Development and characterization of a monoclonal antibody against Taura syndrome virus.

We produced a panel of monoclonal antibodies (MAbs) from the fusion of Taura syndrome virus variants from Belize (TSV-BZ) immunized BALB/cJ mouse spleen cells and non-immunoglobulin secreting SP2/0 mouse myeloma cells. One antibody, 2C4, showed strong specificity and sensitivity for TSV in dot-blot immunoassay and immunohistochemistry (IHC) analysis. The MAb reacted against native TSV-BZ, TSV variants from Sinaloa, Mexico (TSV-SI) and TSV variants from Hawaii (TSV-HI) in dot-blot immunoassay. By IHC, the antibody identified the virus in a pattern similar to the digoxigenin-labelled TSV-cDNA probe for the TSV-BZ, TSV-HI and TSV-SI variants, but not for the TSV variants from Venezuela (TSV-VE) and the TSV variants from Thailand (TSV-TH). MAb 2C4 did not react against other shrimp pathogens or with normal shrimp tissue. Western blot analysis showed a strong reaction against CP2, a region of high antigenic variability amongst TSV variants. This antibody has potential diagnostic application in detection and differentiation of certain TSV biotypes.

Comparison of Taura syndrome virus (TSV) detection methods during chronic-phase infection in Penaeus vannamei.

Methods to detect Taura syndrome virus (TSV) were assessed for their ability to detect the virus during chronic phase infection in the Pacific white shrimp Penaeus vannamei. In situ hybridization (ISH), immunohistochemistry (IHC) using monoclonal antibody 1A1, conventional RT-PCR and real-time quantitative (q)RT-PCR were compared using shrimp sampled over 60 wk following experimental TSV infection. Between Weeks 7 and 60, hematoxylin-eosin histology confirmed the presence of lymphoid organ spheroids (LOS) and an absence of lesions in the cuticular epithelium. ISH detected TSV in LOS over the duration of the study. IHC was generally less sensitive than ISH, and after Week 24, was often unable to confirm TSV infection. Detection of TSV by RT-PCR was highly dependent on sample source after Week 43, where viral RNA was detected in 12 of 14 hemolymph samples but only 5 of 16 pleopod samples. qRT-PCR detected TSV over the 60 wk in both hemolymph and pleopods, although RNA copy numbers in pleopods were consistently lower throughout the study. This study demonstrates that ISH and qRT-PCR are the most reliable methods for detecting TSV during late chronic phase infection. RT-PCR was also reliable if hemolymph was used as the sample source.

Application of molecular diagnostic methods to penaeid shrimp diseases: advances of the past 10 years for control of viral diseases in farmed shrimp.

The most important diseases of farmed penaeid shrimp have infectious aetiologies. Among these are diseases with viral, rickettsial, bacterial, fungal and parasitic aetiologies. Diagnostic methods for these pathogens include the traditional methods of gross pathology, histopathology, classical microbiology, animal bioassay, antibody-based methods, and molecular methods using DNA probes and DNA amplification. While methods using clinical chemistry and tissue culture are standard methods in veterinary and human diagnostic laboratories, the former has not been routinely applied to the diagnosis of penaeid shrimp diseases and the latter has yet to be developed, despite considerable research and development efforts that have spanned the past 40 years. No continuous shrimp cell lines, or lines from other crustaceans, have been developed. Hence, when molecular methods began to be routinely applied to the diagnosis of infectious diseases in humans and domestic animals in the mid- to late 1980s, the technology was applied to the diagnosis of certain important diseases of penaeid shrimp for which only classical diagnostic methods were previously available. A DNA hybridization assay for the parvovirus IHHNV was the first molecular test developed for a shrimp disease. This was followed within a year by the first PCR test for MBV, an important baculovirus disease of shrimp. Today, shrimp disease diagnostic laboratories routinely use molecular tests for diagnostic and surveillance purposes for most of the important penaeid shrimp diseases.

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.

Protein analysis of geographic isolates of shrimp white spot syndrome virus.

