Saengchan Senapin

Detection of shrimp infectious myonecrosis virus by reverse transcription loop-mediated isothermal amplification combined with a lateral flow dipstick.

Infectious myonecrosis virus (IMNV) has caused a slowly progressive disease with cumulative mortalities of up to 70% or more in cultured Penaeus (Litopenaeus) vannamei in Northeast Brazil and Indonesia. Rapid detection of viruses by loop-mediated isothermal amplification (LAMP) of genomic material with high specificity and sensitivity can be applied for diagnosis, monitoring and control of diseases in shrimp aquaculture. Using an IMNV template, successful detection was achieved after a 60-min RT-LAMP reaction using biotin-labeled primers followed by 5min hybridization with an FITC-labeled DNA probe and 5min assay using a chromatographic lateral flow dipstick (LFD). Thus, the combined system of RT-LAMP and LFD required a total assay interval of less than 75min, excluding the RNA extraction time. The sensitivity of detection was comparable to that of other commonly used methods for nested RT-PCR detection of IMNV. In addition to reducing amplicon detection time when compared to electrophoresis, LFD confirmed amplicon identity by hybridization and eliminated the need to handle carcinogenic ethidium bromide. The RT-LAMP-LFD method gave negative test results with nucleic acid extracts from normal shrimp and from shrimp infected with other viruses including infectious hypodermal hematopoietic necrosis virus (IHHNV), monodon baculovirus (MBV), a hepatopancreatic parvovirus from P. monodon (PmDNV), white spot syndrome virus (WSSV), yellow head virus (YHV), Taura syndrome virus (TSV), Macrobrachium rosenbergii nodavirus (MrNV) and gill associated virus (GAV).

The role of Pm-fortilin in protecting shrimp from white spot syndrome virus (WSSV) infection.

Crustacean fortilin or the product of the translationally controlled tumor protein (TCTP) gene isolated from Penaeus monodon, is well conserved and has a Ca(++) binding domain. Pm-fortilin has anti-apoptotic properties and is present at high levels during the onset of viral infections in P. monodon. The possibility of using rFortilin to protect against white spot syndrome virus (WSSV) infection was tested. Injection of shrimp with rFortilin, after infection with WSSV, resulted in 80-100% survival and detection of very low levels of WSSV by PCR, whereas in moribund samples WSSV levels were very high. This result implies that injection of recombinant rFortilin decreases viral infection by an unknown mechanism, but probably by inhibiting viral replication. Using a yeast two-hybrid screen for cellular protein partners to rFortilin we identified an unknown protein that bound to fortilin. This is a novel polypeptide of 93 amino acids with a number of XPPX signature sequences that are often reported to have a function in antiviral peptides.

A novel lectin domain-containing protein (LvCTLD) associated with response of the whiteleg shrimp Penaeus (Litopenaeus) vannamei to yellow head virus (YHV).

When using mRNA from gills of normal whiteleg shrimp Penaeus (Litopenaeus) vannamei as the tester and mRNA from yellow head virus (YHV)-infected shrimp as the driver, subtractive suppression hybridization (SSH) revealed that a novel EST clone of 198 bp with a putative C-type lectin-like domain (CTLD) was downregulated in YHV-infected shrimp. The clone nucleotide sequence had 99% identity with one contig MGID1052359 (1,380 bp) reported in an EST database of P. vannamei, and the presence of this target in normal shrimp was confirmed by RT-PCR using primers designed from the MGID1052359 sequence. Analysis of the primary structure of the deduced amino acid (a.a.) sequence of the contig revealed a short portion (40 a.a. residues) at its N-terminus with high similarity to a low density lipoprotein receptor (LDLR) class A domain and another 152 a.a. residues at its C-terminus with high similarity to a C-type lectin domain. Thus, the clone was named LvCTLD and three recombinant proteins (LvCTLD, the LDLR domain and the CTLD domain) were synthesized in a bacterial system based on its sequence. An in vitro encapsulation assay revealed that Sepharose 4B beads coated with rLvCTLD were encapsulated by shrimp hemocytes and that melanization followed by 24 h post-encapsulation. The encapsulation activity of rLvCTLD was inhibited by 100 mM galactose, but not mannose or EDTA. In vivo injection of rLvCTLD or rLvCTLD plus YHV resulted in a significant elevation of PO activity in the hemolymph of the challenged shrimp when compared to shrimp injected with buffer, suggesting that rLvCTLD could activate the proPO system. An ELISA test revealed that rLvCTLD could bind to YHV particles in the presence of shrimp hemolymph. Phylogenetic analysis suggested that the LvCTLD sequence was more closely related to an antiviral gene found in Penaeus monodon (PmAV) than to other reported shrimp lectins. Taken together, we conclude that a novel shrimp LvCTLD is a host recognition molecule involved in the shrimp defense mechanism against YHV via recruitment of hemocytes, probably at the site of viral infection, and via activation of the proPO system.

