Characterization and reverse genetic establishment of cattle derived Akabane virus in China

Background Akabane virus (AKAV) is an important insect-borne virus which is widely distributed throughout the world except the Europe and is considered as a great threat to herbivore health. Results An AKAV strain defined as TJ2016 was firstly isolated from the bovine sera in China in 2016. Sequence analysis of the S and M segments suggested that the isolated AKAV strain was closely related to the AKAV strains JaGAr39 and JaLAB39, which belonged to AKAV genogroup II. To further study the pathogenic mechanism of AKAV, the full-length cDNA clone of TJ2016 S, M, and L segment was constructed separately into the TVT7R plasmid at the downsteam of T7 promoter and named as TVT7R-S, TVT7R-M, and TVT7R-L, respectively. The above three plasmids were further transfected into the BSR-T7/5 cells simultaneously with a ratio of 1:1:1 to produce the rescued virus AKAV. Compared with the parental wild type AKAV (wtAKAV), the rescued virus (rAKAV) was proved to be with similar cytopathic effects (CPE), plaque sizes and growth kinetics in BHK-21 cells. Conclusion We successfully isolated a AKAV strain TJ2016 from the sera of cattle and established a reverse genetic platform for AKAV genome manipulation. The established reverse genetic system is also a powerful tool for further research on AKAV pathogenesis and even vaccine studies.

3′UTR SL-IV and DB1 Regions Contribute to Japanese Encephalitis Virus Replication and Pathogenicity

Japanese encephalitis virus (JEV), a mosquito-borne flavivirus that causes fatal neurological disease in humans, is one of the most important emerging pathogens of public health significance. JEV is maintained in an enzootic cycle and causes reproductive failure in pigs. Notably, the shift in JEV genotypes is not fully protected by existing vaccines, so the development of a candidate vaccine is urgently needed. In this study, we compared pathogenicity between Japanese encephalitis virus SA14 and BJB (isolated from humans in the 1970s) strains. We found that the BJB strain was attenuated in mice and that there was no case fatality rate. The growth rate of BJB was higher than SA14 virus in BHK-21 cells. Based on the sequence alignment of the viral genome between the SA14 and BJB virus strains, some mutations at sites 248, 254, 258, and 307 were observed in the 3′ untranslated region (3′UTR). The 3′UTR of JEV plays a very important role in the viral life cycle. Furthermore, using a reverse genetic system, we conducted and rescued the parental JEV strain SA14 (T248, A254, and A258) and the mutant virus rSA14-3′UTRmut (T248C, A254G, A258G, and 307G). Through an analysis of the RNA secondary structure model of the 3′UTR, we discovered that the mutations of T248C, A254G, and A258G reduced the apiculus ring and increased the lateral ring significantly in the stem-loop structures IV (SL-IV) structure region of 3′UTR. Moreover, the insertion of 307G added a ring to the dumbbell structure 1 (DB1) structure region. Strikingly, these RNA secondary structure changes in 3′UTR of rSA14-3′UTRmut increased viral negative chain RNA production and enhanced the replication ability of the virus in BHK-21 cells. However, in vivo mouse experiments illustrated that the rSA14-3′UTRmut virus significantly decreased the neurovirulence of JEV. These results affirmed that the JEV SL-IV and DB1 regions play an important role in viral proliferation and pathogenicity. Taken together, we complement the study of RNA element function in the 3′UTR region of JEV by providing a new target for the rational design of live attenuated candidate vaccines and the increase of virus production.

Construction of an infectious clone of Zika virus stably expressing an EGFP marker in a eukaryotic expression system

Background Zika virus is becoming one of the most widely transmitted arboviruses in the world. Development of antiviral inhibitor and vaccine requires an experimental system that allows rapid monitoring of the virus infection. This is achievable with a reverse genetic system. In this study, we constructed an infectious clone for Zika virus that stably expressing EGFP. Methods A PCR-mediated recombination approach was used to assemble the full-length Zika virus genome containing the CMV promoter, intron, EGFP, hepatitis delta virus ribozyme, and SV40 terminator sequence for cloning into the pBAC11 vector to produce recombinant pBAC-ZIKA-EGFP. ZIKA-EGFP virus was rescued by transfection of pBAC-ZIKA-EGFP into 293T cells. The characterization of ZIKA-EGFP virus was determined by qPCR, plaque assay, CCK-8, and Western blot. Results Rescued ZIKA-EGFP virus exhibited stable replication for at least five generations in tissue culture. ZIKA-EGFP can effectively infect C6/36, SH-SY5Y and Vero cells, and cause cytopathic effects on SH-SY5Y and Vero cells. The inhibition of ZIKA-EGFP by NF-κB inhibitor, caffeic acid phenethyl ester was observed by fluorescence microscopy. Conclusion Our results suggested that Zika virus infectious clone with an EGFP marker retained it infectivity as wide-type Zika virus which could be used for drugs screening.

Characterization and Reverse Genetic Establishment of Cattle Derived Akabane Virus in China

Background: Akabane virus (AKAV) is an important insect-borne virus which is widely distributed in the tropical and temperate zones of Asia and Africa and is considered as a great threat in herbivores.Results: An AKAV defined as TJ2016 was firstly isolated from the serum of cattle in China in 2016. Sequence analysis of the S and M segments suggested that the isolated TJ2016 was closely related to the strains JaGAr39 and JaLAB39, which belonged to genogroup II. To further study the pathogenic mechanism of AKAV, the full-length cDNA clone of TJ-2016 S, M, and L segment was separately constructed into the TVT7R plasmid under the control of T7 promoter which named as TVT7R-S, TVT7R-M, and TVT7R-L, respectively. Then, the three constructed plasmids were transfected into the BSR-T7/5 cells simultaneously with a ratio of 1:1:1 to rescue AKAV. Compared with the parental wild type AKAV (wtAKAV), the rescued virus (rAKAV) was proved to have similar cytopathic effects (CPE), plaque sizes and growth kinetics in BHK-21 cells.Conclusion: We successfully isolated a AKAV strain TJ2016 from the serum of cattle and established a reverse genetic platform for AKAV genome manipulation. The established reverse genetic system is also a powerful tool which can be used for further AKAV pathogenesis and even vaccine studies.

