Viral MicroRNAs Targeting Virus Genes Promote Virus Infection in Shrimp In Vivo

Viral microRNAs (miRNAs), most of which are characterized in cell lines, have been found to play important roles in the virus life cycle to avoid attack by the host immune system or to keep virus in the latency state. Viral miRNAs targeting virus genes can inhibit virus infection. In this study, in vivo findings in Marsupenaeus japonicus shrimp revealed that the viral miRNAs could target virus genes and further promote the virus infection. The results showed that white spot syndrome virus (WSSV)-encoded miRNAs WSSV-miR-66 and WSSV-miR-68 were transcribed at the early stage of WSSV infection. When the expression of WSSV-miR-66 and WSSV-miR-68 was silenced with sequence-specific anti-miRNA oligonucleotides (AMOs), the number of copies of WSSV and the WSSV-infected shrimp mortality were significantly decreased, indicating that the two viral miRNAs had a great effect on virus infection. It was revealed that the WSSV wsv094 and wsv177 genes were the targets of WSSV-miR-66 and that the wsv248 and wsv309 genes were the targets of WSSV-miR-68. The data demonstrate that the four target genes play negative roles in the WSSV infection. The targeting of the four virus genes by WSSV-miR-66 and WSSV-miR-68 led to the promotion of virus infection. Therefore, our in vivo findings show a novel aspect of viral miRNAs in virus-host interactions.     

Involvement of Viral MicroRNA in the Regulation of Antiviral Apoptosis in Shrimp

Viruses, in particular DNA viruses, generate microRNAs (miRNAs) to control the expression of host and viral genes. Due to their essential roles in virus-host interactions, viral miRNAs have attracted extensive investigations in recent years. To date, however, most studies on viral miRNAs have been conducted in cell lines. In this study, the viral miRNAs from white spot syndrome virus (WSSV) were characterized in shrimp in vivo. On the basis of our previous study and small RNA sequencing in this study, a total of 89 putative WSSV miRNAs were identified. As revealed by miRNA microarray analysis and Northern blotting, the expression of viral miRNAs was tissue specific in vivo. The results indicated that the viral miRNA WSSV-miR-N24 could target the shrimp caspase 8 gene, and this miRNA further repressed the apoptosis of shrimp hemocytes in vivo. As a result, the number of WSSV copies in shrimp in vivo was significantly increased compared with the control level (WSSV only). Therefore, our study presents the first report on the in vivo molecular events of viral miRNA in antiviral apoptosis.     

Prevalence of three shrimp viruses in Zhejiang Province in 2008

White spot syndrome virus (WSSV), Taura syndrome virus (TSV) and Infectious hypodermal and haematopoietic necrosis virus (IHHNV) are three shrimp viruses responsible for major pandemics affecting the shrimp farming industry. Shrimps samples were collected from 12 farms in Zhejiang province, China, in 2008 and analyzed by PCR to determine the prevalence of these viruses. From the 12 sampling locations, 8 farms were positive for WSSV, 8 for IHHNV and 6 for both WSSV and IHHNV. An average percentage of 57.4% of shrimp individuals were infected with WSSV, while 49.2% were infected with IHHNV. A high prevalence of co-infection with WSSV and IHHNV among samples was detected from the following samples: Bingjiang (93.3%), liuao (66.7%), Jianshan (46.7%) and Xianxiang (46.7%). No samples exhibited evidence of infection with TSV in collected samples. This study provides comprehensive information of the prevalence of three shrimp viruses in Zhejiang and may be helpful for disease prevention control in this region.     

Functional Analysis of a Crustacean MicroRNA in Host-Virus Interactions

Growing evidence from mammals suggests that host microRNAs (miRNAs) play important roles in the antiviral immune response. However, the roles of invertebrate miRNAs in response to virus infection remain to be investigated. Based on our previous studies, the shrimp miR-7 was found to be upregulated in response to white spot syndrome virus (WSSV) infection. In this study, the results showed that shrimp miR-7 could target the 3′-untranslated region (3′UTR) of the WSSV early gene wsv477, implying that miR-7 was involved in viral DNA replication. In insect High Five cells, the synthesized miR-7 significantly decreased the expression level of the fluorescent construct bearing the 3′UTR of wsv477 compared with the expression of the control constructs. When the activity of transfected miR-7 was blocked by locked-nucleic-acid (LNA)-modified anti-miR-7 oligonucleotide (AMO-miR-7), the repression of luciferase gene expression by miR-7 was relieved. In vivo, when the synthesized miR-7 was injected into shrimp, the numbers of WSSV genome copies/mg gills were 1,000-fold lower than those of WSSV only at 72 and 96 h postinfection. The results indicated that the blocking of endogenous miR-7 by AMO-miR-7 led to about a 10-fold increase of WSSV genome copies/mg gills in WSSV-infected shrimp compared with the control WSSV only. Further, it was revealed that the host Dicer1 was an important component for the biogenesis of miR-7, which had a large effect on virus infection. Therefore, our study revealed a novel regulatory function for an invertebrate miRNA in host-virus interactions by targeting the viral early gene.     

