Denaturation of β-sheet structure

A two-dimensional Ising model is used to study the thermal denaturation of parallel β-sheet structures in biomolecules.The fraction of intact hydrogen bonds and the excess heat capacity are evaluated as a function of the temperature.     

Studies on the rules of β-strand alignment in a protein β-sheet structure

To further disclose the underlying mechanisms of protein β-sheet formation, studies were made on the rules of β-strands alignment forming β-sheet structure using statistical and machine learning approaches. Firstly, statistical analysis was performed on the sum of β-strands between each β-strand pairs in protein sequences. The results showed a propensity of near-neighbor pairing (or called “first come first pair”) in the β-strand pairs. Secondly, based on the same dataset, the pairwise cross-combinations of real β-strand pairs and four pseudo-β-strand contained pairs were classified by support vector machine (SVM). A novel feature extracting approach was designed for classification using the average amino acid pairing encoding matrix (APEM). Analytical results of the classification indicated that a segment of β-strand had the ability to distinguish β-strands from segments of α-helix and coil. However, the result also showed that a β-strand was not strongly conserved to choose its real partner from all the alternative β-strand partners, which was corresponding with the ordination results of the statistical analysis each other. Thus, the rules of “first come first pair” propensity and the non-conservative ability to choose real partner, were possible important factors affecting the β-strands alignment forming β-sheet structures.     

Minimal model systems for β-sheet secondary structure in proteins

Use of model systems to explore the forces that control β sheet formation was stymied for many years by the perception that small increments of β sheet necessarily aggregate. Recently, however, a number of short peptides (9–16 residues in length) that fold into two-stranded antiparallel β sheets (‘β hairpins’) have been reported; several short peptides (20–24 residues in length) that fold into three-stranded antiparallel β sheets have also been described. These model systems are beginning to provide fundamental insights into the origins of β sheet conformational stability.     

Protein dynamics of a β-sheet protein

Rhodnius prolixus Nitrophorin 4 (abbreviated NP4) is an almost pure β-sheet heme protein. Its dynamics is investigated by X-ray structure determination at eight different temperatures from 122 to 304 K and by means of Mössbauer spectroscopy. A comparison of this β-sheet protein with the pure α-helical protein myoglobin (abbreviated Mbmet) is performed. The mean square displacement derived from the Mössbauer spectra increases linearly with temperature below a characteristic temperature T _c. It is about 10 K larger than that of myoglobin. Above T _c the mean square displacements increase dramatically. The Mössbauer spectra are analyzed by a two state model. The increased mean square displacements are caused by very slow motions occurring on a time scale faster than 140 ns. With respect to these motions NP4 shows the same protein specific modes as Mbmet. There is, however, a difference in the fast vibration regime. The B values found in the X-ray structures vary linearly over the entire temperature range. The mean square displacements in NP4 increase with slopes which are 60% larger than those observed for Mbmet. This indicates that nitrophorin has a larger structural distribution which makes it more flexible than myoglobin.     

Application of protein knockdown strategy targeting β-sheet structure to multiple disease-associated polyglutamine proteins

Polyglutamine diseases are a class of neurodegenerative diseases associated with the accumulation of aggregated mutant proteins. We previously developed a class of degradation-inducing agents targeting the β-sheet-rich structure typical of such aggregates, and we showed that these agents dose-, time-, and proteasome-dependently decrease the intracellular level of mutant huntingtin with an extended polyglutamine tract, which correlates well with the severity of Huntington’s disease. Here, we demonstrate that the same agents also deplete other polyglutamine disease-related proteins: mutant ataxin-3 and ataxin-7 in cells from spino-cerebellar ataxia patients, and mutant atrophin-1 in cells from dentatorubral-pallidoluysian atrophy patients. Targeting cross-β-sheet structure could be an effective design strategy to develop therapeutic agents for multiple neurodegenerative diseases.     

Diverse effects on the native β-sheet of the human prion protein due to disease-associated mutations

Prion diseases are fatal neurodegenerative disorders that involve the conversion of the normal cellular form of the prion protein (PrP(C)) to a misfolded pathogenic form (PrP(Sc)). There are many genetic mutations of PrP associated with human prion diseases. Three of these point mutations are located at the first strand of the native β-sheet in human PrP: G131V, S132I, and A133V. To understand the underlying structural and dynamic effects of these disease-causing mutations on the human PrP, we performed molecular dynamics of wild-type and mutated human PrP. The results indicate that the mutations induced different effects but they were all related to misfolding of the native β-sheet: G131V caused the elongation of the native β-sheet, A133V disrupted the native β-sheet, and S132I converted the native β-sheet to an α-sheet. The observed changes were due to the reorientation of side chain-side chain interactions upon introducing the mutations. In addition, all mutations impaired a structurally conserved water site at the native β-sheet. Our work suggests various misfolding pathways for human PrP in response to mutation.     

