Detection of gill-associated virus (GAV) by in situ hybridization during acute and chronic infections of Penaeus monodon and P. esculentus

Chronic and acute gill-associated virus (GAV) infections were examined by in situ hybridization (ISH) using a DNA probe targeting a 779 nucleotide region of the ORF1b-gene. Chronic GAV infections were observed in healthy Penaeus monodon collected from farms and healthy P. esculentus surviving experimental infection. During chronic-phase infections in both species, GAV was detected only in partitioned foci of cells with hypertrophied nuclei (spheroids) within the lymphoid organ. Acute-phase infections were observed in moribund P. monodon and P. esculentus infected experimentally with a high dose of GAV, and in moribund P. monodon collected from farms during outbreaks of disease. During acute experimental infections in P. monodon, ISH detected GAV throughout the lymphoid organ, in gills and in connective tissues throughout the cephalothorax. In moribund P. monodon collected from natural outbreaks of disease, GAV was also detected in the gills and in connective tissues of the cephalothorax, but the distribution of virus within the lymphoid organ varied. In acutely infected P. esculentus, GAV was detected in connective tissues, but was restricted to the inner stromal matrix cells and endothelial cells of intact lymphoid organ tubules. The tissue distribution of GAV identified by ISH suggests that shrimp are able to control and maintain chronic asymptomatic infection by a process involving lymphoid organ spheroids. Acute phase infections and the development of disease appear to be dose-related and involve the systemic distribution of virus in connective tissues throughout the cephalothorax.     

Viral diseases of penaeid shrimp with particular reference to four viruses recently found in shrimp from Queensland

The culture of penaeid shrimp world-wide is primarily dependent on wild-caught broodstock which has an enormous potential to introduce new pathogens, particularly viruses, into culture systems. Of the 13 viruses described for cultured penaeid shrimp, seven have been described within the past 5 years; the most devastating viral epidemics on record for cultured penaeid shrimp have also occurred within the past 5years. During examination of local wild and cultured shrimp, four new viruses were found. Bennettae baculovirus was discovered in the digestive gland of wild Metapenaeus bennettae. It closely resembles monodon baculovirus (MBV) but has a more slender virion, does not cross-react with a DNA probe for MBV and is not infectious to Penaeus monodon. Two morphologically indistinguishable viruses, one pathogenic (gill-associated virus, GAV) and the other benign (lymphoid organ virus, LOV), were found in cultured P. monodon. LOV and GAV closely resemble yellow head virus (YHV) of Thailand. A parvo-like virus was found recently in dying post-larvae of P. japonicus. As the intensity of shrimp culture world-wide increases, researchers can expect to discover more penaeid viruses. The need to close the life cycle of P. monodon and other cultured species and develop rapid diagnostic methods for viral infections has become imperative.     

RT-nested PCR detection of Mourilyan virus in Australian Penaeus monodon and its tissue distribution in healthy and moribund prawns

Mourilyan virus (MoV) is a newly identified virus of Penaeus monodon prawns that is genetically related to the Uukuniemi virus and other phleboviruses of the Bunyaviridae. This paper describes an RT-nested PCR test that can reliably detect between 2 and 6 copies of a synthetic MoV RNA. Total RNA isolated from the lymphoid organ, gills and haemocytes of P. monodon with moderate infections gave comparable amplicon yields in the RT-PCR step of the test. However, in prawns with extremely low-level infections, haemocytes and gill tissue proved slightly more reliable in detecting MoV RNA following nested PCR. The distribution of MoV in tissues of healthy and moribund P. monodon was examined by in situ hybridisation (ISH) using a digoxigenin-labelled DNA probe to a approximately 0.8 kb M RNA segment cDNA insert in clone pMoV4.1. The DNA probe targeted a region in the MoV M RNA segment containing a coding sequence with homology to the C-terminus of the G2 glycoprotein of phleboviruses. In healthy prawns harbouring an unapparent MoV infection, ISH signal primarily occurred in the lymphoid organ, where it was more prominent in hypertrophied cells of 'spheroids' than within cells of normal tubules. ISH signal was also sometimes detected in cells of cuticular epithelium, segmental nerve ganglion and the antennal and tegmental glands. MoV was distributed widely throughout these and other cephalothoracic tissues of mesodermal and ectodermal origin in moribund P. monodon following experimental infection or collected from farm pond edges during disease episodes. Transmission electron microscopy of gill of moribund, captive-reared P. monodon identified spherical (approximately 85 nm diameter) to ovoid MoV particles (approximately 85 x 100 nm) in and around highly necrotic cells in which the nucleus and other organelles had disintegrated. MoV virions co-existed with rod-shaped virions of gill-associated virus and were often seen clustered within cytoplasmic vacuoles or associated with the outer rim of concentric ring-shaped structures comprised of endoplasmic membranes likely to represent degenerated Golgi.     

