Structural Determinants of the Alzheimer's Amyloid β-Peptide

Abstract: The hallmark event of Alzheimer's disease (AD) is the deposition of amyloid as insoluble fiber masses in extracellular neuritic plaques and around the walls of cerebral blood vessels. The main component of amyloid is a hydrophobic peptide, named amyloid β-peptide (βA4), which results from the processing of a much longer membrane amyloid precursor protein (APP). This review focuses on the structural features of βA4 and the factors that determine βA4 insolubilization. Theoretical and experimental studies of the primary structure of βA4 have shown that it is composed of a completely hydrophobic C-terminal domain, which adopts β-strand structure, and an N-terminal region, whose sequence permits different secondary structures. In fact, this region can exist as an α-helical or β-strand conformation depending on the environmental condition (pH and hydrophobicity surrounding the molecule). The effects of pH and hydrophobicity on βA4 structure may elucidate the mechanisms determining its aggregation and amyloid deposition in AD.     

Folding type-specific secondary structure propensities of amino acids,derived from α-helical, β-sheet, α/β, and α+β proteins of known structures

Folding type-specific secondary structure propensities of 20 naturally occurring amino acids have been derived from α-helical, β-sheet, α/β, and α+β proteins of known structures. These data show that each residue type of amino acids has intrinsic propensities in different regions of secondary structures for different folding types of proteins. Each of the folding types shows markedly different rank ordering, indicating folding type-specific effects on the secondary structure propensities of amino acids. Rigorous statistical tests have been made to validate the folding type-specific effects. It should be noted that α and β proteins have relatively small α-helices and β-strands forming propensities respectively compared with those of α+β and α/β proteins. This may suggest that, with more complex architectures than α and β proteins, α+β and α/β proteins require larger propensities to distinguish from interacting α-helices and β-strands. Our finding of folding type-specific secondary structure propensities suggests that sequence space accessible to each folding type may have differing features. Differing sequence space features might be constrained by topological requirement for each of the folding types. Almost all strong β-sheet forming residues are hydrophobic in character regardless of folding types, thus suggesting the hydrophobicities of side chains as a key determinant of β-sheet structures. In contrast, conformational entropy of side chains is a major determinant of the helical propensities of amino acids, although other interactions such as hydrophobicities and charged interactions cannot be neglected. These results will be helpful to protein design, class-based secondary structure prediction, and protein folding. © 1998 John Wiley & Sons, Inc. Biopoly 45: 35–49, 1998     

A Secondary Structure Model of the Integrin a Subunit N-Terminal Domain Based on Analysis of Multiple Alignments

The integrins are α/β heterodimeric proteins which mediate cell-matrix and cell-cell inter-actions. Current data indicate that the N-terminal moiety of the a subunit is involved in ligand binding. This region of the receptor is made up of a seven-fold repeated sequence of unknown structure which contains EF-hand-like putative divalent cation-binding sites. Recent studies have shown that multiple sequence alignments can be analysed to yield secondary structure predictions. Therefore, to obtain a model structure for the integrin a subunit N-terminal domain repeat, a large alignment of the seven repeats from sixteen integrin sequences was generated. Two methods of analysis were used: First, Chou and Fasman and Garnier, Osguthorpe and Robson predictions were carried out for individual sequences and the consensus predictions derived. Consensus hydrophobicity and chain flexibility data were also used to provide additional data. Second, sites of conservation and variation were analysed by a computer program STAMA (STructure After Multiple Alignment) to yield a secondary structure prediction. The two analyses gave essentially the same predicted structure: undefined region, loop, α-helix, β-strand, divalent cation-binding loop, β-strand, putative turn, loop, β-strand. This is the first model structure to be presented for an integrin domain. Its implications for integrin function are discussed.     

