White Sturgeon as a Potential Vector of Infectious Hematopoietic Necrosis Virus

Abstract

Cell lines from white sturgeon Acipenser transmontanus were derived from peripheral blood cells, heart, and spleen. Incubated with infectious hematopoietic necrosis virus (IHNV) for 8 d at l5°C, these cell lines produced 0.7–53.2 plaque-forming units (PFU)/cell. Waterborne exposure of larval white sturgeons (60 d posthatch) to 10⁶ PFU/mL of IHNV resulted in 10% mortality 5–6 d postinfection, with virus concentrations consistently greater than 10⁵ PFU/g. A replicate group of larval white sturgeons that were sampled at different times post-IHNV exposure had no detectable virus at 24 h, but 72% of the fish had IHNV concentrations of 10²-10⁶ PFU/g when they were examined 2–9 d postinfection. Juvenile white sturgeons (mean weight, 35 g) immersed in or injected with IHNV exhibited no mortality, and virus was only detected immediately postexposure in just 25% of the fish tested. Juvenile white sturgeons fed either virus-free rainbow trout Oncorhynchus mykiss or dead IHNV-infected rainbow trout had no viable virus in their feces. Juvenile white sturgeons fed or exposed to IHNV failed to transmit the virus to cohabiting rainbow trout fry. These results suggest that IHNV can replicate in larval white sturgeons but presumably not in juveniles or adults. Virus neutralization activity was detected in serum from adult white sturgeons (4–6 years old) cultured with rainbow trout exposed to IHNV but not in white sturgeons kept in a pathogen-free environment and fed a manufactured diet. White sturgeon serum with IHNV-neutralizing activity was used to passively immunize rainbow trout, and it provided significant (P < 0.01) protection against IHNV challenge.     

In Vitro Infection of Salmonid Epidermal Tissues by Infectious Hematopoietic Necrosis Virus and Viral Hemorrhagic Septicemia Virus

Abstract

The ability of two rhabdoviruses, infectious hematopoietic necrosis virus (IHNV) and viral hemorrhagic septicemia virus (VHSV), to infect fish skin was investigated by in vitro infection of excised tissues. Virus replication was determined by plaque assay of homogenized tissue extracts, and the virus antigen was detected by immunohistology of tissue sections. Gill, fin, and ventral abdominal skin tissues of rainbow trout Oncorhynchus mykiss that had been infected in vitro with a virulent strain of IHNV (193–110) produced substantial increases in virus titer within 24 h. Titers continued to increase up until day 3 of incubation; by this time, virus had increased 1,000-fold or more. This increase in IHNV titer occurred in epidermal tissues of fingerlings and of older fish. In another experiment, IHNV replicated in excised rainbow trout tissues whether the fish had been subject to prior infection with a virulent strain of IHNV (Western Regional Aquaculture Consortium isolate) or whether the fish had been infected previously with an attenuated strain of the virus (Nan Scott Lake, with 100 passes in culture). A virulent strain of VHSV (23/75) replicated effectively in excised gill tissues and epidermal tissues of rainbow trout and chinook salmon O. tshawytscha; however, the avirulent North American strain of VHSV (Makah) replicated poorly or not at all.     

Experimental Infection of Brook Trout with Infectious Hematopoietic Necrosis Virus Types 1 and 2

Abstract

Fry of brook trout Salvelinus fontinalis became infected and diseased after immersion exposure to infectious hematopoietic necrosis virus (IHNV), but a long-lasting IHNV carrier state was not induced. Duplicate groups of 100 fish were immersed for 6 h in baths containing a type 1 (Round Butte, RB) or a type 2 (Rangen, RA) IHNV isolate at a high or low dose. Brook trout mortalities induced by immersion in a bath of the RB or RA IHNV isolate at 10² plaque-forming units (pfu) per milliliter were equivalent (1 and 0%), but fish were more susceptible to infection with RA IHNV. Only the single dead fish in the RB group was infected, but 24% of the RAexposed fish were infected 1 week after exposure. At a dose of 10⁶ pfu/mL, exposure to RB IHNV resulted in a higher mortality (35%) and prevalence of infection (89% of live fish sampled at 1 week postexposure), but no infectious virus was detectable by 5 weeks after exposure. In contrast, RA IHNV exposure at a dose of 10⁴ pfu/mL resulted in only 5% mortality, and live fish killed at 1 week postexposure had a 22% prevalence of infection, but infectious virus was not detectable by week 3. Although brook trout have been previously considered to be resistant to IHNV, this study has shown that brook trout become diseased and die after exposure to a high dose of one type I IHNV isolate and can be infected after immersion exposure to even a low dose of type 1 or type 2 IHNV.     

