Virulence of white spot syndrome virus (WSSV) isolates may be correlated with the degree of replication in gills of Penaeus vannamei juveniles

A standardized inoculation model was used in 2 separate experiments to gauge the virulence of 3 white spot syndrome virus (WSSV) isolates from Thailand and Vietnam (WSSV Thai-1, WSSV Thai-2, and WSSV Viet) in Penaeus vannamei juveniles. Mortality patterns (Expt 1) were compared and WSSV-positive cells quantified (Expt 2) in tissues following intramuscular inoculation of shrimp with the most (WSSV Thai-1) and least (WSSV Viet) virulent isolates as determined by Expt 1. The results of Expt 1 demonstrated that mortalities began at 36 h post inoculation (hpi) for both Thai isolate groups and at 36 to 60 hpi for the Viet isolate group. Cumulative mortality reached 100% 96 to 240 h later in shrimp challenged with the WSSV Viet isolate compared to shrimp challenged with the Thai isolates. WSSV infection was verified in all groups by indirect immunofluorescence. In Expt 2, WSSV-infected cells were quantified by immunohistochemical analysis of both dead and time-course sampled shrimp. WSSV-positive cells were detected in tissues of Thai-1 inoculated dead and euthanized shrimp from 24 hpi onwards and from 36 hpi onwards in shrimp injected with the Viet isolate. Significantly more infected cells were found in tissues of dead shrimp inoculated with the Thai-1 than in Viet isolate-inoculated shrimp. In these experiments, substantial differences in virulence were demonstrated between the WSSV isolates. The Vietnamese isolate induced a more chronic disease and mortality pattern than was found for the Thai isolates, possibly because it infected fewer cells. This difference was most pronounced in gills.     

Development and application of monoclonal antibodies for the detection of white spot syndrome virus of penaeid shrimp.

Monoclonal antibodies (MAbs) were produced against white spot syndrome virus (WSSV) of penaeid shrimp. The virus isolate used for immunization was obtained from China in 1994 and was passaged in Penaeus vannamei. The 4 hybridomas selected for characterization all produced MAbs that reacted with the 28 kD structural protein by Western blot analysis. The MAbs tested in dot-immunoblot assays were capable of detecting the virus in hemolymph samples collected from moribund shrimp during an experimentally induced WSSV infection. Two of the MAbs were chosen for development of serological detection methods for WSSV. The 2 MAbs detected WSSV infections in fresh tissue impression smears using a fluorescent antibody for final detection. A rapid immunohistochemical method using the MAbs on Davidson's fixed tissue sections identified WSSV-infected cells and tissues in a pattern similar to that seen with digoxigenin-labeled WSSV-specific gene probes. A whole mount assay of pieces of fixed tissue without paraffin embedding and sectioning was also successfully used for detecting the virus. None of the MAbs reacted with hemolymph from specific pathogen-free shrimp or from shrimp infected with infectious hypodermal and hematopoietic necrosis virus, yellow head virus or Taura syndrome virus. In Western blot analysis, the 2 MAbs did not detect any serological differences among WSSV isolates from China, Thailand, India, Texas, South Carolina or Panama. Additionally, the MAbs did not detect a serological difference between WSSV isolated from penaeid shrimp and WSSV isolated from freshwater crayfish.     

Preservation of necrotizing hepatopancreatitis bacterium (NHPB) by freezing tissue collected from experimentally infected Litopenaeus vannamei

Necrotizing hepatopancreatitis (NHP), a severe disease of penaeid shrimp, is caused by bacteria (NHPB) that have previously been demonstrated to reside in tubular epithelial hepatopancreatic (HP) cells of infected shrimp. There has yet to be a successful in vitro culture method to grow the intracellular organism; therefore, it must be propagated in vivo via transmission from NHPB-infected shrimp to healthy individuals. In our studies, NHPB propagation tanks containing infected shrimp were used to maintain a constant supply of organisms for experiments. In order to develop a method for storing infectious NHPB material for future challenge studies, we collected HP tissue containing NHPB by flash freezing whole, fresh HPs at -80 degrees C for up to 80 d and used it to successfully infect specific pathogen-free Litopenaeus vannamei per os in controlled experiments. HP tissue samples were collected from dead shrimp, and PCR was performed to confirm the presence of NHPB. Our results demonstrate that the infectivity of NHPB in tissue is not altered after being frozen at -80 degrees C when compared to NHPB in fresh tissue. Thus, the continual propagation of NHPB in vivo is not required to assure a source of the infectious agent.     

