Multiscale MD simulations of wild-type and sickle hemoglobin aggregation.

Sickle cell disease is a hemoglobinopathy resulting from a point mutation from glutamate to valine at position six of the ß-globin chains of hemoglobin. This mutation gives rise to pathological aggregation of the sickle hemoglobin and, as a result, impaired oxygen binding, misshapen and short-lived erythrocytes, and anemia. We aim to understand the structural effects caused by the single Glu6Val mutation leading to protein aggregation. To this end, we perform multiscale molecular dynamics simulations employing atomistic and coarse-grained models of both wild-type and sickle hemoglobin. We analyze the dynamics of hemoglobin monomers and dimers, study the aggregation of wild-type and sickle hemoglobin into decamers, and analyze the protein-protein interactions in the resulting aggregates. We find that the aggregation of sickle hemoglobin is driven by both hydrophobic and electrostatic protein-protein interactions involving the mutation site and surrounding residues, leading to an extended interaction area and thus stable aggregates. The wild-type protein can also self-assemble, which, however, results from isolated interprotein salt bridges that do not yield stable aggregates. This knowledge can be exploited for the development of sickle hemoglobin-aggregation inhibitors.

Novel inhibitors of the main protease enzyme of SARS-CoV-2 identified via molecular dynamics simulation-guided in vitro assay.

For the COVID-19 pandemic caused by SARS-CoV-2, there are currently no effective drugs or vaccines to treat this coronavirus infection. In this study, we focus on the main protease enzyme of SARS-CoV-2, 3CLpro, which is critical for viral replication. We employ explicit solvent molecular dynamics simulations of about 150 compounds docked into 3CLpro's binding site and that had emerged as good main protease ligands from our previous in silico screening of over 1.2 million compounds. By incoporating protein dynamics and applying a range of structural descriptors, such as the ability to form specific contacts with the catalytic dyad residues of 3CLpro and the structural fluctuations of the ligands in the binding site, we are able to further refine our compound selection. Fourteen compounds including estradiol shown to be the most promising based on our calculations were procured and screened against recombinant 3CLpro in a fluorescence assay. Eight of these compounds have significant activity in inhibiting the SARS-CoV-2 main protease. Among these are corilagin, a gallotannin, and lurasidone, an antipsychotic drug, which emerged as the most promising natural product and drug, respectively, and might thus be candidates for drug repurposing for the treatment of COVID-19. In addition, we also tested the inhibitory activity of testosterone, and our results reveal testosterone as possessing moderate inhibitory potency against the 3CLpro enzyme, which may thus provide an explanation why older men are more severely affected by COVID-19.

The Influences of Sulphation, Salt Type, and Salt Concentration on the Structural Heterogeneity of Glycosaminoglycans.

The increasing recognition of the biochemical importance of glycosaminoglycans (GAGs) has in recent times made them the center of attention of recent research investigations. It became evident that subtle conformational factors play an important role in determining the relationship between the chemical composition of GAGs and their activity. Therefore, a thorough understanding of their structural flexibility is needed, which is addressed in this work by means of all-atom molecular dynamics (MD) simulations. Four major GAGs with different substitution patterns, namely hyaluronic acid as unsulphated GAG, heparan-6-sulphate, chondroitin-4-sulphate, and chondroitin-6-sulphate, were investigated to elucidate the influence of sulphation on the dynamical features of GAGs. Moreover, the effects of increasing NaCl and KCl concentrations were studied as well. Different structural parameters were determined from the MD simulations, in combination with a presentation of the free energy landscape of the GAG conformations, which allowed us to unravel the conformational fingerprints unique to each GAG. The largest effects on the GAG structures were found for sulphation at position 6, as well as binding of the metal ions in the absence of chloride ions to the carboxylate and sulphate groups, which both increase the GAG conformational flexibility.

High Throughput Virtual Screening to Discover Inhibitors of the Main Protease of the Coronavirus SARS-CoV-2.