Establishment of a Reverse Genetic System from a Bovine Derived Influenza D Virus Isolate

The ruminant-associated influenza D virus (IDV) has a broad host tropism and was shown to have zoonotic potential. To identify and characterize molecular viral determinants influencing the host spectrum of IDV, a reverse genetic system is required. For this, we first performed 5′ and 3′ rapid amplification of cDNA ends (RACE) of all seven genomic segments, followed by assessment of the 5′ and 3′ NCR activity prior to constructing the viral genomic segments of a contemporary Swiss bovine IDV isolate (D/CN286) into the bidirectional pHW2000 vector. The bidirectional plasmids were transfected in HRT-18G cells followed by viral rescue on the same cell type. Analysis of the segment specific 5′ and 3′ non-coding regions (NCR) highlighted that the terminal 3′ end of all segments harbours an uracil instead of a cytosine nucleotide, similar to other influenza viruses. Subsequent analysis on the functionality of the 5′ and 3′ NCR in a minireplicon assay revealed that these sequences were functional and that the variable sequence length of the 5′ and 3′ NCR influences reporter gene expression. Thereafter, we evaluated the replication efficiency of the reverse genetic clone on conventional cell lines of human, swine and bovine origin, as well as by using an in vitro model recapitulating the natural replication site of IDV in bovine and swine. This revealed that the reverse genetic clone D/CN286 replicates efficiently in all cell culture models. Combined, these results demonstrate the successful establishment of a reverse genetic system from a contemporary bovine IDV isolate that can be used for future identification and characterization of viral determinants influencing the broad host tropism of IDV.

The trypsin-enhanced infection of porcine epidemic diarrhea virus is determined by the S2 subunit of the spike glycoprotein

Porcine epidemic diarrhea virus (PEDV) is an enteric pathogen in the swine industry, causing high mortality in neonatal piglets. Efficient PEDV infection usually relies on the presence of trypsin, yet the mechanism of trypsin dependency is ambiguous. Here, we identified two PEDV strains, trypsin-enhanced YN200 and trypsin-independent DR13, in which the spike (S) protein of YN200 exhibits a stronger ability to induce syncytium formation and cleaved by trypsin than that of DR13. Using a full-length infectious YN200 cDNA clone, we confirmed that the S protein is a trypsin dependency determinant by comparison of rYN200 and rYN200-SDR13. To explore the trypsin-associated sites of the YN200 S protein, we then constructed a series of mutations adjacent to the fusion peptide. The results show that the putative S2’ cleavage site (R892G) is not the determinant for virus trypsin dependency. Hence, we generated viruses carrying chimeric S proteins: the S1 subunit, S2 subunit, and S2720∼892 aa domain (NS2’) were individually replaced by the corresponding DR13 sequences. Intriguingly, only the S2 substitution, not the S1 or NS2’ substitutions, provides trypsin-independent growth of YN200. Additionally, the NS2’ recombinant virus significantly abrogated effective infection, indicating a vital role for NS2’ in viral entry. These findings suggest that the trypsin dependency of PEDV is mainly controlled by mutations in the S2 subunit rather than directly trypsin cleavage site. Importance With the emergence of new variants, PEDV remains a major problem in the global swine industry. Efficient PEDV infection usually requires trypsin, while the mechanism of trypsin dependency is complex. Here, we used two PEDV strains, trypsin-enhanced YN200 and trypsin-independent DR13, and results showed that the S protein determined PEDV trypsin dependency by using a reverse genetic system of YN200. The S2 subunit was verified as the main portion of PEDV trypsin dependency, though the putative S2’ site mutation cannot render trypsin-independent growth of YN200. Finally, these results provide some different insight to the PEDV trypsin dependency and might inspire vaccine development.

Coordination between terminal variation of the viral genome and insect microRNAs regulates rice stripe virus replication in insect vectors

Maintenance of a balance between the levels of viral replication and selective pressure from the immune systems of insect vectors is one of the prerequisites for efficient transmission of insect-borne propagative phytoviruses. The mechanism regulating the adaptation of RNA viruses to insect vectors by genomic variation remains unknown. Our previous study demonstrated an extension of the 3’-untranslated terminal region (UTR) of two genomic segments of rice stripe virus (RSV). In the present study, a reverse genetic system for RSV in human cells and an insect vector, the small brown planthopper Laodelphax striatellus, was used to demonstrate that the 3’-terminal extensions suppressed viral replication in vector insects by inhibiting promoter activity due to structural interference with the panhandle structure formed by viral 3’- and 5’-UTRs. The extension sequence in the viral RNA1 segment was targeted by an endogenous insect microRNA, miR-263a, which decreased the inhibitory effect of the extension sequence on viral promoter activity. Surprisingly, the expression of miR-263a was negatively regulated by RSV infection. This elaborate coordination between terminal variation of the viral genome and endogenous insect microRNAs controls RSV replication in planthopper, thus reflecting a distinct strategy of adaptation of phytoviruses to insect vectors.