Effects of shrimp density on transmission of penaeid acute viremia in Penaeus japonicus by cannibalism and the waterborne route.

To investigate the effects of shrimp density on mortalities of Penaeus japonicus in experimental penaeid acute viremia (= white spot syndrome), shrimp injected intramuscularly with penaeid rod-shaped DNA virus (PRDV) were reared at different densities. In Expt 1, challenged (10(-6) dilution of a PRDV preparation) shrimp were reared collectively in a tank or individually in separate chamber units. A significant difference in cumulative mortalities was found between collectively (75.6%) and individually (1.2%) reared groups after 30 d. In Expt 2, effects of density on mortality were clearly shown when challenged (10(-5) dilution) shrimp were reared collectively in tanks at high (260 shrimp m(-2)), middle (135 shrimp m(-2)) and low densities (73 shrimp m(-2)). The cumulative mortalities for 14 d in the high, middle and low density groups were 72, 46 and 18%, respectively. In Expt 3, challenged (10(-5) dilution) shrimp were reared collectively in 3 tanks (Groups A, B and C) at the same high density (260 shrimp m(-2)): Group A, dead shrimp were immediately removed to avoid transmission of the pathogen through cannibalism and the waterborne route; Group B, dead shrimp were removed at scheduled times but were separated from living shrimp by a net partition to avoid cannibalism; and Group C, dead shrimp were removed twice a day at scheduled times. Resulting cumulative mortalities for 20 d in Groups A, B and C were 4, 24 and 64 %, respectively. These results show that the higher mortalities occur in P. japonicus reared at the higher densities in experimental PRDV infection, and this phenomenon is caused mainly by a higher opportunity of horizontal transmission of the virus through cannibalism and the waterborne route.     

Pathogenesis of a Thai strain of white spot syndrome virus (WSSV) in juvenile, specific pathogen-free Litopenaeus vannamei

White spot syndrome virus (WSSV) causes disease and mortality in cultured and wild shrimp. A standardized WSSV oral inoculation procedure was used in specific pathogen-free (SPF) Litopenaeus vannamei (also called Penaeus vannamei) to determine the primary sites of replication (portal of entry), to analyze the viral spread and to propose the cause of death. Shrimp were inoculated orally with a low (10(1.5) shrimp infectious dose 50% endpoint [SID50]) or a high (10(4) SID50) dose. Per dose, 6 shrimp were collected at 0, 6, 12, 18, 24, 36, 48 and 60 h post inoculation (hpi). WSSV-infected cells were located in tissues by immunohistochemistry and in hemolymph by indirect immunofluorescence. Cell-free hemolymph was examined for WSSV DNA using 1-step PCR. Tissues and cell-free hemolymph were first positive at 18 hpi (low dose) or at 12 hpi (high dose). With the 2 doses, primary replication was found in cells of the foregut and gills. The antennal gland was an additional primary replication site at the high dose. WSSV-infected cells were found in the hemolymph starting from 36 hpi. At 60 hpi, the percentage of WSSV-infected cells was 36 for the epithelial cells of the foregut and 27 for the epithelial cells of the integument; the number of WSSV-infected cells per mm2 was 98 for the gills, 26 for the antennal gland, 78 for the hematopoietic tissue and 49 for the lymphoid organ. Areas of necrosis were observed in infected tissues starting from 48 hpi (low dose) or 36 hpi (high dose). Since the foregut, gills, antennal gland and integument are essential for the maintenance of shrimp homeostasis, it is likely that WSSV infection leads to death due to their dysfunction.     