We use state-of-the-art computer-aided drug design (CADD) techniques to identify prospective inhibitors of the main protease enzyme, 3CLpro of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causing COVID-19. From our screening of over one million compounds including approved drugs, investigational drugs, natural products, and organic compounds, and a rescreening protocol incorporating enzyme dynamics via ensemble docking, we have been able to identify a range of prospective 3CLpro inhibitors. Importantly, some of the identified compounds had previously been reported to exhibit inhibitory activities against the 3CLpro enzyme of the closely related SARS-CoV virus. The top-ranking compounds are characterized by the presence of multiple bi- and monocyclic rings, many of them being heterocycles and aromatic, which are flexibly linked allowing the ligands to adapt to the geometry of the 3CLpro substrate site and involve a high amount of functional groups enabling hydrogen bond formation with surrounding amino acid residues, including the catalytic dyad residues H41 and C145. Among the top binding compounds we identified several tyrosine kinase inhibitors, which include a bioflavonoid, the group of natural products that binds best to 3CLpro. Another class of compounds that decently binds to the SARS-CoV-2 main protease are steroid hormones, which thus may be endogenous inhibitors and might provide an explanation for the age-dependent severity of COVID-19. Many of the compounds identified by our work show a considerably stronger binding than found for reference compounds with in vitro demonstrated 3CLpro inhibition and anticoronavirus activity. The compounds determined in this work thus represent a good starting point for the design of inhibitors of SARS-CoV-2 replication.

Rational Drug Design of Peptide-Based Therapies for Sickle Cell Disease.

Sickle cell disease (SCD) is a group of inherited disorders affecting red blood cells, which is caused by a single mutation that results in substitution of the amino acid valine for glutamic acid in the sixth position of the ß-globin chain of hemoglobin. These mutant hemoglobin molecules, called hemoglobin S, can polymerize upon deoxygenation, causing erythrocytes to adopt a sickled form and to suffer hemolysis and vaso-occlusion. Until recently, only two drug therapies for SCD, which do not even fully address the manifestations of SCD, were approved by the United States (US) Food and Drug Administration. A third treatment was newly approved, while a monoclonal antibody preventing vaso-occlusive crises is also now available. The complex nature of SCD manifestations provides multiple critical points where drug discovery efforts can be and have been directed. These notwithstanding, the need for new therapeutic approaches remains high and one of the recent efforts includes developments aimed at inhibiting the polymerization of hemoglobin S. This review focuses on anti-sickling approaches using peptide-based inhibitors, ranging from individual amino acid dipeptides investigated 30-40 years ago up to more promising 12- and 15-mers under consideration in recent years.

Identification of compounds with cytotoxic activity from the leaf of the Nigerian medicinal plant, Anacardium occidentale L. (Anacardiaceae).

Cancer is now the second-leading cause of mortality and morbidity, behind only heart disease, necessitating urgent development of (chemo)therapeutic interventions to stem the growing burden of cancer cases and cancer death. Plants represent a credible source of promising drug leads in this regard, with a long history of proven use in the indigenous treatment of cancer. This study therefore investigated Anacardium occidentale, one of the plants in a Nigerian Traditional Medicine formulation commonly used to manage cancerous diseases, for cytotoxic activity. Bioassay-guided fractionation, spectroscopy, Alamar blue fluorescence-based viability assay in cultured HeLa cells and microscopy were used. Four compounds, zoapatanolide A (1), agathisflavone (2), 1,2-bis(2,6-dimethoxy-4-methoxycarbonylphenyl)ethane (anacardicin, 3) and methyl gallate (4), were isolated, with the most potent being zoapatanolide A with an IC50 value of 36.2±9.8µM in the viability assay. To gain an insight into the likely molecular basis of their observed cytotoxic effects, Autodock Vina binding free energies of each of the isolated compounds with seven molecular targets implicated in cancer development (MAPK8, MAPK10, MAP3K12, MAPK3, MAPK1, MAPK7 and VEGF), were calculated. Pearson correlation coefficients were obtained with experimentally-determined IC50 in the Alamar blue viability assay. While these compounds were not as potent as a standard anticancer compound, doxorubicin, the results provide reasonable evidence that the plant species contains compounds with cytotoxic activity. This study provides some evidence of why this plant is used ethnobotanically in anticancer herbal formulations and justifies investigating Nigerian medicinal plants highlighted in recent ethnobotanical surveys.

Polyphenolic compounds with anti-tumour potential from Corchorus olitorius (L.) Tiliaceae, a Nigerian leaf vegetable.

