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.     

High efficacy of white spot syndrome virus replication in tissues of freshwater rice‐field crab,Paratelphusa hydrodomous (Herbst)

An attempt was made to determine the replication efficiency of white spot syndrome virus (WSSV) of shrimp in different organs of freshwater rice‐field crab, Paratelphusa hydrodomous (Herbst), using bioassay, PCR, RT‐PCR, ELISA, Western blot and real‐time PCR analyses, and also to use this crab instead of penaeid shrimp for the large‐scale production of WSSV. This crab was found to be highly susceptible to WSSV by intramuscular injection. PCR and Western blot analyses confirmed the systemic WSSV infection in freshwater crab. The RT‐PCR analysis revealed the expression of VP28 gene in different organs of infected crab. The indirect ELISA was used to quantify the VP28 protein in different organs of crab. It was found that there was a high concentration of VP28 protein in gill tissue, muscle, haemolymph and heart tissue. The copy number of WSSV in different organs of infected crab was quantified by real‐time PCR, and the results revealed a steady increase in copy number in different organs of infected crab during the course of infection. The viral inoculum prepared from different organs of infected crab caused significant mortality in tiger prawn, Penaeus monodon (Fabricius). The results revealed that this crab can be used as an alternate host for WSSV replication and production.     

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.     

White spot syndrome virus (WSSV) prevalence associated with disease resistance among wild populations of black tiger shrimp,Penaeus monodon (Fabricius)

White spot disease caused by white spot syndrome virus (WSSV) is the major issue of huge economic destruction globally in the shrimp aquaculture industry. In the present investigation, WSSV prevalence associated with disease resistance was studied among wild black tiger shrimp, Penaeus monodon (Fabricius) from four distant geographic locations along the East coast of India during 2009–2010. Results suggested that the WSSV prevalence in wild P. monodon was the highest (56.2%) in Chennai, Tamil Nadu followed by Digha, West Bengal (10.9%), Visakhapatnam, Andhra Pradesh (0.6%) and Chilika, Orissa (0%). Quantitative data suggested that the mean copy number of WSSV among these four places was 1.4 × 10⁶, 4.6 × 10⁴, 1.6 × 10² and 2.3 × 10² copies μg^?1 shrimp genomic DNA respectively. The disease resistant prevalence using the 71 bp microsatellite DNA marker was the highest among Chilika, Orissa (63.6%) and Visakhapatnam, Andhra Pradesh (63.5%). Higher WSSV prevalence in Chennai, Tamil Nadu and Digha, West Bengal corresponded to lower disease resistant prevalence (24% and 40.2%). Conclusively, probably collection of broodstock of P. monodon from places like Chilika and Visakhapatnam would be a much safer approach for the development of specific pathogen‐resistant shrimp aquaculture.     

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.     

A Simple PCR Procedure to Detect White Spot Syndrome Virus (WSSV) of Shrimp, <Emphasis Type="Italic">Penaeus monodon</Emphasis> (Fabricious)

A non-stop, single tube and semi-nested polymerase chain reaction (PCR) technique with simple procedure was developed for simultaneous detection and grading the level of white spot syndrome infection in penaeid shrimp, Penaeus monodon. In this PCR procedure, three sense primers and one antisense primer with uniform annealing temperature of 55 °C were used. These primers amplify three PCR products (500, 300 and 200 base pairs [bp]) depending upon the severity of infection. Quantities of WSSV-DNA at 10 pg and greater gave three PCR products of 500, 300, 200 bp. A moderate concentration of WSSV-DNA, around 100 fg, gave two products of 300 and 200 bp and a low concentration of 1 fg or more gave only one PCR product of 200 bp. This PCR technique was assessed for early detection of WSSV in shrimp. In time-course infectivity experiments conducted on shrimp with WSSV, one PCR product (200 bp) was seen in hemolymph, tail tissue and gill at 3 h post infection (p.i.); two PCR products (300 and 200 bp) were seen in tail tissue, hemolymph, heart tissue and gill at 18 h p.i. At 30 h p.i., three PCR products (500, 300, 200 bp) were seen in all the organs tested. The samples collected from control animals showed negative for WSSV.     