Protection of Shrimp Penaeus monodon from WSSV Infection Using Antisense Constructs

White spot syndrome caused by white spot syndrome virus (WSSV) is one of the most threatening diseases of shrimp culture industry. Previous studies have successfully demonstrated the use of DNA- and RNA-based vaccines to protect WSSV infection in shrimp. In the present study, we have explored the protective efficacy of antisense constructs directed against WSSV proteins, VP24, and VP28, thymidylate synthase (TS), and ribonucleotide reductase-2 (RR2) under the control of endogenous shrimp histone-3 (H3) or penaedin (Pn) promoter. Several antisense constructs were generated by inserting VP24 (pH3–VP24, pPn–VP24), VP28 (pH3–VP28, pPn–VP28), TS (pH3–TS, pPn–TS), and RR2 (pH3–RR2) in antisense orientation. These constructs were tested for their protective potential in WSSV infected cell cultures, and their effect on reduction of the viral load was assessed. A robust reduction in WSSV copy number was observed upon transfection of antisense constructs in hemocyte cultures derived from Penaeus monodon and Scylla serrata. When tested in vivo, antisense constructs offered a strong protection in WSSV challenged P. monodon. Constructs expressing antisense VP24 and VP28 provided the best protection (up to 90 % survivability) with a corresponding decrease in the viral load. Our work demonstrates that shrimp treated with antisense constructs present an efficient control strategy for combating WSSV infection in shrimp aquaculture.     

Stimulating the immune response of Litopenaeus vannamei using the phagocytosis activating protein (PAP) gene

High mortality in the shrimp farming industry is caused by several pathogens such as white spot syndrome virus (WSSV), yellow head virus (YHV) and Vibrio harveyi (V. harveyi). A PAP (Phagocytosis activating protein) gene able to activate phagocytosis of shrimp hemocytes was cloned into the eukaryotic expression vector phMGFP. In vitro expression was confirmed by transfection of PAP-phMGFP into CHO (Chinese Hamster Ovary) cells and the expression of the Green Fluorescent Protein (GFP) was observed. In order to activate the phagocytic activity of shrimp, 20, 40 and 80 μg/shrimp of this PAP-phMGFP vector were injected into Litopenaeus vannamei muscle. After challenged with WSSV, 40 μg/shrimp produced the highest relative percent survival (77.78 RPS). Analysis for the expression of the GFP gene in various tissues showed the expression mostly in the hemolymph of the immunized shrimp. The expression level of PAP and proPO (Prophenoloxidase) gene were highest at 7 days after immunization. This agreed with the efficiency of protection against WSSV that also occurred 7 days after immunization with the highest RPS of 86.61%. However there was no protection 30 days after immunization. Hemocytes of shrimp injected with PAP-phMGFP had 1.9 folds and 3 folds higher percentage phagocytosis and phagocytic index than the shrimp injected with PBS. Accordingly, copies of WSSV reduced in the PAP-phMGFP injected shrimp. In addition, PAP-phMGFP also protected shrimp against several pathogens: WSSV, YHV and V. harveyi, with RPS values of 86.61%, 63.34% and 50% respectively. This finding shows that the immune cellular defense mechanisms in shrimp against pathogens can be activated by injection of PAP-phMGFP and could indicate possible useful ways to begin to control this process.     

