Acetylation of late expression factor 4 is crucial for the transcription and proliferation of Bombyx mori nucleopolyhedrovirus.

Late expression factor 4 (LEF4), RNA polymerase subunit of Bombyx mori nucleopolyhedrovirus (BmNPV), plays an enzymatic role to enhance the capping of pre-mRNA of late and very late genes. Lysine acetylation is a post-translational modification process having many important functions associated with the regulation of a gene expression. Our previous study on lysine acetylome in BmNPV infected BmN cells showed that LEF 4 was acetylated at lysine 76 (K76). However, it is still unclear whether the modification of K76 residue contributes to the modulation of viral gene transcription. To elucidate the role played by acetylation or deacetylation of LEF4 K76 in the transcription of viral genes, we constructed acetylation mimicking and deacetylation mimicking mutant virus, K76Q and K76R, respectively. We then transfected BmN cells with these mutants and analyzed the level of pre-mRNA at different times. The K76R showed a significant decrease in the mRNA transcription level of vp39 and p10 genes at 48 and 72 h post-transfection, while K76Q did not show any significant changes compared with lef4-Wt. We further detected the virus titer of lef4-Wt, K76Q [et] K76R, and it was found that K76R impaired the virus infectivity ability at 72 and 96 h, while K76Q did not affect the virus infectivity. Moreover, the yeast two hybrid technique (Y2H) showed that both mutants (K76Q [et] K76R) affected the association of LEF 4 with the P47 protein. Taken together, these results indicated that acetylation modification of K76 is important for the proper transcription of late and very late genes, and the effectiveness of viral infection. Keywords: BmNPV lef4 gene; lysine acetylation, late genes transcription; BmNPV p47 gene; infectivity.

Acetylation of nucleopolyhedrovirus P35 is crucial for its anti-apoptotic activity in silkworm, Bombyx mori.

Apoptosis is a characteristic feature of a nucleopolyhedrovirus infected insect cells. This defensive strategy of the insect cells also affects the viral infectivity. On the contrary, the P35 baculovirus apoptosis inhibitor impedes the insect cell apoptosis induced by viral infection. Our previous investigation of the Bombyx mori nucleopolyhedrovirus (BmNPV) acetylome showed that 3 lysine (K) (70, 127 and 256) sites of P35 were acetylated during infection. How these modifications affect the interaction between the insect cells and BmNPV is still unknown. In order to explore the underlying mechanism of P35 lysine acetylation, mutants with glutamine or arginine substitution were constructed to mimic the acetylated (Q) and deacetylated (R) state. ELISA and DNA fragmentation assay were used to ascertain the acetylation effects on apoptosis. Subsequently the results showed that acetylation of K70 upregulated the anti-apoptotic activity, thereby preventing apoptosis induced by insect cells. Caspase 1 activity assay further confirmed that, acetylated K70 exhibited a strong anti-apoptotic activity in cell lines infected with BmNPV. Intriguingly, an examination with the yeast 2 hybrid (Y2H) assay revealed an interaction with the silkworm caspase 1. Taken together, we demonstrated that acetylation of P35 is crucial for an interaction with caspase 1 and the upregulation of anti-apoptotic activity. Keywords: Bombyx mori; BmNPV; P35; acetylation; anti-apoptotic; caspase 1.

Role of the Bombyx mori nucleopolyhedrovirus LEF3 acetylation on viral replication.

Late expression factor 3 (LEF3) is a single-stranded DNA binding protein of Bombyx mori nucleopolyhedrovirus (BmNPV) with multiple functions. It is an essential factor for viral DNA replication and plays an important regulatory role during BmNPV infection. Our recent quantitative analysis of protein acetylome revealed for the first time that LEF3 can be acetylated at four lysine residues during the viral infection, but the underlying mechanism is unknown. Among the modification sites, two of them (K18 and K27) are located in the conserved nuclear localization sequence region. The acetylation level for K18 especially was up-regulated approximately 7.4 times after 36 h of post-infection. To understand the regulatory function of this modification, site-direct mutagenesis for acetylated mimic (K18Q) or deacetylated mimic (K18R) mutants was performed on LEF3. The fluorescence analysis results showed that the replication capacity of the virus was significantly reduced after K18 acetylation. Meanwhile, co-localization analysis revealed that acetylation at K18 caused LEF3 to lose its nuclear targeting ability and affected the interaction between LEF3 and P143, retaining P143 in the cytoplasm. And further Yeast two-hybrid analysis results also confirmed that the acetylation at K18 did affect the interaction between LEF3 and P143. In conclusion, the acetylation of LEF3 at K18 might act as one of the antiviral strategies for silkworm host by affecting nuclear localization of LEF3, interaction with P143, and then blocking viral replication.

Deacetylation of HSC70-4 Promotes Bombyx mori Nucleopolyhedrovirus Proliferation via Proteasome-Mediated Nuclear Import.