A PixD--PapB Chimeric Protein Reveals the Function of the BLUF Domain C-Terminal α-Helices for Light Signal Transduction

Blue light-using flavin (BLUF) proteins form a subfamily of blue light photoreceptors, are found in many bacteria and algae, and are further classified according to their structures. For one type of BLUF-containing protein, e.g. PixD, the central axes of its two C-terminal α-helices are perpendicular to the β-sheet of its N-terminal BLUF domain. For another type, e.g. PapB, the central axes of its two C-terminal α-helices are parallel to its BLUF domain β-sheet. However, the functional significance of the different orientations with respect to phototransduction is not clear. For the study reported herein, we constructed a chimeric protein, Pix0522, containing the core of the PixD BLUF domain and the C-terminal region of PapB, including the two α-helices, and characterized its biochemical and spectroscopic properties. Fourier transform infrared spectroscopy detected similar light-induced conformational changes in the C-terminal α-helices of Pix0522 and PapB. Pix0522 interacts with and activates the PapB-interacting enzyme, PapA, demonstrating the functionality of Pix0522. These results provide direct evidence that the BLUF C-terminal α-helices function as an intermediary that accepts the flavin-sensed blue light signal and transmits it downstream during phototransduction.     

Molecular modeling indicates that homodimers form the basis for intermediate filament assembly from human and mouse epidermal keratins

Mammalian epidermal keratin molecules adopt rod-shaped conformations that aggregate to form cytoplasmic intermediate filaments. To investigate these keratin conformations and the basis for their patterns of molecular association, graphical methods were developed to relate known amino acid sequences to probable spacial configurations. The results support the predominantly α-helical conformation of keratin chains, interrupted by short non-α-helical linkages. However, it was found that many of the linkages have amino acid sequences typical of β-strand conformations. Space-filling atomic models revealed that the β-strand sequences would permit the formation of 2-chain and 4-chain cylindrical β-helices, fully shielding the hydrophobic amino acid chains that alternate with hydrophilic residues in these sequences. Because of the locations of the β-helical regions in human and mouse stratum corneum keratin chains, only homodimers of the keratins could interact efficiently to form 2-chain and 4-chain β-helices. Tetramers having the directions and degrees of overlap of constituent dimers that have been identified by previous investigators are also predicted from the interactions of β-helical motifs. Heterotetramers formed from dissimilar homodimers could combine, through additional β-helical structures, to form higher oligomers having the dimensions seen in electron microscopic studies. Previous results from chemical crosslinking studies can be interpreted to support the concept of homodimers rather than heterodimers as the basis for keratin filament assembly. © 1995 Wiley-Liss, Inc.     

Crystal structure of Escherichia coli methionyl-tRNA synthetase at 2.5 Å resolution

Native methionyl-tRNA synthetase from Escherichia coli (a dimer of molecular weight 172,000) can be converted by mild proteolysis into a well-defined monomeric fragment of molecular weight 64,000. This fragment retains full specificity towards methionine and tRNA^Met, and has unimpaired activity in both the activation and aminoacylation reactions.This paper describes the structure of the active fragment, as determined by an X-ray crystallographic study at 2.5 Å resolution using five heavy-atom derivatives. The elongated molecule (90 Å × 52 Å × 44 Å) contains several α-helices, which account for 43% of the residues. Three domains can be distinguished in the structure: (1) a central core beginning at the N-terminus, consisting of a five-stranded parallel pleated sheet with α-helices connecting the β-strands; (2) a second domain with less-ordered structure, inserted between the third and fourth strand of the central sheet; (3) a C-terminal domain, beginning after the fifth parallel strand, very rich in α-helices.These three domains are organized in a biglobular structure; one globule contains the first and the second domain (N-terminal globule), the other the third domain. The two globules, linked together by a single chain, are separated by a large cleft.The most salient feature of the structure is the presence, in the N-terminal domain, of a “nucleotide binding fold” similar to that first observed in dehydrogenases. This makes methionyl-tRNA synthetase, and possibly all aminoacyl-tRNA synthetases, a new member of this family of nucleotide binding proteins possessing the characteristic “Rossmann fold”.     

