White spot syndrome virus (WSSV) infection in tiger shrimp <Emphasis Type="Italic">Penaeus monodon</Emphasis>: A non-lethal histopathological rapid diagnostic method using paraffin and frozen sections

White spot syndrome virus (WSSV) infection was induced in tiger shrimp, Penaeus monodon, under laboratory conditions, and histopathological changes in subcuticular epithelial cells of the eye stalk and pleopod were studied sequentially at different time post-challenge. Routine histological techniques using paraffin embedded tissues, as well as frozen tissues, were used to document WSSV infection. Histological manifestations such as cellular hypertrophy in the subcuticular epithelial cells of the eyestalk and pleopod could be detected as early as 18 h post-infection (p.i.) before the manifestation of clinical signs of the disease. However, no histopathological changes could be detected before 18 h p.i.. Hypertrophy of the nuclei in the epithelial cells was pronounced after 24 h p.i. Marked necrosis, and eosinophilic intranuclear inclusions, characteristic of early stages of WSSV infection were observed between 24–36 h p.i. Clinical signs of the disease appeared at 48 h p.i. The presence of WSSV at early asymptomatic stages of p.i. has been tested in parallel samples using polymerase chain reaction, for further confirmation of WSSV. This paper discusses the potential of a non-lethal and rapid histopathological diagnostic method to document WSSV infection, using the eyestalk or pleopod, when expensive DNA based diagnostics are not available or affordable.     

Studies on pathogenicity and prevalence of white spot syndrome virus in mud crab, Scylla serrata (Forskal), in Zhejiang Province, China

Mud crab, Scylla serrata (Forskal), is the most commercially important marine crab species in China. In recent years, serious diseases have occurred in major mud crab culture regions in SE China. PCR detection of white spot syndrome virus (WSSV) in diseased mud crabs collected from Zhejiang Province during 2006–2008 showed a prevalence of 34.82%. To study the pathogenicity of WSSV to mud crab, healthy mud crabs were injected intramuscularly with serial 10‐fold dilutions of a WSSV inoculum. The cumulative mortalities in groups challenged with 10^?1, 10^?2, 10^?3 and 10^?4 dilutions were 100%, 100%, 66.7% and 38.9% at 10 days post‐injection, respectively. All moribund and dead mud crabs except the control group were positive for WSSV by PCR. Based on the viral load of the WSSV inoculum by quantitative real‐time PCR, the median lethal dose (LD50) of WSSV in S. serrata was calculated as 1.10 × 10⁶ virus copies/crab, or 7.34 × 10³ virus copies g^?1 crab weight. The phenoloxidase, peroxidase and superoxide dismutase activities in haemolymph of WSSV‐infected moribund crabs, were significantly lower than the control group, whereas alkaline phosphatase, glutamate‐pyruvate transaminase and glutamic‐oxaloacetic transaminase were higher than in the control group. WSSV was mainly distributed in gills, subcuticular epithelia, heart, intestine and stomach as shown by immunohistochemical analysis with Mabs against WSSV. The epithelial cells of infected gill showed hypertrophied nuclei with basophilic inclusions. Numerous bacilliform virus particles were observed in nuclei of infected gill cells by transmission electron microscopy. It is concluded that WSSV is a major pathogen of mud crab with high pathogenicity.     

Competition of infectious hypodermal and haematopoietic necrosis virus (IHHNV) with white spot syndrome virus (WSSV) for binding to shrimp cellular membrane

Infectious hypodermal and haematopoietic necrosis virus (IHHNV) and white spot syndrome virus (WSSV) are two widespread shrimp viruses. The interference of IHHNV on WSSV was the first reported case of viral interference that involved crustacean viruses and has been subsequently confirmed. However, the mechanisms underlying the induction of WSSV resistance through IHHNV infection are practically unknown. In this study, the interference mechanisms between IHHNV and WSSV were studied using a competitive ELISA. The binding of WSSV and IHHNV to cellular membrane of Litopenaeus vannamei was examined. The results suggested that there existed a mutual competition between IHHNV and WSSV for binding to receptors present on cellular membrane of L. vannamei and that the inhibitory effects of WSSV towards IHHNV were more distinct than those of IHHNV towards WSSV.     

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.     