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.     

Does hyperthermia increase apoptosis in white spot syndrome virus (WSSV)-infected Litopenaeus vannamei?

Apoptosis plays a critical role in development and maintenance of multicellular organisms. It has also been described as an anti-viral mechanism in both insects and vertebrates. In fact, to escape the immune system and to increase their spread, some viruses such as baculovirus produce anti-apoptotic molecules. Conversely, a recent report showing a positive correlation between the number of apoptotic cells and the severity of white spot syndrome virus (WSSV) infection in Penaeus monodon suggested that apoptosis might be the cause of death in viral-infected shrimp. Searching for the mechanisms involved in the beneficial effect of hyperthermia for WSSV-infected Litopenaeus vannamei (also called Penaeus vannamei) and considering that hyperthermia increases apoptosis in other experimental models, we investigated the presence of apoptosis by Tdt-mediated dUTP nick-end label (TUNEL), from 4 of 168 h in 3 groups of 50 L. vannamei juveniles. Group 1 consisted of experimentally infected shrimp (intramuscular injection of 3 x 10(7) viral copies) kept at 25 degrees C, Group 2 of similarly infected shrimp kept at 32 degrees C and Group 3 of uninjected shrimp kept at 32 degrees C. Apoptosis was found only in WSSV-infected individuals. Shrimp at 25 degrees C were positive for apoptotic cells in 48 (16%) of their examined tissues or organs, compared to 62 (21%) for those at 32 degrees C. Moreover, shrimp at 32 degrees C also had a significantly higher overall mean apoptotic index (AI) than shrimp at 25 degrees C (p < 0.05). Comparison of mean AI at 72, 96 and 120 h post-infection showed that individuals at 32 degrees C presented a significantly higher values than those at 25 degrees C. These results suggested that hyperthermia might facilitate apoptosis in WSSV-infected L. vannamei and might be one of the mechanisms responsible for increased survival of infected shrimp maintained at 32 degrees C.     

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.     

Enzyme E2 from Chinese white shrimp inhibits replication of white spot syndrome virus and ubiquitinates its RING domain proteins

Recent studies have shown that the ubiquitin (Ub) proteasome pathway (UPP) is closely related to immune defense. We have identified a ubiquitin-conjugating enzyme, E2, from the Chinese white shrimp, Fenneropenaeus chinensis (FcUbc). Injection of recombinant FcUbc protein (rFcUbc) reduced the mortality of shrimp infected with white spot syndrome virus (WSSV) and inhibited replication of WSSV. rFcUbc, but not a mutant FcUbc (mFcUbc), bound to WSSV RING domains (WRDs) from four potential E3 ligase proteins of WSSV in vitro. Importantly, rFcUbc could ubiquitinate the RING domains (named WRD2 and WRD3) of WSSV277 and WSSV304 proteins in vitro and the two proteins in WSSV-infected Drosophila melanogaster Schneider 2 (S2) cells. Furthermore, overexpression of FcUbc increased ubiquitination of WSSV277 and WSSV304 during WSSV infection. In summary, our study demonstrates that FcUbc from Chinese white shrimp inhibited WSSV replication and could ubiquitinate WSSV RING domain-containing proteins. This is the first report about antiviral function of Ubc E2 in shrimp.     