Biotransformation of β-ketosulfides to produce chiral β-hydroxysulfoxides

The biotransformations of a series of substituted phenylthio-2-propanone and benzylthio-2-propanone were carried out using Helminthosporium sp. NRRL 4671, Mortierella isabellina ATCC 42613, or Rhodococcus erythropolis IGTS8. Several products gave microbial oxidation of sulfide to sulfoxide and reduction of carbonyl to secondary alcohol, producing β-hydroxysulfoxides in medium to high enantiomeric and diastereomeric purities. Fungal biotransformations using Helminthosporium sp. and M. isabellina resulted in the opposite sulfoxide configurations of various β-hydroxysulfoxide products.     

Nonnative intermediate state of acid-stable β-sheet protein

Cell adhesion molecule, CD2, from the immunoglobulin superfamily, is comprised of antibodies and Ig-like domains and plays a fundamental role, not only in the immune system, but also in the interactions between cells, specifically in cell-cell adhesion. This study examines the N-terminal domain 1 of CD2 (CD2-1) at different pHs, and in 2,2,2-trifluoroethanol (TFE), using nears- and far-UV circular dichroism (CD), fluorescence, and 1H nuclear magnetic resonance to elucidate factors contributing to the Ig beta-structure. Contrary to the complete unfolding induced by guanidinehydrochloride, CD2-1 retains its native tertiary structure at pHs from 1.0 to 10.0. Like the effects of high temperatures that have previously been observed, TFE reduces the integrity of the tertiary structure, while reorganizing the secondary structure from a native all-beta-sheet to a significantly alpha-helical conformation. The induced helicity of CD2-1 correlates with the helicity inherent in its primary sequence. Our results suggest that electrostatic interactions are less important for the formation of the native secondary and tertiary structure of CD2-1, although they are crucial for CD2's adhesion function. Interference with the protein's hydrophobic interactions and hydrogen-bonding networks, however, causes significant changes in its conformation. Residues of CD2-1, with high conformational flexibility, may contribute for the formation of a metastable dimer by domain-swapping.     

Interaction of β-sheet folds with a gold surface

The adsorption of proteins on inorganic surfaces is of fundamental biological importance. Further, biomedical and nanotechnological applications increasingly use interfaces between inorganic material and polypeptides. Yet, the underlying adsorption mechanism of polypeptides on surfaces is not well understood and experimentally difficult to analyze. Therefore, we investigate here the interactions of polypeptides with a gold(111) surface using computational molecular dynamics (MD) simulations with a polarizable gold model in explicit water. Our focus in this paper is the investigation of the interaction of polypeptides with β-sheet folds. First, we concentrate on a β-sheet forming model peptide. Second, we investigate the interactions of two domains with high β-sheet content of the biologically important extracellular matrix protein fibronectin (FN). We find that adsorption occurs in a stepwise mechanism both for the model peptide and the protein. The positively charged amino acid Arg facilitates the initial contact formation between protein and gold surface. Our results suggest that an effective gold-binding surface patch is overall uncharged, but contains Arg for contact initiation. The polypeptides do not unfold on the gold surface within the simulation time. However, for the two FN domains, the relative domain-domain orientation changes. The observation of a very fast and strong adsorption indicates that in a biological matrix, no bare gold surfaces will be present. Hence, the bioactivity of gold surfaces (like bare gold nanoparticles) will critically depend on the history of particle administration and the proteins present during initial contact between gold and biological material. Further, gold particles may act as seeds for protein aggregation. Structural re-organization and protein aggregation are potentially of immunological importance.     

Molecular mechanism of β-sheet self-organization at water-hydrophobic interfaces

The capacity to form β‐sheet structure and to self‐organize into amyloid aggregates is a property shared by many proteins. Severe neurodegenerative pathologies such as Alzheimer's disease are thought to involve the interaction of amyloidogenic protein oligomers with neuronal membranes. To understand the experimentally observed catalysis of amyloid formation by lipid membranes and other water‐hydrophobic interfaces, we examine the physico‐chemical basis of peptide adsorption and aggregation in a model membrane using atomistic molecular simulations. Blocked octapeptides with simple, repetitive sequences, (Gly‐Ala)₄, and (Gly‐Val)₄, are used as models of β‐sheet‐forming polypeptide chains found in the core of amyloid fibrils. In the presence of an n‐octane phase mimicking the core of lipid membranes, the peptides spontaneously partition at the octane‐water interface. The adsorption of nonpolar sidechains displaces the peptides' conformational equilibrium from a heterogeneous ensemble characterized by a high degree of structural disorder toward a more ordered ensemble favoring β‐hairpins and elongated β‐strands. At the interface, peptides spontaneously aggregate and rapidly evolve β‐sheet structure on a 10 to 100 ns time scale, while aqueous aggregates remain amorphous. Catalysis of β‐sheet formation results from the combination of the hydrophobic effect and of reduced conformational entropy of the polypeptide chain. While the former drives interfacial partition and displaces the conformational equilibrium of monomeric peptides, the planar interface further facilitates β‐sheet organization by increasing peptide concentration and reducing the dimensionality of self‐assembly from three to two. These findings suggest a general mechanism for the formation of β‐sheets on the surface of globular proteins and for amyloid self‐organization at hydrophobic interfaces. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Self-assembly and Self-replication of Short Amphiphilic β-sheet Peptides

