Monomeric a-synuclein (aS) inhibits amyloidogenesis of human prion protein (hPrP) by forming a stable aS-hPrP hetero-dimer.

Intermolecular interaction between hPrP and αS was investigated using high-speed atomic force microscopy, dynamic light scattering, and nuclear magnetic resonance. We found that hPrP spontaneously gathered and naturally formed oligomers. Upon addition of monomer αS with a disordered conformation, poly-dispersive property of hPrP was lost, and hetero-dimer formation started quite coherently, and further oligomerization was not observed. Solution structure of hPrP-αS dimer was firstly characterized using hetero-nuclear NMR spectroscopy. In this hetero-dimeric complex, C-terminal helical region of hPrP was in the molten-globule like state, while specific sites including hot spot and C-terminal region of αS selectively interacted with hPrP. Thus αS may suppress amyloidogenesis of hPrP by trapping the hPrP intermediate by the formation of a stable hetero-dimer with hPrP.Abbreviations: hPrP, human prion protein of amino acid residues of 23-231; PrPC, cellular form of prion protein; PrPSc, scrapie form of prion protein, HS-AFM; high speed atomic force microscopy; αS, α-synuclein; DLS, dynamic light scattering.

Differences in fractal patterns and characteristic periodicities between word salads and normal sentences: Interference of meaning and sound.

Fractal dimensions and characteristic periodicities were evaluated in normal sentences, computer-generated word salads, and word salads from schizophrenia patients, in both Japanese and English, using the random walk patterns of vowels.　In normal sentences, the walking curves were smooth with gentle undulations, whereas computer-generated word salads were rugged with mechanical repetitions, and word salads from patients with schizophrenia were unreasonably winding with meaningless repetitive patterns or even artistic cohesion. These tendencies were similar in both languages. Fractal dimensions between normal sentences and word salads of schizophrenia were significantly different in Japanese [1.19 ± 0.09 (n = 90) and 1.15 ± 0.08 (n = 45), respectively] and English [1.20 ± 0.08 (n = 91), and 1.16 ± 0.08 (n = 42)] (p < 0.05 for both). Differences in long-range (>10) periodicities between normal sentences and word salads from schizophrenia patients were predominantly observed at 25.6 (p < 0.01) in Japanese and 10.7 (p < 0.01) in English. The differences in fractal dimension and characteristic periodicities of relatively long-range (>10) presented here are sensitive to discriminate between schizophrenia and healthy mental state, and could be implemented in social robots to assess the mental state of people in care.

Electrochemical and Mechanistic Study of Reactivities of α-, ß-, γ-, and δ-Tocopherol toward Electrogenerated Superoxide in N,N-Dimethylformamide through Proton-Coupled Electron Transfer.

Scavenging of superoxide radical anion (O2•-) by tocopherols (TOH) and related compounds was investigated on the basis of cyclic voltammetry and in situ electrolytic electron spin resonance spectrum in N,N-dimethylformamide (DMF) with the aid of density functional theory (DFT) calculations. Quasi-reversible dioxygen/O2•- redox was modified by the presence of TOH, suggesting that the electrogenerated O2•- was scavenged by α-, ß-, γ-TOH through proton-coupled electron transfer (PCET), but not by δ-TOH. The reactivities of α-, ß-, γ-, and δ-TOH toward O2•- characterized by the methyl group on the 6-chromanol ring was experimentally confirmed, where the methyl group promotes the PCET mechanism. Furthermore, comparative analyses using some related compounds suggested that the para-oxygen-atom in the 6-chromanol ring is required for a successful electron transfer (ET) to O2•- through the PCET. The electrochemical and DFT results in dehydrated DMF suggested that the PCET mechanism involves the preceding proton transfer (PT) forming a hydroperoxyl radical, followed by a PCET (intermolecular ET-PT). The O2•- scavenging by TOH proceeds efficiently along the PCET mechanism involving one ET and two PTs.

