Kenta Teruya

Orally Administered Amyloidophilic Compound Is Effective in Prolonging the Incubation Periods of Animals Cerebrally Infected with Prion Diseases in a Prion Strain-Dependent Manner

ABSTRACT The establishment of effective therapeutic interventions for prion diseases is necessary. We report on a newly developed amyloidophilic compound that displays therapeutic efficacy when administered orally. This compound inhibited abnormal prion protein formation in prion-infected neuroblastoma cells in a prion strain-dependent manner: effectively for RML prion and marginally for 22L prion and Fukuoka-1 prion. When the highest dose (0.2% [wt/wt] in feed) was given orally to cerebrally RML prion-inoculated mice from inoculation until the terminal stage of disease, it extended the incubation periods by 2.3 times compared to the control. The compound exerted therapeutic efficacy in a prion strain-dependent manner such as that observed in the cell culture study: most effective for RML prion, less effective for 22L prion or Fukuoka-1 prion, and marginally effective for 263K prion. Its effectiveness depended on an earlier start of administration. The glycoform pattern of the abnormal prion protein in the treated mice was modified and showed predominance of the diglycosylated form, which resembled that of 263K prion, suggesting that diglycosylated forms of abnormal prion protein might be least sensitive or resistant to the compound. The mechanism of the prion strain-dependent effectiveness needs to be elucidated and managed. Nevertheless, the identification of an orally available amyloidophilic chemical encourages the pursuit of chemotherapy for prion diseases.

Human Prion Protein (PrP) 219K Is Converted to PrPSc but Shows Heterozygous Inhibition in Variant Creutzfeldt-Jakob Disease Infection

Prion protein gene (PRNP) E219K is a human polymorphism commonly occurring in Asian populations but is rarely found in patients with sporadic Creutzfeldt-Jakob disease (CJD). Thus the polymorphism E219K has been considered protective against sporadic CJD. The corresponding mouse prion protein (PrP) polymorphism variant (mouse PrP 218K) is not converted to the abnormal isoform (PrPSc) and shows a dominant negative effect on wild-type PrP conversion. To define the conversion activity of this human molecule, we herein established knock-in mice with human PrP 219K and performed a series of transmission experiments with human prions. Surprisingly, the human PrP 219K molecule was converted to PrPSc in variant CJD infection, and the conversion occurred more efficiently than PrP 219E molecule. Notably the knock-in mice with PRNP codon 219E/K showed the least efficient conversion compared with their hemizygotes with PRNP codon 219E/0 or codon 219K/0, or homozygotes with PRNP codon 219E/E or codon 219K/K. This phenomenon indicated heterozygous inhibition. This heterozygous inhibition was observed also in knock-in mice with PRNP codon 129M/V genotype. In addition to variant CJD infection, the human PrP 219K molecule is conversion-competent in transmission experiments with sporadic CJD prions. Therefore, the protective effect of PRNP E219K against sporadic CJD might be due to heterozygous inhibition.

Antiprion activity of functionalized 9-aminoacridines related to quinacrine.

A library of functionalized 6-chloro-2-methoxy-(N(9)-substituted)acridin-9-amines structurally related to quinacrine were synthesized and evaluated for antiprion activity on four different cell models persistently infected with scrapie prion strains (ScN2a, N167, Ch2) or a human disease prion strain (F3). Most of the compounds were distinguished by the side chain attached to 9-amino of the acridine ring. These were dialkylaminoalkyl and phenyl with basic groups on the phenyl ring. The most promising compound was 6-chloro-2-methoxy-N-(4-(4-methylpiperazin-1-yl)phenyl)acridin-9-amine (15) which had submicromolar EC(50) values (0.1-0.7microM) on all cell models, was able to clear PrP(Sc) at non-toxic concentrations of 1.2-2.5microM, and was more active than quinacrine in terms of EC(50) values. Other promising compounds were 14 (a regioisomer of 15) and 17 which had a 1-benzylpiperidin-4-yl substituent attached to the 9-amino function. Activity was strongly dependent on the presence of a substituted acridine ring, which in this library comprised 6-chloro-2-methoxy substituents on the acridine ring. The side chains of 14, 15, and 17 have not been previously associated with antiprion activity and are interesting leads for further optimization of antiprion activity.