Multiple infections caused by white spot syndrome virus and Enterocytozoon hepatopenaei in pond‐reared Penaeus vannamei in India and multiplex PCR for their simultaneous detection

White leg shrimp, Penaeus vannamei, were collected on a monthly basis from grow‐out ponds located at Tamil Nadu and Andhra Pradesh states along the east coast of India for screening of viral and other pathogens. Totally 240 shrimp samples randomly collected from 92 farms were screened for white spot syndrome virus (WSSV), infectious hypodermal and haematopoietic necrosis virus (IHHNV), infectious myonecrosis virus (IMNV) and Enterocytozoon hepatopenaei (EHP). The number of shrimp collected from shrimp farms ranged from 6 to 20 based on the body weight of the shrimp. All the shrimp collected from one farm were pooled together for screening for pathogens by PCR assay. Among the samples screened, 28 samples were WSSV‐positive, one positive for IHHNV and 30 samples positive for EHP. Among the positive samples, four samples were found to be positive for both WSSV and EHP, which indicated that the shrimp had multiple infections with WSSV and EHP. This is the first report on the occurrence of multiple infections caused by WSSV and EHP. Multiplex PCR (m‐PCR) protocol was standardized to detect both pathogens simultaneously in single reaction instead of carrying out separate PCR for both pathogens. Using m‐PCR assay, naturally infected shrimp samples collected from field showed two prominent bands of 615 and 510 bp for WSSV and EHP, respectively.     

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.     

Effects of total ammonia,temperature and salinity on the mortality and viral replication of WSSV‐infected Chinese shrimp (Fenneropenaeus chinensis)

In this study, we evaluated the effects of three factors, total ammonia, temperature and salinity, on the mortality of and viral proliferation in white spot syndrome virus (WSSV)‐infected Chinese shrimp. Shrimp maintained in 30‰ seawater at 25°C with 0.34 mg L^?1 total ammonia (control group) were injected with approximately 20 WSSV particles per shrimp and subsequently subjected to the following conditions: 30‰ seawater at 25°C, with 6 mg L^?1 (N1 group) or 14 mg L^?1 (N2 group) total ammonia; 30‰ seawater at 18°C (T1 group) or 30°C (T2 group), with 0.34 mg L^?1 total ammonia and 20‰ (S1 group) or 40‰ (S2 group) seawater at 25°C, with 0.34 mg L^?1 total ammonia. An anova analysis revealed that the cumulative mortality of WSSV‐infected Chinese shrimp was significantly lower when reared in the T1 group compared to that of the T2 and control group. Similarly, the mortality of the shrimp in the S1 group was also significantly lower than that of the S2 and control group. No significant differences were detected among the N1, N2 and control groups. Accordingly, the WSSV level in the T1 and S1 groups was significantly lower than those in the control, T2 or S2 groups respectively. No significant differences in viral loads were detected among the control, N1 and N2 groups. The transfer of Chinese shrimp to lower temperature and lower salinity enhanced their resistance to WSSV infection, whereas a change in the concentration of total ammonia had no significant effect on the mortalities and viral loads of WSSV‐infected shrimp.     

Experimental white spot syndrome virus challenge of juvenile Litopenaeus vannamei (Boone) at different salinities

In recent years, the shrimp industry has turned to inland freshwater culture as one method to avoid problems such as the introduction of possible vectors of viral pathogens into seawater ponds. Our experiments evaluated susceptibility to white spot syndrome virus (WSSV) in Litopenaeus vannamei held under different salinity regimens. Juvenile L. vannamei that were conditioned at salinities of 35, 25, 15, 5 and 2 g L⁻¹ were challenged with WSSV. In order to assess the severity of white spot disease, histological analysis and nested polymerase chain reaction (PCR) tests were carried out on the challenged shrimp every 4 h after 48 h post challenge. The results indicated that significantly more severe infections resulted at 15‰ than at other salinities. Mortality could not be compared due to the sampling design and because severe WSSV infections occurred in all test groups such that few shrimp remained alive in each challenged group at the end of the test. Despite this, the results suggest that salinity may affect the course and outcome of WSSV infections.     

Identification of RAPD‐SCAR marker linked to white spot syndrome virus resistance in populations of giant black tiger shrimp,Penaeus monodon Fabricius

White spot disease (WSD) caused by white spot syndrome virus (WSSV) creates severe epizootics in shrimp aquaculture industry worldwide. Despite several efforts, no such permanent remedy was yet developed. Selective breeding using DNA markers would be a cost‐effective strategy for long‐term solution of this problem. In the present investigation, out of 30 random primers, only one primer produced a statistically significant (P < 0.01) randomly amplified polymorphic DNA (RAPD) marker of 502 bp, which provided a good discrimination between disease resistant and disease susceptible populations of Penaeus monodon from three geographical locations along the East coast of India. Because RAPD markers are dominant, a sequence characterized amplified region (SCAR) marker was developed by cloning and sequencing of 502 bp RAPD fragment, which generates a single 457 bp DNA fragment after PCR amplification only in the disease resistant shrimps. Challenge experiment was also conducted to validate this 457 bp SCAR marker, and the results suggested that the WSSV loads were 2.25 × 10³ fold higher in disease susceptible than that in disease resistant shrimps using real‐time PCR. Therefore, this 457 bp DNA SCAR marker will be very valuable towards the development of disease‐free shrimp aquaculture industry.     

