White spot syndrome virus in decapods from Mississippi Sound, USA, and susceptibility of Palaemonetes pugio and Uca panacea to a Chinese isolate.

The presence and quantity of white spot syndrome virus (WSSV) was surveyed using TaqMan real-time PCR to assess the extent of the virus in Mississippi Sound, USA. A total of 3577 wild decapods comprising 11 species was collected between November 2012 and August 2015: WSSV was present in 10 of the 11 species. Prevalence ranged from 5.1% in Uca rapax to 38.8% in U. spinicarpa. Viral load ranged from 1.8 to 7.3 log10 copies of WSSV µg-1 total DNA. Two Gulf species, Palaemonetes pugio and U. panacea, were injected with a series of doses of a virulent WSSV isolate from China to determine relative susceptibility and virulence because continuing translocation of highly pathogenic isolates of WSSV poses risk to native species. Survival was 0-65% for P. pugio and 5-60% for U. panacea. Median survival time was lower for P. pugio than U. panacea at all doses. Mean (±SD) lethal load was 9.0 ± 8.9 log copies of WSSV µg-1 total DNA in P. pugio and 8.2 ± 8.3 in U. panacea. Mean viral load in survivors was higher in U. panacea than in P. pugio (5.8 ± 6.1 vs. 3.2 ± 3.0 log copies of WSSV µg-1 total DNA); mean viral load was lower in wild individuals of those species (2.9 ± 3.2 for P. pugio and 4.9 ± 5.0 for U. panacea). U. panacea is potentially more tolerant of WSSV than P. pugio and may serve as an important reservoir host in the community.

White spot syndrome virus (WSSV) in cultured juvenile blue crabs Callinectes sapidus: oral versus injection exposure, and feeding frequency effects.

The efficacy of oral versus injection exposure and the effect of feeding frequency on the transmission of white spot syndrome virus (WSSV) in cultured juvenile blue crabs Callinectes sapidus were investigated. Crabs in Group 1 (G-1, n = 48) were exposed once orally to 100 mg of WSSV-infected shrimp tissue mg-1 of body weight (BW). The oral inoculum contained 2.6 × 109 WSSV genome copies mg-1 tissue. Group 2 (G-2, n = 46) received the same dosage once weekly for 5 wk. Group 3 (G-3, n = 12) was injected with 0.01 ml (2.6 × 107 genome copies 0.01 ml-1) WSSV inoculum g-1 BW. Group 4 (G-4, n = 12) was injected with 0.01 ml WSSV-negative shrimp serum and saline mixture g-1 BW. Dead and moribund animals were frozen at -80°C. After 37 d, all remaining crabs were frozen. Genomic DNA from gill tissue was evaluated for the presence and quantity of WSSV using TaqMan real-time PCR. All G-3 animals died and tested positive. No G-4 animals died or tested positive. In the fed groups, WSSV prevalence was approximately 16%, but viral load was higher and survival was lower in G-2 compared to G-1. Injected animals carried a higher viral load than fed animals, and dead animals had higher viral loads than live animals. Blue crab juveniles are susceptible to WSSV, but oral exposure does not efficiently transmit WSSV in juvenile blue crabs. Some animals can die from WSSV if repeatedly exposed.

Population model for Amyloodinium ocellatum infecting the spotted seatrout Cynoscion nebulosus and the red snapper Lutjanus campechanus.