Development of a Rapid Method for Identifying Carryover Contamination of Positive Control DNA,Using a Chimeric Positive Control and Restriction Enzyme for the Diagnosis of White Spot Syndrome Virus by Nested PCR

Chimeric positive plasmids have been developed to minimize false-positive reactions caused by polymerase chain reaction (PCR) contamination. Here, we developed a rapid method for identifying false-positive results while detecting white spot syndrome virus (WSSV) by nested PCR, using chimeric positive plasmids. The results of PCRs using WSSV diagnostic primer sets showed PCR products of a similar size (WSSV 1st PCR product, 1,447 bp; WSSV 2nd PCR product, 941 bp) using WSSV chimeric plasmids or DNA from shrimp infected with WSSV. The PCR products were digested with DraI for 1 h at 37 °C. The digested chimeric DNA separated into two DNA bands; however, the WSSV-infected shrimp DNA did not separate. Thus, chimeric plasmid DNA may be used as positive control DNA instead of DNA from WSSV-infected shrimp, in order to prevent PCR contamination. Thus, the use of restriction enzyme digestion allowed us to rapidly distinguish between WSSV DNA and WSSV chimeric plasmid DNA.     

Suppression of Shrimp Melanization during White Spot Syndrome Virus Infection

The melanization cascade, activated by the prophenoloxidase (proPO) system, plays a key role in the production of cytotoxic intermediates, as well as melanin products for microbial sequestration in invertebrates. Here, we show that the proPO system is an important component of the Penaeus monodon shrimp immune defense toward a major viral pathogen, white spot syndrome virus (WSSV). Gene silencing of PmproPO(s) resulted in increased cumulative shrimp mortality after WSSV infection, whereas incubation of WSSV with an in vitro melanization reaction prior to injection into shrimp significantly increased the shrimp survival rate. The hemolymph phenoloxidase (PO) activity of WSSV-infected shrimp was extremely reduced at days 2 and 3 post-injection compared with uninfected shrimp but was fully restored after the addition of exogenous trypsin, suggesting that WSSV probably inhibits the activity of some proteinases in the proPO cascade. Using yeast two-hybrid screening and co-immunoprecipitation assays, the viral protein WSSV453 was found to interact with the proPO-activating enzyme 2 (PmPPAE2) of P. monodon. Gene silencing of WSSV453 showed a significant increase of PO activity in WSSV-infected shrimp, whereas co-silencing of WSSV453 and PmPPAE2 did not, suggesting that silencing of WSSV453 partially restored the PO activity via PmPPAE2 in WSSV-infected shrimp. Moreover, the activation of PO activity in shrimp plasma by PmPPAE2 was significantly decreased by preincubation with recombinant WSSV453. These results suggest that the inhibition of the shrimp proPO system by WSSV partly occurs via the PmPPAE2-inhibiting activity of WSSV453.     

Activation of Rice Aminopeptidase by Anions and Some Properties of the Enzyme

In order to determine which proteases are responsible for the autolysis of krill, the effects of several protease inhibitors on the autolysis and protease activities of krill were investigated.

Homogenates of whole bodies, and the cephalothorax and abdomen parts of frozen krill were equilibrated at 37°C at different pHs between 2 to 10 and allowed to stand for 16 hr, following which the increase in the TCA soluble fraction was monitored. ¹⁴C-Hemoglobin (¹⁴C-Hb) hydrolyzing activity was also measured using each homogenate as a crude enzyme preparation. The degree of autolysis and the ¹⁴C-Hb hydrolyzing activity were maximum at pH 5 ~ 8 for the parts studied. The hydrolytic activity was highest in the cephalothorax, followed by that in the whole body and then the abdomen.

The effects of inhibitors on the ¹⁴C-Hb hydrolyzing activity were examined, and it was seen that soybean trypsin inhibitor (STI), diisopropyl fluorophosphate (DFP) and leupeptin significantly inhibited the activity at neutral pH, and pepstatin, monoiodoacetic acid (IAAcid) and leupeptin were effective at acidic pH for all the parts. Investigation of the effects of inhibitors on the autolysis at 20°C at pH 4 and 7 by SDS–polyacrylamide gel electrophoresis indicated that the autolysis of the cephalothorax and whole body at pH 7 was suppressed a little by STI and the autolysis of the abdomen and whole body at pH 4 was significantly inhibited by iodoacetamide (IAA) and leupeptin.

These results suggest that the main proteases responsible for the autolysis of krill are trypsin like-proteases at neutral pH and cathepsins (B, H and L types) at acidic pH.     