Improved Anti-Prion Nucleic Acid Aptamers by Incorporation of Chemical Modifications.

Nucleic acid aptamers are innovative and promising candidates to block the hallmark event in the prion diseases, that is the conversion of prion protein (PrP) into an abnormal form; however, they need chemical modifications for effective therapeutic activity. This communication reports on the development and biophysical characterization of a small library of chemically modified G-quadruplex-forming aptamers targeting the cellular PrP and the evaluation of their anti-prion activity. The results show the possibility of enhancing anti-prion aptamer properties through straightforward modifications.

The Principles of protein surgery and its application to the logical drug design for the treatment of neurodegenerative diseases.

Here we describe the principles of protein surgery and its application to the molecular design for regulating the protein conformation. We initially describe the Poincare duality that defines the basis of complementarity in the time-dependent geometrical space. Next we introduce the theory of protein surgery consisting of "dissection" and "suture," which correspond to differentiation and integration in a phase space, respectively. Then we introduce the surgical (pan-manifold) differential equation and solve several simple cases. In this way, we constructed "medical quantization" strategy which makes a bridge between quantum mechanics and molecular biology. As the application of this theory, here we describe a logical drug design methodology in detail, and its application to anti-prion drug design. Finally, we propose a plan for logical drug (and medical device) design center, in which all the necessary procedures could be done in one place.

Short disordered protein segment regulates cross-species transmission of a yeast prion.

Soluble prion proteins contingently encounter foreign prion aggregates, leading to cross-species prion transmission. However, how its efficiency is regulated by structural fluctuation of the host soluble prion protein remains unsolved. In the present study, through the use of two distantly related yeast prion Sup35 proteins, we found that a specific conformation of a short disordered segment governs interspecies prion transmissibility. Using a multidisciplinary approach including high-resolution NMR and molecular dynamics simulation, we identified critical residues within this segment that allow interspecies prion transmission in vitro and in vivo, by locally altering dynamics and conformation of soluble prion proteins. Remarkably, subtle conformational differences caused by a methylene group between asparagine and glutamine sufficed to change the short segment structure and substantially modulate the cross-seeding activity. Thus, our findings uncover how conformational dynamics of the short segment in the host prion protein impacts cross-species prion transmission. More broadly, our study provides mechanistic insights into cross-seeding between heterologous proteins.

Development and structural determination of an anti-PrPC aptamer that blocks pathological conformational conversion of prion protein.

Prion diseases comprise a fatal neuropathy caused by the conversion of prion protein from a cellular (PrPC) to a pathological (PrPSc) isoform. Previously, we obtained an RNA aptamer, r(GGAGGAGGAGGA) (R12), that folds into a unique G-quadruplex. The R12 homodimer binds to a PrPC molecule, inhibiting PrPC-to-PrPSc conversion. Here, we developed a new RNA aptamer, r(GGAGGAGGAGGAGGAGGAGGAGGA) (R24), where two R12s are tandemly connected. The 50% inhibitory concentration for the formation of PrPSc (IC50) of R24 in scrapie-infected cell lines was ca. 100 nM, i.e., much lower than that of R12 by two orders. Except for some antibodies, R24 exhibited the lowest recorded IC50 and the highest anti-prion activity. We also developed a related aptamer, r(GGAGGAGGAGGA-A-GGAGGAGGAGGA) (R12-A-R12), IC50 being ca. 500 nM. The structure of a single R12-A-R12 molecule determined by NMR resembled that of the R12 homodimer. The quadruplex structure of either R24 or R12-A-R12 is unimolecular, and therefore the structure could be stably formed when they are administered to a prion-infected cell culture. This may be the reason they can exert high anti-prion activity.

Discovery of a multipotent chaperone, 1-(2,6-Difluorobenzylamino)-3-(1,2,3,4-tetrahydrocarbazol-9-yl)-propan-2-ol with the inhibitory effects on the proliferation of prion, cancer as well as influenza virus.