The dinoflagellate Amyloodinium ocellatum, a major pathogen in warm water mariculture, has a trophont, a tomont and a dinospore life history stage. This paper presents a population model for A. ocellatum infecting spotted seatrout Cynoscion nebulosus and red snapper Lutjanus campechanus and evaluates the relative effect of each vital rate on the A. ocellatum population growth rate. The vital rates were estimated by incubating trophonts in vitro and tracking their development through the successive life history stages at 25°C and 33 ppt. The A. ocellatum population growth rate was 1.90 d-1 for spotted seatrout and 1.92 d-1 for red snapper. Highest elasticity values (0.24 and 0.23 in spotted seatrout and red snapper, respectively) corresponded to transitions from the dinospore to the trophont stage, the trophont stage to the tomont stage and the tomont stage back to the dinospore stage in both host species (self-loops not included). A 50% change in vital rates showed that the mean number of dinospores produced by a tomont had the largest effect on the A. ocellatum population growth rate (15%), followed by the dinospore infection rate (14%), the tomont sporulation rate (12%) and the dinospore mortality rate (10%) in both host species. A comparison of modeled and experimental vital rate threshold values revealed a 2.5- (spotted seatrout) or a 2.6-fold (red snapper) difference in the values for dinospore mortality, which is the smallest difference among all the modeled and experimental vital rates. Therefore, measures that increase dinospore mortality have a greater likelihood of influencing the outcome of an epidemic.

Development of a rapid assay to detect the dinoflagellate Amyloodinium ocellatum using loop-mediated isothermal amplification (LAMP).

Amyloodinium ocellatum is a highly pathogenic dinoflagellate parasite with global distribution that causes high mortalities in the culture of tropical and sub-tropical marine and estuarine fishes. Diagnosis typically occurs through gross examination following the onset of morbidity, at which point treatment is of limited benefit. In the present study, a new molecular diagnostic tool for the rapid detection of A. ocellatum (AO) was developed using the loop-mediated isothermal amplification method (LAMP). The AO-LAMP assay designed is highly specific using a set of four primers - two outer and two inner primers targeting six different regions on the 5' end of the Small Subunit rDNA region (SSU rDNA) of A. ocellatum. The AO-LAMP assay, optimized for 25-30 min at 62°C, amplified the DNA from A. ocellatum extracted from both water and gill tissue samples and did not amplify DNA from four closely related dinoflagellate sp ecies. The detection limit of the AO-LAMP assay was 10 fg, exceptionally higher than the conventional PCR (1 pg). In addition, the standardized AO-LAMP assay was capable of detecting single tomonts and trophonts; the assay was not affected by the presence of possible inhibitory substances present in environmental water samples or gill samples. The AO-LAMP assay developed in the present study provides a novel useful tool for the simple, rapid and sensitive detection of A. ocellatum in water and gill tissue samples, which could assist in the early detection and improved control of A. ocellatum infections in aquaculture systems.

The role of selective breeding and biosecurity in the prevention of disease in penaeid shrimp aquaculture.

About 3.5 million metric tons of farmed shrimp were produced globally in 2009 with an estimated value greater than USD$14.6 billion. Despite the economic importance of farmed shrimp, the global shrimp farming industry continues to be plagued by disease. There are a number of strategies a shrimp farmer can employ to mitigate crop loss from disease, including the use of Specific Pathogen Free (SPF), selectively bred shrimp and the adoption of on-farm biosecurity practices. Selective breeding for disease resistance began in the mid 1990s in response to outbreaks of Taura syndrome, caused by Taura syndrome virus (TSV), which devastated populations of farmed shrimp (Litopenaeus vannamei) throughout the Americas. Breeding programs designed to enhance TSV survival have generated valuable information about the quantitative genetics of disease resistance in shrimp and have produced shrimp families which exhibit high survival after TSV exposure. The commercial availability of these selected shrimp has benefitted the shrimp farming industry and TSV is no longer considered a major threat in many shrimp farming regions. Although selective breeding has been valuable in combating TSV, this approach has not been effective for other viral pathogens and selective breeding may not be the most effective strategy for the long-term viability of the industry. Cost-effective, on-farm biosecurity protocols can be more practical and less expensive than breeding programs designed to enhance disease resistance. Of particular importance is the use of SPF shrimp stocked in biosecure environments where physical barriers are in place to mitigate the introduction and spread of virulent pathogens.