Quantitative real-time RT-PCR demonstrates that handling stress can lead to rapid increases of gill-associated virus (GAV) infection levels in Penaeus monodon

Gill-associated virus (GAV) of the black tiger prawn Penaeus monodon has been implicated as a cause of periodic production losses in Australia since 1996. We report here the development of a real-time quantitative RT-PCR (qRT-PCR) for GAV. A dilution series of in vitro transcribed RNA was used to determine the sensitivity limit of the qRT-PCR and as a standard for GAV quantification. A linear relationship between cycle threshold (Ct) values and input RNA was obtained over a wide concentration range between 4.86 x 10(9) and 0.5 template copies per reaction, the latter being the test detection limit. The qRT-PCR was used to follow the progression of GAV levels in a group of 15 adult male P. monodon with chronic GAV infections that were super-infected by intramuscular injection of an inoculum containing high levels of GAV. By Day 9 post-injection, cumulative mortalities reached 100% (15/15) in the GAV-injected prawns and 40% (2/5) in placebo-injected prawns. Spermatophores were collected at the beginning, and together with other tissues, at the end of the trial. Prawns were also bled at regular intervals to collect circulating haemocytes. The qRT-PCR revealed that GAV loads increased significantly in haemocytes collected from both the control and super-infected prawns (p = 0.010). This increase was significantly higher in the super-infected prawns (p = 0.047). The rapid increase in GAV levels in super-infected P. monodon was expected. However, the increase in the control prawns was not, and indicates that repetitive bleeding and handling stress can stimulate GAV proliferation in chronically infected P. monodon.     

The gene encoding the nucleocapsid protein of Gill-associated nidovirus of Penaeus monodon prawns is located upstream of the glycoprotein gene

The ORF2 gene of Gill-associated virus (GAV) of Penaeus monodon prawns resides 93 nucleotides downstream of the ORF1a-ORF1b gene and encodes a 144-amino-acid hydrophilic polypeptide (15,998 Da; pI, 9.75) containing 20 basic (14%) and 13 acidic (9%) residues and 19 prolines (13%). Antiserum to a synthetic ORF2 peptide or an Escherichia coli-expressed glutathione S-transferase-ORF2 fusion protein detected a 20-kDa protein in infected lymphoid organ and gill tissues in Western blots. The GAV ORF2 fusion protein antiserum also cross-reacted with the p20 nucleoprotein in virions of the closely related Yellow head virus. By immuno-gold electron microscopy, it was observed that the ORF2 peptide antibody localized to tubular GAV nucleocapsids, often at the ends or at lateral cross sections. As GAV appears to contain only two structural protein genes (ORF2 and ORF3), these data indicate that GAV differs from vertebrate nidoviruses in that the gene encoding the nucleocapsid protein is located upstream of the gene encoding the virion glycoproteins.     

Time-course and levels of apoptosis in various tissues of black tiger shrimp Penaeus monodon infected with white-spot syndrome virus