湖北省潜江地区克氏原螯虾(procambarus clarkii)白斑综合征(White Spot Syndrome)PCR诊断及组织病理学观察

近年来在湖北省范围内人工养殖的克氏原螯虾暴发了严重的疾病,其中白斑综合征病毒（WSSV）已成为危害克氏原螯虾健康养殖的重要病原。2016年5月湖北省潜江市养殖区暴发了一种传染性疾病,为探究此次疾病病因和流行规律,将染病虾进行临床症状观察、对病料进行PCR检测、系统发育树分析、人工感染和组织病理学观察。结果显示,发病克氏原螯虾临床症状主要表现为摄食减少,活力下降,反应迟钝;组织病理学观察结果显示,克氏原螯虾的肝胰腺、肠、肌肉、鳃组织均出现不同程度变性和坏死以及炎性细胞浸润等典型病理学变化,与WSSV感染克氏原螯虾出现的病变相似;PCR检测患病克氏原螯虾样品,结果显示WSSV呈阳性,阳性检出率为55.56%（15/27）,未检测到斑节对虾杆状病毒（MBV）和传染性皮下及造血组织坏死病毒（IHHNV）;检测产物测序并进行系统发育树分析,结果显示,该基因序列与WSSV的EG3株（KR083866.1）核苷酸序列同源性为100%。将病虾的肝胰腺、肠和肌肉组织投喂健康克氏原螯虾,投喂组均表现为急性死亡（累积死亡率为100%）,并出现与自然发病虾相同的症状。WSSV的巢式PCR检测结果显示,人工感染病虾为WSSV阳性。根据以上显示,本次养殖克氏原螯虾大规模死亡的病原是WSSV。     

Purification of white spot syndrome virus by iodixanol density gradient centrifugation

Up to now, only a few brief procedures for purifying white spot syndrome virus (WSSV) have been described. They were mainly based on sucrose, NaBr and CsCl density gradient centrifugation. This work describes for the first time the purification of WSSV through iodixanol density gradients, using virus isolated from infected tissues and haemolymph of Penaeus vannamei (Boone). The purification from tissues included a concentration step by centrifugation (2.5 h at 60 000  g ) onto a 50% iodixanol cushion and a purification step by centrifugation (3 h at 80 000  g ) through a discontinuous iodixanol gradient (phosphate‐buffered saline, 5%, 10%, 15% and 20%). The purification from infected haemolymph enclosed a dialysis step with a membrane of 1 000 kDa (18 h) and a purification step through the earlier iodixanol gradient. The gradients were collected in fractions and analysed. The number of particles, infectivity titre (in vivo), total protein and viral protein content were evaluated. The purification from infected tissues gave WSSV suspensions with a very high infectivity and an acceptable purity, while virus purified from haemolymph had a high infectivity and a very high purity. Additionally, it was observed that WSSV has an unusually low buoyant density and that it is very sensitive to high external pressures.     

First report of white spot syndrome virus in wild crustaceans and mollusks in the Paraíba River,Brazil

The aim of the present study was to investigate the presence of white spot syndrome virus (WSSV) in the Paraíba River, Brazil. Eight sampling sites were established on the bank of the river near water intake areas for the farming of Litopenaeus vannamei. Ten specimens of the shrimp Palaemon pandaliformis and the gastropods Pomacea lineata and Melanoides tuberculatus were collected at each site. Eighty‐one gill fragments from P. pandaliformis, 40 whole individuals of M. tuberculatus and 26 muscle fragments from P. lineata were collected. All samples were stored in microcentrifuge tubes with 95% ethanol (1:10; v:v). Tests were performed at the Potiporã Molecular Analysis Laboratory (state of Rio Grande do Norte, Brazil) for the detection of WSSV using Loop Mediated Isothermal Amplification with the aid of the LAMP WSSV kit (Concepto Azul, Ecuador). Twenty‐nine per cent of P. pandaliformis, 48% of M. tuberculatus and 8% of P. lineata tested positive. The findings demonstrate that WSSV is present in wild crustaceans and mollusks, which may serve as vectors and/or reservoirs of the virus, thereby posing a potential risk to local shrimp farming. This is the first report of WSSV in wild specimens of M. tuberculatus and P. lineata.     

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.     

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.     

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.     

Immune responses by dietary supplement with Astragalus polysaccharides in the Pacific white shrimp,Litopenaeus vannamei

Two experiments were conducted to investigate the immune‐enhancing effect of dietary supplement with Astragalus polysaccharides (APS) on the Pacific white shrimp, Litopenaeus vannamei. In experiment 1, the optimal APS dose was determined based on the immune responses of shrimps fed APS diet for 30 days. In experiment 2, the effect of APS supplementation on immune response of shrimp suffering white spot syndrome virus (WSSV) challenge was determined. Results showed that the total haemocyte count and phagocytic activity in shrimps fed APS diets significantly (p < .05) increased in comparison with those fed the basal diet. Dietary supplement with APS markedly (p < .05) increased the activity of phenoloxidase (PO), total superoxide dismutase (SOD), lysozyme (LZM), acid phosphatase and alkaline phosphatase in shrimp hemolymph, but decreased the maleic dialdehyde (MDA) content. Significantly higher (p < .05) activity on PO, SOD and LZM and lower (p < .05) MDA content have also been found in shrimps suffering WSSV challenge. Therefore, APS could be used as a safe and effective feed additive in shrimp aquaculture, and the optimal dose of APS for the Pacific white shrimp was suggested to be 0.2 g/kg based on our results.     

