Tissue distribution of hepatopancreatic parvo‐like virus of shrimp in freshwater rice‐field crab,Paratelphusa hydrodomous (Herbst)

An attempt was made to determine the replication efficiency of hepatopancreatic parvo‐like virus (HPV) of shrimp in different organs of freshwater rice‐field crab Paratelphusa hydrodomous (Herbst) using bioassay, PCR, RT‐PCR, ELISA, Western blot and q‐PCR analyses. Another attempt was made to use this crab as an alternative to penaeid shrimp for the large‐scale production of HPV. This crab was found to be highly susceptible to HPV by intramuscular injection. The systemic HPV infection was confirmed by PCR and Western blot analyses in freshwater crab. The expression of capsid protein gene in different organs of infected crab was revealed by RT‐PCR analysis. Indirect ELISA was used to quantify the capsid protein in different organs of the crab. The copy number of HPV in different organs of the infected crab was quantified by q‐PCR. The results revealed a steady decrease in C_T values in different organs of the infected crab during the course of infection. The viral inoculum that was prepared from different organs of the infected crab caused significant mortality in post‐larvae of tiger prawn, Penaeus monodon (Fabricius). The results revealed that this rice‐field crab could be used as an alternative host for HPV replication and also for large‐scale production of HPV.     

Development of immunodot blot assay for the detection of white spot syndrome virus infection in shrimps (Penaeus monodon)

The VP 28 gene encoding a structural envelope protein of the white spot syndrome virus (WSSV) was cloned into a pET32a(+) expression vector for the production of the recombinant VP28 protein. A purified recombinant protein of 39.9 kDa size was used for polyclonal antibody production in rabbit. Specific immunoreactivity of the rabbit anti rVP28 antiserum to the viral antigen was confirmed by a Western blot. The specificity of this polyclonal anti‐rVP28 antiserum to detect the presence of the virus in WSSV‐infected Penaeus monodon was verified using a immunodot blot assay. Immunodot blot showed a positive reaction in infected shrimp tissues with prominent colour development using 3,3′,5,5′‐tetramethylbenzidine (TMB) as a chromogenic substrate when compared with 3–3′ diaminobenzidine tetrahydrochloride (DAB). Highest signal intensities of the immunodots were observed in infected shrimp pleopod extracts and haemolymph. On comparison with polymerase chain reaction (PCR), immunodot blot could detect 76% of PCR‐positive WSSV‐infected shrimp samples. Immunodot blot was found to be equivalent to first‐step PCR sensitivity to detect WSSV particles estimated to contain 1.0 × 10⁵ viral DNA copies.     

Analysis of viral load between different tissues and rate of progression of white spot syndrome virus (WSSV) in Penaeus monodon

At present the most common and most devastating disease of shrimp is caused by the white spot syndrome virus (WSSV), which has spread throughout the world mainly by different species of crustaceans carrying the virus. After experimental injection of Penaeus monodon with a known copy number of WSSV in the abdominal muscle, the rate of viral progression in different tissues at 12, 24, 36 and 48 hpi (hours post infection) was assessed using quantitative real‐time PCR. At 12 hpi the viral load was highest in haemocytes followed by pleopod, muscle and gills whereas at 48 hpi, the gills, the main target of WSSV, showed the highest viral load followed by pleopod, muscle and haemocytes. Viral copy number in the haemocytes was the lowest beyond 12 hpi indicating a remarkable reduction in the rate of viral replication in haemocytes compared with other tissues. The viral load in haemocytes, though increased again beyond 36 hpi, never surpassed the load in the other tissues. The real‐time PCR assay with its high sensitivity and wide dynamic range make it ideal for detecting low‐level WSSV infections that can occur in apparently healthy P. monodon.     

