Junji Hosokawa-Muto

Hot spots in prion protein for pathogenic conversion

Prion proteins are key molecules in transmissible spongiform encephalopathies (TSEs), but the precise mechanism of the conversion from the cellular form (PrPC) to the scrapie form (PrPSc) is still unknown. Here we discovered a chemical chaperone to stabilize the PrPC conformation and identified the hot spots to stop the pathogenic conversion. We conducted in silico screening to find compounds that fitted into a “pocket” created by residues undergoing the conformational rearrangements between the native and the sparsely populated high-energy states (PrP*) and that directly bind to those residues. Forty-four selected compounds were tested in a TSE-infected cell culture model, among which one, 2-pyrrolidin-1-yl-N-[4-[4-(2-pyrrolidin-1-yl-acetylamino)-benzyl]-phenyl]-acetamide, termed GN8, efficiently reduced PrPSc. Subsequently, administration of GN8 was found to prolong the survival of TSE-infected mice. Heteronuclear NMR and computer simulation showed that the specific binding sites are the A-S2 loop (N159) and the region from helix B (V189, T192, and K194) to B-C loop (E196), indicating that the intercalation of these distant regions (hot spots) hampers the pathogenic conversion process. Dynamics-based drug discovery strategy, demonstrated here focusing on the hot spots of PrPC, will open the way to the development of novel anti-prion drugs.

Characterizing antiprion compounds based on their binding properties to prion proteins: implications as medical chaperones.

A variety of antiprion compounds have been reported that are effective in ex vivo and in vivo treatment experiments. However, the molecular mechanisms for most of these compounds remain unknown. Here we classified antiprion mechanisms into four categories: I, specific conformational stabilization; II, nonspecific stabilization; III, aggregation; and IV, interaction with molecules other than PrPC. To characterize antiprion compounds based on this classification, we determined their binding affinities to PrPC using surface plasmon resonance and their binding sites on PrPC using NMR spectroscopy. GN8 and GJP49 bound specifically to the hot spot in PrPC, and acted as “medical chaperones” to stabilize the native conformation. Thus, mechanisms I was predominant. In contrast, quinacrine and epigallocathechin bound to PrPC rather nonspecifically; these may stabilize the PrPC conformation nonspecifically including the interference with the intermolecular interaction following mechanism II. Congo red and pentosan polysulfate bound to PrPC and caused aggregation and precipitation of PrPC, thus reducing the effective concentration of prion protein. Thus, mechanism III was appropriate. Finally, CP‐60, an edarabone derivative, did not bind to PrPC. Thus these were classified into mechanism IV. However, their antiprion activities were not confirmed in the GT + FK system, whose details remain to be elucidated. This proposed antiprion mechanisms of diverse antiprion compounds could help to elucidate their antiprion activities and facilitate effective antiprion drug discovery.

Caffeoylquinic acids are major constituents with potent anti-influenza effects in brazilian green propolis water extract.

Influenza A viral infections reached pandemic levels in 1918, 1957, 1968, and, most recently, in 2009 with the emergence of the swine-origin H1N1 influenza virus. The development of novel therapeutics or prophylactics for influenza virus infection is urgently needed. We examined the evaluation of the anti-influenza virus (A/WSN/33 (H1N1)) activity of Brazilian green propolis water extract (PWE) and its constituents by cell viability and real-time PCR assays. Our findings showed strong evidence that PWE has an anti-influenza effect and demonstrate that caffeoylquinic acids are the active anti-influenza components of PWE. Furthermore, we have found that the amount of viral RNA per cell remained unchanged even in the presence of PWE, suggesting that PWE has no direct impact on the influenza virus but may have a cytoprotective activity by affecting internal cellular process. These findings indicate that caffeoylquinic acids are the active anti-influenza components of PWE. Above findings might facilitate the prophylactic application of natural products and the realization of novel anti-influenza drugs based on caffeoylquinic acids, as well as further the understanding of cytoprotective intracellular mechanisms in influenza virus-infected cells.

Synthesis of 9-substituted 2,3,4,9-tetrahydro-1H-carbazole derivatives and evaluation of their anti-prion activity in TSE-infected cells.

2,3,4,9-Tetrahydro-9-[2-hydroxy-3-(1-piperidinyl)propyl]-6-methyl-1H-carbazol-1-one (GJP14) is a novel anti-prion compound that we previously discovered by in silico screening and cellular assay. In this study, a variety of GJP14 derivatives were prepared using pyrrole derivatives, (haloalkyl)oxiranes, and amines, and their anti-prion activity was evaluated in TSE-infected cells. It was found that the tricyclic aromatic ring, a hydroxy group at the 2-position and an amino group at the 3-position of the N-propyl group were the basic requirements for anti-prion activity. The derivatives bearing an N-ortho-halobenzyl group exhibited an improved activity, and the most potent derivative was 8 times as effective as the original lead compound, GJP14.