Structure-based design, synthesis, and evaluation of peptide-mimetic SARS 3CL protease inhibitors.

The design and evaluation of low molecular weight peptide-based severe acute respiratory syndrome (SARS) chymotrypsin-like protease (3CL) protease inhibitors are described. A substrate-based peptide aldehyde was selected as a starting compound, and optimum side-chain structures were determined, based on a comparison of inhibitory activities with Michael type inhibitors. For the efficient screening of peptide aldehydes containing a specific C-terminal residue, a new approach employing thioacetal to aldehyde conversion mediated by N-bromosuccinimide was devised. Structural optimization was carried out based on X-ray crystallographic analyses of the R188I SARS 3CL protease in a complex with each inhibitor to provide a tetrapeptide aldehyde with an IC(50) value of 98 nM. The resulting compound carried no substrate sequence, except for a P(3) site directed toward the outside of the protease. X-ray crystallography provided insights into the protein-ligand interactions.

Synthesis of cyclic RGD derivatives via solid phase macrocyclization using the Heck reaction

Abstract A novel intramolecular macrocyclization reaction on a solid support using the Heck reaction has been achieved. For head to tail cyclization on a solid support, the linear precursor was anchored to a chlorotrityl chloride resin via an ester linkage using the β-carboxyl group of Asp. The Heck coupling of acrylic acid amide to 3-iodobenzylamine on the solid support proceeds smoothly to yield a cyclic tetrapeptide derivative, which contains a new 3-substituted cinnamic acid template and Arg-Gly-Asp sequence. The macrocyclization reaction takes place considerably more rapidly on a solid support than in solution. The solid phase procedure was successfully used for the construction of cyclic RGD libraries having diverse side chain structures, combined with a variety of ring sizes.

The influence of PRNP polymorphisms on human prion disease susceptibility: an update

Two normally occurring polymorphisms of the human PRNP gene, methionine (M)/valine (V) at codon 129 and glutamic acid (E)/lysine (K) at codon 219, can affect the susceptibility to prion diseases. It has long been recognized that 129M/M homozygotes are overrepresented in sporadic Creutzfeldt–Jakob disease (CJD) patients and variant CJD patients, whereas 219E/K heterozygotes are absent in sporadic CJD patients. In addition to these pioneering findings, recent progress in experimental transmission studies and worldwide surveillance of prion diseases have identified novel relationships between the PRNP polymorphisms and the prion disease susceptibility. For example, although 219E/K heterozygosity confers resistance against the development of sporadic CJD, this genotype is not entirely protective against acquired forms (iatrogenic CJD and variant CJD) or genetic forms (genetic CJD and Gerstmann–Sträussler–Scheinker syndrome) of prion diseases. In addition, 129M/V heterozygotes predispose to genetic CJD caused by a pathogenic PRNP mutation at codon 180. These findings show that the effects of the PRNP polymorphisms may be more complicated than previously thought. This review aims to summarize recent advances in our knowledge about the influence of the PRNP polymorphisms on the prion disease susceptibility.

Amyloidophilic Compounds for Prion Diseases

Recent outbreaks of variant Creutzfeldt-Jakob disease and iatrogenic Creutzfeldt-Jakob disease have aroused great concern in many countries and have necessitated the development of suitable therapies. We have demonstrated that sulfated glycans such as pentosan polysulfate and fucoidan, and amyloidophilic compounds such as amyloid dye derivatives, styrylbenzoazole derivatives, and phenylhydrazine derivatives have efficacies in prion-infected animals. Amyloidophilic compounds present potentialities not only as therapeutic candidates but also as prion amyloid imaging probes for use in nuclear medicine technology such as positron emission tomography. A representative of styrylbenzoazole compounds has been used recently for clinical trials of brain prion amyloid imaging in patients. On the other hand, a representative of phenylhydrazine compounds, compB, displays excellent effectiveness in prolonging the incubation times of infected animals when given orally. However, both its anti-prion effectiveness in vitro and its therapeutic efficacy in vivo are consistently dependent on the prion strain. This prion-strain-dependency is similarly observed in other amyloidophilic compounds. Therefore, aside from further improvement of the safety profiles and pharmacokinetic properties of such compounds, elucidation and management in the mechanism of the prion strain-dependent effectiveness is necessary. Nevertheless, because compB studies suggest that amyloidophilic compounds are also therapeutic candidates for Alzheimers disease, amyloidophilic compounds might be attractive as drug candidates for various conformational diseases and hasten development of therapeutic drugs for prion diseases.