Pleckstrin homology (PH) domains in signal transducton

A diverse array of molecules involved in signal transduction have recently been recognised as containing a new homology domain, the pleckstrin homology (PH) domain. These include kinases (both serine/threonine and tyrosine specific), all currently known mammalian phospholipase Cs, GTPases, GTPage-activatng proteins, GTpace-exchange factors, “adapter” proteins, cyotskeletal proteins, and kinase substrates. This has sparked a new surge of research into elucidating its sturcture and function. The NMR solution structure of the PH domains of β-spectrin and pleckstrin (the N-terminal domain) both display a core consisting of seven anti-parallel β-sheet strands. The carboxy terminus is folded into a long α-helix. The molecule is electrostatically polarised and contains a pocket which may be involved in the inding of a ligand. The PH domain overall topological relatedness to the retinoid inding protein family of molecules would suggest a lipid ligand could bind to this pocket. the prime function of the PH domain still remains to be elucidated. However, it has been shown to be important in signal transduction, most probably by mediating protein-protein interactions. An extended PH domain of the β-adrenergic receptor kinase (βARK), as well as that of several other molecules, can bind to βγ subunits of the heterotrimeric G-proteins. The possibility that the PH domain, which is found in so many signalling molecules, being generally inovolved in βγ binding site appear to be concomitant in βARK, detailed analysis indicates that the PH domain is not generally a βγ binding domain. Thus, the race is on to find the ligands of each PH domain and determine a common nature to their interaction.     

Structure,Function, and Regulation of the Three β-Adrenergic Receptors

Three β-adrenergic receptor subtypes are now known to be functionally expressed in mammals. All three belong to the R₇G family of receptors coupled to G-proteins, and characterized by an extracellular glycosylated N-terminal and an intracellular C-terminal region and seven transmembrane domains, linked by three exta- and three intracellular loops. The catecholamine ligand binding domain, studied using affinity-labeling and site-directed mutagenesis, is a pocket lined by residues belonging to the transmembrane domains. The region responsible for the interaction with the Gs protein which, when activated, stimulates adenylyl cyclase, is composed of residues belonging to the parts most proximal to the membrane of intracellular loop i₃ and the C-terminal region. The pharmacology of the three subtypes is quite distinct: in fact most of the potent β₁/β₂ antagonists (the well known β blockers) act as agonists on β₃. The subtype is resistant to short-term desensitization mediated by phosphorylation through PKA or βARK, in stark contrast to the β₁ or β₂ subtypes. Various compounds (dexamethasone, butyrate, insulin) up regulate β₁ or β₁ subtypes while down-regulating β₃ whose expression strictly correlates with differentiation of 3T3-F442A fibroblasts into adipocytes, thus confirming that the expression of the three subtypes may each be regulated independently to exert a specific physiologic role in different tissues or at different stages of development.     

A S-adenosylmethionine methyltransferase-like domain within the essential, Fe-S-containing yeast protein Dre2

Yeast Dre2 is an essential Fe-S cluster-containing protein that has been implicated in cytosolic Fe-S protein biogenesis and in cell death regulation in response to oxidative stress. Its absence in yeast can be complemented by the human homologous antiapoptotic protein cytokine-induced apoptosis inhibitor 1 (also known as anamorsin), suggesting at least one common function. Using complementary techniques, we have investigated the biochemical and biophysical properties of Dre2. We show that it contains an N-terminal domain whose structure in solution consists of a stable well-structured monomer with an overall typical S-adenosylmethionine methyltransferase fold lacking two α-helices and a β-strand. The highly conserved C-terminus of Dre2, containing two Fe-S clusters, influences the flexibility of the N-terminal domain. We discuss the hypotheses that the activity of the N-terminal domain could be modulated by the redox activity of Fe-S clusters containing the C-terminus domain in vivo.     

Evolution of β-amylase: Patterns of variation and conservation in subfamily sequences in relation to parsimony mechanisms

Soybean and sweet potato β-amylases are structured as α/β barrels and the same kind of folding may account for all known β-amylases. We provide a comprehensive analysis of both protein and DNA (coding region) sequences of β-amylases. The aim of the study is to contribute to the knowledge of the evolutionary molecular relationships among all known β-amylases. Our approach combines the identification of the putative eightfold structural core formed by β-strands with a complete multi-alignment analysis of all known sequences. Comparing putative β-amylase (α/β)₈ cores from plants and microorganisms, two differentiated versions of residues at the packing sites, and a unique set of eight identical residues at the C-terminal catalytical site are observed, indicating early evolutionary divergence and absence of localized three-dimensional evolution, respectively. A new analytical approach has been developed in order to work out conserved motifs for β-amylases, mostly related with the enzyme activity. This approach appears useful as a new routine to find sets of motifs (each set being known as a fingerprint) in protein families. We demonstrate that the evolutionary mechanism for β-amylases is a combination of parsimonious divergence at three distinguishable rates in relation to the functional signatures, the barrel scaffold, and α-helix-containing loops. © 1996 Wiley-Liss, Inc.     