Silkworm (Bombyx mori) is a model organism with great agricultural economic value that plays a crucial role in biological studies. B. mori nucleopolyhedrovirus (BmNPV) is a major viral pathogen found in silkworms, which leads to huge silk loss annually. In a recent lysine acetylome of silkworm infected with BmNPV, we focused on the heat shock cognate protein 70-4 (HSC70-4) lysine acetylation change due to the consequent nuclear accumulation and viral structure assembly. In this study, the genome replication, proliferation, and production of budded viruses (BVs) were arrested by HSP/HSC70 inhibitor treatment. However, HSC70-4 overexpression enhanced BmNPV reproduction. Furthermore, site-direct mutagenesis for acetylated mimic (K/Q) or deacetylated mimic (K/R) mutants of HSC70-4 demonstrated that lysine 77 (K77) deacetylation promotes HSC70-4 stability, viral DNA duplication, and HSC70-4 nuclear entry upon BmNPV challenge, and the nuclear propulsion of HSC70-4 after viral stimulus might be dependent on the interaction with the carboxyl terminus of HSC70-interacting protein (CHIP, an E3 ubiquitin ligase), followed by ubiquitin-proteasome system assistance. In this study, single lysine 77 deacetylation of HSC70-4 was deemed a part of the locomotive pathway for facilitating BmNPV proliferation and provided novel insights into the antiviral strategic development.

HN1L is essential for cell growth and survival during nucleopolyhedrovirus infection in silkworm, Bombyx mori.

Hematological and neurological expressed 1-like (HN1L) protein is an evolutionarily conserved protein that plays an important role in embryonic development. It has been reported that HN1L is involved in the process of cell growth and cancer formation and that cell cycle arrest occurs during suppression of HN1L expression. Previous studies have demonstrated that the expression levels of the Bombyx mori HN1L protein were significantly downregulated in Bombyx mori Nucleopolyhedrovirus (BmNPV) infected silkworm cells. Transient transfections were performed with plasmids for pIEX-1-HN1L expression in Bombyx mori ovarian cells (BmN) in order to explore the effect of the HN1L protein on the growth of silkworm cells and its regulatory role in the process of viral infection. Cellular localization analysis revealed that HN1L was localized in the cytoplasm and that its upregulation could significantly enhance cellular activity. Furthermore, HN1L could promote G1/S phase conversion, thereby contributing to cell proliferation. Upon infection of BmN cells with BmNPV, the induction of apoptosis increased, although HN1L overexpression could inhibit DNA fragmentation, suggesting that the HN1L protein could inhibit cell apoptosis induced by viral invasion. In addition, Western blotting indicated that the HN1L protein inhibited the activation of caspase-9 zymogen and the expression of Bax protein, although it promoted Bcl-2 expression. Flow cytometry analysis further confirmed that overexpression of HN1L significantly inhibited apoptosis induced by BmNPV infection. Consequently, we demonstrated that BmN HN1L is a protein with multiple functions, which enhanced cell activity, regulated the cell cycle and induced an anti-apoptotic response by BmNPV infection.

Acetylation of BmAtg8 inhibits starvation-induced autophagy initiation.

Silkworm (Bombyx mori) is not only a model organism for scientific studies, but also a commercial insect for agricultural production. BmAtg8 (a B. mori homolog of yeast Atg8) plays crucial roles in macroautophagy (hereafter referred to autophagy), which is helpful for silkworm metamorphosis. Relevant mechanism about BmAtg8 currently remains ambiguous. Based on our previous acetylome of B. mori after BmNPV infection, we focused on that acetylation of BmAtg8 K13 was changed upon virus challenge. Subsequently, anti-BmAtg8 antibody was generated, and EBSS-induced BmN cellular autophagy model was established. Next, by constructing acetylation-mimic K13Q or deacetylation-mimic K13R mutant BmAtg8, we further examined that K13 of BmAtg8 was acetylated after BmNPV infection and chose 3 h as an appropriate point after EBSS treatment for autophagy initiation. Furthermore, acetylation of BmAtg8 K13 significantly reduced BmAtg8-PE formation in the presence of EBSS, thereby interfering autophagy initiation. Interestingly, acetylated K13 of BmAtg8 contributed to weaken interaction with Atg7, which may influence BmAtg8-PE conjugation. Eventually, acetylation of BmAtg8 K13 is critical for attenuating cell rescue through impaired autophagy initiation. Taken together, our data support an acetylated molecular function for BmAtg8 during starvation-induced autophagy, and provide insights into the modulating mechanisms that potentially reveal the LC3 (a mammalian homolog of Atg8) function in mammal.

Quantitative proteomics of Bombyx mori after BmNPV challenge.

The domesticated silkworm is an ideal and economic insect model that plays crucial roles in sericulture and bioreactor. Bombyx mori nucleopolyhedrovirus (BmNPV) is not only an infectious pathogen to B. mori, but also an efficient vector expressing recombinant proteins. Although, the proteomics of silkworm and BmN cell membrane lipid raft towards BmNPV infection had been investigated, proteome results of BmN cells upon BmNPV challenge currently remain ambiguous. In order to explore the interaction between silkworm and BmNPV, we analyzed several pivotal processes of BmNPV infected BmN cell by quantitative mass spectrometry. Our study indicated that a total of 4205 identified proteins, among which 4194 were with quantitative level. Concretely, during BmNPV infection, several transcription factors and epigenetically modified proteins showed substantially different abundance levels. Especially, proteins with binding activity, displayed significant changes in their molecular functions. Disabled non-homologous end joining by BmNPV reflects irreversible breakage of DNA. Nevertheless, highly abundant superoxide dismutase suggests that the cellular defense system is persistently functional in maintaining biochemical homeostasis. Our comparative and quantitative proteomics will be helpful to unravel the dynamics of B.mori after BmNPV infection and could provide new insights to decipher the mechanism of interaction between BmN cell and BmNPV.