This study focused on apoptosis in various tissues of the black tiger shrimp Penaeus monodon following white spot syndrome virus (WSSV) injection. The study included: (1) light microscopy (LM) and transmission electron microscopy (TEM) of various tissues; (2) fluorescent LM of nuclear DNA by staining with 4, 6-diamidine-2-phenyl indole dihydrochloride (DAPI) and TdT-mediated dUTP nick-end labelling (TUNEL) techniques; and (3) determination of caspase-3 activity. Juvenile P. monodon were injected with WSSV, and several tissues of ectodermal and mesodermal origin were studied at different intervals after injection. The total haemocyte count had decreased to one-tenth of its original level 60 h after WSSV injection. By LM, extensive destruction by WSSV was observed in the stomach epithelium, gills, hematopoietic tissue, hemocytes and the heart, but the most severely affected tissue was the subcuticular epithelium. TEM revealed that at 6 h post-injection (p.i.) the chromatin of infected nuclei was marginated, and by 24 h p.i. the nuclei were filled with enveloped and non-enveloped WSSV virions. At later stages of the infection, the nucleus extruded WSSV particles. Chromatin margination and nuclear condensation and fragmentation (i.e. signs of apoptosis) were observed as early as 6 h p.i. in all affected tissues, but occurred in cells without WSSV virions rather than in cells with virions. The occurrence of apoptosis was supported by data obtained using TUNEL and by DAPI-staining and progressed from 6 to 60 h p.i. In addition, caspase-3 activity in WSSV-infected shrimp was about 6-fold higher than that in uninfected shrimp. The data strongly suggests that apoptosis occurs following WSSV infection in P. monodon, but the extent to which it contributes to shrimp mortality requires further investigation.     

Penaeus monodon is protected against gill-associated virus by muscle injection but not oral delivery of bacterially expressed dsRNAs

Gill-associated virus (GAV) is a nidovirus that commonly infects Penaeus monodon (black tiger shrimp) in eastern Australia, causing morbidity and mortalities in the acute stage of disease. Here we explored the possibility of inhibiting GAV replication and disease using double-stranded (ds)RNAs expressed in bacteria and delivered either orally or by muscle injection. To enhance potential RNA interference (RNAi) responses, 5 long dsRNAs were used that targeted open reading frame 1a/1b (ORF1a/b) gene regions and thus only the genomic length RNA. To examine oral delivery, P. monodon were fed pellets incorporating a pool of formalin-fixed bacteria containing the 5 GAV-specific dsRNAs before being injected with a minimal lethal GAV dose. Feeding with the pellets continued post-challenge but did not reduce mortality accumulation and elevation in GAV loads. In contrast, muscle injection of the dsRNAs purified from bacteria was highly effective at slowing GAV replication and protecting shrimp against acute disease and mortalities. In synergy with these data, dsRNA targeted to P. monodon beta-actin mRNA caused 100% mortality following injection, whilst its oral delivery caused no mortality. Findings confirm that injected dsRNA can mount effective RNAi responses in P. monodon to endogenous shrimp mRNA and exogenous viral RNAs, but when delivered orally in bacteria as a feed component, the same dsRNAs are ineffective. The efficacy of the RNAi response against GAV provided by injection of dsRNAs targeted to multiple genome sites suggests that this strategy might have general applicability in enhancing protection against other shrimp single-stranded (ss)RNA viruses, particularly in hatcheries or breeding programs where injection-based delivery systems are practical.     

Development of in situ hybridization and RT-PCR assay for the detection of a nodavirus (PvNV) that causes muscle necrosis in Penaeus vannamei

A nodavirus (tentatively named PvNV, Penaeus vannamei nodavirus) that causes muscle necrosis in P. vannamei was found in Belize in 2004. From 2004 to 2006, shrimp samples collected from Belize exhibited clinical signs, white, opaque lesions in the tails and histopathology similar to those of shrimps infected by infectious myonecrosis virus (IMNV). Histological examination revealed multifocal necrosis and hemocytic fibrosis in the skeletal muscle. In addition, basophilic, cytoplasmic inclusions were found in striated muscle, lymphoid organ and connective tissues. However, IMNV was not detected in these shrimps by either RT-PCR or in situ hybridization, suggesting that these lesions may be caused by another RNA virus. Thus, a cDNA library was constructed from total RNA extracted from hemolymph collected from infected shrimp. One clone (designated PvNV-4) with a 928 bp insert was sequenced and found to be similar (69% similarity when comparing the translated amino acid sequences) to the capsid protein gene of MrNV (Macrobrachium rosenbergii nodavirus). The insert of PvNV-4 was labeled with digoxigenin-11-deoxyuridine triphosphate (dUTP) and hybridized to tissue sections of P. vannamei with muscle necrosis collected in Belize and from laboratory bioassays. The samples were positive for PvNV infection. Positively reacting tissues included skeletal muscle, connective tissues, the lymphoid organ, and hemocytes in the heart and gills. In addition, we experimentally infected both P. vannamei and P. monodon with PvNV prepared from Belize samples. A nested RT-PCR assay developed from the PvNV-4 cloned sequence showed that both species are susceptible to PvNV infection.     