Crystallization,molecular replacement solution,and refinement of tetrameric β-amylase from sweet potato

Sweet potato β-amylase is a tetramer of identical subunits, which are arranged to exhibit 222 molecular symmetry. Its subunit consists of 498 amino acid residues (Mr 55,880). It has been crystallized at room temperature using polyethylene glycol 1500 as precipitant. The crystals, growing to dimensions of 0.4 mm × 0.4 mm × 1.0 mm within 2 weeks, belong to the tetragonal space group P4₂2₁2 with unit cell dimensions of a = b = 129.63 Å and c = 68.42 Å. The asymmetric unit contains 1 subunit of β-amylase, with a crystal volume per protein mass (V_M) of 2.57 ų/Da and a solvent content of 52% by volume. The three-dimensional structure of the tetrameric β-amylase from sweet potato has been determined by molecular replacement methods using the monomeric structure of soybean enzyme as the starting model. The refined subunit model contains 3,863 nonhydrogen protein atoms (488 amino acid residues) and 319 water oxygen atoms. The current R-value is 20.3% for data in the resolution range of 8–2.3 Å (with 2 σ cut-off) with good stereochemistry. The subunit structure of sweet potato β-amylase (crystallized in the absence of α-cyclodextrin) is very similar to that of soybean β-amylase (complexed with α-cyclodextrin). The root-mean-square (RMS) difference for 487 equivalent Cα atoms of the two β-amylases is 0.96 Å. Each subunit of sweet potato β-amylase is composed of a large (α/β)₈ core domain, a small one made up of three long loops [L3 (residues 91–150), LA (residues 183–258), and L5 (residues 300–327)], and a long C-terminal loop formed by residues 445–493. Conserved Glu 187, believed to play an important role in catalysis, is located at the cleft between the (α/β)₈ barrel core and a small domain made up of three long loops (L3, L4, and L5). Conserved Cys 96, important in the inactivation of enzyme activity by sulfhydryl reagents, is located at the entrance of the (α/β)₈ barrel. © 1995 Wiley-Liss, Inc.     

168 NMR study of RQC domain of BLM protein

BLM, a member of the RecQ helicase associated with the Bloom’s syndrome human genetic disorder, has been found to bind to noncanonical DNA with high affinity via its RecQ C-terminal domain (RQC). Using multi-dimensional NMR spectroscopy, we have determined the solution structure of BLM RQC, and found that BLM RQC retains the overall winged-helix motif previously observed for other RQC proteins. Comparison between BLM RQC and the RQC domain of its homologue, Werner syndrome protein (WRN RQC), revealed two major structural differences. Firstly, BLM RQC contains an extended 14-residue insertion forming a flexible loop between two first α-helices, only found in BLM RQC and not other RQC proteins. Secondly, in contrast to the third α-helix of WRN RQC, an unstructured loop was observed for this region of BLM RQC.     

Structure of the leech protein saratin and characterization of its binding to collagen

The leech protein Saratin from Hirudo medicinalis prevents thrombocyte aggregation by interfering with the first binding step of the thrombocytes to collagen by binding to collagen. We solved the three-dimensional structure of the leech protein Saratin in solution and identified its collagen binding site by NMR titration experiments. The NMR structure of Saratin consists of one α-helix and a five-stranded β-sheet arranged in the topology ββαβββ. The C-terminal region, of about 20 amino acids in length, adopts no regular structure. NMR titration experiments with collagen peptides show that the collagen interaction of Saratin takes place in a kind of notch that is formed by the end of the α-helix and the β-sheet. NMR data-driven docking experiments to collagen model peptides were used to elucidate the putative binding mode of Saratin and collagen. Mainly, parts of the first and the end of the fifth β-strand, the loop connecting the α-helix and the third β-strand, and a short part of the loop connecting the fourth and fifth β-strand participate in binding.     