Chromatographic fractionation of the methanolic extract of Corchorus olitorius (L.) (Tiliaceae), on silica gel yielded two polyphenolic compounds. The structures of the compounds were elucidated as Methyl-1,4,5-tri-O-caffeoyl quinate and trans-3-(4-Hydroxy-3-methoxyphenyl)acrylic anhydride, based on extensive use of spectroscopic techniques such as (1)H and (13)C NMR, DEPT and 2D NMR experiments (COSY, HSQC, HMBC), IR and MS. To establish an initial proof-of-concept for the biological relevance of these compounds, their cytotoxicity against the cancer cell lines HeLa, HL460 and PC3, which might indicate their anti-tumour potential, was assessed. The compounds when tested at a range of concentrations up to 1.6mM were found to possess mild cytotoxic activity which was significant against HeLa cells at ⩾800µM. The trans-3-(4-Hydroxy-3-methoxyl phenyl)acrylic anhydride was found to be related to curcumin, a compound known to have anti-cancer activity. Docking of each of the two compounds and also of curcumin into some molecular targets implicated in tumourigenesis revealed that the three compounds had binding affinities that were superior to those obtained for the co-crystallized inhibitors of metalloproteinase-9, fibroblast growth factor receptor 2 (FGFR2) and epidermal growth factor receptor (EGFR). The plant Corchorus olitorius therefore represents a potential source of natural 'lead' compounds with anti-tumour potential.

Antibiofilm agents with therapeutic potential against enteroaggregative Escherichia coli.

BACKGROUND: Enteroaggregative Escherichia coli (EAEC) is a predominant but neglected enteric pathogen implicated in infantile diarrhoea and nutrient malabsorption. There are no non-antibiotic approaches to dealing with persistent infection by these exceptional colonizers, which form copious biofilms. We screened the Medicines for Malaria Venture Pathogen Box for chemical entities that inhibit EAEC biofilm formation. METHODOLOGY: We used EAEC strains, 042 and MND005E in a medium-throughput crystal violet-based antibiofilm screen. Hits were confirmed in concentration-dependence, growth kinetic and time course assays and activity spectra were determined against a panel of 25 other EAEC strains. Antibiofilm activity against isogenic EAEC mutants, molecular docking simulations and comparative genomic analysis were used to identify the mechanism of action of one hit. PRINCIPAL FINDINGS: In all, five compounds (1.25%) reproducibly inhibited biofilm accumulation by at least one strain by 30-85% while inhibiting growth by under 10%. Hits exhibited potent antibiofilm activity at concentrations at least 10-fold lower than those reported for nitazoxanide, the only known EAEC biofilm inhibitor. Reflective of known EAEC heterogeneity, only one hit was active against both screen isolates, but three hits showed broad antibiofilm activity against a larger panel of strains. Mechanism of action studies point to the EAEC anti-aggregation protein (Aap), dispersin, as the target of compound MMV687800. CONCLUSIONS: This study identified five compounds, not previously described as anti-adhesins or Gram-negative antibacterials, with significant EAEC antibiofilm activity. Molecule, MMV687800 targets the EAEC Aap. In vitro small-molecule inhibition of EAEC colonization opens a way to new therapeutic approaches against EAEC infection.

Dataset of AMBER force field parameters of drugs, natural products and steroids for simulations using GROMACS.

We provide general AMBER force field (GAFF) parameters for 160 organic molecules including drugs, natural products, and steroids, which can be employed without further processing in molecular dynamics (MD) simulations using GROMACS. We determined these parameters based on quantum mechanical (QM) calculations involving geometry optimization at the HF6-31G* level of theory. For each molecule we provide a coordinate file of the three-dimensional molecular structure, the topology and the parameter file. The applicability of these parameters was demonstrated by MD simulations of these molecules bound to the active site of the main protease of the coronavirus SARS-CoV-2, 3CLpro, which is a main player during viral replication causing COVID-19.

Quinoline Antimalarials Increase the Antibacterial Activity of Ampicillin.

