Analogues of diflunisal, an FDA-approved nonsteroidal antiinflammatory drug (NSAID), were synthesized and evaluated as inhibitors of transthyretin (TTR) aggregation, including amyloid fibril formation. High inhibitory activity was observed for 26 of the compounds. Of those, eight exhibited excellent binding selectivity for TTR in human plasma (binding stoichiometry >0.50, with a theoretical maximum of 2.0 inhibitors bound per TTR tetramer). Biophysical studies reveal that these eight inhibitors dramatically slow tetramer dissociation (the rate-determining step of amyloidogenesis) over a duration of 168 h. This appears to be achieved through ground-state stabilization, which raises the kinetic barrier for tetramer dissociation. Kinetic stabilization of WT TTR by these eight inhibitors is further substantiated by the decreasing rate of amyloid fibril formation as a function of increasing inhibitor concentration (pH 4.4). X-ray cocrystal structures of the TTR.18(2) and TTR.20(2) complexes reveal that 18 and 20 bind in opposite orientations in the TTR binding site. Moving the fluorines from the meta positions in 18 to the ortho positions in 20 reverses the binding orientation, allowing the hydrophilic aromatic ring of 20 to orient in the outer binding pocket where the carboxylate engages in favorable electrostatic interactions with the epsilon-ammonium groups of Lys 15 and 15'. The hydrophilic aryl ring of 18 occupies the inner binding pocket, with the carboxylate positioned to hydrogen bond to the serine 117 and 117' residues. Diflunisal itself appears to occupy both orientations based on the electron density in the TTR.1(2) structure. Structure-activity relationships reveal that para-carboxylate substitution on the hydrophilic ring and dihalogen substitution on the hydrophobic ring afford the most active TTR amyloid inhibitors.
Benzoxazoles pevent misfolding: Benzoxazole‐based inhibitors of transthyretin (TTR) amyloid fibril formation are among the most effective found to date. They stabilize TTR against both acid‐mediated misfolding and urea denaturation by raising the activation barrier to tetramer dissociation, the rate‐limiting step for amyloid formation. The figure depicts the cocrystal structure of one of the better benzoxazole inhibitors bound to TTR.
The severe acute respiratory syndrome (SARS) coronavirus encodes several RNA-processing enzymes that are unusual for RNA viruses, including Nsp15 (nonstructural protein 15), a hexameric endoribonuclease that preferentially cleaves 3 of uridines. We solved the structure of a catalytically inactive mutant version of Nsp15, which was crystallized as a hexamer. The structure contains unreported flexibility in the active site of each subunit. Substitutions in the active site residues serine 293 and proline 343 allowed Nsp15 to cleave at cytidylate, whereas mutation of leucine 345 rendered Nsp15 able to cleave at purines as well as pyrimidines. Mutations that targeted the residues involved in subunit interactions generally resulted in the formation of catalytically inactive monomers. The RNA-binding residues were mapped by a method linking reversible crosslinking, RNA affinity purification, and peptide fingerprinting. Alanine substitution of several residues in the RNA-contacting portion of Nsp15 did not affect hexamer formation but decreased the affinity of RNA binding and reduced endonuclease activity. This suggests a model for Nsp15 hexamer interaction with RNA.The Nidoviruses contain three families of viruses, including the Coronaviridae that cause numerous diseases in humans (1). Severe acute respiratory syndrome coronavirus (SARS-CoV) 3 is a member of the Coronavirus genus (2, 3). It originated from animals but spread to humans, causing severe respiratory distress with a fatality rate of ϳ10% (as shown by the World Health Organization, www.who.int/csr/ sars/country/en/country2003_08_15.pdf). In addition to their medical importance, coronaviruses are of interest for their large ϳ30-kb positive-strand genome and novel mechanisms that have evolved to replicate and transcribe this large RNA (5, 6). In keeping with the novel strategies used, coronaviruses encode several unusual RNA-processing enzymes, including an RNA endoribonuclease, an RNA methyltransferase, a second RNA-dependent RNA polymerase that generates primers for coronavirus replication (7), and a mechanism to decrease replication errors (8).Coronavirus subgenomic RNAs are particularly interesting in that they all have the same 5Ј leader sequence derived from the 5Ј end of the genomic RNA. This organization requires recombination as part of transcription. Various mechanisms have been proposed for subgenomic RNA production, but a discontinuous transcription mechanism is increasingly favored (5). This model proposes that transcription regulatory sequences in the minus-strand RNA direct translocation of the ternary complex to the 5Ј leader sequence, where transcription resumes. The minus-strand RNAs serves as the template for subgenomic RNA transcription. Ribonucleases that process the RNA intermediates for transcription have been proposed (9 -11), but the mechanism for the process is still not completely understood.Nsp15 (nonstructural protein 15) was predicted to be an RNA endoribonuclease as part of a bioinformatics analysis of the SARSCoV genome (7). S...