We previously discovered three carbazole derivatives, GJP14 (1-piperidinylmethyl-2-(1-oxo-6-methyl-1,2,3,4-tetrahydrocarbazol-9-yl)-ethan-1-ol) with anti-prion activity, GJC29 (benzylamino-3-(1,2,3,4-tetrahydrocarbazol-9-yl)-propan-2-ol) with anti-cancer activity, and THC19 (1-piperidinylmethyl-2-(1,2,3,4-tetrahydrocarnazol-9-yl)-ethan-1-ol) with anti-influenza virus activity. During optimization of GJP14 for the anti-prion activity, we discovered a compound, 1-(2,6-difluorobenzylamino)-3-(1,2,3,4-tetrahydrocarbazol-9-yl)-propan-2-ol, termed 5Y, had the most strong anti-prion activity among a series of newly synthesized derivatives. Intriguingly, we noticed that 5Y had also the most strong anti-colon cancer as well as the anti-influenza virus activities among derivatives. No significant toxicity of 5Y was observed. These results demonstrate that 5Y is a multipotent lead compound with unusually wide spectrum, and may be applicable to therapeutics targeting multiple diseases.Abbreviations: MoPrP: mouse prion protein of amino acid residues of 23-231; PrPC: cellular form of prion protein; PrPSc: scrapie form of prion protein.

α-Synuclein chaperone suppresses nucleation and amyloidogenesis of prion protein.

Protein misfolding diseases are a group of devastating disorders characterized by structural conversion of a soluble protein into an amyloid-like aggregate. Typically, the structural conversion occurs by misfolding of a single disease-associated protein, such as α-synuclein (αS) in Parkinson's disease, amyloid-ß in Alzheimer's disease, and prion protein (PrP) in transmissible spongiform encephalopathies (TSEs). However, accumulating evidence has implicated that cross-interactions between heterologous amyloidogenic proteins dramatically impact on amyloidogenesis and disease pathology. Here we show αS in a monomeric state can suppress amyloidogenesis of PrP in vitro. Thioflavin-T assays and transmission electron miscopy revealed that monomeric αS inhibits the nucleation step of amyloidogenesis without inhibiting the growing step. Surface plasmon resonance and co-sedimentation assays neither detected interaction between αS and monomeric PrP nor fibrillar PrP. These results suggested that αS suppress amyloidogenesis of PrP by binding to a transiently accumulated intermediate, such as a partially unfolded state. Moreover, we found that oligomeric αS, which was recently suggested to interact with PrP, also did not interact with PrP. Taken together, our study revealed a chaperon-like activity of αS against PrP amyloidogenesis, suggesting a possible involvement of αS in the pathology of TSEs.

A designer molecular chaperone against transmissible spongiform encephalopathy slows disease progression in mice and macaques.

Transmissible spongiform encephalopathies (TSEs) are fatal neurodegenerative diseases that lack therapeutic solutions. Here, we show that the molecular chaperone (N,N'-([cyclohexylmethylene]di-4,1-phenylene)bis(2-[1-pyrrolidinyl]acetamide)), designed via docking simulations, molecular dynamics simulations and quantum chemical calculations, slows down the progress of TSEs. In vitro, the designer molecular chaperone stabilizes the normal cellular prion protein, eradicates prions in infected cells, prevents the formation of drug-resistant strains and directly inhibits the interaction between prions and abnormal aggregates, as shown via real-time quaking-induced conversion and in vitro conversion NMR. Weekly intraperitoneal injection of the chaperone in prion-infected mice prolonged their survival, and weekly intravenous administration of the compound in macaques infected with bovine TSE slowed down the development of neurological and psychological symptoms and reduced the concentration of disease-associated biomarkers in the animals' cerebrospinal fluid. The de novo rational design of chaperone compounds could lead to therapeutics that can bind to different prion protein strains to ameliorate the pathology of TSEs.

Identification of Alprenolol Hydrochloride as an Anti-prion Compound Using Surface Plasmon Resonance Imaging.