Immunological responses of Penaeus monodon to DNA vaccine and its efficacy to protect shrimp against white spot syndrome virus (WSSV)

White spot disease is an important viral disease caused by white spot syndrome virus (WSSV) and is responsible for huge economic losses in the shrimp culture industry worldwide. The VP28 gene encoding the most dominant envelope protein of WSSV was used to construct a DNA vaccine. The VP28 gene was cloned in the eukaryotic expression vector pcDNA3.1 and the construct was named as pVP28. The protective efficiency of pVP28 against WSSV was evaluated in Penaeus monodon by intramuscular challenge. In vitro expression of VP28 gene was confirmed in sea bass kidney cell line (SISK) by fluorescence microscopy before administering to shrimp. The distribution of injected pVP28 in different tissues of shrimp was studied and the results revealed the presence of pVP28 in gill, head soft tissue, abdominal muscle, hemolymph, pleopods, hepatopancreas and gut. RT-PCR and fluorescence microscopy analyses showed the expression of pVP28 in all these tissues examined. The results of vaccination trials showed a significantly higher survival rate in shrimp vaccinated with pVP28 (56.6-90%) when compared to control groups (100% mortality). The immunological parameters analyzed in the vaccinated and control groups revealed that the vaccinated shrimp showed significantly high level of prophenoloxidase and superoxide dismutase (SOD) when compared to the control groups. The high levels of prophenoloxidase and superoxide dismutase (SOD) might be responsible for developing resistance against WSSV in DNA vaccinated shrimp.     

An immersion of Gracilaria tenuistipitata extract improves the immunity and survival of white shrimp Litopenaeus vannamei challenged with white spot syndrome virus

The innate immunity and resistance against white spot syndrome virus (WSSV) in white shrimp Litopenaeus vannamei which received the Gracilaria tenuistipitata extract were examined. Shrimp immersed in seawater containing the extract at 0 (control), 400 and 600 mg L(-1) for 3 h were challenged with WSSV at 2 × 10(4) copies shrimp(-1). Shrimp not exposed to the extract and not received WSSV challenge served as unchallenged control. The survival rate of shrimp immersed in 400 mg L(-1) or 600 mg L(-1) extract was significantly higher than that of challenged control shrimp over 24-120 h. The haemocyte count, phenoloxidase activity, respiratory burst, superoxide dismutase activity, and lysozyme activity of shrimp immersed in 600 mg L(-1) extract were significantly higher than those of unchallenged control shrimp at 6, 6, 6, 6, and 6-24 h post-challenge. In another experiment, shrimp which had received 3 h immersion of 0, 400, 600 mg L(-1) extract were challenged with WSSV. The shrimp were then received a booster (3 h immersion in the same dose of the extract), and the immune parameters were examined at 12-120 h post-challenge. The immune parameters of shrimp immersed in 600 mg L(-1) extract, and then received a booster at 9, 21, and 45 h were significantly higher than those of unchallenged control shrimp at 12-48 h post-challenge. In conclusion, shrimp which had received the extract exhibited protection against WSSV as evidenced by the higher survival rate and higher values of immune parameters. Shrimp which had received the extract and infected by WSSV showed improved immunity when they received a booster at 9, 21, and 45 h post-WSSV challenge. The extract treatment caused less decrease in PO activity, and showed better performance of lysozyme activity and antioxidant response in WSSV-infected shrimp.     

Development of a Rapid Method for Identifying Carryover Contamination of Positive Control DNA,Using a Chimeric Positive Control and Restriction Enzyme for the Diagnosis of White Spot Syndrome Virus by Nested PCR

Chimeric positive plasmids have been developed to minimize false-positive reactions caused by polymerase chain reaction (PCR) contamination. Here, we developed a rapid method for identifying false-positive results while detecting white spot syndrome virus (WSSV) by nested PCR, using chimeric positive plasmids. The results of PCRs using WSSV diagnostic primer sets showed PCR products of a similar size (WSSV 1st PCR product, 1,447 bp; WSSV 2nd PCR product, 941 bp) using WSSV chimeric plasmids or DNA from shrimp infected with WSSV. The PCR products were digested with DraI for 1 h at 37 °C. The digested chimeric DNA separated into two DNA bands; however, the WSSV-infected shrimp DNA did not separate. Thus, chimeric plasmid DNA may be used as positive control DNA instead of DNA from WSSV-infected shrimp, in order to prevent PCR contamination. Thus, the use of restriction enzyme digestion allowed us to rapidly distinguish between WSSV DNA and WSSV chimeric plasmid DNA.     