Polychlorinated biphenyls (PCBs) and their hydroxylated metabolites (OH-PCBs) are known to bind to transthyretin (TTR) in vitro, possibly explaining their bioaccumulation, rodent toxicity, and presumed human toxicity. Herein, we show that several OH-PCBs bind selectively to TTR in blood plasma; however, only one of the PCBs tested binds TTR in plasma. Some of the OH-PCBs displace thyroid hormone (T4) from TTR, rationalizing the toxicity observed in rodents, where TTR is the major T4 transporter. Thyroid binding globulin and albumin are the major T4 carriers in humans, making it unlikely that enough T4 could be displaced from TTR to be toxic. OH-PCBs are excellent TTR amyloidogenesis inhibitors in vitro because they bind to the TTR tetramer, imparting kinetic stability under amyloidogenic denaturing conditions. Four OH-PCB/TTR cocrystal structures provide further insight into inhibitor binding interactions.
The goal of this project was to better define the relationship between the endoribonuclease activity of murine hepatitis virus (MHV) Nsp15 (mNsp15) and its role in virus infection. Molecular modeling demonstrated that the catalytic residues of mNsp15 are superimposable with its severe acute respiratory syndrome coronavirus ortholog. Alanine substitutions at three key residues in the mNsp15 catalytic pocket (H262, H277, and G275) and a double-mutant version (H262P and H277A) generated proteins with greatly reduced but detectable endoribonuclease activities. Furthermore, these mutant proteins demonstrated lower cleavage specificities for uridylate than wild-type (WT) mNsp15. These mutations were successfully incorporated into viruses named vH262A, vH277A, vG275A, and vH262P؉H277A. All four mutant viruses formed plaques with diameters similar to that of MHV-A59 1000 (WT virus) on several different cell lines. Interestingly, viruses with a mutation at a noncatalytic residue, D324A, could not be recovered despite repeated attempts, and expression of mNsp15 containing the D324A mutation in Escherichia coli resulted in an insoluble protein. Plaques derived from vH262A produced approximately 6-to 13-fold fewer PFU than those from WT virus. Cells infected with mNsp15 mutant viruses accumulated lesser amounts of plus-and minus-sense subgenomic RNAs and spike protein than WT virus. The expression of mNsp15 in trans by transient transfection partially restored RNA synthesis by vH262A. These results demonstrate that mNsp15 is required for optimal infection by MHV.Coronaviruses are significant pathogens of humans and animals. They are also interesting because they use replication mechanisms that are unusual among the positive-stranded RNA viruses (18). For example, coronaviruses produce minusstrand subgenomic RNAs (sgRNAs) by a discontinuous transcription mechanism and utilize these as templates for subgenomic mRNA (sgmRNA) synthesis (18,22). In addition, the viral genome encodes a number of proteins that are not typically found in the positive-strand RNA viruses, including a potential RNA primase and several RNA-processing enzymes such as ExoN, XendoU, and cap methyltransferases (20,(24)(25)(26)32).One of these novel RNA-processing enzymes is nonstructural protein 15 (Nsp15), a hexameric endoribonuclease that preferentially cleaves 3Ј of uridylates (12,21,28). Severe acute respiratory syndrome coronavirus (SARS-CoV) recombinant Nsp15 (sNsp15) produced in Escherichia coli has endoribonuclease activity that is stimulated by Mn 2ϩ , generating a 2Ј,3Ј cyclophosphodiester cleavage product (2, 3). The structure of sNsp15 was first determined by electron microscopy and then by X-ray crystallography (3, 21). The structure of murine hepatitis virus (MHV) Nsp15 (mNsp15) was also recently solved (28). A mutation (D6408A) in the Nsp15 coding sequence of human coronavirus (HCoV) 229E prevented viral RNA accumulation, suggesting that HCoV-229E Nsp15 is required for viral replication (12).Both the arterivirus and coronavirus families are ...