Prion diseases are transmissible neurodegenerative disorders of humans and animals, which are characterized by the aggregation of abnormal prion protein (PrPSc) in the central nervous system. Although several small compounds that bind to normal PrP (PrPC) have been shown to inhibit structural conversion of the protein, an effective therapy for human prion disease remains to be established. In this study, we screened 1200 existing drugs approved by the US Food and Drug Administration (FDA) for anti-prion activity using surface plasmon resonance imaging (SPRi). Of these drugs, 31 showed strong binding activity to recombinant human PrP, and three of these reduced the accumulation of PrPSc in prion-infected cells. One of the active compounds, alprenolol hydrochloride, which is used clinically as a ß-adrenergic blocker for hypertension, also reduced the accumulation of PrPSc in the brains of prion-infected mice at the middle stage of the disease when the drug was administered orally with their daily water from the day after infection. Docking simulation analysis suggested that alprenolol hydrochloride fitted into the hotspot within mouse PrPC, which is known as the most fragile structure within the protein. These findings provide evidence that SPRi is useful in identifying effective drug candidates for neurodegenerative diseases caused by abnormal protein aggregation, such as prion diseases.

A DISC1 point mutation promotes oligomerization and impairs information processing in a mouse model of schizophrenia.

Disrupted-in-schizophrenia 1 (DISC1) is strongly associated with schizophrenia, but it remains elusive how the modification of the intermolecular interaction of DISC1 affects the information processing in brain. We show that a DISC1 point mutation alters intermolecular cohesiveness promoting the phase separation, and disrupts sensorimotor gating monitored by the prepulse inhibition in a mouse model of schizophrenia. Although the conformation of DISC1 partial peptide with the schizophrenia-related mutation L607F in human or the corresponding L604F in mouse was essentially indistinguishable from the wild type (WT) as long as monitored by fluorescence, circular dichroism, ultracentrifugation, dynamic light scattering and nuclear magnetic resonance, the atomic force microscopy was able to detect their morphological distinctions. The WT peptides were round and well dispersed, while mutants were inhomogeneous and disrupted to form dimer to trimer that aligned along one direction without apparent aggregate formation. Homozygous L604F mutant mice created by CRISPR exhibited the significant decrease in DISC1 level in the immunohistopathology at the hippocampal region compared to the WTs. The ratio of prepulse inhibition of the homozygous mutant mice was significantly impaired compared to WTs. Altered DISC1 distribution or function caused by aberrant intermolecular interactions may contribute to information processing characteristics in schizophrenia.

A valine-to-lysine substitution at position 210 induces structural conversion of prion protein into a ß-sheet rich oligomer.

Prion diseases are fatal neurodegenerative diseases associated with structural conversion of α-helical prion protein (PrP) into its ß-sheet rich isoform (PrPSc). Previous genetic analyses have indicated that several amino acid residues involved in the hydrophobic core of PrP (such as V180, F198, and V210) play a critical role in the development of prion diseases. To understand how these hydrophobic residues would contribute to the α-to-ß conversion process of PrP, we substituted the V210 residue with bulkier (V210F, V210I, and V210L), smaller (V210A), and charged amino acids (V210K) and characterized its effects. Interestingly, although most of the mutations had little or no effect on the biochemical properties of PrP, the V210K mutation induced structural conversion of PrP into a ß-structure. The ß-inducing effect was prominent and observed even under a physiological condition (i.e., in the absence of denaturant, acidic pH, reducing agent, and high temperature) in contrast to the disease-associated mutations in the PrP gene. We also examined structural features of V210K PrP using guanidine-hydrochloride unfolding, dynamic light scattering, 8-anilino-1-naphthalene sulfonate fluorescence, and electron microscopy, and revealed that V210K PrP assembles into a non-fibrillar ß-rich oligomer. Thus, the α-to-ß conversion can be induced by introduction of a charged residue into the hydrophobic core, which provide novel insight into the structural dynamics of PrP.

Poly-L-histidine inhibits prion propagation in a prion-infected cell line.

