rhamnopyranose residues in the sugar chain appeared to be 2-O-glycosylated by the β-1,4-D-galactopyranosyl uronic acid residues. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 6, pp. 798–807.     

Identifying a Folding Nucleus for the Lysozyme/α-Lactalbumin Family from Sequence Conservation Clusters

Four subfamilies of c-type lysozyme and one subfamily of α-lactalbumin are defined from 78 sequences, and their folding nucleus is identified with a method based on conserved residues and native structural contacts between pairs of conserved residues. One large cluster of 19 conserved residues is found which is mostly nonpolar, buried, and nonfunctional. It can be subdivided into three subclusters: (1) conserved residues in four helices; (2) conserved residues that stabilize the connector between the α and the β domains; and (3) a β-turn, sitting in the middle of a bowl of α-helix residues. It is proposed that this folding nucleus initiates four helices, A, B, C, and D, three β sheets, and the connector, which corresponds closely to the nucleation of the so-called fast folding track pathway. As the secondary structures propagate, nonconserved residues and functionally conserved residues would form additional contacts. The conserved residues are selected with a phylogenetic scheme in which single members of subfamilies are selected. Subfamilies are then equally weighted to obtain the consensus conservation. Received: 11 June 2001 / Accepted: 28 August 2001