田村 真生

Open reading frame 6 (ORF6), the accessory protein of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) that suppresses host type-I interferon signaling, possesses amyloidogenic sequences. ORF6 amyloidogenic peptides self-assemble to produce cytotoxic amyloid fibrils. Currently, the molecular properties of the ORF6 remain elusive. Here, we investigate the structural dynamics of the full-length ORF6 protein in a near-physiological environment using high-speed atomic force microscopy. ORF6 oligomers were ellipsoidal and readily assembled into ORF6 protofilaments in either a circular or a linear pattern. The formation of ORF6 protofilaments was enhanced at higher temperatures or on a lipid substrate. ORF6 filaments were sensitive to aliphatic alcohols, urea, and SDS, indicating that the filaments were predominantly maintained by hydrophobic interactions. In summary, ORF6 self-assembly could be necessary to sequester host factors and causes collateral damage to cells via amyloid aggregates. Nanoscopic imaging unveiled the innate molecular behavior of ORF6 and provides insight into drug repurposing to treat amyloid-related coronavirus disease 2019 complications.

LaIT2, composed of 59 amino acid residues, is a peptide toxin isolated from the venom of the Yaeyama scorpion, Liocheles australasiae. LaIT2 is toxic to insects but not most mammals. The N- and C-domains of LaIT2 are known to possess antimicrobial and insecticidal activities, respectively. However, the molecular mechanisms are largely unknown because of the lack of a three-dimensional structure of LaIT2. Thus, we elucidated the solution NMR structure of LaIT2. LaIT2 adopts a β-KTx-like two-domain structure, in which the N- and C-terminal domains form a random coil and an α-β-β motif, respectively. Trifluoro ethanol and liposomes titration experiments showed that the unstructured N-domain of LaIT2 has the ability to form an α-helix. The N-terminal helix is amphiphilic, and one side of the helix is positively charged. Measurements of the antimicrobial and insecticidal activities of LaIT2 mutants suggested K15 in the N-domain was found to be responsible for the antimicrobial activities, whereas L53 and L54 in the C-domain were key residues involved in the insecticidal activity. Moreover, K21 in the N-domain is important for both activities. Therefore, two domains are suggested that they work together to show antimicrobial and insecticidal activity.

In Japan, there are two species of scorpions, Madara scorpion (Isometrus maculatus) and Yaeyama scorpion (Liocheles australasiae), and both of them are living in Yaeyama island. It has been shown that Liocheles australasiae has venom including β-toxin acting on K+-channels (β-KTx) (Juichi et al., 2018) [1]. Interestingly, LaIT2, one of the toxins found in the venom of Liocheles australasiae, displays the virulence for insects but almost not for mammals. Until now, molecular mechanism of the functional specificity of LaIT2 is unknown. To clear this issue, we tried to establish the overexpression system of LaIT2 in Rosetta-gami B (DE3) pLysS, which have trxB/gor mutations to induce the disulfide bond formation. In this study, we have succeeded to overexpress the recombinant LaIT2 (rLaIT2) as a thioredoxin (Trx)-tagged protein, and established the purification protocol with Ni2+-NTA column chromatography, enterokinase digestion, and HPLC. We succeeded to obtain approximately 0.5 mg of rLaIT2 from the E. coli cells cultured in 1 L of M9 culture medium. Intramolecular disulfide bonding pattern of rLaIT2 was identified by endopeptidase fragmentation and mass spectrometry. rLaIT2 showed insecticidal activity and antimicrobial activity, and these are almost identical to those of natural LaIT2. 1H-15N HSQC spectrum of 15N-labeled rLaIT2 indicated that the rLaIT2 has a stable conformation.