Polyclonal antibody‐based farmer‐friendly flow‐through test for the detection of acute hepatopancreatic necrosis disease in shrimp

Early mortality syndrome (EMS) or acute hepatopancreatic necrosis disease (AHPND) is currently the most significant disease of shrimp in farms of Vietnam, Thailand, Malaysia, China and Mexico, and there is a great risk that it may spread to other shrimp farming countries. Although, an array of sophisticated detection tools for AHPND available, there is a need for a sensitive, simple and rapid detection method. In this study, a simple, sensitive, rapid and polyclonal antibody‐based farmer‐friendly flow‐through assay (FTA) test has been developed for the detection of AHPND pathogen. The recombinant Photorhabdus insect‐related (Pir) A toxin‐like protein of AHPND pathogen was used to immunize rabbits at 21‐day interval observed for highest antibody titre after third booster by ELISA. The raised rabbit antiserum was purified by affinity chromatography and characterized by Western blot. The antiserum showed no cross‐reactivity with AHPND‐free Vibrio parahaemolyticus, V. anguillarum, White Spot Virus (WSV), Aeromonashydrophila and Aphanomycesinvadans. This polyclonal rabbit antiserum was used to develop a farmer‐friendly FTA test for the detection of AHPND pathogen. This simple FTA testis is more sensitive and could detect PirA^VP toxin up to 0.121 µg/ml, compared with 0.242 µg/ml by immunodot assay. Furthermore, FTA test requires only 8–10 min for completion, compared with 3 hr by immunodot thus found to be more sensitive, specific and cost‐effective. Collectively, sensitive FTA test would help shrimp farmers to take real‐time management decisions, especially emergency harvest and finally be a better hope for the prevention of AHPND.     

TaqMan real-time PCR assay for relative quantification of white spot syndrome virus infection in Penaeus monodon Fabricius exposed to ammonia

White spot disease is caused by a highly virulent pathogen, the white spot syndrome virus (WSSV). The disease is usually triggered by changes in environmental parameters causing severe losses to the shrimp industry. This study was undertaken to quantify the relative WSSV load in shrimp exposed to ammonia, using a TaqMan‐based real‐time PCR, and their subsequent susceptibility to WSSV. Shrimp were exposed to different levels of total ammonia nitrogen (TAN) (8.1, 3.8 and 1.1 mg L^?1) for 10 days and challenged with WSSV by feeding WSSV‐positive shrimp. WSSV was detected simultaneously in haemolymph, gills and pereopods at four hours post‐infection. The TaqMan real‐time PCR assay showed a highly dynamic detection limit that spanned over 6 log₁₀ concentrations of DNA and high reproducibility (standard deviation 0.33–1.42) and small correlation of variability (CV) (1.89–3.85%). Shrimp exposed to ammonia had significantly higher (P < 0.01) WSSV load compared to the positive control, which was not exposed to ammonia. Shrimp exposed to 8.1 mg L^?1 of TAN had the highest (P < 0.01) WSSV load in all three organs in comparison with those exposed to 3.8 and 1.1 mg L^?1 of TAN. However, haemolymph had significantly higher (P < 0.01) viral load compared to the gills and pereopods. Results showed that shrimp exposed to ammonia levels as low as 1.1 mg L^?1 (TAN) had increased susceptibility to WSSV.     