Biochemical changes and tissue distribution of Enterocytozoon hepatopenaei (EHP) in naturally and experimentally EHP‐infected whiteleg shrimp,Litopenaeus vannamei (Boone, 1931), in India

Stunted growth in pond‐reared Litopenaeus vannamei was observed in different farms located in Tamil Nadu and Andhra Pradesh, India. No mortality was associated with stunted growth. PCR assay on these samples revealed the presence of Enterocytozoon hepatopenaei (EHP) in stunted shrimp. Tissue distribution of EHP in naturally and experimentally infected shrimp was studied by PCR and histology. Histological examination revealed the presence of EHP in hepatopancreas and gut, but not in other organs. The PCR assay revealed the presence of EHP in all the organs tested in both naturally and experimentally infected shrimp. Healthy shrimp were challenged with E. hepatopenaei by intramuscular injection and oral route, and no mortality was observed in both routes after 30 days post‐challenge. Different developmental stages of the microsporidian parasite were observed in the hepatopancreatic epithelial cells. Biochemical parameters such as total protein, albumin, aspartate transaminase (AST), alanine transaminase (ALT) and alkaline phosphatase were measured in the haemolymph of naturally and experimentally EHP‐infected shrimp. All biochemical parameters mentioned were found to be significantly higher in EHP‐infected shrimp when compared to normal shrimp. This is the first report relating AST and ALT levels to EHP infection in naturally and experimentally infected shrimp.     

Potential role of LvDscam in specific immune response of Litopenaeus vannamei against white spot syndrome virus by oral delivery of VP28 using Bacillus subtilis

Envelope protein VP28 has been suggested as a candidate vaccine component to evoke a better protection against white spot syndrome virus (WSSV). We have reported that Bacillus subtilis spores harbouring VP28 (rVP28‐bs) can specifically protect shrimp against WSSV. However, the mechanism that supports the production of unique molecules induced by rVP28‐bs to trigger specific immunity is originally unknown. It has recently been suggested that Dscam (Down syndrome cell adhesion molecule) plays an essential role in the alternative adaptive immunity of invertebrates. In this study, we compared the diversity of Litopenaeus vannamei Dscam (LvDscam) variable regions by different antigens immunization. A total of 13, 15 and 11 expressed alternative sequences were identified for N‐terminal Ig2, N‐terminal Ig3 and the entire Ig7 domain, respectively. More than half of the unique variants (16 out of 22) were found in the Ig2/Ig3 domains. Further analysis of the interaction between VP28 and unique Ig2/Ig3 variants was confirmed by both yeast two‐hybrid and GST pull‐down approach. We also found that the percentage of haemocytes phagocytosing WSSV was significantly higher (P < 0.001) in the shrimp injected with control‐siRNA (43.8 ± 2.2) than those with Dscam‐siRNA (11.3 ± 5.4) in the rVP28‐bs groups. With Dscam‐siRNA injection, survivorship significantly decreased (P < 0.001) in the rVP28‐bs group after WSSV challenge. Our data suggested that LvDscam‐mediated pathway may be involved in the specific immune response of shrimp against WSSV induced by rVP28‐bs.     

Production of polyclonal antiserum against recombinant VP28 protein and its application for the detection of white spot syndrome virus in crustaceans

The VP28 gene of white spot syndrome virus (WSSV) was cloned into pRSET B expression vector. The VP28 protein was expressed as a protein with a 6-histidine taq in Escherichia coli GJ1158 with NaCl induction. Antiserum was raised against this recombinant-VP28 protein in rabbits and it recognized VP28 protein in naturally and experimentally WSSV-infected shrimp, marine crabs, freshwater prawns and freshwater crabs. The antiserum did not recognize any of the other known WSSV structural proteins. Various organs such as eyestalks, head muscle, gill tissue, heart tissue, haemolymph, tail tissue and appendages were found to be good materials for detection of WSSV using the antiserum and detection of WSSV was successful in experimentally infected Penaeus monodon and P. indicus at 12 and 24 h post-infection (p.i.), respectively. The antiserum was capable of detecting WSSV in 5 ng of total haemolymph protein from WSSV-infected shrimp.     