Six geographic isolates of the white spot syndrome virus (WSSV) of penaeid shrimp, from China, India, Thailand, South Carolina, Texas, as well as from crayfish kept at the US National Zoo in Washington D. C, were compared by electron microscopy and sodium sulfate polyacrylamine gel electrophoresis (SDS-PAGE). Amino acid compositions of four of the major structural polypeptides of the South Carolina WSSV were analyzed, and three of the four polypeptides were partially sequenced from their NH2 termini. The morphologies of purified virions of the six geographic isolates of WSSV were indistinguishable by transmission electron microscopy. By SDS-PAGE, the protein profiles of the six isolates were very similar, but not identical. They all contained three major polypeptides with sizes of approximately 25, 23 and 19 kDa. A fourth major polypeptide at the 14.5 kDa position was observed in four of the geographic isolates. The WSSV isolated from crayfish presented a slightly different structural protein profile, particularly with regard to the protein in the 19 kDa range that appeared larger in size than those of the other isolates. The NH2 terminal amino acids of the 25, 23 and 14.5 kDa polypeptides of the South Carolina WSSV were sequenced as MDLSFTLSVVTA, MEFGNLTNLDVA, and VARGGKTKGRRG, respectively. No significant homologous sequence was found in the GenBank. These protein sequences have been submitted to the SWISS-PROT Protein Data Bank and assigned the accession numbers P82004, P82005 and P82006.

Reverse transcription polymerase chain reaction (RT-PCR) used for the detection of Taura syndrome virus (TSV) in experimentally infected shrimp.

Taura Syndrome Virus (TSV) has adversely affected the shrimp culture industries of the Americas. First recognized in 1992, this viral agent has spread throughout the shrimp growing regions of South and Central America to become established in North America in the short span of 5 yr. Diagnostic methods for TSV include histopathology, bioassay using susceptible Penaeus vannamei as the indicator species and in situ hybridization with TSV specific complimentary DNA (cDNA) gene probes. An additional method for detecting TSV is through the use of reverse transcription polymerase chain reaction (RT-PCR). Two oligonucleotide primers were selected using the sequence information from a cloned cDNA segment of the TSV genome. The primers, designated 9195 and 9992, used in the RT-PCR procedure amplify a 231 base pair (bp) fragment of the cDNA. Using the RT-PCR technique, TSV has been detected in the hemolymph of P. stylirostris and P. vannamei with experimentally induced TSV infections.

Risk of spread of penaeid shrimp viruses in the Americas by the international movement of live and frozen shrimp.

Within the past decade, viral diseases have emerged as serious economic impediments to successful shrimp farming in many of the shrimp-farming countries of the world. In the western hemisphere, the viral agents of Taura syndrome (TS) and infectious hypodermal and haematopoietic necrosis have caused serious disease epizootics throughout the shrimp-growing regions of the Americas and Hawaii, while in Asia the viral agents of white spot syndrome (WSS) and yellow head (YH) have caused pandemics with catastrophic losses. The international transfer of live shrimp for aquaculture purposes is an obvious mechanism by which the viruses have spread within and between regions in which they have occurred. Shrimp-eating gulls, other seabirds and aquatic insects may also be factors in the spread of shrimp viruses between and within regions. Another potentially important mechanism for the international spread of these pathogens is the trade in frozen commodity shrimp, which may contain viruses exotic to the importing countries. The viral agents of WSS, YH and TS have been found, and demonstrated to be infectious, in frozen shrimp imported into the United States market. Mechanisms identified for the potential transfer of virus in imported frozen products to domestic populations of cultured or wild penaeid shrimp stocks include: the release of untreated liquid or solid wastes from shrimp importing and processing plants directly into coastal waters, improper disposal of solid waste from shrimp importing and processing plants in landfills so that the waste is accessible to gulls and other seabirds, and the use of imported shrimp as bait by sports fishermen.

Taura syndrome of marine penaeid shrimp: characterization of the viral agent.

The causative agent of Taura syndrome (TS) was recognized in 1994 to be viral in nature and tentatively classified as belonging to either the family Picornaviridae or Nodaviridae. The work reported here has led to a more definitive classification of this new penaeid virus. Located within the cytoplasm of infected cuticular epithelial cells of penaeid shrimp, the virus is a 31 to 32 nm icosahedral particle with a buoyant density of 1.338+/-0.001 g/ml. Three major (55, 40 and 24 kDa) and one minor (58 kDa) polypeptides constitute its proteinic capsid. Its genome contains a single molecule of ssRNA, which is polyadenylated at the 3' end and approximately 9 kb in length. Based on these characteristics, we believe that TS virus should be included in the family Picornaviridae. Ecuadorian and Hawaiian TS virus isolates were found to be identical in their biophysical, biochemical and biological characteristics, and should be considered as the same virus.

Characterization of hepatopancreatic parvo-like virus, a second unusual parvovirus pathogenic for penaeid shrimps.

The hepatopancreatic parvo-like virus (HPV) of penaeid shrimp was extracted from infected shrimp tissues, purified and subsequently characterized. The viral particles, icosahedral in shape, are 22 nm in diameter and possess a buoyant density of 1.41 g/ml. They contain ssDNA, of approximately 5 kb in size which encodes a single polypeptide of 54 kDa. On the basis of its general characteristics this pathogenic agent belongs to the Parvoviridae family, but because of two unusual characteristics (capsid protein formed with a single polypeptide and genome structure more closely related to the autonomous parvoviruses rather than the densoviruses), it seems to constitute a novel group in the Parvoviridae family.