The misfolding of transthyretin (TTR), including rate-limiting tetramer dissociation and partial monomer denaturation, is sufficient for TTR misassembly into amyloid and other abnormal quaternary structures associated with senile systemic amyloidosis, familial amyloid polyneuropathy, and familial amyloid cardiomyopathy. Monovalent small molecules that bind to one or both of the unoccupied thyroid hormone binding sites at the TTR quaternary structure interface stabilize the native state, raising the kinetic barrier for tetramer dissociation sufficiently that the rate of dissociation, and therefore amyloidosis, becomes slow. Bivalent amyloid inhibitors that bind to both binding sites simultaneously are reported herein. The candidate bivalent inhibitors are generally unable to bind to the native TTR tetramer and typically do not engage in monovalent binding owing to a strong inhibitor orientation preference. However, the TTR quaternary structure can assemble around several of the bivalent inhibitors if the inhibitor intercepts the protein before assembly occurs. Some of the wild-type TTR.bivalent inhibitor complexes prepared in this fashion retain a tetrameric structure when subjected to substantial denaturation stresses (8 M urea, 120 h). The best bivalent inhibitor reduced acid-mediated TTR (3.6 microM) amyloid fibril formation to 6% of that exhibited by TTR in the absence of inhibitor, a significant improvement over the approximately 30% observed for the best monovalent inhibitors (3.6 microM, 72 h). The apparent dissociation rate of the best bivalent inhibitor is effectively zero, consistent with the idea that TTR tetramer dissociation and inhibitor dissociation are linked-as a result of the inhibitor-templating tetramer assembly. X-ray cocrystal structures of two of the complexes demonstrate that the bivalent inhibitors simultaneously occupy both sites in TTR, consistent with the 1:1 binding stoichiometry derived from HPLC analysis. The purpose of this study was to demonstrate that bivalent inhibitors could be useful; what resulted are the best inhibitors produced to date. In this context, molecules capable of intercepting TTR during folding and assembly in the lumen of the endoplasmic reticulum would be of obvious interest.
Mutational analysis of the hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) template channel identified two residues, Trp(397) and His(428), which are required for de novo initiation but not for extension from a primer. These two residues interact with the Delta1 loop on the surface of the RdRp. A deletion within the Delta1 loop also resulted in comparable activities. The mutant proteins exhibit increased double-stranded RNA binding compared with the wild type, suggesting that the Delta1 loop serves as a flexible locking mechanism to regulate the conformations needed for de novo initiation and for elongative RNA synthesis. A similar locking motif can be found in other viral RdRps. Products associated with the open conformation of the HCV RdRp were inhibited by interaction with the retinoblastoma protein but not cyclophilin A. Different conformations of the HCV RdRp can thus affect RNA synthesis and interaction with cellular proteins.
Amyloid fibril formation by the plasma protein transthyretin (TTR), requiring rate-limiting tetramer dissociation and monomer misfolding, is implicated in several human diseases. Amyloidogenesis can be inhibited through native state stabilization, mediated by small molecule binding to TTR's primarily unoccupied thyroid hormone binding sites. New native state stabilizers have been discovered herein by the facile condensation of arylaldehydes with aryloxyamines affording a bisarylaldoxime ether library. Of the library's 95 compounds, 31 were active inhibitors of TTR amyloid formation in vitro. The bisaryloxime ethers selectively stabilize the native tetrameric state of TTR over the dissociative transition state under amyloidogenic conditions, leading to an increase in the dissociation activation barrier. Several bisaryloxime ethers bind selectively to TTR in human blood plasma over the plethora of other plasma proteins, a necessary attribute for efficacy in vivo. While bisarylaldoxime ethers are susceptible to degradation by N-O bond cleavage, this process is slowed by their binding to TTR. Furthermore, the degradation rate of many of the bisarylaldoxime ethers is slow relative to the half-life of plasma TTR. The bisaryloxime ether library provides valuable structure-activity relationship insight for the development of structurally analogous inhibitors with superior stability profiles, should that prove necessary.
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