Bacterial and malaria co-infections are common in malaria endemic countries and thus necessitate co-administration of antibiotics and antimalarials. There have long been anecdotal clinical reports of interactions between penicillins and antimalarial agents, but the nature and mechanisms of these interactions remain to be investigated. In this study, we employed antimicrobial interaction testing methods to study the effect of two antimalarials on the antibacterial activity of ampicillin in vitro. Paper strip diffusion, a modified disc diffusion and checkerboard methods were used to determine the nature of interactions between ampicillin and quinoline antimalarials, chloroquine and quinine, against Gram-positive and Gram-negative bacteria. The impact of antimalarials and ampicillin-antimalarial drug combinations on cell integrity of test bacteria were determined by measuring potassium release. The tested antimalarials did not show substantial antibacterial activity but quinine was bactericidal at high concentrations. Chloroquine and quinine increased ampicillin activity, with increasing concentrations extending the antibacterial's inhibition zones by 2.7-4.4 mm and from 1.1 to over 60 mm, respectively. Observed interactions were largely additive with Fractional Inhibitory Concentration Indices of >0.5-1 for all ampicillin-antimalarial combinations. Quinine and, to a lesser extent, chloroquine increase the activity of ampicillin and potentially other ß-lactams, which has implications for combined clinical use.

Computer simulations of protein-membrane systems.

The interactions between proteins and membranes play critical roles in signal transduction, cell motility, and transport, and they are involved in many types of diseases. Molecular dynamics (MD) simulations have greatly contributed to our understanding of protein-membrane interactions, promoted by a dramatic development of MD-related software, increasingly accurate force fields, and available computer power. In this chapter, we present available methods for studying protein-membrane systems with MD simulations, including an overview about the various all-atom and coarse-grained force fields for lipids, and useful software for membrane simulation setup and analysis. A large set of case studies is discussed.

Computational Prospecting for the Pharmacological Mechanism of Activity: HIV-1 Inhibition by Ixoratannin A-2.

BACKGROUND: Ixora coccinea is a tropical ornamental shrub employed in ethnomedicine for the treatment of a number of diseases none of which include the Human Immunodeficiency Virus (HIV) infection. Ixoratannin A-2, one of the constituents, was previously identified via virtual-screening and experimentally confirmed to possess significant anti-HIV-1 activity in an in vitro CD4+ replication assay. This activity was observed to be significantly reduced in degree in viruses lacking the protein Vpu. This suggests the involvement of Vpu as well as other extra-Vpu macromolecules in its antiviral activity. METHODS: In the present computational search for the identity of the other macromolecules that could possibly explain the observed activity, a panel of fourteen established HIV-1 macromolecular targets was assembled against which ixoratannin A-2 and other major phytoconstituents of I. coccinea were virtually screened. RESULTS: Structural analyses of the computed ligand-bound complexes, as well as the careful investigation of the thermodynamic attributes of the predicted binding, revealed subtle selectivity patterns at the atomistic level that suggest the likely involvement of multiple macromolecular processes. Some of the binding interactions were found to be thermodynamically favourable, including the multidrug-resistant HIV protease enzyme, CXCR4 and the human elongin C protein all of which formed reasonably strong interactions with ixoratannin A-2 and other constituents of I. coccinea. CONCLUSION: Ixoratannin A-2's ability to favourably interact with multiple HIV-1 and human targets could explain its observed extra-Vpu antiviral activity. This, however, does not imply uncontrolled binding with all available targets; on the other hand, molecular size of ixoratannin A-2 and combination of functional groups confer on it a decent level of selectivity against many of the investigated HIV/AIDS targets.

Structural Basis of Antisickling Effects of Selected FDA Approved Drugs: A Drug Repurposing Study.

INTRODUCTION: Sickle cell disease is characterized by a point mutation involving substitution of glutamic acid at position 6 to valine. Encoded in this hydrophobic mutation is both an intrinsic capacity for the beta globin molecules to assemble into thermodynamically favoured polymeric states as well as a rational way of interrupting the aggregation. METHODS: In this work, starting with a theoretical model that employs occlusive binding onto the beta globin aggregation surface and using a range of computational methods and an effective energy for screening, a number of FDA approved drugs with computed aggregation inhibitory activities were identified. RESULTS AND CONCLUSION: The validity of the model was confirmed using sickling tests, after which pharmacophore models as well the structural basis for the observed antisickling effects were identified.

Structural Optimization of Mangiferin Binding to Cancer Molecular Targets: A Guide for Synthetic Derivatization.