3,4-Dicaffeoylquinic Acid, a Major Constituent of Brazilian Propolis, Increases TRAIL Expression and Extends the Lifetimes of Mice Infected with the Influenza A Virus

Brazilian green propolis water extract (PWE) and its chemical components, caffeoylquinic acids, such as 3,4-dicaffeoylquinic acid (3,4-diCQA), act against the influenza A virus (IAV) without influencing the viral components. Here, we evaluated the anti-IAV activities of these compounds in vivo. PWE or PEE (Brazilian green propolis ethanol extract) at a dose of 200 mg/kg was orally administered to Balb/c mice that had been inoculated with IAV strain A/WSN/33. The lifetimes of the PWE-treated mice were significantly extended compared to the untreated mice. Moreover, oral administration of 3,4-diCQA, a constituent of PWE, at a dose of 50 mg/kg had a stronger effect than PWE itself. We found that the amount of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) mRNA in the mice that were administered 3,4-diCQA was significantly increased compared to the control group, while H1N1 hemagglutinin (HA) mRNA was slightly decreased. These data indicate that PWE, PEE or 3,4-diCQA possesses a novel and unique mechanism of anti-influenza viral activity, that is, enhancing viral clearance by increasing TRAIL.

Characterization of Recombinant Rabies Virus Carrying Double Glycoprotein Genes

A recombinant rabies virus carrying double glycoprotein (G) genes, R(NPMGGL) strain, was generated by a reverse genetics system utilizing cloned cDNA of the RC‐HL strain, and the biological properties of the virus were compared to those of the recombinant RC‐HL (rRC‐HL) strain. The extents of virus growth in cultured cells and virulence for adult mice of the R(NPMGGL) strain were almost same as those of the rRC‐HL strain, while G protein content of the purified R(NPMGGL) virion and G protein expression level in R(NPMGGL)‐infected cells were 1.5‐fold higher than those of the rRC‐HL strain. As a result of serial passages of the R(NPMGGL) strain in cultured cells, the expression level of G protein in cultured cells infected with the passaged R(NPMGGL) strain was maintained and virus titers rose with adaptation to the cultured cells. Furthermore, analysis of neutralization titers in mice immunized with UV‐inactivated virus suggested that the R(NPMGGL) strain had higher immunogenicity than that of the rRC‐HL strain. The results suggest that the R(NPMGGL) strain carrying double G genes might be a useful candidate for development of a new inactivated rabies vaccine.

Synthesis of GN8 derivatives and evaluation of their antiprion activity in TSE-infected cells.

A series of GN8 derivatives were synthesized from various diamines, carboxylic acid derivatives, and nitrogen nucleophiles, and their antiprion activity was tested in TSE-infected mouse neuronal cells. We found that two ethylenediamine units, hydrophobic substituents on the nitrogen atoms, and the diphenylmethane scaffold were essential structural features responsible for the activity. Seven derivatives bearing substituents at the benzylic position exhibited an improved antiprion activity with the IC(50) values of 0.51-0.83 μM. Conformational analysis of model compounds suggested that the introduction of the substituent at the benzylic position restricted the conformational variability of the diphenylmethane unit.

Respiratory and cardiovascular toxicity studies of a novel antiprion compound, GN8, in rats and dogs.

Prion diseases, also known as transmissible spongiform encephalopathies, are fatal neurodegenerative disorders for which no effective curative or prophylactic method has been established. Recently, we discovered a novel antiprion compound, GN8. Administration of GN8 was found to prolong the survival of prion-infected mice. The aim of this study was to characterize the toxicological and pharmacological features of GN8 in rats and dogs treated via a single intravenous injection. Minimum lethal doses of GN8 were estimated to be approximately 60 and 40 mg/kg in rats and dogs, respectively. In the respiratory toxicity experiments, GN8 was administered to rats at doses of 0, 15.6, and 46.9 mg/kg, and rats were observed for consciousness, behavior, autonomic nervous symptoms, and body weights. GN8 was found to have little adverse effect on the rat respiratory system at a dose of 46.9 mg/kg. In the cardiovascular toxicity experiments, GN8 was administered to dogs at doses of 0, 7.8, and 31.3 mg/kg, and dogs were observed similarly. Although GN8 was found to have a slight effect on the cardiovascular system at a dose of 31.3 mg/kg, we did not find severe adverse effects of GN8 at doses sufficient for antiprion activity. This study would serve as a stepping stone to a clinical application of GN8 as an antiprion agent.

Synthesis of double-fluorescent labeled prion protein for FRET analysis

An abnormal form of prion protein (PrP) is considered to be the pathogen in prion diseases. However, the structural details of this abnormal form are not known. To characterize the non-native structure of PrP, we synthesized position-specific double-fluorescent labeled PrP for a fluorescence resonance energy transfer (FRET) experiment. Using FRET, we observed a conformational change in the labeled PrP associated with amyloid fibril formation. The FRET analysis indicated that the distance between fluorescent labeled N- and C-terminal sites of PrP increased upon the formation of amyloid fibrils compared with that of the native state. This approach using FRET analysis is useful for elucidating the structure of abnormal PrP. Graphical abstract The double-fluorescent labeled PrP is a useful for analyses of the structure and the formation of amyloid fibrils or PrPSc by using FRET.