Preliminary study on haemocyte response to white spot syndrome virus infection in black tiger shrimp Penaeus monodon

White spot syndrome virus (WSSV) has been a major cause of shrimp mortality in aquaculture in the past decade. In contrast to extensive studies on the morphology and genome structure of the virus, little work has been done on the defence reaction of the host after WSSV infection. Therefore, we examined the haemocyte response to experimental WSSV infection in the black tiger shrimp Penaeus monodon. Haemolymph sampling and histology showed a significant decline in free, circulating haemocytes after WSSV infection. A combination of in situ hybridisation with a specific DNA probe for WSSV and immuno-histochemistry with a specific antibody against haemocyte granules in tissue sections indicated that haemocytes left the circulation and migrated to tissues where many virus-infected cells were present. However, no subsequent haemocyte response to the virus-infected cells was detected. The number of granular cells decreased in the haematopoietic tissue of infected shrimp. In addition, a fibrous-like immuno-reactive layer appears in the outer stromal matrix of tubule walls in the lymphoid organ of infected shrimp. The role of haemocytes in shrimp defence after viral infection is discussed.     

Different responses to infectious hypodermal and hematopoietic necrosis virus (IHHNV) in Penaeus monodon and P. vannamei

Infectious hypodermal and hematopoietic necrosis virus (IHHNV) is widespread in cultured Penaeus monodon and P. vannamei in Thailand. It causes runt-deformity syndrome that is characterized by physical abnormalities and stunted growth in P. vannamei, but causes no apparent disease in P. monodon. In both species, the virus may produce Cowdry Type A inclusions in tissues of ectodermal and mesodermal origin, but these are common in P. vannamei and rare in P. monodon. The virus can be more easily detected in both species by IHHNV-specific PCR primers. By in situ hybridization (ISH) using specific IHHNV probes, fixed phagocytes associated with myocardial cells tended to show strong positive reactions in both shrimp species. Ovarian and neural tissue (neurons in the nerve ganglia and glial cells in the nerve cord) were ISH positive for IHHNV only in P. vannamei. By transmission electron microscopy, necrotic cells were found in the gills of IHHNV-infected P. vannamei, while paracrystalline arrays of virions and apoptotic cells rather than necrotic cells were found in the lymphoid organ of IHHNV-infected P. monodon. Thus, it is possible that apoptosis in P. monodon contributes to the absence of clinical disease from IHHNV. These findings reveal different responses to IHHNV infection by the 2 shrimp species. A curious feature of IHHNV infection in P. monodon was inconsistency in the comparative viral load amongst tissues of different specimens, as detected by both ISH and real-time PCR. This inconsistency in apparent tissue preference and the reasons for different cellular responses between the 2 shrimp species remain unexplained.     

In situ hybridization demonstrates that Litopenaeus vannamei, L. stylirostris and Penaeus monodon are susceptible to experimental infection with infectious myonecrosis virus (IMNV)

Infectious myonecrosis virus (IMNV) was recently found to be the cause of necrosis in the skeletal muscle of farm-reared Litopenaeus vannamei from northeastern Brazil. Nucleic acid extracted from semi-purified IMN virions showed that this virus contains a 7.5 kb RNA genome. A cDNA library was constructed, and a clone, designated as IMNV-317, was labeled with digoxigenin-11-dUTP and used as a gene probe for in situ hybridization (ISH). This probe specifically detected IMNV in infected tissues. To determine the susceptibility of 3 species of penaeid shrimp (L. vannamei, L. stylirostris, Penaeus monodon) to IMNV infection, juveniles were injected with purified virions and observed for clinical signs of infection and mortality over a 4 wk period. All L. vannamei exhibited typical lesions after 6 d, and lesions were visible in all L. stylirostris by Day 13. The clinical signs of opaque muscle were not seen in P. monodon, due to their highly pigmented exoskeleton precluding visual detection of lesions. Moderate mortality (20%) occurred in infected L. vannamei. No mortalities were observed in either L. stylirostris or P. monodon. Histological examination and ISH indicated that all 3 species are susceptible to IMNV infection. Using ISH, IMNV was detected in tissues including the skeletal muscle, lymphoid organ, hindgut, and phagocytic cells within the hepatopancreas and heart. In all 3 species, skeletal muscle cells produced the strongest ISH reactions. Based on the onset of clinical signs of infection and mortality, L. vannamei appears to be the most susceptible of these 3 species to IMNV infection.     