White spot syndrome virus (WSSV) infection and immunity responses in white shrimp (Litopenaeus vannamei) exposed to sublethal levels of metals

To determine if exposure to a sublethal mixture of metals (Cd, Cu, Fe, Mn, Pb and Zn) increases susceptibility to White spot syndrome virus (WSSV) infection, Litopenaeus vannamei juveniles were fed WSSV‐infected shrimp tissues after 21 days of exposure to the metal mixture (WS‐MM treatment). Other treatments consisted of shrimp not exposed to metals and fed infected tissues (WS), and shrimp fed healthy tissues and exposed (MM) or not exposed to metals (C). The presence of viral DNA and inclusion bodies was detected at 32 hr postinfection (hpi) in the stomach epithelium of shrimp from the WS treatment, and eight hours later in shrimp from the WS‐MM treatment, possibly because of an initial negative effect of metals in viral replication. At 40 hpi, the severity of infection represented by the histopathological index increased in both WS and WS‐MM treatments, and values were higher in WS‐MM than in WS shrimp at the end of the experiment. From 56 hpi to the end of experiment, total hemocyte counts were lower in both WS‐MM and WS treatments, and concentrations were particularly low in WS‐MM shrimp. Conversely, phenoloxidase activity was higher in the WS‐MM treatment from 32 to 56 hpi, suggesting a possible role of the prophenoloxidase (proPO) system in the antiviral defense against WSSV. The presence of heavy metals at sublethal concentrations may increase shrimp susceptibility to WSSV; this is supported by a decrease in circulating hemocytes, an increase in the humoral response, and the development of a higher number of WSSV inclusion bodies.     

A new strain of white spot syndrome virus affecting Litopenaeus vannamei in Indian shrimp farms

White spot syndrome virus (WSSV)‐infected shrimp samples collected from grow‐out ponds located at Nellore, Andhra Pradesh, India, showed WSSV negative and positive by PCR using primer sets specific to ORF119 and VP28 gene of WSSV, respectively. This indicated the deletion of genetic fragments in the genome of WSSV. The WSSV isolate along with lab strain of WSSV was subjected to next‐generation sequencing. The sequence analysis revealed a deletion of 13,170 bp at five positions in the genome of WSSV‐NS (new strain) relative to WSSV‐TH and WSSV‐LS (lab strain). The PCR analysis using the ORF's specific primer sets revealed the complete deletion of 10 ORFs in the genome of WSSV‐NS strain. The primer set was designed based on sequence covering ORF161/162/163 to amplify a product of 2,748 bp for WSSV‐LS and 402 bp for WSSV‐NS. Our surveillance programme carried out since 2002 revealed the replacement of WSSV‐LS by WSSV‐NS in Indian shrimp culture system.     

Development of monoclonal antibodies against VP28 of WSSV and its application to detect WSSV using immunocomb

White spot disease (WSD) is an important viral disease of penaeid shrimp caused by white spot syndrome virus (WSSV). WSSV isolated from WSD outbreaks in commercial shrimp (Penaeus monodon) farms in India were propagated in the laboratory in healthy shrimp. The virus was purified from the infected tissues by sucrose gradient centrifugation. The VP28 was electroeluted from SDS-PAGE gels and was used to immunize Balb/c mice to produce hybridomas secreting monoclonal antibodies (MAb) against WSSV. A total of five hybridoma clones secreting MAbs to VP28 were produced. The MAbs were of the isotypes IgG1, IgG2b and IgM. The MAbs reacted with VP28 of WSSV and not with any other viral or shrimp protein in western blot. The MAbs were used to develop dot immunoblot assay using an immunocomb to detect WSSV from field samples. The test developed had an analytical sensitivity of 625 pg and a diagnostic sensitivity of 100% compared to single step polymerase chain reaction (PCR). The test can be used as an alternate for first step PCR to detect WSSV from field samples.     

Virulence status,viral accommodation and structural protein profiles of white spot syndrome virus isolates in farmed Penaeus monodon from the southeast coast of India

The objective of this study was to investigate the reason for variation in the virulence of white spot syndrome virus (WSSV) from different shrimp farms in the Southeast coast of India. Six isolates of WSSV from farms experiencing outbreaks (virulent WSSV; vWSSV) and three isolates of WSSV from farms that had infected shrimps but no outbreaks (non‐virulent WSSV; nvWSSV) were collected from different farms in the Southeast coast of India. The sampled animals were all positive for WSSV by first‐step PCR. The viral isolates were compared using histopathology, electron microscopy, SDS‐PAGE analysis of viral structural proteins, an in vivo infectivity experiment and sequence comparison of major structural protein VP28; there were no differences between isolates in these analyses. A significant observation was that the haemolymph protein profile of nvWSSV‐infected shrimps showed three extra polypeptide bands at 41, 33 and 24 kDa that were not found in the haemolymph protein profile of vWSSV‐infected shrimps. The data obtained in this study suggest that the observed difference in the virulence of WSSV may not be due to any change in the virus, rather it could be due to the shrimp defence system producing certain factors that help it to accommodate the virus without causing any mortality.     