以枯草芽孢杆菌递呈VP28对南美白对虾免疫相关基因表达和细胞特异性吞噬的影响

以枯草芽孢杆菌(Bacillus subtilis)为活载体口服递呈对虾白斑综合征病毒(WSSV)囊膜蛋白VP28, 评价其抗病毒感染能力、对南美白对虾免疫相关基因表达以及血淋巴细胞对病毒特异性吞噬的影响。经口服免疫枯草重组菌株B. subtilis-VP28攻毒后, 对虾的相对存活率达83.3%。为探讨重组菌株的抗病机理, 比较研究了免疫相关基因proPO(酚氧化酶原)、Peroxinectin(PE)和脂多糖--1, 3-葡聚糖结合蛋白(LGBP)基因的表达差异, 并进一步分析了血淋巴细胞吞噬活性和特异性。结果表明, B. subtilis-VP28菌液能显著提高(P 0.05)对虾proPO、PE和LGBP mRNA的表达水平和血细胞对WSSV的吞噬活性, B. subtilis组对免疫相关基因也有一定的激活作用, 而B. subtilis-VP28发酵上清液则能增加血细胞吞噬活性; 此外, B. subtilis-VP28菌液组血细胞对WSSV具有特异性吞噬作用。研究为枯草重组菌株B. subtilis-VP28抗WSSV感染作用及其作为特殊功能水产微生态制剂的应用提供了一定的科学依据。       

Vp28 of shrimp white spot syndrome virus is involved in the attachment and penetration into shrimp cells

White spot disease (WSD) is caused by the white spot syndrome virus (WSSV), which results in devastating losses to the shrimp farming industry around the world. However, the mechanism of virus entry and spread into the shrimp cells is unknown. A binding assay in vitro demonstrated VP28-EGFP (envelope protein VP28 fused with enhanced green fluorescence protein) binding to shrimp cells. This provides direct evidence that VP28-EGFP can bind to shrimp cells at pH 6.0 within 0.5 h. However, the protein was observed to enter the cytoplasm 3 h post-adsorption. Meanwhile, the plaque inhibition test showed that the polyclonal antibody against VP28 (a major envelope protein of WSSV) could neutralize the WSSV and block an infection with the virus. The result of competition ELISA further confirmed that the envelope protein VP28 could compete with WSSV to bind to shrimp cells. Overall, VP28 of the WSSV can bind to shrimp cells as an attachment protein, and can help the virus enter the cytoplasm.     

White spot syndrome virus (WSSV) in Litopenaeus vannamei captured from the Gulf of California near an area of extensive aquaculture activity

For the shrimp farming industry of Mexico, disease outbreaks caused by white spot syndrome virus (WSSV) are relatively recent. Efforts to control the virus are assisted by monitoring for its prevalence in aquaculture systems, but few attempts have been made to search for it in carriers from coastal waters. To search for WSSV carriers in the Gulf of California, we made surveys off the coast of Sinaloa, Mexico, in March 2001, November 2001, and September 2003 using polymerase chain reaction (PCR) assays and histopathology. WSSV-positive shrimp were detected only in November 2001, after hurricane Julliete. This suggested possible dispersal of WSSV to the marine environment from infected shrimp farms.     

A model for apoptotic interaction between white spot syndrome virus and shrimp

White spot syndrome virus (WSSV) is an enveloped, large dsDNA virus that mainly infects penaeid shrimp, causing serious damage to the shrimp aquaculture industry. Like other animal viruses, WSSV infection induces apoptosis. Although this occurs even in by-stander cells that are free of WSSV virions, apoptosis is generally regarded as a kind of antiviral immune response. To counter this response, WSSV has evolved several different strategies. From the presently available literature, we construct a model of how the host and virus both attempt to regulate apoptosis to their respective advantage. The basic sequence of events is as follows: first, when a WSSV infection occurs, cellular sensors detect the invading virus, and activate signaling pathways that lead to (1) the expression of pro-apoptosis proteins, including PmCasp (an effecter caspase), MjCaspase (an initiator caspase) and voltage-dependent anion channel (VDAC); and (2) mitochondrial changes, including the induction of mitochondrial membrane permeabilization and increased oxidative stress. These events initiate the apoptosis program. Meanwhile, WSSV begins to express its genes, including two anti-apoptosis proteins: AAP-1, which is a direct caspase inhibitor, and WSV222, which is an E3 ubiquitin ligase that blocks apoptosis through the ubiquitin-mediated degradation of shrimp TSL protein (an apoptosis inducer). WSSV also induces the expression of a shrimp anti-apoptosis protein, Pm-fortilin, which can act on Bax to inhibit mitochondria-triggered apoptosis. This is a life and death struggle because the virus needs to prevent apoptosis in order to replicate. If WSSV succeeds in replicating in sufficient numbers, this will result in the death of the infected penaeid shrimp host.