Structure of Senecavirus A 3C Protease Revealed the Cleavage Pattern of 3C Protease in Picornaviruses.

Senecavirus A (SVA) is an emerging picornavirus infecting porcine of all age groups and causing foot and mouth disease (FMD)-like symptoms. One of its key enzymes is the 3C protease (3Cpro), which is similar to other picornaviruses and essential for virus maturation by controlling polyprotein cleavage and RNA replication. In this study, we reported the crystal structure of SVA 3Cpro at a resolution of 1.9 Å and a thorough structural comparison against all published picornavirus 3Cpro structures. Using statistical and graphical visualization techniques, we also investigated the sequence specificity of the 3Cpro. The structure revealed that SVA 3Cpro adopted a typical chymotrypsin-like fold with the S1 subsite as the most conservative site among picornavirus 3Cpro. The surface loop, A1-B1 hairpin, adopted a novel conformation in SVA 3Cpro and formed a positively charged protrusion around S' subsites. Correspondingly, SVA scissile bonds preferred Asp rather than neutral amino acids at P3' and P4'. Moreover, SVA 3Cpro showed a wide range tolerance to P4 residue volume (acceptable range: 67 Å3 to 141 Å3), such as aromatic side chain, in contrast to other picornaviruses. In summary, our results provided valuable information for understanding the cleavage pattern of 3Cpro. IMPORTANCE Picornaviridae is a group of RNA viruses that harm both humans and livestock. 3Cpro is an essential enzyme for picornavirus maturation, which makes it a promising target for antiviral drug development and a critical component for virus-like particle (VLP) production. However, the current challenge in the development of antiviral drugs and VLP vaccines includes the limited knowledge of how subsite structure determines the 3Cpro cleavage pattern. Thus, an extensive comparative study of various picornaviral 3Cpro was required. Here, we showed the 1.9 Å crystal structure of SVA 3Cpro. The structure revealed similarities and differences in the substrate-binding groove among picornaviruses, providing new insights into the development of inhibitors and VLP.

Enhanced rate capability and high-voltage cycling stability of single-crystal nickel-rich cathode by surface anchoring dielectric BaTiO3.

The single-crystal Ni-rich Li(NixCoyMn1-x-y)O2 cathode (NCM) demonstrates better cycle performance, enhanced tap density and improved mechanical structure stability, compared with polycrystalline NCM.However, limited Li+ transports, (003) plane slips and microcracks in large single particles hinder rate capability and cycle performance. To overcome these shortcomings,single-crystal NCM cathodes have been modified by nanosized tetragonal BaTiO3. Due to the dielectric properties, BaTiO3 particles induce electric field concentration at the BaTiO3-NCM-electrolyte interface. Thus, a large amount of lithium vacancies can be formed, providing sufficient sites for the hopping diffusion of lithium ions, thereby significantly enhancing the diffusion coefficient of Li+. Moreover, the redistribution of charges can inhibit the formation and accumulation of cathode-electrolyte-interface. Owing to the synergetic effect of BaTiO3, the BT-modified single-crystal NCM with the optimized loading shows a remarkable initial discharge capacity of 138.5 mAh g-1 and maintains 53.8% of its initial discharge capacity after 100 cycles under 5C at 4.5 V cut-off voltage. Overall, the proposed dielectric cathode-electrolyte-interface strategy can enhance Li+ ion transport and stabilize the interface structure, leading to improved rate performance. Meanwhile, the diffusion-induced state of charge gradient can also be inhibited, resulting in high structure stability of single-crystal NCMs under high rate and cut-off voltage cycling.