Rapid and sensitive detection of Penaeus monodon nucleopolyhedrovirus (PemoNPV) by loop-mediated isothermal amplification combined with a lateral-flow dipstick

Several methods such as traditional PCR or nested-PCR, immuno assay and histopathology have been developed for detection of Penaeus monodon nucleopolyhedrovirus (PemoNPV) formerly called monodon baculovirus (MBV). However, these methods have various disadvantages including low sensitivity, long assay time, use of toxic substances or unsuitability for field diagnosis. Loop-mediated isothermal amplification of target nucleotide sequences under isothermal conditions, combined with amplicon detection by chromatographic lateral-flow dipsticks allows for more efficient, field friendly detection within 75 min (not including DNA preparation time). In this study, the LAMP amplicon was biotinylated via an inner LAMP primer designed from a BamHI fragment B, a hypothetical protein gene of PemoNPV under isothermal condition at 63 degrees C for 1 h. Next, the LAMP product was hybridized at 63 degrees C for 5 min with an optimal FITC-labeled probe that was designed specifically for the LAMP amplicons. The FITC-labeled biotinylated LAMP product picked up gold-labeled, anti-FITC near the LFD origin and the whole, triple-labeled complex was captured by an immobilized biotin-binding protein to yield a red nano-gold stripe at the LFD test line. With a DNA template extracted from PemoNPV-infected shrimp, the LAMP-LFD detection limit was 0.1 pg, whereas one-step PCR and nested-PCR followed with gel electrophoresis was 1 pg. The LAMP-LFD method gave negative test results with buffer and DNA from shrimp infected with other common shrimp DNA viruses including, Penaeus monodon densovirus (PmDNV) formerly called hepatopancreatic parvovirus (HPV), white spot syndrome virus (WSSV) and Penaeus stylirostris densovirus (PstDNV) formerly called infectious hypodermal and hematopoietic necrosis virus (IHHNV). The test platform can be adapted easily for rapid detection of other shrimp viruses, since the LAMP-LFD combination system was a highly sensitive, specific, convenient, and does not require sophisticated instruments.

Rapid and sensitive detection of Macrobrachium rosenbergii nodavirus in giant freshwater prawns by reverse transcription loop-mediated isothermal amplification combined with a lateral flow dipstick.

Loop-mediated isothermal amplification (LAMP) allows rapid amplification of nucleic acids under isothermal conditions. It can be combined with a chromatographic lateral flow dipstick (LFD) for much more efficient, field-friendly detection of MrNV. In this work, RT-LAMP was performed at 65 degrees C for 40 min, followed by 5 min for hybridization with an FITC-labeled DNA probe and 5 min for LFD resulted in visualization of DNA amplicons trapped at the LFD test line. Thus, total assay time, including 10 min for rapid RNA extraction was approximately 60 min. In addition to advantages of short assay time, confirmation of amplicon identity by hybridization and elimination of electrophoresis with carcinogenic ethidium bromide, the RT-LAMP-LFD was more sensitive than an existing RT-PCR method for detection of MrNV. The RT-LAMP-LFD method gave negative test results with nucleic acid extracts from normal shrimp and from shrimp infected with other viruses including DNA viruses [PstDNV (IHHNV), PemoNPV (MBV), PmDNV (HPV), WSSV] and RNA viruses (TSV, IMNV, YHV/GAV).

Suppression of Shrimp Melanization during White Spot Syndrome Virus Infection

Background: Melanization plays a major role in invertebrate defense. Results: Suppression of shrimp melanization increased the WSSV susceptibility. The viral protein, WSSV453, interferes the proPO system via PmPPAE2 inhibition. Conclusion: Shrimp melanization has an antiviral role. WSSV overcomes this by suppressing the host proPO proteinase cascade. Significance: The regulation of shrimp melanization during WSSV infection was first demonstrated. The melanization cascade, activated by the prophenoloxidase (proPO) system, plays a key role in the production of cytotoxic intermediates, as well as melanin products for microbial sequestration in invertebrates. Here, we show that the proPO system is an important component of the Penaeus monodon shrimp immune defense toward a major viral pathogen, white spot syndrome virus (WSSV). Gene silencing of PmproPO(s) resulted in increased cumulative shrimp mortality after WSSV infection, whereas incubation of WSSV with an in vitro melanization reaction prior to injection into shrimp significantly increased the shrimp survival rate. The hemolymph phenoloxidase (PO) activity of WSSV-infected shrimp was extremely reduced at days 2 and 3 post-injection compared with uninfected shrimp but was fully restored after the addition of exogenous trypsin, suggesting that WSSV probably inhibits the activity of some proteinases in the proPO cascade. Using yeast two-hybrid screening and co-immunoprecipitation assays, the viral protein WSSV453 was found to interact with the proPO-activating enzyme 2 (PmPPAE2) of P. monodon. Gene silencing of WSSV453 showed a significant increase of PO activity in WSSV-infected shrimp, whereas co-silencing of WSSV453 and PmPPAE2 did not, suggesting that silencing of WSSV453 partially restored the PO activity via PmPPAE2 in WSSV-infected shrimp. Moreover, the activation of PO activity in shrimp plasma by PmPPAE2 was significantly decreased by preincubation with recombinant WSSV453. These results suggest that the inhibition of the shrimp proPO system by WSSV partly occurs via the PmPPAE2-inhibiting activity of WSSV453.