Tissue-specific expression and regulation of the haemolymph clottable protein of tiger shrimp (Penaeus monodon)

The clottable protein (CP) involved in Penaeus monodon haemolymph coagulation has previously been characterized and cloned. Polyclonal antibodies against purified CP were also prepared from rabbit serum. By Western blot analyses, we showed occurrence of CP in the shrimp central nervous system, gill, and lymphoid organ. Results of RT-PCR further indicated that the central nervous system, gill, and lymphoid organ transcribed more CP, heart and hepatopancreas transcribed less, while the haemocytes and the muscle did not. We further analyzed the CP distribution within shrimp lymphoid organ by immunohistochemical method, CP was found to localise in stromal cells of lymphoid organ rather than in the developing haemocytes. In addition, concentrations and regulation of the plasma CP under normal and artificially traumatic conditions were studied with rocket immunoelectrophoresis. The average plasma CP concentration in normal intermolt shrimps was elevated from 3 mg ml(-1) to above 12 mg ml(-1) after successive blood-withdrawing for a week. The production and secretion of CP apparently were increased more than 4 folds to compensate its loss. Our result also suggested that the shrimp sinus gland endocrine system is not directly required for the expression and up-regulation of CP.     

Polychaete worms--a vector for white spot syndrome virus (WSSV)

The present work provides the first evidence of polychaete worms as passive vectors of white spot syndrome virus (WSSV) in the transmission of white spot disease to Penaeus monodon broodstocks. The study was based on live polychaete worms, Marphysa spp., obtained from worm suppliers/worm fishers as well as samples collected from 8 stations on the northern coast of Tamilnadu (India). Tiger shrimp Penaeus monodon broodstock with undeveloped ovaries were experimentally infected with WSSV by feeding with polychaete worms exposed to WSSV. Fifty percent of polychaete worms obtained from worm suppliers were found to be WSSV positive by 2-step PCR, indicating high prevalence of WSSV in the live polychaetes used as broodstock feed by hatcheries in this area. Of 8 stations surveyed, 5 had WSSV positive worms with prevalence ranging from 16.7 to 75%. Polychaetes collected from areas near shrimp farms showed a higher level of contamination. Laboratory challenge experiments confirmed the field observations, and > 60% of worms exposed to WSSV inoculum were proved to be WSSV positive after a 7 d exposure. It was also confirmed that P. monodon broodstock could be infected with WSSV by feeding on WSSV contaminated polychaete worms. Though the present study indicates only a low level infectivity in wild polychaetes, laboratory experiments clearly indicated the possibility of WSSV transfer from the live feed to shrimp broodstock, suggesting that polychaete worms could play a role in the epizootiology of WSSV.     

Prevalence of white spot syndrome virus (WSSV) in wild shrimp Penaeus monodon in the Philippines

Prevalence of white spot syndrome virus (WSSV) was determined using polymerase chain reaction (PCR) methodology on DNA extracted from the gills of wild black tiger shrimp Penaeus monodon collected from 7 sampling sites in the Philippines. These 7 sampling sites are the primary sources of spawners and broodstock for hatchery use. During the dry season, WSSV was detected in shrimp from all sites except Bohol, but during the wet season it was not detected in any site except Palawan. None of the WSSV-PCR positive shrimp showed signs of white spots in the cuticle. Prevalence of WSSV showed seasonal variations, i.e. prevalence in dry season (April to May) was higher than in the wet season (August to October). These results suggest that WSSV has already become established in the local marine environment and in wild populations of P. monodon. Thus, broodstock collected during the dry season could serve as the main source of WSSV contamination in shrimp farms due to vertical transmission of the virus in hatcheries.     