Susceptibility and tolerance of spotted seatrout, Cynoscion nebulosus , and red snapper, Lutjanus campechanus , to experimental infections with Amyloodinium ocellatum.

Amyloodinium ocellatum is a parasitic dinoflagellate that infects warm-water marine and estuarine fishes and causes mortalities in aquaculture. Its life cycle consists of 3 stages: a feeding trophont that parasitizes the gills and skin where it interferes with gas exchange, osmoregulation, and tissue integrity; a detached reproductive tomont; and a free-swimming infective dinospore. We compared the susceptibility and tolerance of juvenile spotted seatrout, Cynoscion nebulosus, and red snapper, Lutjanus campechanus, to this parasite by individually exposing fish in 3-L aquaria (at 25 C and 33 practical salinity units) to several dinospore doses over different time periods and quantified the size and number of resulting trophonts. We estimated the trophont detachment rate and trophont size at detachment, the 24-hr dinospore infection rate, the dinospore 48-hr median lethal dose (LD(50)), and the trophont lethal load at the 48-hr LD(50). There were no significant differences in dinospore infection rates or dinospore lethal doses between spotted seatrout and red snapper; however, trophonts remained attached longer and attained a larger size in red snapper than in spotted seatrout. The trophont lethal load was significantly higher in spotted seatrout than in red snapper. A proposed model simulating the trophont dynamics reflected our experimental findings and showed that A. ocellatum reproductive success is linked both to the number of dinospores and the size of the trophont, factors that, in turn, are linked to the time the trophont spends on the host and the number of trophonts the host can tolerate.

Taura syndrome virus loads in Litopenaeus vannamei hemolymph following infection are related to differential mortality.

Taura syndrome is an economically important disease that can cause catastrophic losses of farmed shrimp. Without effective treatments for Taura syndrome virus (TSV), one approach to managing the problem is to selectively breed shrimp populations with increased disease resistance. To better understand why some shrimp can survive exposure to TSV, information is needed on how viral loads progress and persist following infection. Data reported here show that mortalities occurring mostly within 1 wk of infection are associated with high viral titers, and titers as high as 10(8.7) genome copies per microl hemolymph can persist for up to 3 wk in survivors. Thereafter, and up to approximately 9 wk post-exposure, most surviving shrimp remain chronically infected with TSV loads ranging from 10(4) to 10(8) genome copies per microl hemolymph. Challenging shrimp from families with varying TSV resistance showed that in shrimp from less resistant families, the TSV load in hemolymph increased earlier and reached higher peaks than in shrimp from more resistant families. Although TSV loads in moribund shrimp from families differing in resistance did not differ significantly, infection loads among survivors were lower in shrimp from more resistant families. Taken together, the data suggest that lethal infection loads can occur in both more and less susceptible shrimp and that survivors represent shrimp in which viral expansion is better contained.

Effect of salinity on transmission of necrotizing hepatopancreatitis bacterium (NHPB) to Kona stock Litopenaeus vannamei.

Elevated salinity and temperature have been observed prior to devastating necrotizing hepatopancreatitis (NHP) outbreaks in several geographically isolated shrimp ponds. These observations have led to the hypothesis that the NHP-bacterium (NHPB) is hindered by reduced salinity, even though the mechanism is not understood. The objective of this research was to examine the effect of salinity on transmission of NHPB. The transmission rate of NHPB was estimated through laboratory experiments whereby individuals of Kona stock Litopenaeus vannamei were orally exposed to a dead NHPB-infected shrimp. For each replicate, 12 susceptible shrimp were placed with a dead NHPB-infected shrimp in a 1 m2 bottom area cylindrical tank maintained at 30 degrees C for a period of 24 h. Four salinities of 10, 20, 30, and 40 per thousand were replicated 2 times in 2 trials, giving a total of 192 shrimp exposed per os to infective material. In each trial, a negative control group was included at each salinity, giving a total of 96 shrimp exposed orally to uninfected material. After the 24 h exposure period, susceptible shrimp were individually isolated at the same physical conditions for up to 60 d to determine NHPB transmission. The NHPB was transmissible regardless of salinity: nearly a quarter of susceptible shrimp exposed to NHPB at the lowest (10 per thousand) and highest (40 per thousand) salinity examined acquired NHPB. Transmission rates were highest at the intermediate salinities of 20 and 30 per thousand, suggesting that those salinities are optimal for NHPB transmission. The observed association between high salinity and NHP outbreak in a shrimp pond is not explained by these results because reduced transmission occurred at very low and very high salinities.