Impact of yellow head virus outbreaks in the whiteleg shrimp, Penaeus vannamei (Boone), in Thailand.

Abstract Yellow head virus (YHV) is known as a major pathogen in the black tiger shrimp, Penaeus (Penaeus) monodon. It can also cause serious mortality in farmed whiteleg shrimp, Penaeus (Litopenaeus) vannamei. However, there is no published information on the economic and/or production impact of the disease in P. vannamei. Shrimp with gross signs of YHV disease (faded body colour and 60–70% mortality) were observed in 20 study farms rearing P. vannamei in the central part of Thailand from the end of 2007 through early 2008. The estimated economic loss for these farms according to the Thai Animal Aquaculture Association was approximately US

Shrimp laminin receptor binds with capsid proteins of two additional shrimp RNA viruses YHV and IMNV.

3 million. Detailed sequence analysis of RT‐PCR amplicons from shrimp in all the study ponds revealed the presence of YHV Type 1b (YHV‐1b) alone (characterized by a 162‐bp deletion in the ORF3 region encoding the structural gene for gp116) and the absence of YHV Type 1a (YHV‐1a), the original YHV type reported from Thailand. Despite the large 162‐bp deletion (= 54 deduced amino acids) in the gp116 structural gene, histopathology of YHV‐1b infections was identical to that of YHV‐1a infections, and electron microscopy revealed that YHV‐1b virions were morphologically indistinguishable from those previously reported for YHV‐1a. In addition, an existing commercial RT‐PCR detection kit and an immunochromatographic test strip for the detection of YHV were proven to have been valid tests for both YHV‐1b and YHV‐1a. The source of the virus for these outbreaks was unlikely to have been the post‐larvae used to stock the ponds, as they were derived from domesticated specific pathogen‐free stocks free of YHV. Thus, it is possible that they originated from an unknown, natural reservoir.

Anti-lipopolysaccharide factor isoform 3 from Penaeus monodon (ALFPm3) exhibits antiviral activity by interacting with WSSV structural proteins

Laminin receptor (Lamr) in shrimp was previously proposed to be a potential receptor protein for Taura syndrome virus (TSV) based on yeast two-hybrid assays. Since shrimp Lamr bound to the VP1 capsid protein of TSV, we were interested to know whether capsid/envelope proteins from other shrimp viruses would also bind to Lamr. Thus, capsid/envelope encoding genes from 5 additional shrimp viruses were examined. These were Penaeus stylirostris densovirus (PstDNV), white spot syndrome virus (WSSV), infectious myonecrosis virus (IMNV), Macrobrachium rosenbergii nodavirus (MrNV), and yellow head virus (YHV). Protein interaction analysis using yeast two-hybrid assay revealed that Lamr specifically interacted with capsid/envelope proteins of RNA viruses IMNV and YHV but not MrNV and not with the capsid/envelope proteins of DNA viruses PstDNV and WSSV. In vitro pull-down assay also confirmed the interaction between Lamr and YHV gp116 envelope protein, and injection of recombinant Lamr (rLamr) protein produced in yeast cells protected shrimp against YHV in laboratory challenge tests.

False rumours of disease outbreaks caused by infectious myonecrosis virus (IMNV) in the whiteleg shrimp in Asia

In innate immunity, antimicrobial peptides (AMPs) play a vital role in combating microbial pathogens. Among the AMPs identified in Penaeus monodon, only anti-lipopolysaccharide factor isoform 3 (ALFPm3) has been reported to exhibit activity against white spot syndrome virus (WSSV). However, the mechanism(s) involved are still not clear. In the present study, ALFPm3-interacting proteins were screened for from a WSSV library using the yeast two-hybrid screening system, revealing the five potential ALFPm3-interacting proteins of WSSV186, WSSV189, WSSV395, WSSV458 and WSSV471. Temporal transcriptional analysis in WSSV-infected P. monodon revealed that all five of these WSSV gene transcripts were expressed in the late phase of infection (24h and 48h post-infection). Of these, WSSV189 that was previously identified as a structural protein, was selected for further analysis and was shown to be an enveloped protein by Western blot and immunoelectron microscopy analyses. The in vitro pull-down assay using recombinant WSSV189 (rWSSV189) protein as bait confirmed the interaction between ALFPm3 and WSSV189 proteins. Moreover, pre-incubation of rWSSV189 protein with rALFPm3 protein interfered with the latters neutralization effect on WSSV in vivo, as shown by the increased cumulative mortality of shrimp injected with WSSV following prior treatment with pre-incubated rWSSV189 and rALFPm3 proteins compared to that in shrimp pre-treated with rALFPm3 protein. Thus, ALFPm3 likely performs its anti-WSSV action by binding to the envelope protein WSSV189 and possibly other WSSV structural proteins.