Low impact of infectious hypodermal and hematopoietic necrosis virus (IHHNV) on growth and reproductive performance of Penaeus monodon

No controlled studies on the effect of infectous hypodermal and necrosis virus (IHHNV) on Penaeus monodon have been previously reported. Here we describe domesticated P. monodon that became positive for IHHNV and other viruses at variable levels of prevalence during cultivation in 16 open-air, earthen ponds. These were stocked with domesticated postlarvae (PL) that tested negative for 7 shrimp viruses including IHHNV at 6% prevalence in 3 checks using polymerase chain reaction (PCR) methods. These PL were derived from domesticated female broodstock that individually tested negative for the same viruses. At 4 mo of culture, the shrimp in some ponds without obvious mortality tested positive by PCR methods for IHHNV and 3 other viruses at variable levels of maximum estimated prevalence (MEP). Stained tissue sections showed no lesions typical of IHHNV, but in situ hybridization tests with an IHHNV-specific DNA probe were positive. There was no significant difference in mean body weight (i.e. ca. 25 g) between shrimp groups positive or negative for IHHNV. Similar results were obtained with IHHNV negative and positive adults at 1 yr. Adults that individually tested negative for all 7 viruses and some that tested lightly positive for IHHNV were bred for the next generation. There were no significant differences in the number of eggs (> 600 000) and nauplii (ca. 300,000) produced by females negative and positive for IHHNV. From these females, 11/49 (22%) IHHNV PCR-positive PL batches were obtained from PCR-negative spawners, while 8/11 (73%) were obtained from IHHNV PCR-positive spawners. The results suggested that IHHNV infection can be transmitted vertically but does not seriously retard growth of P. monodon or affect fecundity of lightly infected broodstock.     

Differences in the susceptibility of some penaeid prawn species to gill-associated virus (GAV) infection

Four species of penaeid prawn cultured in Australia (Penaeus monodon, Penaeus esculentus, Marsupenaeus japonicus and Fenneropenaeus merguiensis) were injected with a virulent preparation of gill-associated virus (GAV). P. monodon (average weight = 8.9, 13.9 and 19.2 g), P. esculentus (average weight = 19.5 g), F. merguiensis (average weight = 10.5 g), and small (average weight = 5.8 g) M. japonicus displayed overt signs of disease and mortalities which reached 82 to 100% within 23 d post-injection. Cumulative mortalities in P. esculentus and F. merguiensis were significantly lower than for P. monodon of the same size class. Medium (average weight = 13.0 g) M. japonicus also developed overt signs of disease but cumulative mortalities were not significantly higher than uninfected controls. Large (average weight = 20.3 g) M. japoncius did not display symptoms of disease and there were no significant mortalities up to 23 d post-injection.     

Natural host-range and experimental transmission of Laem-Singh virus (LSNV)

Slow growth caused by viral diseases has become a major constraint in shrimp aquaculture. Laem-Singh virus (LSNV), a positive-sense single-stranded RNA (ssRNA) virus, has been identified in Penaeus monodon showing slow growth syndrome. To examine the host-range and transmission modes of the virus, 6 species of penaeid shrimp of varying life stages, sourced from the wild and from farms, as well as juvenile mud crabs Scylla serrata, were screened using RT-nested PCR. LSNV was detected in P. monodon, Fenneropenaeus merguiensis, Metapenaeus dobsoni, and Litopenaeus vannamei, but not in E indicus, Marsupenaeus japonicus or S. serrata. LSNV was most prevalent in P. monodon followed by M. dobsoni, F. merguiensis, and L. vannamei, and real-time quantitative RT-PCR (qRT-PCR) showed that LSNV infection loads were highest in P. monodon, followed by L. vannamei, M. dobsoni, and E merguiensis. The nucleotide sequence of the LSNV RdRP gene fragment amplified by RT-nested PCR was highly conserved (99% identity) across these 4 penaeid species. LSNV was detected in both small and normal-sized P. monodon collected from the same pond. In experimental infections of both P. monodon and S. serrata, LSNV infection loads increased over time. The present study extends the known natural penaeid host-range and geographical distribution of LSNV and shows for the first time the potential susceptibility of S. serrata.