Transmission of white spot syndrome virus (WSSV) from Dendronereis spp. (Peters) (Nereididae) to penaeid shrimp

Dendronereis spp. (Peters) (Nereididae) is a common polychaete in shrimp ponds built on intertidal land and is natural food for shrimp in traditionally managed ponds in Indonesia. White spot syndrome virus (WSSV), an important viral pathogen of the shrimp, can replicate in this polychaete (Desrina et al. 2013); therefore, it is a potential propagative vector for virus transmission. The major aim of this study was to determine whether WSSV can be transmitted from naturally infected Dendronereis spp. to specific pathogen‐free (SPF) Pacific white shrimp Litopenaeus vannamei (Boone) through feeding. WSSV was detected in naturally infected Dendronereis spp. and Penaeus monodon Fabricius from a traditional shrimp pond, and the positive animals were used in the current experiment. WSSV‐infected Dendronereis spp. and P. monodon in a pond had a point prevalence of 90% and 80%, respectively, as measured by PCR. WSSV was detected in the head, gills, blood and mid‐body of Dendronereis spp. WSSV from naturally infected Dendronereis spp was transmitted to SPF L. vannamei and subsequently from this shrimp to new naïve‐SPF L. vannamei to cause transient infection. Our findings support the contention that Dendronereis spp, upon feeding, can be a source of WSSV infection of shrimp in ponds.     

Prevalence of white spot syndrome virus infection detected by one-step and nested PCR in selected tiger shrimp (<Emphasis Type="Italic">Penaeus monodon</Emphasis>) hatcheries

White spot syndrome (WSS) is considered as a great threat to commercial farming of the tiger shrimp (Penaeus monodon). The causal agent of WSS is a DNA virus called white spot syndrome virus (WSSV). The prevalence of this dreadful virus infection has been studied in five randomly selected hatcheries located in the Cox’s Bazar district of Bangladesh. Both one-step and nested polymerase chain reaction (PCR) involving two pairs of primers, namely, 146F1/146R1 and 146F2/146R2, amplifying the 1447 bp and 941 bp fragments, respectively, were conducted to detect the WSSV. Out of 60 randomly collected shrimps, 12 (20%) were found to be positive by one-step PCR, while 18 (30%) were found to be positive by nested PCR. The nested PCR was found to be much more sensitive than the one-step PCR. The shrimp specimens showing clinical signs of WSS were positive for WSSV by both one-step and nested PCR. Some of the apparently healthy samples were also found to be positive for WSSV by nested PCR. Among the two primer-pairs, the inner pair amplifying the 941 bp fragment was more sensitive than the outer primer pair amplifying the 1447 bp fragment when used in one-step PCR.     

Evidence for the presence of white spot syndrome virus (WSSV) and monodon baculovirus (MBV) in wild Penaeus monodon (Fabricius) broodstock,in the southeast coast of India

A survey on the presence of the viruses of two economically significant diseases, white spot syndrome virus (WSSV) and monodon baculovirus (MBV) in wild‐collected Penaeus monodon broodstock, was conducted during different seasons of the year in two major coastal areas of southeast India. The broodstock were collected along the coast of Tamil Nadu and Andhra Pradesh during summer, premonsoon, monsoon and post‐monsoon seasons for three consecutive years. A total of 7905 samples were collected and subjected to MBV screening, and 6709 samples that were screened as MBV negative were diagnosed for WSSV. MBV was detected using rapid malachite green staining and WSSV by nested polymerase chain reaction. Prevalence data of the viruses were analysed using the EpiCalc 2000 program at 95% confidence interval. Samples collected from the Andhra Pradesh coast displayed a slightly higher prevalence of WSSV and MBV infection than those collected from Tamil Nadu, although this difference was not statistically significant (P > 005). In addition, it was found that the prevalence of both WSSV and MBV infections fluctuated according to season. Data on prevalence of these viruses in broodstock would be useful to develop strategies for shrimp health management along the southeast coast of India.     

Passive immunity in tiger shrimp (Penaeus monodon) fed with monoclonal antibody to white spot syndrome virus

A study was conducted on the stability of monoclonal antibody (MAb) in the hepatopancreas and hemolymph of Penaeus monodon and its effect on protection against white spot syndrome virus (WSSV) upon challenge. MAb C-5 raised against WSSV was purified and coated onto a commercial shrimp feed at dosages of 5, 10 and 15 mg/kg feed. The feed was fed to P. monodon and stability of the MAb in hepatopancreas and hemolymph was determined by immunodot and Western blot. Immunodot results indicated the presence of MAb for 2 h post-feeding in hepatopancreas and hemolymph which was dose-dependent. MAb was also detected in hemolymph by Western blot up to 1 h post-feeding. Shrimp fed with MAb were challenged with WSSV by oral and injection methods. In shrimp fed with 15 mg antibody/kg feed (0.45 μg MAb/g shrimp/day) WSSV infection significantly delayed both in oral and injection challenges with a survival of 65 and 70 % (p < 0.05), respectively, during 15 days post-challenge. MAb was stable in shrimp for passive immunization against WSSV and could be a potential tool for prophylaxis against the virus.