Effect of chronic Taura syndrome virus infection on salinity tolerance of Litopenaeus vannamei.

Taura syndrome virus (TSV) is one of the most important shrimp viruses affecting farmed shrimp worldwide. After an acute phase during which the likelihood of mortality is elevated, infected shrimp enter a chronic phase during which shrimp appear to resume normal behavior and display no gross signs of infection. This study was designed to determine if chronically TSV-infected shrimp Litopenaeus vannamei are compromised by the infection. Specifically we investigated whether chronically infected shrimp could tolerate a drop in salinity as strongly as uninfected shrimp. The study consisted of 3 trials that compared survival of uninfected and chronically TSV-infected L. vannamei after drops in salinity from 24 ppt to salinities varying from 18 to 0 ppt. Logistic regression detected a significant effect of TSV infection on survival of chronically infected shrimp (p < 0.05). Salinity drops from 24 ppt to 3 and 6 ppt resulted in statistically different survivals (p < 0.05). Survival rates were similar among groups for salinity drops to greater than 6 ppt or less than 3 ppt. Salinities at which 50% of the shrimp died (LC50) were 3.06 ppt for the uninfected and 6.65 ppt for the chronically infected groups. Moreover, histopathological analysis of chronically infected shrimp that were moribund or recently dead showed no signs of having reverted to the acute stage of the disease. These results suggest that chronically infected shrimp are not able to tolerate a salinity drop as strongly as uninfected shrimp.

Time course of necrotizing hepatopancreatitis (NHP) in experimentally infected Litopenaeus vannamei and quantification of NHP-bacterium using real-time PCR.

Necrotizing hepatopancreatitis (NHP), a severe bacterial disease affecting penaeid shrimp aquaculture, is caused by a gram-negative, pleomorphic, intracellular alpha-proteobacterium referred to as the NHP-bacterium (NHPB). The time course of NHP was investigated in experimentally infected juveniles of Kona stock Litopenaeus vannamei. Susceptible animals were individually isolated in 41 of aerated artificial seawater at salinity 30 +/- 1 ppt and maintained in a water bath at 30 +/- 1 degree C for 60 d. A total of 120 individuals were exposed per os to a 0.05 g piece of NHPB-infected hepatopancreas and 100 controls were exposed to uninfected tissue. At intervals of 3, 6, 9, 16, 23, 30, 37, 44, and 53 d post-exposure, 6 shrimp exposed to NHPB-infected tissue and 4 controls were randomly removed from the experiment; hepatopancreas samples were processed for histological and molecular analysis, and feces were processed for molecular diagnosis of NHPB infection. NHPB was first detected in the hepatopancreas through histology at 6 d post-exposure. All control shrimp were diagnosed as NHPB negative. NHPB infections classified as stage I (scattering of hepatopancreatic tubules with adjacent epithelial cells containing NHPB) and stage II (numerous infected tubules with occasional hemocyte infiltration) were observed from 6 to 37 d post-exposure. All animals that experienced NHPB-induced mortality from 16 to 51 d post-exposure were at stage III (numerous necrotic tubules, dense hemocyte infiltration, and presence of granulomas). NHPB is capable of infecting all hepatopancreatic cell types including embryonic, resorptive, fibrillar and blister-like cells. The percent of hepatopancreatic tubules containing NHPB in epithelial cells increased over time, representing bacteria multiplication and spread. Real-time PCR allowed for quantification of NHPB in hepatopancreas and feces. Over the course of infection, NHPB was present at 10(3) to 10(7) copies mg(-1) of hepatopancreas and 10(1) to 10(5) copies mg(-1) of feces. Lethal infections contained 10(6) to 10(7) copies mg(-1) of hepatopancreas and 10(3) to 10(6) copies mg(-1) of feces.