Studies on the occurrence of infectious myonecrosis virus in pond‐reared Litopenaeus vannamei (Boone, 1931) in India

Whiteleg shrimp, Litopenaeus vannamei, with clinical sign of muscle opaqueness with reddish colour at the distal abdominal segments were observed in farms located in West Bengal State, India. The mortality of shrimp in all disease outbreak ponds ranged from 20% to 50%, and mortality increased gradually. The RT‐PCR assay of these samples using primer sets specific to infectious myonecrosis virus (IMNV) revealed its presence in the disease outbreak ponds. The IMNV infection was reproduced in healthy shrimp by intramuscular injection to satisfy River's postulates. The virus caused mortality in intramuscularly challenged shrimp, but failed to cause mortality by oral route. Tissue distribution of IMNV in infected shrimp by RT‐PCR assay revealed the presence of this virus in haemolymph, gill, hepatopancreas and muscle. This study confirms that the disease outbreak which occurred in the shrimp farms located at Purba Medinipur District, West Bengal, India, was due to IMNV.     

Production of recombinant capsid protein of Macrobrachium rosenbergii nodavirus (r‐MCP43) of giant freshwater prawn,M. rosenbergii (de Man) for immunological diagnostic methods

White tail disease (WTD) caused by Macrobrachium rosenbergii nodavirus (MrNV) and extra small virus (XSV) is a serious problem in prawn hatcheries. The gene for capsid protein of MrNV (MCP43) was cloned into pRSET B expression vector. The MCP43 protein was expressed as a protein with a 6‐histidine tag in Escherichia coli GJ1158 with NaCl induction. This recombinant protein, which was used to raise the antiserum in rabbits, recognized capsid protein in different WTD‐infected post‐larvae and adult prawn. Various immunological methods such as Western blot, dot blot and ELISA techniques were employed to detect MrNV in infected samples using the antiserum raised against recombinant MCP43 of MrNV. The dot blot assay using anti‐rMCP43 was found to be capable of detecting MrNV in WTD‐infected post‐larvae as early as at 24 h post‐infection. The antiserum raised against r‐MCP43 could detect the MrNV in the infected samples at the level of 100 pg of total protein. The capsid protein of MrNV estimated by ELISA using anti‐rMCP43 and pure r‐MCP43 as a standard was found to increase gradually during the course of infection from 24 h p.i. to moribund stage. The results of immunological diagnostic methods employed in this study were compared with that of RT‐PCR to test the efficiency of antiserum raised against r‐MCP43 for the detection of MrNV. The Western blot, dot blot and ELISA detected all MrNV‐positive coded samples as detected by RT‐PCR.     

Development of a monoclonal antibody‐based flow‐through immunoassay (FTA) for detection of white spot syndrome virus (WSSV) in black tiger shrimp Penaeus monodon

A flow‐through immunoassay (FTA), an improved version of immunodot, was developed using a nitrocellulose membrane baked onto adsorbent pads enclosed in a plastic cassette to detect white spot syndrome virus (WSSV) in shrimp. Sharp purple dots developed with WSSV against the white background of the nitrocellulose membrane. The detection limits of WSSV by the FTA and immunodot were 0.312 and 1.2 μg mL^?1 crude WSSV protein, respectively. The FTA could be completed in 8–10 min compared with 90 min for immunodot. The FTA was 100 times more sensitive than 1‐step polymerase chain reaction (PCR) and in between that of the 1‐ and 2‐step PCR protocol recommended by the Office of International Epizootics (OIE). In experimental, orally infected shrimp post‐larvae, WSSV was first detected 14, 16 and 18 h post‐infection (hpi) by FTA, immunodot and one‐step PCR, respectively. The FTA detected WSSV 2 and 4 h earlier than immunodot and one‐step PCR, respectively. The FTA was more sensitive (25/27) than one‐step PCR (23/27) and immunodot (23/27) for the detection of WSSV from white spot disease outbreak ponds. The reagent components of the FTA were stable giving expected results for 6 m at 4–8 °C. The FTA is available as a rapid test kit called ‘RapiDot’ for the early detection of WSSV under field conditions.     

