Nucleoprotein phosphorylation site (Y385) mutation confers temperature sensitivity to influenza A virus due to impaired nucleoprotein oligomerization at a lower temperature

Phosphorylation of PA at serine 225 enhances viral fitness of the highly pathogenic H5N1 avian influenza virus in mice

Currently, there is increasing spillover of highly pathogenic H5N1 avian influenza virus (AIV) to mammals, raising a concern of pandemic threat about this virus. Although the function of PA protein of the influenza virus is well understood, the understanding of how phosphorylation regulates this protein and influenza viral life cycle is still limited. We previously identified PA S225 as the phosphorylation site in the highly pathogenic H5N1 AIV. In this study, we investigated the role of phosphorylation in regulating PA function and viral fitness through dephosphorylation (PA S225A) or continuous phosphorylation (PA S225E)-mimetic mutation of PA S225. Structure analysis revealed that PA S225A or PA S225E mutation had no obvious effect on the structure of PA protein. Replication assay in vitro showed that PA S225A phosphorylation-ablative mutation significantly inhibited virus replication both in mammalian and avian-derived cells, while PA S225E enhanced viral replication in these cells. Correspondingly, PA S225A dephosphorylation significantly attenuated viral replication and virulence in mice, while PA S225E enhanced these aspects in mice. Mechanistically, PA S225A mutation significantly decreased viral polymerase activity, disabled viral ribonucleoprotein complex (vRNP) assembly and attenuated PA nuclear accumulation. Altogether, our study directly suggested that phosphorylation of PA protein at site S225 enhances viral fitness of the highly pathogenic H5N1 virus in mammals by assuring effective vRNP activity, providing a framework for further study of phosphorylation events in influenza virus life cycle.

Phosphorylation of PB2 at serine 181 restricts viral replication and virulence of the highly pathogenic H5N1 avian influenza virus in mice

Influenza A virus (IAV) continues to pose a pandemic threat to public health, resulting a high mortality rate annually and during pandemic years. Posttranslational modification of viral protein plays a substantial role in regulating IAV infection. Here, based on immunoprecipitation (IP)-based mass spectrometry (MS) and purified virus-coupled MS, a total of 89 phosphorylation sites distributed among 10 encoded viral proteins of IAV were identified, including 60 novel phosphorylation sites. Additionally, for the first time, we provide evidence that PB2 can also be acetylated at site K187. Notably, the PB2 S181 phosphorylation site was consistently identified in both IP-based MS and purified virus-based MS. Both S181 and K187 are exposed on the surface of the PB2 protein and are highly conserved in various IAV strains, suggesting their fundamental importance in the IAV life cycle. Bioinformatic analysis results demonstrated that S181E/A and K187Q/R mimic mutations do not significantly alter the PB2 protein structure. While continuous phosphorylation mimicked by the PB2 S181E mutation substantially decreases viral fitness in mice, PB2 K187Q mimetic acetylation slightly enhances viral virulence in mice. Mechanistically, PB2 S181E substantially impairs viral polymerase activity and viral replication, remarkably dampens protein stability and nuclear accumulation of PB2, and significantly weakens IAV-induced inflammatory responses. Therefore, our study further enriches the database of phosphorylation and acetylation sites of influenza viral proteins, laying a foundation for subsequent mechanistic studies. Meanwhile, the unraveled antiviral effect of PB2 S181E mimetic phosphorylation may provide a new target for the subsequent study of antiviral drugs.

p38MAPK- and GSK3-Mediated Phosphorylation of Snakehead Vesiculovirus Phosphoprotein at Threonine 160 Facilitates Viral Replication