Total synthesis of [L40I, C90A, C109A]-human T-cell leukemia virus type 1 protease

Abstract [L40I, C90A, C109A]-Human T-cell leukemia virus type 1 protease, which contains 125 amino acid residues, was synthesized by means of the thioester method. The construction of the backbone of this protease, involved the synthesis of three building blocks, using the Boc solid-phase method. To suppress epimerization during the first segment coupling between Phe and Arg by the thioester method, DMF was employed as a solvent for the reaction. The amount of d -Phe-containing coupling product in the total product was less than 6% and the desired product was isolated by reversed-phase HPLC in 59% yield. The synthetic product showed enzymatic activities comparable to those reported for the [L40I, C90A, C109A]-human T-cell leukemia virus type 1 protease, prepared by an expression method.

Heterozygous inhibition in prion infection: the stone fence model.

The human PrP gene (PRNP) has two major polymorphic codons: 129 for methionine (M) or valine (V), and 219 for glutamate (E) or lysine (K). The PRNP heterozygotes appear to be protected from sporadic CJD compared to the PRNP homozygotes. The molecular mechanism responsible for these protective effects of PRNP heterozygosity has remained elusive. In this review, we describe the inhibition of PrP conversion observed in a series of transmission studies using PRNP heterozygous animal models. In vCJD infection, the conversion incompetent human PrP 129V molecules showed an inhibitory effect on the conversion of human PrP 129M molecules in the 129M/V heterozygous mice. Furthermore, though the human PrP 219E and PrP 219K were both conversion competent in vCJD infection, these conversion competent PrP molecules showed an inhibitory effect in the 219E/K heterozygous animals. To explain this heterozygous inhibition, we propose a possible mechanism designated as the stone fence model.

Binding and Selectivity of the Marine Toxin Neodysiherbaine A and Its Synthetic Analogues to GluK1 and GluK2 Kainate Receptors.

Dysiherbaine (DH) and neodysiherbaine A (NDH) selectively bind and activate two kainate-type ionotropic glutamate receptors, GluK1 and GluK2. The ligand-binding domains of human GluK1 and GluK2 were crystallized as bound forms with a series of DH analogues including DH, NDH, 8-deoxy-NDH, 9-deoxy-NDH and 8,9-dideoxy-NDH (MSVIII-19), isolated from natural sources or prepared by total synthesis. Since the DH analogues exhibit a wide range of binding affinities and agonist efficacies, it follows that the detailed analysis of crystal structure would provide us with a significant opportunity to elucidate structural factors responsible for selective binding and some aspects of gating efficacy. We found that differences in three amino acids (Thr503, Ser706 and Ser726 in GluK1 and Ala487, Asn690 and Thr710 in GluK2) in the ligand-binding pocket generate differences in the binding modes of NDH to GluK1 and GluK2. Furthermore, deletion of the C(9) hydroxy group in NDH alters the ligand conformation such that it is no longer suited for binding to the GluK1 ligand-binding pocket. In GluK2, NDH pushes and rotates the side chain of Asn690 (substituted for Ser706 in GluK1) and disrupts an interdomain hydrogen bond with Glu409. The present data support the idea that receptor selectivities of DH analogues resulted from the differences in the binding modes of the ligands in GluK1/GluK2 and the steric repulsion of Asn690 in GluK2. All ligands, regardless of agonist efficacy, induced full domain closure. Consequently, ligand efficacy and domain closure did not directly coincide with DH analogues and the kainate receptors.