Most self-replicating peptide systems are made of α-helix forming sequences. However, it has been postulated that shorter and simpler peptides may also serve as templates for replication when arranged into well-defined structures. We describe here the design and characterization of new peptides that form soluble β-sheet aggregates that serve to significantly accelerate their ligation and self-replication. We then discuss the relevance of these phenomena to early molecular evolution, in light of additional functionality associated with β-sheet assemblies.     

Analysis and prediction of the packing of α-helices against a β-sheet in the tertiary structure of globular proteins

The packing of α-helices and β-sheets in six $\text{α}\text{β}$ proteins (e.g. flavodoxin) has been analysed. The results provide the basis for a computer algorithm to predict the tertiary structure of an $\text{α}\text{β}$ protein from its amino acid sequence and actual assignment of secondary structure.The packing of an individual α-helix against a β-sheet generally involves two adjacent ± 4 rows of non-polar residues on the α-helix at the positions i, i + 4, i + 8, i + 1, i + 5, i + 9. The pattern of interacting β-sheet residues results from the twisted nature of the sheet surface and the attendant rotation of the side-chains. At a more detailed level, four of the α-helical residues (i + 1, i + 4, i + 5 and i + 8) form a diamond that surrounds one particular β-sheet residue, generally isoleucine, leucine or valine. In general, the α-helix sits 10 Å above the sheet and lies parallel to the strand direction.The prediction follows a combinational approach. First, a list of possible β-sheet structures (10⁶ to 10¹⁴) is constructed by the generation of all β-sheet topologies and β-strand alignments. This list is reduced by constraints on topology and the location of non-polar residues to mediate the sheet/helix packing, and then rank-ordered on the extent of hydrogen bonding. This algorithm was uniformly applied to 16 $\text{α}\text{β}$ domains in 13 proteins. For every structure, one member of the reduced list was close to the crystal structure; the root-mean-square deviation between equivalenced C^α atoms averaged 5.6 Å for 100 residues. For the $\text{α}\text{β}$ proteins with pure parallel β-sheets, the total number of structures comparable to or better than the native in terms of hydrogen bonds was between 1 and 148. For proteins with mixed β-sheets, the worst case is glyceraldehyde-3-phosphate dehydrogenase, where as many as 3800 structures would have to be sampled. The evolutionary significance of these results as well as the potential use of a combinatorial approach to the protein folding problem are discussed.     

Toxic prefibrillar α-synuclein amyloid oligomers adopt a distinctive antiparallel β-sheet structure

Parkinson's disease is an age-related movement disorder characterized by the presence in the mid-brain of amyloid deposits of the 140-amino-acid protein AS (α-synuclein). AS fibrillation follows a nucleation polymerization pathway involving diverse transient prefibrillar species varying in size and morphology. Similar to other neurodegenerative diseases, cytotoxicity is currently attributed to these prefibrillar species rather than to the insoluble aggregates. Nevertheless, the underlying molecular mechanisms responsible for cytotoxicity remain elusive and structural studies may contribute to the understanding of both the amyloid aggregation mechanism and oligomer-induced toxicity. It is already recognized that soluble oligomeric AS species adopt β-sheet structures that differ from those characterizing the fibrillar structure. In the present study we used ATR (attenuated total reflection)-FTIR (Fourier-transform infrared) spectroscopy, a technique especially sensitive to β-sheet structure, to get a deeper insight into the β-sheet organization within oligomers and fibrils. Careful spectral analysis revealed that AS oligomers adopt an antiparallel β-sheet structure, whereas fibrils adopt a parallel arrangement. The results are discussed in terms of regions of the protein involved in the early β-sheet interactions and the implications of such conformational arrangement for the pathogenicity associated with AS oligomers.     