Transmissible spongiform encephalopathies (TSEs) are a group of lethal neurodegenerative diseases involving the structural conversion of cellular prion protein (PrPC) into the pathogenic isoform (PrPSc) for which no effective treatment is currently available. Previous studies have implicated that a polymeric molecule with a repeating unit, such as pentosane polysulfate and polyamidoamide dendrimers, exhibits a potent anti-prion activity, suggesting that poly-(amino acid)s could be a candidate molecule for inhibiting prion propagation. Here, by screening a series of poly-(amino acid)s in a prion-infected neuroblastoma cell line (GTFK), we identified poly-L-His as a novel anti-prion compound with an IC50 value of 1.8 µg/mL (0.18 µM). This potent anti-prion activity was specific to a high-molecular-weight poly-L-His and absent in monomeric histidine or low-molecular-weight poly-L-His. Solution NMR data indicated that poly-L-His directly binds to the loop region connecting Helix 2 and Helix 3 of PrPC and sterically blocks the structural conversion toward PrPSc. Poly-L-His, however, did not inhibit prion propagation in a prion-infected mouse when administered intraperitoneally, suggesting that the penetration of blood-brain barrier and/or the chemical stability of this polypeptide must be addressed before its application in vivo. Taken together, this study revealed the potential use of poly-L-His as a novel treatment against TSEs. (203 words).

Daidzein reductase of Eggerthella sp. YY7918, its octameric subunit structure containing FMN/FAD/4Fe-4S, and its enantioselective production of R-dihydroisoflavones.

S-Equol is a metabolite of daidzein, a type of soy isoflavone, and three reductases are involved in the conversion of daidzein by specific intestinal bacteria. S-Equol is thought to prevent hormone-dependent diseases. We previously identified the equol producing gene cluster (eqlABC) of Eggerthella sp. YY7918. Daidzein reductase (DZNR), encoded by eqlA, catalyzes the reduction of daidzein to dihydrodaidzein (the first step of equol synthesis), which was confirmed using a recombinant enzyme produced in Escherichia coli. Here, we purified recombinant DZNR to homogeneity and analyzed its enzymological properties. DZNR contained FMN, FAD, and one 4Fe-4S cluster per 70-kDa subunit as enzymatic cofactors. DZNR reduced the CC bond between the C-2 and C-3 positions of daidzein, genistein, glycitein, and formononetin in the presence of NADPH. R-Dihydrodaidzein and R-dihydrogenistein were highly stereo-selectively produced from daidzein and genistein. The Km and kcat for daidzein were 11.9 µM and 6.7 s-1, and these values for genistein were 74.1 µM and 28.3 s-1, respectively. This enzyme showed similar kinetic parameters and wide substrate specificity for isoflavone molecules. Thus, this enzyme appears to be an isoflavone reductase. Gel filtration chromatography and chemical cross-linking analysis of the active form of DZNR suggested that the enzyme consists of an octameric subunit structure. We confirmed this by small-angle X-ray scattering and transmission electron microscopy at a magnification of ×200,000. DZNR formed a globular four-petal cloverleaf structure with a central vertical hole. The maximum particle size was 173 Å.

Evidence for a central role of PrP helix 2 in the nucleation of amyloid fibrils.

Amyloid fibrils are filamentous protein aggregates associated with the pathogenesis of a wide variety of human diseases. The formation of such aggregates typically follows nucleation-dependent kinetics, wherein the assembly and structural conversion of amyloidogenic proteins into oligomeric aggregates (nuclei) is the rate-limiting step of the overall reaction. In this study, we sought to gain structural insights into the oligomeric nuclei of the human prion protein (PrP) by preparing a series of deletion mutants lacking 14-44 of the C-terminal 107 residues of PrP and examined the kinetics and thermodynamics of these mutants in amyloid formation. An analysis of the experimental data using the concepts of the Φ-value analysis indicated that the helix 2 region (residues 168-196) acquires an amyloid-like ß-sheet during nucleation, whereas the other regions preserves a relatively disordered structure in the nuclei. This finding suggests that the helix 2 region serves as the nucleation site for the assembly of amyloid fibrils.-Honda, R., Kuwata, K. Evidence for a central role of PrP helix 2 in the nucleation of amyloid fibrils.