Experimental infection of Pacific white shrimp Litopenaeus vannamei with Necrotizing Heptopancreatitis (NHP) bacterium by per os exposure.

Necrotizing Hepatopancreatitis Bacterium (NHPB), which causes Necrotizing Hepatopancreatitis, was successfully transmitted in individually isolated Kona stock Litopenaeus vannamei through per os exposure. Animals (140) were individually exposed orally to a 0.05 g piece of an NHPB-infected hepatopancreas and 120 control animals were each exposed to a 0.05 g piece of NHPB-negative hepatopancreas. Shrimp were maintained in Sterilite containers with approximately 41 of artificial seawater at 30 per thousand salinity and 30 degrees C for 60 d. Mortality of infected shrimp was observed from Day 16 to Day 51 post-exposure. Infected animals sustained reduced feeding activity and displayed empty guts. Some infected animals developed a pale hepatopancreas noticeable through the carapace. Survival probabilities fit a Weibull distribution and parametric survival analysis revealed lowered survival due to NHPB infection. Median survival time of NHPB-infected animals was 34.5 d. After correcting for background daily mortality in the controls, mean acute daily mortality of NHPB was estimated at 0.09, a value much lower than that estimated for other diseases in Kona stock L. vannamei such as White Spot Syndrome Virus (0.40) and Taura Syndrome Virus (0.30). A chronic, or carrier, state was not demonstrated in NHPB epizootics because all NHPB-positive animals experienced mortality and no animals surviving to 60 d post-exposure were diagnosed NHPB-positive through PCR or histology.

The use of differential display to isolate viral genomic sequence for rapid development of PCR-based detection methods. A test case using Taura syndrome virus.

The purpose of this study was to explore the efficacy of using differential display (DD) to isolate viral genomic sequence using tissues from infected organisms so that a PCR procedure to detect the pathogen may be developed rapidly. The model virus used was the Taura syndrome virus (TSV), a ssRNA virus that cause high rates of mortality at shrimp farms. Two random primers in combination with four anchored primers were used to isolate five cDNAs, ranging in size from 241 to 822 bp, that were differentially expressed in TSV-infected shrimp (Litopenaeus vannamei). PCR experiments revealed that four of the five encoded shrimp genes while the fifth was likely to be a TSV gene. Evidence that the putative TSV sequence is part of the TSV genome was obtained by the 97% sequence identity it shared with the published TSV genome. PCR primers were designed successfully using the differential display sequence to develop a RT-PCR-based method to detect TSV. Because differential display does not require physical isolation of the virus and only a small amount of infected sample is needed, the technique may be useful as a method to isolate nucleic acid sequences from emerging pathogens so that PCR primers for their detection may be developed rapidly.

A model of Taura syndrome virus (TSV) epidemics in Litopenaeus vannamei.

Taura syndrome virus (TSV) is a highly virulent pathogen of Litopenaeus vannamei, has affected shrimp aquaculture throughout the world, and threatens wild populations. Despite its importance, little work has been done on the pathogen's formal epidemiology. Therefore we developed a compartment model for epidemics of TSV in closed populations of L. vannamei. The model includes five compartments, uninfected susceptible, prepatently infected, acutely infected, chronically infected, and dead infected shrimp. The transmission coefficients, patency coefficient, virulence coefficients, and removal coefficient (disappearance of dead infected shrimp) control the dynamics of the model. We estimated the coefficients in laboratory studies and inserted the estimates in the model to characterize TSV epidemics and to estimate the basic reproduction ratio R(0) and threshold density for TSV epidemics in L. vannamei. Further we examined through computer simulation the effect of varying the coefficients on R(0). Decreases in transmission decrease R(0), decreases in virulence increase R(0), increases in patency do not affect R(0), and increases in recovery most likely increase R(0) but under some conditions might decrease it.