INTRODUCTION: Nigerian medicinal plants have been demonstrated to be veritable source of lead compounds for drug discovery efforts. One such example is mangiferin. Mangiferin was originally isolated from the Nigerian plant Ceiba pentandra (Mombacaceae), after which its structure was elucidated with the aid of spectroscopy. Mangiferin, a xanthone glycoside, has also been reported in certain other plant families including Gentianaceae and Anacardiaceae. In certain other climes and different parts of the world, folkloric and traditional medicine has extensively employed Mangifera indica (another source of mangiferin) in treating different diseases. For many of such cultural uses carefully designed experimental investigations have been conducted confirming mangiferin's efficacies in those different pathologies which have included but not limited to cytotoxic as well as chemopreventive properties in selected cancer cell lines. METHODS: In this study, computational techniques were employed to profile the interaction of the xanthone glycoside at the atomistic level against nine selected molecular targets with clinical relevance in tumorigenesis. In attempt to investigate the potential of the mangiferin structure as a viable starting point for synthetic exploration of mangiferin-based analogs, extensive structural modifications were performed. RESULTS AND CONCLUSION: By analyzing the resulting structure-energetic pattern, critical points capable of improving mangiferin interaction with the profiled targets were identified. The outcome of this study provides both direction and impetus for synthetic derivitization of the mangiferin molecule into novel optimized inhibitors for anticancer lead development.

Schistosomiasis: Snail-vector control, molecular modelling and dynamic studies of bioactive N-acetylglycoside saponins from Tetrapleura tetraptera.

Schistosomiasis, a chronic neglected tropical disease caused by the Schistosoma spp. parasite, is associated with disabling patient symptoms. The new focus of the WHO roadmap on 'transmission control, wherever possible' offers drug development opportunities for intermediate-host control to prevent human-to-snail-to-human parasite transmission. Reports on the analysis of the impact of 'chemical-based mollusciciding' have concluded that constant application of molluscicides may contribute significantly towards the elimination of schistosomiasis in endemic areas. In South-Western Nigeria, Tetrapleura tetraptera is a tree whose fruit has been widely used in snail vector control. The presence of molluscicidal N-acetyl triterpene glycosides in the fruit has been reported. In this study, a bioactivity-directed fractionation of the fruit extract was performed to isolate the most potent molluscicidal saponin from the fruit. In an attempt to provide mechanistic insight into the observed activity, in silico screening was performed, profiling the molluscicidal N-acetyl triterpene glycosides reported from the fruit against two potential therapeutic targets in the mollusk used, NADH-ubiquinone oxidoreductase (NAD1) and retinoid X receptor. The docking predicted binary complexes of the saponins, which were subjected to explicit solvent conformational sampling from which patterns of structural stability were obtained. The binding energies alone did not account for the potency of the saponins indicating the influence of other factor like pharmacokinetic parameters. The study concluded that there is a preferential suitability of ND1's MWFE site for the rational design and development of novel molluscicidal agents.

Computational Analysis of Physicochemical Factors Driving CYP2D6 Ligand Interaction.

BACKGROUND: The metabolic action of CYP2D6 remains a crucial factor influencing the therapeutic outcomes for many drug molecules while others are either only slightly affected or not affected altogether. OBJECTIVE: This study seeks to understand, atomistic resolution, the structural and physicochemical factors influencing CYP2D6 metabolic discrimination. METHOD: Explicit solvent molecular dynamics simulations in GROMACS were employed to probe the conformational dynamics of CYP2D6 following which the most populated structures were employed for ligand interaction docking studies with AutoDock Vina using selected CYP2D6 drug substrates. RESULTS: Using atomistic treatment at the molecular mechanics level and multiple CYP2D6 conformations for docking, two primary ligand binding subsites (subsites A and B) were identified within an otherwise extensive ligand recognition site. The studied drug molecules were found to display distinct preference for either of the two subsites. Correlation and center-of-mass distribution analysis showed subsite binding preference to depend significantly on CYP2D6 conformation, as well as molecular properties such as molecular size and number of hydrogen bond donor present in the drug molecule. CONCLUSION: CYP2D6 binding subsite A was found to be relatively selective for small molecular weight with higher polarity compared with subsite B which tends to favor larger molecular weight and relatively hydrophobic molecules such as tamoxifen and imipramine. Our simulations further suggest that the ability of the CYP2D6 binding site residues to sample different conformations may partly account for its ability to metabolize diverse drug classes.

Structure-Based Study of Natural Products with Anti-Schistosoma Activity.