Structural and functional characterization of the amino terminal domain of the yeast ribosomal stalk P1 and P2 proteins

The essential ribosomal stalk is formed in eukaryotes by a pentamer of two P1–P2 protein heterodimers and the P0 rRNA binding protein. In contrast to the highly stable prokaryotic complex, the P1 and P2 proteins in the eukaryotic stalk undergo a cyclic process of assembly and disassembly during translation that seems to modulate the ribosome activity. To better understand this process, the regions of the Saccharomyces cerevisiae P1α and P2β proteins that are directly involved in heterodimer formation and ribosome binding have been characterized using a series of P1α/P2β chimeras. The region required for a stable interaction with the ribosome is formed by the first three predicted α-helices in the N-terminal domain of both proteins. The same region is required for heterodimer formation in P2β but the third helix is dispensable for this association in P1α. It seems, therefore, that stable ribosome binding is more structurally demanding than heterodimerization. A fourth predicted α-helix in the N-terminal domain of P1α and P2β appears not to be involved in the assembly process but rather, it contributes to the conformation of the proteins by apparently restricting the mobility of their C-terminal domain and paradoxically, by reducing their activity. In addition, the study of P1/P2 chimeras showed that the C-terminal domains of these two types of protein are functionally identical and that their protein specificity is exclusively determined by their N-terminal domains.     

Toward the molecular basis of inherited prion diseases: NMR structure of the human prion protein with V210I mutation

The development of transmissible spongiform encephalopathies (TSEs) is associated with the conversion of the cellular prion protein (PrP^C) into a misfolded, pathogenic isoform (PrP^Sc). Spontaneous generation of PrP^Sc in inherited forms of disease is caused by mutations in gene coding for PrP (PRNP). In this work, we describe the NMR solution-state structure of the truncated recombinant human PrP (HuPrP) carrying the pathological V210I mutation linked to genetic Creutzfeldt-Jakob disease. The three-dimensional structure of V210I mutant consists of an unstructured N-terminal part (residues 90-124) and a well-defined C-terminal domain (residues 125-228). The C-terminal domain contains three α-helices (residues 144-156, 170-194 and 200-228) and a short antiparallel β-sheet (residues 129-130 and 162-163). Comparison with the structure of the wild-type HuPrP revealed that although two structures share similar global architecture, mutation introduces some local structural differences. The observed variations are mostly clustered in the α₂-α₃ inter-helical interface and in the β₂-α₂ loop region. Introduction of bulkier Ile at position 210 induces reorientations of several residues that are part of hydrophobic core, thus influencing α₂-α₃ inter-helical interactions. Another important structural feature involves the alteration of conformation of the β₂-α₂ loop region and the subsequent exposure of hydrophobic cluster to solvent, which facilitates intermolecular interactions involved in spontaneous generation of PrP^Sc. The NMR structure of V210I mutant offers new clues about the earliest events of the pathogenic conversion process that could be used for the development of antiprion drugs.     

Packing constraints of hydrophobic side chains in (α/β)8 barrels

An analysis of possible tight packing of hydrophobic groups simultaneously at the both surfaces of β-hyperboloid-8 was conducted. This analysis shows that the disposition of amino acid side chains at the real β-structure's surface is unique. If we sign the mean distance between adjacent β-strands as “a,” and the mean distance along β-strand between C_α atoms, whose side chains are directed to one side of the β-sheet, as “b,” the ratio b/a = √2 very precisely. This ratio ensures the most efficient packing of side hydrophobic groups at the outer surface of β-hyperboloid-8, forming, at the same time, the second by efficiency packing at its inner surface. © 1995 Wiley-Liss, Inc.     