Model of white spot syndrome virus (WSSV) epidemics in Litopenaeus vannamei.

White spot syndrome virus (WSSV) is devastating shrimp aquaculture throughout the world, but despite its economic importance no work has been done on modeling epidemics of this pathogen. Therefore we developed a Reed-Frost epidemic model for WSSV in Litopenaeus vannamei. The model includes uninfected susceptible, latently infected, acutely infected, and dead infected shrimp. The source of new infections during an outbreak is considered to be dead infected shrimp. The transmission coefficient, patency coefficient, virulence coefficient, and removal coefficient (disappearance of dead infected shrimp) control the dynamics of the model. In addition, an explicit area parameter is included to help to clarify the distinction between density and absolute shrimp population size. An analysis of the model finds that as number of shrimp, initial dose, transmission coefficient, patency coefficient, virulence coefficient, or removal coefficient changes, the speed of the epidemic changes. The model predicts that a threshold density of susceptible shrimp exists below which an outbreak of WSSV will not occur. Only initial dose, transmission coefficient, removal coefficient, and area coefficient affect the predicted threshold density. Increases in the transmission coefficient reduce the threshold value, whereas increases in the other factors cause the threshold value to increase. Epidemic models may prove useful to the shrimp aquaculture industry by suggesting testable hypotheses, some of which may contribute to the eventual control of WSSV outbreaks.

On the systematic position of Ophiosacculus Macy, 1935 (digenea: Lecithodendriidae), with the erection of the Ophiosacculinae n. subfam.

The phylogenetic relationships and systematic position of the digenean genus Ophiosacculus Macy, 1935 has been controversial and opinions of different authors on its systematic position and content are contradictory. Molecular analysis based on the partial sequences of the large subunit ribosomal DNA gene of the type and only valid species of the genus, Ophiosacculus mehelyi (Mödlinger, 1930), as well as previously published sequences of members of several families of Plagiorchiata (including the Allassogonoporidae, Lecithodendriidae and Pleurogenidae as potential relatives of Ophiosacculus) has shown that Ophiosacculus forms a clade with the typical representatives of the Lecithodendriidae from bats. Ophiosacculus is basal to the cluster containing Lecithodendrium, Prosthodendrium and Pycnoporus and has quite pronounced differences in the sequenced fragment compared to these genera. Based on the results of the molecular study, morphological characteristics of Ophiosacculus (in particular, possession of a seminal vesicle lying freely in parenchyma) and the fact that the type-specimen of Gyrabascus brevigastrus Macy, 1835 (type-species of the monotypic genus Gyrabascus and type-genus of the subfamily Gyrabascinae) belongs to Allassogonoporus, a new subfamily, the Ophiosacculinae, with Ophiosacculus as the type-genus, is established within the Lecithodendriidae. Molecular study did not support a close phylogenetic relationship between Allassogonoporus and Ophiosacculus, although several authors previously allocated both these genera to the Allassogonoporidae. Morphological study revealed the position of the genital pore in O. mehelyi to be at the posterior margin of the ventral sucker. An amended diagnosis of Ophiosacculus and a diagnosis of Ophiosacculinae n. subfam. are given.

Microphallus fonti sp. n. (Digenea: Microphaliidae) from the red swamp crawfish in southern United States

A new species of digenean, Microphallus fonti, is described from the red swamp crawfish in Lousiania, U.S.A. It has a small pharynx and a rudimentary gut like M. opacus and a possibly related species from crayfishes, but it differs from them by its relatively large male copulatory papilla and a conspicuous metraterm