BACKGROUND: Schistosomiasis is a parasitic protozoal disease caused by flatworms of the genus Schistosoma. Although the disease threatens millions of lives, it is still at the top list of neglected tropical diseases and praziquantel, the only common schistosocidal drug in use, has records of decreasing efficiency and cases of resistance. Also, reports revealed that people in the rural areas, who are most affected, rely mostly on traditional herbal medicines because of limited access to modern healthcare. The use of computers in drug development has become a routine practice because they are cost and time effective. OBJECTIVE: We used computational techniques to discover potent Schistosoma inhibitors of natural product origin. METHODS: Computer-based techniques were employed to discover anti-schistosoma lead/hit from plant metabolites isolated from African medicinal plants which have shown activity or are responsible for activity against Schistosomes. The plant metabolites were evaluated for 'drug-likeness' and docked toward four selected validated Schistosoma drug targets; Glutathione S-transferase, Thioredoxin glutathione reductase, Histone deacetylase and Schistosoma masoni arginase, with PDB codes: 1M9A, 2X99, 4BZ8 and 4Q3T respectively. RESULTS: A total of 27 bioactive compounds with anti-Schistosoma history were retrieved from literature. The phytochemicals with Lipinski violation of ≤ 2 were found to exhibit comparable binding affinities toward the studied targets as the co-crystallized inhibitors. Predicted binding modes of the compounds toward respective target showed key intermolecular interactions involved in the ligandtarget relationship. Moreover, one of the compounds emerged as the most interesting candidate by both being drug-like and inhibiting the activities of the studied enzyme targets at micro-molar range. CONCLUSION: Our study identified schistosocidal leads with high bioavailability profile and the exploration of binding modes could lay the foundation for synthetic modification of the plant metabolites for the development of novel anti-schistosoma drug(s) with new mechanism of action.

Topology and parameter data of thirteen non-natural amino acids for molecular simulations with CHARMM22.

In this article we provide a data package containing the topology files and parameters compatible with the CHARMM22 force field for thirteen non-natural amino acids. The force field parameters were derived based on quantum mechanical (QM) calculations involving geometry optimization and potential energy surface scanning at the HF 6-31G(d) and HF 6-311G(d,p) levels of theory. The resulting energy data points were fitted to mathematical functions representing each component of the CHARMM22 force field. Further fine-tuning of the parameters utilized molecular mechanics energies, which were iteratively calculated and compared to the corresponding QM values until the latter were satisfactorily reproduced. The final force field data were validated with molecular dynamics simulations in explicit solvent conditions.

Early amyloid ß-protein aggregation precedes conformational change.

The aggregation of amyloid-ß protein (1-42) is studied at experimental concentrations using all-atom molecular dynamics simulations. We observe a fast aggregation into oligomers without significant changes in the internal structure of individual proteins. The aggregation process is characterized in terms of transition networks.

Structures of the amyloid ß-peptides Aß1-40 and Aß1-42 as influenced by pH and a D-peptide.

In this simulation study, we present a comparison of the secondary structure of the two major alloforms of the Alzheimer's peptide (Aß(1-40) and Aß(1-42)) on the basis of molecular dynamics (MD) simulations on thea microsecond time scale using the two GROMOS96 force fields ffG43a2 and ffG53a6. We observe peptide and force-field related differences in the sampled conformations of Aß(1-40) and Aß(1-42), which we characterize in terms of NMR chemical shifts calculated from the MD trajectories and validate against the corresponding experimental NMR results. From this analysis, we can conclude that ffG53a6 is better able to model the structural propensities of Aß(1-40) and Aß(1-42) than ffG43a2. Furthermore, we provide a description of the influences of pH and binding of D3, a 12-residue D-enantiomeric peptide with demonstrated antiamyloid effects, on the structure of Aß(1-42). We demonstrate that, under slightly acidic conditions, protonation of the three histidine residues in Aß(1-42) promotes the formation of ß-sheets via a reduction in electrostatic repulsion between the two terminal regions. Our studies further reveal that the binding between D3 and Aß(1-42) is driven by electrostatic interactions between negatively charged Aß(1-42) residues and the five positively charged arginine residues of D3. The binding of D3 was found to induce large conformational changes in the amyloid peptide, with a reduction in ß-sheet units being the most significant effect recorded, possibly explaining the observed amyloid-inhibiting properties of the D-peptide.