Acceleration of nucleation of prion protein during continuous ultrasonication.

Although pulsatile irradiation of ultrasonication is frequently used for generating amyloid fibrils in vitro, the potential for inducing amyloid fibrillation of proteins during continuous ultrasonication is unknown. In this study, we implemented a continuous irradiation system and measured far-ultraviolet circular dichroism in a real-time manner. During the continuous ultrasonication, the conformation of full-length mouse prion protein (mPrP) was rapidly altered without a lag time and electron microscopy revealed that distorted fibrils, ß-oligomers and amorphous aggregates were formed at pH 2.2, 4.0 and 9.1, respectively. Similarly, hen egg white lysozyme formed distorted fibrils and small and large amorphous aggregates at pH 2.2 and 7.1 and 11.9, respectively, without a lag time. The concentration dependencies of the initial rates were different between the two systems. The aggregate formation of mPrP followed a first-order reaction, whereas that of lysozyme followed the zeroth-order reaction. Importantly, the reactions were immediately stopped by switching off ultrasonication, and restarted instantaneously when ultrasonication was restarted. Thus, the continuous ultrasonication significantly accelerates the nucleations of mPrP and lysozyme aggregates by the interaction between monomer and cavitation bubble. These cavitation bubbles may act as catalysts that decrease the activation free energy for nucleation, which is low in mPrP and high in lysozyme.

Molecular basis for diversification of yeast prion strain conformation.

Self-propagating ß-sheet-rich fibrillar protein aggregates, amyloid fibers, are often associated with cellular dysfunction and disease. Distinct amyloid conformations dictate different physiological consequences, such as cellular toxicity. However, the origin of the diversity of amyloid conformation remains unknown. Here, we suggest that altered conformational equilibrium in natively disordered monomeric proteins leads to the adaptation of alternate amyloid conformations that have different phenotypic effects. We performed a comprehensive high-resolution structural analysis of Sup35NM, an N-terminal fragment of the Sup35 yeast prion protein, and found that monomeric Sup35NM harbored latent local compact structures despite its overall disordered conformation. When the hidden local microstructures were relaxed by genetic mutations or solvent conditions, Sup35NM adopted a strikingly different amyloid conformation, which redirected chaperone-mediated fiber fragmentation and modulated prion strain phenotypes. Thus, dynamic conformational fluctuations in natively disordered monomeric proteins represent a posttranslational mechanism for diversification of aggregate structures and cellular phenotypes.

Protein-Ligand Dissociation Simulated by Parallel Cascade Selection Molecular Dynamics.

We investigated the dissociation process of tri-N-acetyl-d-glucosamine from hen egg white lysozyme using parallel cascade selection molecular dynamics (PaCS-MD), which comprises cycles of multiple unbiased MD simulations using a selection of MD snapshots as the initial structures for the next cycle. Dissociation was significantly accelerated by PaCS-MD, in which the probability of rare event occurrence toward dissociation was enhanced by the selection and rerandomization of the initial velocities. Although this complex was stable during 1 µs of conventional MD, PaCS-MD easily induced dissociation within 100-101 ns. We found that velocity rerandomization enhances the dissociation of triNAG from the bound state, whereas diffusion plays a more important role in the unbound state. We calculated the dissociation free energy by analyzing all PaCS-MD trajectories using the Markov state model (MSM), compared the results to those obtained by combinations of PaCS-MD and umbrella sampling (US), steered MD (SMD) and US, and SMD and the Jarzynski equality, and experimentally determined binding free energy. PaCS-MD/MSM yielded results most comparable to the experimentally determined binding free energy, independent of simulation parameter variations, and also gave the lowest standard errors.