Multiplication of Infectious Hematopoietic Necrosis Virus in Rainbow Trout following Immersion Infection: Organ Assay and Electron Microscopy

Abstract

Sequential spread of infectious hematopoietic necrosis virus (IHNV) to tissues of rainbow trout Oncorhynchus mykiss was examined following immersion infection with two different isolates of IHNV, a pathogenic strain and a nonpathogenic strain from rainbow trout. Virus strain 193–110 was highly pathogenic to 1-month-old rainbow trout and caused 100% mortality within 13 d, whereas strain RB-76 was much less virulent, causing 50% mortality by the 19th day. Virus titers of 1-month-old fingerling fish dying soon after infection were significantly higher than titers of those dying later. Assays of dissected tissues showed that gills of infected 2-month-old fingerlings contained virus as early as 16 and 20 h postinfection, with definite replication occurring at 48 h. The early presence of the virus in the gills followed shortly by appearance of the virus in the kidneys and spleen indicated that the virus spreads rapidly to the target organs. Virus was detected in many other organs at lower levels on the third day and increased to higher levels during the following days. Heart tissue had high titers later in the infection. When 4-month-old rainbow trout were infected with strain 193–110, the mortality was reduced and delayed, whereas those infected with strain RB-76 produced no mortality. Assays on the day of death of these older fingerlings infected with strain 193–110 revealed that fish dying soon after infection also had higher titers than those dying later. Electron microscopic examination offish organs showed the presence of typical IHNV particles budding off from various tissue cells of affected organs, including gill tissue. The destructive effect of the virus was particularly noticeable in the disarrangement of heart muscle organelles.     

Serological Evidence of Infectious Hematopoietic Necrosis in Rainbow Trout from a French Outbreak of Disease

Abstract

Following the detection of infectious hematopoietic necrosis virus (IHNV) in France in April 1987, a serological survey was conducted of the rainbow trout Oncorhynchus mykiss (formerly Salmo gairdneri) from an infected cultured stock previously known to be contaminated with viral hemorrhagic septicemia virus (VHSV) for 3 years. The work lasted from April to December 1987, at which time all the remaining fish were slaughtered. Serum samples were assayed by a plaque-reduction test and a simplified neutralization test that is more suitable for processing large numbers of serum samples. Such investigations revealed that IHNV neutralization by trout antibodies depended on trout complement, as did neutralization of VHSV. Incubation for 16 h at 4°C increased the sensitivity of the test compared to incubation for 1 h at 20°C. During the course of clinical IHN from April to June, young fish did not display any neutralizing activity, but in September, 29 of 50 of them exhibited significant anti-IHN neutralizing antibody titers ranging from 21 to over 160, and 18 of 46 of these same fingerlings did so in December. Similarly, fish that had undergone VHS infection in August began to develop anti-VHSV antibodies in December (5 of 50), demonstrating that one fish can harbor neutralizing antibodies to both IHNV and VHSV, and that these antibodies had required 14 weeks to appear under fish culture conditions at 10°C. As could be expected from seroneutralization tests, neutralizing antibodies to IHNV did not result in protection against VHS. Sera from 13 of 20 adult fish sampled in mid-June revealed neutralizing antibodies to IHNV, suggesting that they harbored the virus prior to the clinical infection that affected their progeny. Only two of the fish showed low anti-VHSV antibody titers. Similarly, neutralizing antibodies to IHNV were detected in 53 of 73 other adult fish sampled in late October, 10 months after they had spawned and 7 months after mortality had occurred among their progeny. Given the prevalence, level, and persistence of neutralizing antibody titers, the seroneutralization test would be worth investigating more thoroughly to define the conditions that could make it a reliable tool for checking the virus status of trout carriers.     

Infectious Hematopoietic Necrosis Virus (IHNV) in Coho Salmon

Abstract

Infectious hematopoietic necrosis virus (IHNV) causes important losses of chinook salmon Oncorhynchus tshawytscha, sockeye salmon Oncorhynchus nerka, and rainbow trout and steelhead Oncorhynchus mykiss on the west coast of North America. Although coho salmon Oncorhynchus kisutch are considered resistant to IHNV infection, the virus was detected in numerous adult coho salmon returning to Trinity River Hatchery, California, in 1985 and 1986. The virus was isolated from internal organs and ovarian fluids of these fish. Antigenic and structural polypeptides of the viruses were identical in adult coho and chinook salmon collected at the same location. Chinook salmon and rainbow trout alevins exhibited high degrees of susceptibility to IHNV obtained from adult coho and chinook salmon. Coho salmon alevins were resistant to both virus isolants.     