NMR structure of the bank vole prion protein at 20 degrees C contains a structured loop of residues 165-171

The recent introduction of bank vole (Clethrionomys glareolus) as an additional laboratory animal for research on prion diseases revealed an important difference when compared to the mouse and the Syrian hamster, since bank voles show a high susceptibility to infection by brain homogenates from a wide range of diseased species such as sheep, goats, and humans. In this context, we determined the NMR structure of the C-terminal globular domain of the recombinant bank vole prion protein (bvPrP) [bvPrP(121-231)] at 20 °C. bvPrP(121-231) has the same overall architecture as other mammalian PrPs, with three α-helices and an antiparallel β-sheet, but it differs from PrP of the mouse and most other mammalian species in that the loop connecting the second β-strand and helix α2 is precisely defined at 20 °C. This is similar to the previously described structures of elk PrP and the designed mouse PrP (mPrP) variant mPrP[S170N,N174T](121-231), whereas Syrian hamster PrP displays a structure that is in-between these limiting cases. Studies with the newly designed variant mPrP[S170N](121-231), which contains the same loop sequence as bvPrP, now also showed that the single-amino-acid substitution S170N in mPrP is sufficient for obtaining a well-defined loop, thus providing the rationale for this local structural feature in bvPrP.     

Crystal structure of the superfamily 1 helicase from Tomato mosaic virus

The genomes of the Tomato mosaic virus and many other plant and animal positive-strand RNA viruses of agronomic and medical importance encode superfamily 1 helicases. Although helicases play important roles in viral replication, the crystal structures of viral superfamily 1 helicases have not been determined. Here, we report the crystal structure of a fragment (S666 to Q1116) of the replication protein from Tomato mosaic virus. The structure reveals a novel N-terminal domain tightly associated with a helicase core. The helicase core contains two RecA-like α/β domains without any of the accessory domain insertions that are found in other superfamily 1 helicases. The N-terminal domain contains a flexible loop, a long α-helix, and an antiparallel six-stranded β-sheet. On the basis of the structure, we constructed deletion mutants of the S666-to-Q1116 fragment and performed split-ubiquitin-based interaction assays in Saccharomyces cerevisiae with TOM1 and ARL8, host proteins that are essential for tomato mosaic virus RNA replication. The results suggested that both TOM1 and ARL8 interact with the long α-helix in the N-terminal domain and that TOM1 also interacts with the helicase core. Prediction of secondary structures in other viral superfamily 1 helicases and comparison of those structures with the S666-to-Q1116 structure suggested that these helicases have a similar fold. Our results provide a structural basis of viral superfamily 1 helicases.     

The Cancer Mutation D83V Induces an α-Helix to β-Strand Conformation Switch in MEF2B

MEF2B is a major target of somatic mutations in non-Hodgkin lymphoma. Most of these mutations are non-synonymous substitutions of surface residues in the MADS-box/MEF2 domain. Among them, D83V is the most frequent mutation found in tumor cells. The link between this hotspot mutation and cancer is not well understood. Here we show that the D83V mutation induces a dramatic α-helix to β-strand switch in the MEF2 domain. Located in an α-helix region rich in β-branched residues, the D83V mutation not only removes the extensive helix stabilization interactions but also introduces an additional β-branched residue that further shifts the conformation equilibrium from α-helix to β-strand. Cross-database analyses of cancer mutations and chameleon sequences revealed a number of well-known cancer targets harboring β-strand favoring mutations in chameleon α-helices, suggesting a commonality of such conformational switch in certain cancers and a new factor to consider when stratifying the rapidly expanding cancer mutation data.     

Solution structure of HtrA PDZ domain from Streptococcus pneumoniae and its interaction with YYF-COOH containing peptides

High-temperature requirement A (HtrA), a highly conserved family of serine protease, plays crucial roles in protein quality control in prokaryotes and eukaryotes. The HtrA protein contains a C-terminal PDZ domain that mediates the proteolytic activity. Here we reported the solution structure of the HtrA PDZ domain from Streptococcus pneumoniae by NMR spectroscopy. Our results showed that the structure of HtrA PDZ domain, which contains three α-helices and five β-strands, illustrates conservation within the canonical PDZ domains. In addition, we demonstrated the interactions between S. pneumoniae HtrA PDZ domain and peptides with the motif XXX–YYF–COOH by surface plasmon resonance. Besides, we identified the ligand binding surface and the critical residues responsible for ligand binding of HtrA PDZ domain by chemical shift perturbation and site-directed mutagenesis.