Comparison of white spot syndrome virus quantification of fleshy shrimp Fenneropenaeus chinensis in outdoor ponds between different growing seasons by TaqMan real‐time polymerase chain reaction

In the present study, we used TaqMan real‐time polymerase chain reaction to quantify and compare infection of white spot syndrome virus (WSSV) with shrimp production of Fenneropenaeus chinensis cultured in outdoor ponds along the west coast of the South Korea. In 2007, a total of 60 specimens in summer and 116 specimens in autumn were collected from 12 growing‐out ponds and 12 harvest ponds respectively. Pond harvest data were obtained from farmers. Of the summer samples, all specimens were WSSV positive, with a wide range of 12.4–7.0 × 10⁷ (mean 7.5 × 10⁶) copies ng^?1 DNA; shrimp production was 1.7 metric tonnes per hectare (mt ha^?1). Of the 116 autumn‐sample specimens, 81 (69.8%) were WSSV positive; WSSV infection had been decreased dramatically, to 0–7.2 (mean 3.5) copies ng^?1 DNA. Shrimp production of autumn ponds was 2.1 mt ha^?1. Statistical analysis indicated that the difference in WSSV infections detected in summer and autumn was highly significant (P<0.01). In summer, seven ponds (58.3%) with low‐WSSV infection loads (0–1000 WSSV copies ng^?1 DNA) had shrimp production of 2.7 mt ha^?1; the others had shrimp production of only 0.2 mt ha^?1. The mean shrimp production between the two infection levels showed a highly statistically significant difference (P<0.01).     

White Spot Syndrome Virus in cultured shrimp: A review

Shrimp is one of the main aquaculture species in the world. Different viruses affect them, which causes serious mortality to economically important species, such as Penaeus monodon, Litopenaeus vannamei and L. stylirostris, among others. White spot syndrome virus or WSSV is a highly lethal, stress‐dependent virus, which belongs to the family Nimaviridae, genus Whispovirus. Three WSSV virus isolates were first detected in 1992 in Thailand, Taiwan and China. Later, a fourth isolate of the virus was detected in the Americas in 1999. This virus has a large circular double‐stranded DNA genome with different sizes (292.9–307.2 kb), where the diverse isolates show differences in virulence. This virus infects a wide range of aquatic crustaceans by vertical and horizontal transmission, with different mortality results. The spread of infection between regions may be due to infected shrimp and carriers such as other crustaceans, seabirds, aquatic arthropods or other vectors. The aim of this work is to describe the current knowledge on the status, transmission, pathology, isolation, control and genomic characteristics of WSSV.     

Development of a multiplex PCR system for the simultaneous detection of white spot syndrome virus and hepatopancreatic parvovirus infection

A multiplex PCR kit for simultaneous detection of white spot syndrome virus (WSSV) and hepatopancreatic parvovirus (HPV) was developed and field testing was conducted. A 604‐bp target sequence was selected from the vp28 gene of WSSV. A primer set was developed to amplify a 338‐bp DNA fragment at the junction of the NS2 and NS1 protein genes of HPV after alignment of eight sequences from different strains. Another internal positive control primer set produced a 139‐bp PCR fragment from the β‐actin gene by alignment of this gene from Litopenaeus vannamei, Fenneropenaeus chinensis and Penaeus monodon. The detection limits, tested using purified plasmids, for WSSV and HPV were 21.4 and 19.0 copies respectively. The optimum ratio for HPV, WSSV and β‐actin was 3:1:1, with an optimum annealing temperature of 57°C. Field test of the multiplex PCR with 170 L. vannamei individuals from 17 aquaculture farms showed 41.8% coinfection with WSSV and HPV, and 40.0% and 3.5% single infection with WSSV and HPV respectively. No virus‐free shrimp farm was found. Ten wild catch F. chinensis individuals showed 60% coinfection, and 40% were infected with HPV.     