Phosphoprotein (P), co-factor of the polymerase (large protein, L) of single-stranded negative-sense RNA viruses, is phosphorylated during viral infection and its phosphorylation has been reported to play important roles in viral replication. However, the function of P phosphorylation in viral replication is still far from clear. Snakehead vesiculovirus (SHVV) is a kind of fish rhabdovirus that has caused serious economic losses in snakehead fish culture in China without any effective preventive or therapeutical measures currently. In this study, 4D label-free phosphoproteomics sequencing of SHVV-infected cells identified five phosphorylated sites on SHVV P, among which threonine 160 (T160) was proved to be phosphorylated. Overexpression of wild-type P, but not P-T160A or P-T160E mutant, promoted SHVV replication, suggesting that the T160 phosphorylation on the P protein is critical for SHVV replication. Moreover, we found that T160A or T160E mutation on SHVV P had no effect on the interactions of P-nucleoprotein (N), P-P, or P-L. Further study revealed that p38 mitogen-activated protein kinase (p38MAPK) and glycogen synthase kinase 3 (GSK3) interacted with SHVV P and mediated the T160 phosphorylation. Besides, overexpression of p38MAPK or GSK3 facilitated, while knockdown or activity inhibition of p38MAPK or GSK3 suppressed, SHVV replication. Overall, p38MAPK- and GSK3-mediated phosphorylation of the P protein at T160 is required for SHVV replication, which provided targets for designing anti-SHVV drugs and developing live-attenuated SHVV vaccines. Our study helps understand the role of P phosphorylation in the replication of single-stranded negative-sense RNA viruses. IMPORTANCE Phosphorylation of viral proteins plays important roles in viral replication. Currently, the role of phosphorylation of phosphoprotein (P) in the replication of single-stranded negative-sense RNA viruses is far from clear. Identification of the phosphorylated sites on viral P protein and the related host kinases is helpful for developing live-attenuated vaccines and designing antiviral drugs. This study focused on identifying the phosphorylated sites on P protein of a fish rhabdovirus SHVV, determining the related host kinases, and revealing the effects of the phosphorylated sites and kinases on SHVV replication. We found that SHVV P was phosphorylated at T160, which was mediated by the kinases p38MAPK and GSK3 to promote SHVV replication. This study is the first time to study the role of P phosphorylation in fish rhabdovirus replication.

Dynamic phospho-modification of viral proteins as a crucial regulatory layer of influenza A virus replication and innate immune responses

Influenza viruses are small RNA viruses with a genome of about 13 kb. Because of this limited coding capacity, viral proteins have evolved to fulfil multiple functions in the infected cell. This implies that there must be mechanisms allowing to dynamically direct protein action to a distinct activity in a spatio-temporal manner. Furthermore, viruses exploit many cellular processes, which also have to be dynamically regulated during the viral replication cycle. Phosphorylation and dephosphorylation of proteins are fundamental for the control of many cellular responses. There is accumulating evidence that this mechanism represents a so far underestimated level of regulation in influenza virus replication. Here, we focus on the current knowledge of dynamics of phospho-modifications in influenza virus replication and show recent examples of findings underlining the crucial role of phosphorylation in viral transport processes as well as activation and counteraction of the innate immune response.

Cyclophilin A is a key positive and negative feedback regulator within interleukin-6 trans-signaling pathway

Cyclophilin A (CypA), a member of the cyclophilin family, plays a vital role in microorganismal infections, inflammatory diseases, and cancers. Interleukin-6 (IL-6) is a pleiotropic cytokine, exerting variety of effects on inflammation, immune response, hematopoiesis, and tumor proliferation. Binding of IL-6 to soluble IL-6 receptor (sIL-6R) induces pro-inflammatory trans-signaling, which has been described to be stronger than anti-inflammatory classic signaling triggered by the binding of IL-6 to membrane-bound IL-6 receptor. Here we found that upon the treatment of IL-6 and sIL-6R, CypA inhibited the ubiquitination-mediated degradation of IL-6 membrane receptor gp130 and enhanced its dimerization, thereby positively regulated the IL-6 trans-signaling and increased the expression of downstream iNOS, IL-6, and CypA. Furthermore, CypA expression could be negatively regulated by suppressor of cytokine signaling 1 (SOCS1). The SH2 and Box domains of SOCS1 interacted with CypA and promoted its K48-linked ubiquitination-mediated degradation, which inhibited the IL-6 trans-signaling pathway. Collectively, our findings reveal an important role of CypA in the positive and negative feedback regulation of the IL-6 trans-signaling pathway.