Modified Vaccinia Ankara (MVA) was recently approved as a smallpox vaccine. Variola is transmitted by respiratory droplets and MVA immunization by skin scarification (s.s.) protected mice far more effectively against lethal respiratory challenge with vaccinia virus (VACV) than any other route of delivery, and at lower doses. Comparisons of s.s. with intradermal, subcutaneous, or intramuscular routes showed that MVAOVA s.s.-generated T cells were both more abundant and transcriptionally unique. MVAOVA s.s. produced greater numbers of lung Ova-specific CD8+ TRM and was superior in protecting mice against lethal VACVOVA respiratory challenge. Nearly as many lung TRM were generated with MVAOVA s.s. immunization compared to intra-tracheal immunization with MVAOVA and both routes vaccination protected mice against lethal pulmonary challenge with VACVOVA. Strikingly, MVAOVA s.s.-generated effector T cells exhibited overlapping gene transcriptional profiles to those generated via intra-tracheal immunization. Overall, our data suggest that heterologous MVA vectors immunized via s.s. are uniquely well-suited as vaccine vectors for respiratory pathogens, which may be relevant to COVID-19. In addition, MVA delivered via s.s. could represent a more effective dose-sparing smallpox vaccine.
The assembly of hepatitis C virus (HCV), a complicated process in which many viral and cellular factors are involved, has not been thoroughly deciphered. NS3 is a multifunctional protein that contains an N-terminal amphipathic ␣ helix (designated helix ␣ 0 ), which is crucial for the membrane association and stability of NS3 protein, followed by a serine protease domain and a C-terminal helicase/NTPase domain. NS3 participates in HCV assembly likely through its C-terminal helicase domain, in which all reported adaptive mutations enhancing virion assembly reside. In this study, we determined that the N-terminal helix ␣ 0 of NS3 may contribute to HCV assembly. We identified a single mutation from methionine to threonine at amino acid position 21 (M21T) in helix ␣ 0 , which significantly promoted viral production while having no apparent effect on the membrane association and protease activity of NS3. Subsequent analyses demonstrated that the M21T mutation did not affect HCV genome replication but rather promoted virion assembly. Further study revealed a shift in the subcellular localization of core protein from lipid droplets (LD) to the endoplasmic reticulum (ER). Finally, we showed that the M21T mutation increased the colocalization of core proteins and viral envelope proteins, leading to a more efficient envelopment of viral nucleocapsids. Collectively, the results of our study revealed a new function of NS3 helix ␣ 0 and aid understanding of the role of NS3 in HCV virion morphogenesis.IMPORTANCE HCV NS3 protein possesses the protease activity in its N-terminal domain and the helicase activity in its C-terminal domain. The role of NS3 in virus assembly has been mainly attributed to its helicase domain, because all adaptive mutations enhancing progeny virus production are found to be within this domain. Our study identified, for the first time to our knowledge, an adaptive mutation within the N-terminal helix ␣ 0 domain of NS3 that significantly enhanced virus assembly while having no effect on viral genome replication. The mechanistic studies suggested that this mutation promoted the relocation of core proteins from LD to the ER, leading to a more efficient envelopment of viral nucleocapsids. Our results revealed a possible new function of helix ␣ 0 in the HCV life cycle and provided new clues to understanding the molecular mechanisms for the action of NS3 in HCV assembly.KEYWORDS HCV, NS3, core, helix ␣ 0 , assembly, hepatitis C virus
During vegetative development, higher plants continuously form new leaves in regular spatial and temporal patterns. Mutants with abnormal leaf developmental patterns not only provide a great insight into understanding the regulatory mechanism of plant architecture, but also enrich the ways to its modification by which crop yield could be improved. Here, we reported the characterization of the rice leafy-head2 (lhd2) mutant that exhibits shortened plastochron, dwarfism, reduced tiller number, and failure of phase transition from vegetative to reproductive growth. Anatomical and histological study revealed that the rapid emergence of leaves in lhd2 was resulted from the rapid initiation of leaf primordia whereas the reduced tiller number was a consequence of the suppression of the tiller bud outgrowth. The molecular and genetic analysis showed that LHD2 encodes a putative RNA binding protein with 67% similarity to maize TE1. Comparison of genome-scale expression profiles between wild-type and lhd2 plants suggested that LHD2 may regulate rice shoot development through KNOX and hormone-related genes. The similar phenotypes caused by LHD2 mutation and the conserved expression pattern of LHD2 indicated a conserved mechanism in controlling the temporal leaf initiation in grass.
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