Molecular docking and simulation studies of 3‐(1‐chloropiperidin‐4‐yl)‐6‐fluoro benzisoxazole 2 against VP26 and VP28 proteins of white spot syndrome virus

White spot syndrome virus (WSSV), an aquatic virus infecting shrimps and other crustaceans, is widely distributed in Asian subcontinents including India. The infection has led to a serious economic loss in shrimp farming. The WSSV genome is approximately 300 kb and codes for several proteins mediating the infection. The envelope proteins VP26 and VP28 play a major role in infection process and also in the interaction with the host cells. A comprehensive study on the viral proteins leading to the development of safe and potent antiviral therapeutic is of adverse need. The novel synthesized compound 3‐(1‐chloropiperidin‐4‐yl)‐6‐fluoro benzisoxazole 2 is proved to have potent antiviral activity against WSSV. The compound antiviral activity is validated in freshwater crabs (Paratelphusa hydrodomous). An in silico molecular docking and simulation analysis of the envelope proteins VP26 and VP28 with the ligand 3‐(1‐chloropiperidin‐4‐yl)‐6‐fluoro benzisoxazole 2 are carried out. The docking analysis reveals that the polar amino acids in the pore region of the envelope proteins were involved in the ligand binding. The influence of the ligand binding on the proteins is validated by the molecular dynamics and simulation study. These in silico approaches together demonstrate the ligand's efficiency in preventing the trimers from exhibiting their physiological function.     

Enhancement and confirmation of white spot syndrome virus detection using monoclonal antibody specific to VP26

A portion of the VP26 gene (VP26F109) encoding a structural protein of white spot syndrome virus was expressed, purified by SDS‐PAGE and used for immunization of Swiss mice for monoclonal antibody (MAb) production. Three groups of MAbs specific to different epitopes on VP26 were selected; these MAbs can be used to detect natural WSSV infection in Penaeus vannamei using dot blotting, Western blotting or immunohistochemistry without cross‐reaction with other shrimp tissues or other common shrimp viruses. The detection sensitivity of the MAbs was ranged 7–14 fmole per spot of the rVP26F109 as determined using dot blotting. A combination of three MAbs specific to VP26 with MAbs specific to VP28, VP19 and ICP11 increased the detection sensitivity of WSSV during early infection. Therefore, the MAbs specific to VP26 could be used to confirm and to enhance the detection sensitivity for WSSV infection in shrimp with various types of antibody‐based assays.     

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.     

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.     

Protection of Fenneropenaeus chinensis (Osbeck, 1765) against the white spot syndrome virus using specific chicken egg yolk immunoglobulins by oral delivery

Two kinds of specific chicken egg yolk immunoglobulins (IgYs), IgY‐WSSV and IgY‐VP28, were, respectively, raised against the 2 mM binary ethylenimine (BEI)‐inactivated white spot syndrome virus (WSSV) and a principal envelope protein VP28. The activity of purified specific IgYs was stable under the conditions of 20–70 °C, pH 3.0–10.0 and 0–700 g L^?1 sucrose solution. In the neutralization assay, these high‐affinity IgY antibodies can specifically bind with the virus particles to protect shrimp (Fenneropenaeus chinensis) against WSSV infection. After oral delivery for 20 days, the IgY‐WSSV exerted a higher protection effect (RPS: 71.5%) than IgY‐VP28 (RPS: 63.7%). Moreover, an increase in RPS (79.2%) was found on addition of IgY‐WSSV:VP28 (0.1% IgY‐VP28 plus 0.2% IgY‐WSSV). This may indicate that neutralization of WSSV refers to the multiple‐hit model. By time‐course study of the levels of the specific IgYs in vivo, the data showed that the titre was enhanced to a relatively high level (P/N=8.35±0.45) at 3 days post administration, declined slightly (P/N=7.13±1.01) at 7 days post administration and then remained stable for further investigation. The stable antibody level potentially contributes towards blocking a large number of WSSV particles from entering and infecting on the major tissues at the early and late stages after challenge in shrimp.     

Limited evidence for genetic variation for resistance to the white spot syndrome virus in Indian populations of Penaeus monodon

There has been a highly detrimental impact of the white spot syndrome virus (WSSV) on black tiger shrimp (Penaeus monodon) aquaculture in India. Currently, no cost‐effective measures are available for controlling the disease. One alternative is to improve WSSV resistance through a selective breeding programme for disease‐resistant shrimp, provided that genetic variation exists for this trait. The aim of this study was to evaluate the evidence for genetic variation in resistance to WSSV in P. monodon sourced from Indian populations. Post‐larval shrimp (n=1950) from 54 full‐sibling families were challenged with WSSV using WSSV‐infected mince meat. The heritability was estimated using four different statistical models fitted to the resulting time to death data, including two linear models and two Weibull proportional hazard frailty models. None of the estimated heritabilities were significantly different from zero. We suggest three possible explanations for these results: there actually is very little variation between P. monodon in WSSV resistance and all individuals are highly susceptible to the disease; there is genetic variation in resistance to WSSV in P. monodon but we did not find it in our experiment because the level of challenge in the experiment was too high to allow genetic differences to be expressed; the variation is due to mutations conferring resistance, which are at a low frequency in the population, and we did not sample a broad enough genetic base to capture these mutations.