Early Life Stage Survival and Susceptibility of Brook Trout,Coho Salmon,Rainbow Trout,and Their Reciprocal Hybrids to Infectious Hematopoietic Necrosis Virus

Abstract

Triploid (heat-shocked) and diploid groups of rainbow trout Oncorhynchus mykiss, brook trout Salvelinus fontinalis, coho salmon Oncorhynchus kisutch, and reciprocal hybrids were produced, monitored for early life stage survival, and evaluated for susceptibility to infectious hematopoietic necrosis virus (IHNV). The female rainbow trout × male brook trout triploid hybrids had significantly greater (P < 0.01) survival than the diploid hybrids of this cross. The heat-shocked hybrid group of the female rainbow trout × male coho salmon also exhibited significantly greater survival to the eyed egg stage of development than the untreated group of this hybrid. Studies of the susceptibility of treatment groups to a 1990 IHNV isolate from the Hagerman Valley were conducted by using a standardized immersion exposure procedure at one or two different mean body weights. The diploid brook trout and coho salmon and two triploid hybrids (female rainbow trout × male brook trout or male coho salmon) were significantly less (P < 0.05) susceptible to IHNV than the pure-species diploid and triploid rainbow trout groups.     

Susceptibility of Selected Inland Salmonids to Experimentally Induced Infections with Myxobolus cerebralis,the Causative Agent of Whirling Disease

Abstract

Laboratory exposures to the infectious stages (triactinomyxons) of Myxobolus cerebralis demonstrated a range of susceptibility to whirling disease among four species of inland salmonids. Replicate groups of each species were exposed to two concentrations of triactinomyxons, a low dose (100–200 per fish) and a high dose (1,000–2,000 per fish). Exposed fish were evaluated for clinical signs, for severity of microscopic lesions at 35 d, 2 and 5 months, and for spore concentrations in the head cartilage at 5 months. A standard strain of rainbow trout Oncorhynchus mykiss matched for age served as a susceptible species control. Rainbow trout, westslope cutthroat trout O. clarki lewisi, Yellowstone cutthroat trout O. clarki bouvieri, and bull trout Salvelinus confluentus were susceptible to M. cerebralis infections. Clinical signs, including radical swimming (“whirling”) and black tails, were observed at 7 weeks postexposure among rainbow and cutthroat trout challenged at 3 weeks of age. Clinical signs were rare among bull trout exposed at an age of 4 weeks and absent among rainbow and cutthroat trout exposed at 3 months posthatch. Most rainbow, cutthroat, and bull trout were found to be infected when examined at 5 months postexposure. The most severe microscopic lesions among infected fish at 5 months postexposure were found among rainbow trout. Cutthroat trout had less severe lesions, bull trout had mild infections, and no evidence of infection was found among Arctic grayling Thymallus arcticus. Mean spore concentrations among infected fish correlated with the severity of microscopic lesion scores. Rainbow trout had mean concentrations of spores in head cartilage reaching 10⁶, whereas more resistant species such as bull trout had 10⁴ spores; no spores were found among Arctic grayling at 5 months postexposure.     

Multiplication of Infectious Hematopoietic Necrosis Virus in Rainbow Trout following Immersion Infection: Whole-Body Assay and Immunohistochemistry

Abstract

The sites of replication of infectious hematopoietic necrosis virus (IHNV) in infected tissues were detected in fingerling rainbow trout Oncorhynchus mykiss by in situ histologic techniques following immersion infection. Virus antigens in tissues were detected by a neutralizing mouse monoclonal antibody and a one-step anti-mouse biotin-streptavidin conjugated to horseradish peroxidase. The efficiency of infection and virulence of the virus determined by mortality rates showed high virulence of the selected IHNV isolates, and viral replication in individual fish showed that virus content of the fish increased rapidly from the second day to the seventh day postinfection. The earliest viral lesions following infection were detected in the epidermis of the pectoral fins, opercula, and ventral surface of the body. Virus lesions became evident in kidneys on the third day. By the fifth day, when there was a significant increase in virus titer, foci of viral replication were detected in gill tissue and in the anterior internal tissues below the epidermis. Subsequently, extensive virus replication and tissue destruction were observed in the spleen, dorsal adipose tissues, ventricle, and pseudobranch. Replication in the liver, the muscularis layers of the digestive tract, and the general body musculature followed later. These infection experiments indicated that the epidermis and gills of fish constitute important sites of early IHNV replication.     