Modeling horizontal transmission of microsporidia infecting gypsy moth,Lymantria dispar (L.), larvae

We developed a simulation model that describes the horizontal transmission of three different microsporidia, Endoreticulatus schubergi, Nosema lymantriae and Vairimorpha disparis and their insect host, the gypsy moth, Lymantria dispar. The model describes the stage specific development and mortality of uninfected, latently infected or infectious hosts, the food consumption, the infection by spore-laden feces of E. schubergi and N. lymantriae and by spore-laden cadaver of N. lymantriae and V. disparis. Model results were compared to percent infection of L. dispar test larvae published in earlier studies using caged oak trees and potted oak-plants. When feces were selected as the source of spores for transmission of E. schubergi or N. lymantriae, the model estimated a percent infection in susceptible larvae that was in the range of the experimental studies. When spore-laden cadavers were the source of spores of N. lymantriae or V. disparis, the model did not correctly predict the experimentally measured percent infection in susceptible larvae. The most critical points of the simulation model are exact calculation of spore release, mortality and exact determination of the transmission coefficients when cadavers were included as a source for microsporidian infection.     

Gene expression in haemocytes of kuruma prawn,Penaeus japonicus,in response to infection with WSSV by EST approach

Gene expression in haemocytes of the kuruma prawn (Penaeus japonicus) was investigated using an expressed sequence tag (EST) approach. Partial nucleotide sequences of cDNA library clones constructed from normal and white spot syndrome virus (WSSV)--infected P. japonicus haemocytes were determined. Of 635 clones obtained from the normal library, 284 (44.7%) significantly matched sequences in GenBank, and of 370 clones obtained from WSSV-infected library, 174 (47.0%) significantly matched sequences in the database. One hundred fifty-two deduced proteins were newly identified. Of these, 28 types were involved in biodefence. For the prophenoloxidase system, there are prophenoloxidase, coagulation factor G-beta chain precursor, factor D, Masquarade-like protease, transglutaminase (TGase), clottable protein and eight types of protease inhibitors (two types of antileukoproteinase, alpha-2-macroglobulin, chelonianin, elastase inhibitor, two types of Kazal inhibitor and Kunitz-type inhibitor). For antibacterial peptides, there are bactinecin 11, penaeidin-2 precursor and lysozyme c type. The others defence-related proteins are basophil leukocyte interleukin-3-regulated protein, natural killer enhancing factor (NK-EF), integral membrane protein (CD34+), ESM-1, Notch homologue and Drac homologue. For the adhesion proteins, there are beta-integrin, cell adhesion molecule (CAM) and three types of collagens. All ESTs representing protease inhibitors and tumour-related proteins were found only in the WSSV-infected library. Those encoding for apoptotic peptides were expressed at high levels in infected library. The putative defence proteins accounted for 2.7% of total ESTs in a normal shrimp library and 15.7% of the total ESTs in an infected library.     

Protection of blue shrimp (Litopenaeus stylirostris) against the White Spot Syndrome Virus (WSSV) when injected with shrimp lysozyme

In this study we found that a blue shrimp (Litopenaeus stylirostris) lysozyme gene (Lslzm) was up-regulated in WSSV-infected shrimp, suggesting that lysozyme is involved in the innate response of shrimp to this virus. Shrimp were intramuscularly injected with Lslzm protein to identify how this recombinant protein protects L. stylirostris from WSSV infection and to determine how this protein influences nonspecific cellular and humoral defense mechanisms. Higher survival rates and a lower viral load (compared with controls) were reported for shrimps that were first injected with the Lslzm protein and then infected with WSSV. In addition, the Lslzm expression level and the immunological parameters (including THC, phagocytic activity, respiratory burst activity, phenoloxidase activity and lysozyme activity) were all significantly higher in the WSSV-infected shrimp treated with the Lslzm protein, compared with the controls. These results indicate that lysozyme is effective at blocking WSSV infection in L. stylirostris and that lysozyme modulates the cellular and humoral defense mechanisms after they are suppressed by the WSSV virus.     

