Your search keyword '"Masashi Iwamoto"' showing total 2 results

1. A Single Adaptive Mutation in Sodium Taurocholate Cotransporting Polypeptide Induced by Hepadnaviruses Determines Virus Species Specificity.

Author

Takeuchi, Junko S., Kento Fukano, Masashi Iwamoto, Senko Tsukuda, Ryosuke Suzuki, Hideki Aizaki, Masamichi Muramatsu, Takaji Wakita, Sureau, Camille, and Koichi Watashi

Subjects

*TAUROCHOLIC acid, *HEPATITIS B virus, *GENETIC mutation, *EVOLUTIONARY theories, *COEVOLUTION

Abstract

Hepatitis B virus (HBV) and its hepadnavirus relatives infect a wide range of vertebrates, from fish to human. Hepadnaviruses and their hosts have a long history of acquiring adaptive mutations. However, there are no reports providing direct molecular evidence for such a coevolutionary "arms race" between hepadnaviruses and their hosts. Here, we present evidence suggesting that the adaptive evolution of the sodium taurocholate cotransporting polypeptide (NTCP), an HBV receptor, has been influenced by virus infection. Evolutionary analysis of the NTCPencoding genes from 20 mammals showed that most NTCP residues are highly conserved among species, exhibiting evolution under negative selection (dN/dS ratio [ratio of nonsynonymous to synonymous evolutionary changes] of <1); this observation implies that the evolution of NTCP is restricted by maintaining its original protein function. However, 0.7% of NTCP amino acid residues exhibit rapid evolution under positive selection (dN/dS ratio of >1). Notably, a substitution at amino acid (aa) 158, a positively selected residue, converting the human NTCP to a monkeytype sequence abrogated the capacity to support HBV infection; conversely, a substitution at this residue converting the monkey Ntcp to the human sequence was sufficient to confer HBV susceptibility. Together, these observations suggested a close association of the aa 158 positive selection with the pressure by virus infection. Moreover, the aa 158 sequence determined attachment of the HBV envelope protein to the host cell, demonstrating the mechanism whereby HBV infection would create positive selection at this NTCP residue. In summary, we provide the first evidence in agreement with the function of hepadnavirus as a driver for inducing adaptive mutation in host receptor. [ABSTRACT FROM AUTHOR]

Published

2019

2. A Novel Tricyclic Polyketide, Vanitaracin A, Specifically Inhibits the Entry of Hepatitis B and D Viruses by Targeting Sodium Taurocholate Cotransporting Polypeptide.

Author

Manabu Kaneko, Koichi Watashi, Shinji Kamisuki, Hiroki Matsunaga, Masashi Iwamoto, Fumihiro Kawai, Hirofumi Ohashi, Senko Tsukuda, Satomi Shimura, Ryosuke Suzuki, Hideki Aizaki, Masaya Sugiyama, Sam-Yong Park, Takayoshi Ito, Naoko Ohtani, Fumio Sugawara, Yasuhito Tanak, Masashi Mizokami, Camille Sureau, and Takaji Wakita

Subjects

*HEPATITIS B, *MICROORGANISMS, *GENETIC vectors, *EXTRACHROMOSOMAL DNA, *MOBILE genetic elements

Abstract

Anti-hepatitis B virus (HBV) drugs are currently limited to nucleos(t)ide analogs (NAs) and interferons. A challenge of drug development is the identification of small molecules that suppress HBV infection from new chemical sources. Here, from a fungusderived secondary metabolite library, we identify a structurally novel tricyclic polyketide, named vanitaracin A, which specifically inhibits HBV infection. Vanitaracin A inhibited the viral entry process with a submicromolar 50% inhibitory concentration (IC50) (IC50 = 0.61 ± 0.23 μ-tM), without evident cytotoxicity (50% cytotoxic concentration of >256 μ-tM; selectivity index value of >419) in primary human hepatocytes. Vanitaracin A did not affect the HBV replication process. This compound was found to directly interact with the HBV entry receptor sodium taurocholate cotransporting polypeptide (NTCP) and impaired its bile acid transport activity. Consistent with this NTCP targeting, antiviral activity of vanitaracin A was observed with hepatitis D virus (HDV) but not hepatitis C virus. Importantly, vanitaracin A inhibited infection by all HBV genotypes tested (genotypes A to D) and clinically relevant NA-resistant HBV isolate. Thus, we identified a fungal metabolite, vanitaracin A, which was a potent, well-tolerated, and broadly active inhibitor of HBV and HDV entry. This compound, or its related analogs, could be part of an antiviral strategy for preventing reinfection with HBV, including clinically relevant nucleos(t)ide analog-resistant virus. [ABSTRACT FROM AUTHOR]

Published

2015