White spot syndrome virus epizootic in cultured Pacific white shrimp Litopenaeus vannamei (Boone) in Taiwan

White spot syndrome virus (WSSV) has caused significant losses in shrimp farms worldwide. Between 2004 and 2006, Pacific white shrimp Litopenaeus vannamei (Boone) were collected from 220 farms in Taiwan to determine the prevalence and impact of WSSV infection on the shrimp farm industry. Polymerase chain reaction (PCR) analysis detected WSSV in shrimp from 26% of farms. Juvenile shrimp farms had the highest infection levels (38%; 19/50 farms) and brooder shrimp farms had the lowest (5%; one of 20 farms). The average extent of infection at each farm was as follows for WSSV‐positive farms: post‐larvae farms, 71%; juvenile farms, 61%; subadult farms, 62%; adult farms, 49%; and brooder farms, 40%. Characteristic white spots, hypertrophied nuclei and basophilic viral inclusion bodies were found in the epithelia of gills and tail fans, appendages, cephalothorax and hepatopancreas, and virions of WSSV were observed. Of shrimp that had WSSV lesions, 100% had lesions on the cephalothorax, 96% in gills and tail fans, 91% on appendages and 17% in the hepatopancreas. WSSV was also detected in copepoda and crustaceans from the shrimp farms. Sequence comparison using the pms146 gene fragment of WSSV showed that isolates from the farms had 99.7–100% nucleotide sequence identity with four strains in the GenBank database – China ( AF332093 ), Taiwan ( AF440570 and U50923 ) and Thailand ( AF369029 ). This is the first broad study of WSSV infection in L. vannamei in Taiwan.     

A rapid non-enzymatic method of DNA extraction for PCR detection of white spot syndrome virus in shrimp

The present study describes a simple method of extraction of white spot syndrome viral DNA (WSSV) from infected shrimp for the polymerase chain reaction (PCR) detection of WSSV. The DNA preparation using this method was found to be free from the host DNA, RNA and protein, and is suitable for different PCR protocols such as single‐step PCR, nested PCR and single‐tube semi‐nested PCR. This method of extraction has worked successfully for extracting the WSSV‐DNA from different organs (haemolymph, eyestalk, carapace, head muscle, heart, gills, appendages, heptopancreas, stomach, intestine, abdominal muscle and tail muscle) of WSSV‐infected adult shrimp, and WSSV‐infected larvae and postlarvae.     

Susceptibility of freshwater rearing Asian seabass (Lates calcarifer) to pathogenic Streptococcus iniae

Asian seabass (Lates calcarifer) has been recognized as an economically important aquaculture species which can be adapted to and cultivated in wide range of salinities. The number of freshwater intensive seabass farms in Thailand is increasing annually. Here, we first describe the susceptibility of Asian seabass, which were cultured in freshwater, to Streptococcus inae (SI) and their pathological changes. Three isolates of putative SI were identified using a combination of standard biochemical assays and species‐specific PCR prior subjected to in vivo challenge. Accumulated mortalities of the fish which received 10⁷ CFU fish^?1 of either SI1J, SI SGSA or SI2J were 90%, 90% and 100% at 7 days‐post infection (dpi), respectively, and mortalities increased sharply between 3 and 5 dpi. Clinical signs such as erratic swimming and opaque eyes were identified from a few infected fish, while most died rapidly without any abnormal signs. Histopathological manifestations were observed in the multiple organs (kidney, liver and brain). Haemorrhage, hyperhemia, cellular degeneration and inflammatory cells infiltration were commonly found within the internal organs. Notably, the formation of numerous encyst‐like lesion aggregated by eosinophilic cells, resembling macrophages, were typically found in the brain of the infected fish. Summarily, this study first revealed that freshwater reared Asian seabass is highly susceptible to SI infection and haemorrhagic septicaemia was a major pathological change that could be found in the infected fish.