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.     

Identification of the small heat shock protein, HSP21, of shrimp Penaeus monodon and the gene expression of HSP21 is inactivated after white spot syndrome virus (WSSV) infection

The white spot syndrome virus (WSSV) is the causative agent of a severe disease in cultivated shrimp. The virus causes high mortality and leads to heavy stress on shrimps. In response to a variety of stresses, living organisms express particular sets of genes such as HSPs. In this study, a HSP21 gene, categorized into the small heat shock protein (smHSP) family, of shrimp Penaeus monodon was identified by annotating the EST databases established from WSSV-infected and WSSV-uninfected shrimp. The shrimp HSP21 gene was 555 bp in length. The thermal aggregation assay showed that the HSP21 had chaperone activity. The result of real-time PCR indicated that HSP21 was constitutive and inducible and was highly expressed in almost all organs such as the epithelium, gill, stomach, midgut, lymphoid organ, hepatopancreas, nervous tissue and heart, but less expressed in haemolymph. However, HSP21 gene showed down-regulation after WSSV infection. It suggests that gene regulation of HSP21 was seriously affected by WSSV.     

红螯光壳螯虾白斑综合症血液病理学研究

采用Wright-Geimsa染色法和电镜技术对人工感染的红螯光壳螯虾(Cherax quadricarinatus)白斑综合症(White spot syndrome,WSS)血液病理学进行了研究。结果显示:患病螯虾血细胞总数、透明细胞(AH)数量极显著减少(P<0.01),大颗粒细胞(LGH)极显著增加(P<0.01);病毒感染后3种血细胞大小均有增加趋势,透明细胞和大颗粒细胞的核质比(NP)较感染病毒前极显著下降(P<0.01)。显微病理学变化主要表现为血涂片中血细胞明显减少,病变、破损或解体的细胞增多,至濒死期螯虾血液呈典型的溶血状态。超微病理学变化表现为血细胞受到了损伤。高尔基体变形、线粒体结构模糊破损;核膜变形核固缩、细胞核高度异染色质化;濒临死亡的螯虾血细胞细胞器和染色质溶解,胞浆水肿,细胞溶解坏死。在患病螯虾的血细胞核中清晰可见WSSV粒子。     

田间施药对拟环纹豹蛛羧酸酯酶和乙酰胆碱酯酶分布及活性的影响

利用紫外分光光度法,对化学防治田(化防田)和生物防治田(生防田)中的拟环纹豹蛛Pardosa pseudoannulata体内乙酰胆碱酯酶(AChE)和羧酸酯酶(CarE)的分布及其活性进行了比较研究。结果表明,生防田拟环纹豹蛛身体各分部的AChE活性[包括头胸部1.251 nmol/(mg·min)、腹部0.467 nmol/(mg·min)和附肢0.760 nmol/(mg·min)]均高于化防田蜘蛛[包括头胸部0.895 nmol/(mg·min)、腹部0.445 nmol/(mg·min)和附肢0.724 nmol/(mg·min)],而生防田豹蛛的CarE活性[包括头胸部0.122 nmol/(mg·min)、腹部0.593 nmol/(mg·min)和附肢0.073 nmol/(mg·min)]均低于化防田蜘蛛[包括头胸部0.158 nmol/(mg·min)、腹部0.708 nmol/(mg·min)和附肢0.115 nmol/(mg·min)],说明化防田拟环纹豹蛛产生了一定程度的抗药性。拟环纹豹蛛体内的AChE主要集中在头胸部,CarE主要集中在腹部,这种分布特征是与其抗药性机制相适应的,并对其抗药性机制的形成做出了初步解释。这些结果也提示,拟环纹豹蛛对甲胺磷等农药的抗性不能在短期内形成,必须经历水稻→害虫→蜘蛛的较长的适应演化过程。