Viral inclusion bodies (IBs), or replication factories, are unique structures generated by viral proteins together with some cellular proteins as a platform for efficient viral replication, but little is known about the mechanism underlying IB formation and fusion. Our previous study demonstrated that the interaction between the nucleoprotein (N) and phosphoprotein (P) of human parainfluenza virus type 3 (HPIV3), an enveloped virus with great medical impact, can form IBs. In this study, we found that small IBs can fuse with each other to form large IBs that enhance viral replication. Furthermore, we found that acetylated ␣-tubulin interacts with the N-P complex and colocalizes with IBs of HPIV3 but does not interact with the N-P complex of human respiratory syncytial virus or vesicular stomatitis virus and does not colocalize with IBs of human respiratory syncytial virus. Most importantly, enhancement of ␣-tubulin acetylation using the pharmacological inhibitor trichostatin A (TSA), RNA interference (RNAi) knockdown of the deacetylase enzymes histone deacetylase 6 (HDAC6) and sirtuin 2 (SIRT2), or expression of ␣-tubulin acetyltransferase 1 (␣-TAT1) resulted in the fusion of small IBs into large IBs and effective viral replication. In contrast, suppression of acetylation of ␣-tubulin by overexpressing HDAC6 and SIRT2 profoundly inhibited the fusion of small IBs and viral replication. Our findings offer previously unidentified mechanistic insights into the regulation of viral IB fusion by acetylated ␣-tubulin, which is critical for viral replication.IMPORTANCE Inclusion bodies (IBs) are unique structures generated by viral proteins and some cellular proteins as a platform for efficient viral replication. Human parainfluenza virus type 3 (HPIV3) is a nonsegmented single-stranded RNA virus that mainly causes lower respiratory tract disease in infants and young children. However, no vaccines or antiviral drugs for HPIV3 are available. Therefore, understanding virus-host interactions and developing new antiviral strategies are increasingly important. Acetylation on lysine (K) 40 of ␣-tubulin is an evolutionarily conserved modification and plays an important role in many cellular processes, but its role in viral IB dynamics has not been fully explored. To our knowledge, our findings are the first to show that acetylated ␣-tubulin enhances viral replication by regulating HPIV3 IB fusion.KEYWORDS inclusion bodies, human parainfluenza virus type 3, acetylated ␣-tubulin H uman parainfluenza virus type 3 (HPIV3) is a nonsegmented single-stranded RNA virus (NSV) that belongs to the Paramyxoviridae family and mainly causes lower respiratory tract disease in infants and young children (1). However, no vaccines are available for HPIV3, and therefore, a deeper understanding of the replication of HPIV3
Paramyxovirus particles, like other enveloped virus particles, are formed by budding from membranes of infected cells, and matrix (M) proteins are critical for this process. To identify the M protein important for this process, we have characterized the budding of the human parainfluenza virus type 3 (HPIV3) M protein. Our results showed that expression of the HPIV3 M protein alone is sufficient to initiate the release of virus-like particles (VLPs). Electron microscopy analysis confirmed that VLPs are morphologically similar to HPIV3 virions. We identified a leucine (L302) residue within the C terminus of the HPIV3 M protein that is critical for M protein-mediated VLP production by regulating the ubiquitination of the M protein. When L302 was mutated into A302, ubiquitination of M protein was defective, the release of VLPs was abolished, and the membrane binding and budding abilities of M protein were greatly weakened, but the M L302A mutant retained oligomerization activity and had a dominant negative effect on M protein-mediated VLP production. Furthermore, treatment with a proteasome inhibitor also inhibited M protein-mediated VLP production and viral budding. Finally, recombinant HPIV3 containing the M L302A mutant could not be rescued. These results suggest that L302 acts as a critical regulating signal for the ubiquitination of the HPIV3 M protein and virion release. IMPORTANCEHuman parainfluenza virus type 3 (HPIV3) is an enveloped virus with a nonsegmented negative-strand RNA genome. It can cause severe respiratory tract diseases, such as bronchiolitis, pneumonia, and croup in infants and young children. However, no valid antiviral therapy or vaccine is currently available. Thus, further elucidation of its assembly and budding will be helpful in the development of novel therapeutic approaches. Here, we show that a leucine residue (L302) located at the C terminus of the HPIV3 M protein is essential for efficient production of virus-like particles (VLPs). Furthermore, we found L302 regulated M protein-mediated VLP production via regulation of M protein ubiquitination. Recombinant HPIV3 containing the M L302A mutant is growth defective. These findings provide new insight into the critical role of M protein-mediated VLP production and virion release of a residue that does not belong to L domain and may advance our understanding of HPIV3 viral assembly and budding.
The measles virus (MeV) is a contagious pathogenic RNA virus of the family Paramyxoviridae, genus Morbillivirus, that can cause serious symptoms and even fetal complications. Here, we summarize current molecular advances in MeV research, and emphasize the connection between host cells and MeV replication. Although measles has reemerged recently, the potential for its eradication is promising with significant progress in our understanding of the molecular mechanisms of its replication and host-pathogen interactions.
The nucleoprotein (N) of vesicular stomatitis virus (VSV) plays a central role in transcription and replication by encapsidating genome RNA to form a nucleocapsid as the template for the RNA synthesis. Using minigenome system we evaluated the roles of 21 amino acids of the N-terminal arm of N in forming functional N-RNA templates and found that three triple-amino-acid substitutions (TVK4-6A3, RII7-9A3, and VIV13-15A3) and one single-amino-acid substitution (R7A) resulted in RNA synthesis loss. But all the mutants maintain the ability to oligomerize N, interact with P, and encapsidate viral RNA for template formation. Further analysis showed that the nucleocapsid formed by these mutants failed to protect RNA from nuclease digestion. Then, we found that only recombinant viruses containing R7A could be recovered. Our results show that the several amino acids within the N-terminal arm of N contribute to the template function beyond its role in RNA encapsidation and viral growth.
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