Dynamic transition of α-helix to β-sheet structure in linear surfactin correlating to critical micelle concentration

Summary Linear heptapeptide surfactin was prepared by alkaline cleavage of the lactone ring of cyclic surfactin. The structure of linear surfactin was characterised and confirmed by FAB-mass-spectroscopy, FT-IR and HPLC analysis. It was found that linear surfactin easily forms micelles in aqueous solutions by coordinating -sheet formation from -helical monomolecules, and the cmc value found to be 1.28×10^–5 M. The CD spectra indicates conformational change of linear surfactin from -helical below cmc to -sheet above cmc.     

The Role of Aromatic–Aromatic Interactions in Strand–Strand Stabilization of β-Sheets

Aromatic–aromatic interactions have long been believed to play key roles in protein structure, folding, and binding functions. However, we still lack full understanding of the contributions of aromatic–aromatic interactions to protein stability and the timing of their formation during folding. Here, using an aromatic ladder in the β-barrel protein, cellular retinoic acid-binding protein 1 (CRABP1), as a case study, we find that aromatic π stacking plays a greater role in the Phe65–Phe71 cross-strand pair, while in another pair, Phe50–Phe65, hydrophobic interactions are dominant. The Phe65–Phe71 pair spans β-strands 4 and 5 in the β-barrel, which lack interstrand hydrogen bonding, and we speculate that it compensates energetically for the absence of strand–strand backbone interactions. Using perturbation analysis, we find that both aromatic–aromatic pairs form after the transition state for folding of CRABP1, thus playing a role in the final stabilization of the β-sheet rather than in its nucleation as had been earlier proposed. The aromatic interaction between strands 4 and 5 in CRABP1 is highly conserved in the intracellular lipid-binding protein (iLBP) family, and several lines of evidence combine to support a model wherein it acts to maintain barrel structure while allowing the dynamic opening that is necessary for ligand entry. Lastly, we carried out a bioinformatics analysis and found 51 examples of aromatic–aromatic interactions across non-hydrogen-bonded β-strands outside the iLBPs, arguing for the generality of the role played by this structural motif.     

Self-assembly of amphipathic β-sheet peptides: insights and applications

Amphipathic peptides composed of alternating polar and nonpolar residues have a strong tendency to self-assemble into one-dimensional, amyloid-like fibril structures. Fibrils derived from peptides of general (XZXZ)(n) sequence in which X is hydrophobic and Z is hydrophilic adopt a putative β-sheet bilayer. The bilayer configuration allows burial of the hydrophobic X side chain groups in the core of the fibril and leaves the polar Z side chains exposed to solvent. This architectural arrangement provides fibrils that maintain high solubility in water and has facilitated the recent exploitation of self-assembled amphipathic peptide fibrils as functional biomaterials. This article is a critical review of the development and application of self-assembling amphipathic peptides with a focus on the fundamental insight these types of peptides provide into peptide self-assembly phenomena.     

Design and biological activity of β-sheet breaker peptide conjugates

The sequence LPFFD (iAβ₅) prevents amyloid-β peptide (Aβ) fibrillogenesis and neurotoxicity, hallmarks of Alzheimer’s disease (AD), as previously demonstrated. In this study iAβ₅ was covalently linked to poly(ethylene glycol) (PEG) and the activity of conjugates was assessed and compared to the activity of the peptide alone by in vitro studies. The conjugates were characterized by MALDI-TOF. Competition binding assays established that conjugates retained the ability to bind Aβ with similar strength as iAβ₅. Transmission electron microscopy analysis showed that iAβ₅ conjugates inhibited amyloid fibril formation, which is in agreement with binding properties observed for the conjugates towards Aβ. The conjugates were also able to prevent amyloid-induced cell death, as evaluated by activation of caspase 3. These results demonstrated that the biological activity of iAβ₅ is not affected by the pegylation process.     

Mutants of Cellulomonas which produce increased levels of β-glucosidase

Summary Mutants have been isolated from a strain of Cellulomonas which are capable of producing up to 26-fold higher levels of -glucosidase than the parent under certain growth conditions.     

Molecular characterization of β-thalassemia mutations in Egypt

Summary The relative frequency of different -thalassemia mutations and their association with -globin haplotypes were studied in patients from the Nile delta region, Egypt, by means of the polymerase chain reaction, oligonucleotide hybridization and restriction analysis. We found that 8 mutations account for 77% of -thalassemia chromosomes in this population, the commonest being IVS-1 nt 110, IVS-1 nt 6 and IVS-1 nt 1. Each mutation was associated with a specific haplotype, with the exception of IVS-1 nt 110, found on 3 different chromosomal backgrounds. Our data show that testing for the 8 detectable mutations makes feasible prenatal diagnosis in 65% of at risk couples and exclusion testing in an additional 25% of cases.