Use of non-radioactively labeled DNA probes for the detection of a baculovirus from Penaeus monodon by in situ hybridization on fixed tissue.

Clones isolated from a genomic library of the baculovirus PmSNPV (= MBV) were used to prepare DNA probes for detection of PmSNPV in shrimp tissue. Davidson's AFA fixed shrimp tissues were probed using DNA that had been labeled with the hapten, digoxigenin, by an in situ hybridization assay. The DNA probes readily distinguished PmSNPV-infected from uninfected shrimp tissue. The reactions were localized to the hepatopancreas and midgut, the sites where this virus is detected by standard histological methods. The probes did not react to shrimp infected with Baculovirus penaei (BP = PvSNPV).

Characterization of cross-reactive anti-DNA autoantibodies in murine lupus.

The role of crossreactive anti-DNA autoantibodies in the pathogenesis of Systemic Lupus Erythematosus (SLE) and its counterpart in the mouse (murine lupus) remains undefined. Five murine monoclonal anti-DNA autoantibodies tested in ELISA and immunofluorescence assays were found to cross-react with a variety of both nucleic acid and non-nucleic acid antigens. These included double stranded DNA (dsDNA), single stranded DNA (ssDNA), transfer RNA (tRNA), and the murine thymoma cell lines WEHI-22, WEHI-7, and EL-4. The majority of the autoantibodies reacted with all antigens tested; none of the autoantibodies reacted with only one antigen. To determine if the multiple reactivities demonstrated by these hybridoma-derived monoclonal anti-DNA autoantibodies accurately reflects the in vivo, autoimmune environment, the same assays were used to measure the reactivities of autoantibodies secreted directly from unfused autoimmune spleen cells cultured in vitro. These spleen cell-derived autoantibodies were found to display reactivities very similar to those demonstrated by the monoclonal anti-DNA autoantibodies indicating that the hybridoma process itself does not appear to select and amplify reactivities which are not present in vivo. Initial molecular characterization of F11, a monoclonal anti-DNA autoantibody crossreactive with both dsDNA and ssDNA, revealed that it utilizes the same VH gene segment as an anti-DNA autoantibody specific for ssDNA. F11 was also found to utilize similar VH, D, and JH gene segments as an antibody directed against the hapten polymer (Glutamic acid60, Alanine30, Tyrosine10)n (GAT). Thus, the same Ig gene segments used to encode crossreactive anti-DNA autoantibodies can also be utilized by anti-DNA autoantibodies displaying strict antigen specificity as well as by antibodies directed against exogenous antigens.

Cytotoxic activity of enriched large granular lymphocyte populations in rheumatoid arthritis.

Enriched large granular lymphocyte (LGL) populations and mononuclear cell populations from peripheral blood of rheumatoid arthritis (RA) patients and control individuals were compared for natural killer (NK) cell activity. The NK activity of the two study groups was very similar when mean values for both cell populations were analyzed. When comparing the difference between the NK activity of the mononuclear cell and LGL populations, 44% of the RA patients demonstrated less of an increase than all of the control individuals although the percentages of LGL, Leu 11+, and Leu 7+ cells were equivalent.

Immune function in chronic active Epstein-Barr virus infection.

The spectrum of illness attributed to Epstein-Barr virus (EBV) includes patients with symptoms persisting for more than 1 year without any other obvious underlying disease. High titers of antibodies to EBV, either IgG antiviral capsid antigen or anti-early antigen, can be demonstrated. In this study, 13 patients diagnosed as having chronic active EBV infection were examined to determine aspects of their immunologic status. Morphological examination and fluorescent antibody analysis revealed no abnormalities in the phenotypes of peripheral blood white cells present in these patients. Compared to those from healthy control individuals, mononuclear cells from the patients showed a markedly depressed ability to produce both interleukin-2 and interferon after stimulation with mitogen and a phorbol ester. Studies of natural killer (NK) cell activity revealed that unfractionated mononuclear cells from patients with chronic active EBV infection were significantly lower in killing activity compared to the control group. Fractionation procedures to enrich for large granular lymphocytes resulted in an increase in NK activity for all individuals, but killing activity still remained slightly lower in the patients than in the control group. The dysfunctions which were found in patients with chronic active EBV infection may reflect a primary defect in natural immune functions of the patients predisposing them to a chronic or intermittent clinical disease rather than a self-limiting illness. Alternatively, the abnormalities detected in these experiments may be a result of the viral infection itself.