Susceptibility of Four New Salmonid Cell Lines to Infectious Hematopoietic Necrosis Virus

Abstract

Four salmonid cell lines, CoE 45, CoE 115, CoE 345, and RBTE 45, were established from embryonic tissues of coho salmon Oncorhynchus kisutch and rainbow trout O. mykiss. In vitro challenges of the new lines were conducted with four isolates of infectious hematopoietic necrosis virus (IHNV). Two of the IHNV isolates used for the challenges were derived from infected tissues of rainbow trout, one was derived from chinook salmon O. tshawytscha, and the other isolate was derived from coho salmon. To standardize the virus challenges of the new cell lines, several established piscine cell lines (EPC, CHSE 214, CSE-119, RTH-149, RTG, and RTS) were challenged in the same way as the new lines. Each of the lines was challenged with virus at a single low multiplicity of infection (0.01 plaque-forming unit per cell). Virus yields were quantitated by plaque assay on epithelioma papulosum cyprini (EPC) cells on day 3. Results of the challenge experiments revealed different levels of production of virus for each isolate on the various cell lines. Overall, the new cell line derived from rainbow trout, RBTE 45, was quite susceptible to all viruses tested. The three cell lines newly derived from coho salmon embryo were not as resistant to the replication of IHNV as was the established coho salmon cell line, CSE-119. An established cell line, EPC, derived from an epithelial tumor of common carp Cyprinus carpio, remained the most susceptible to all four IHNV isolates tested.     

Infectious Pancreatic Necrosis Virus: Transmission from Infectious to Susceptible Rainbow Trout Fry

Abstract

Fry of rainbow trout Oncorhynchus mykiss were exposed to serotype VR-299 of infectious pancreatic necrosis virus (IPNV) by using a standardized immersion challenge. In concurrent experiments, fish were monitored for 11 d for excretion of IPNV or monitored for 9 d for excretion and transmission of IPNV to susceptible rainbow trout fry. Immersion-challenged fish began excreting virus within 2 d after challenge. The rate of IPNV excretion per fish increased steadily from about day 4 to day 8 and then decreased. Virus concentrations in tissues of immersion-challenged fish increased exponentially. Susceptible fish became infected with IPNV within 4 d after being introduced to immersion-challenged fish (e.g., 2 d after the challenged fish began excreting virus). By 9 d, 84% of the susceptible fish were infected with IPNV.     

Biochemical and Antigenic Properties of the First Isolates of Infectious Hematopoietic Necrosis Virus from Salmonid Fish in Europe

Abstract

The first isolates of infectious hematopoietic necrosis virus (IHNV) recovered from rainbow trout Oncorhynchus mykiss (formerly Salmo gairdneri) in France and Italy were compared to six representative strains from North America by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of virion polypeptides and neutralization by monoclonal antibodies (MAbs). All three IHNV isolates from Europe had similar polypeptide profiles when compared by SDS-PAGE. An analysis of the antigenic relatedness of the European isolates to representative strains from North America showed that they were clearly different from viruses obtained from salmonids in California. The RB/B5 MAb, which was developed against virus isolated from adult steelhead (anadromous rainbow trout) reared in central Oregon, neutralized all isolates examined. The 193–110/B4 MAb, developed against IHNV isolated from infected yearling rainbow trout in southern Idaho, neutralized all isolates tested except those from California. The SRCV/A4 MAb, developed against Sacramento River chinook virus (SRCV) isolated from adult spring chinook salmon O. tshawytscha in central California, was the least reactive, and strong neutralization was observed only with the SRCV strain of IHNV from California. However, partial reactivity of the virus isolates from France with the SRCV/A4 MAb distinguished them from the virus recovered from salmonids in Italy.     

Vaccination of Rainbow Trout against Infectious Hematopoietic Necrosis (IHN) by Using Attenuated Mutants Selected by Neutralizing Monoclonal Antibodies

Abstract

A neutralizing monoclonal antibody against infectious hematopoietic necrosis virus (IHNV) was used to select neutralization-resistant mutants from isolates of virus obtained from adult steelhead Oncorhynchus mykiss returning to the Round Butte Hatchery (RB mutants) on the Deschutes River in Oregon, USA, and from rainbow trout (nonanadromous O. mykiss) at a commercial hatchery in the Hagerman Valley of Idaho, USA (193-110 mutants). Two of the mutants, RB-1 and 193-110-4, were significantly (P < 0.001) attenuated compared with parental strains. Vaccination of rainbow trout by waterborne exposure to the mutants conferred solid protection against challenge with wild-type virus. In some trials, fish vaccinated with the RB-1 mutant at 50% tissue culture infectious doses (TCID50) of 1 × 10⁴–1 × 10⁵ TCID50/mL or with the 193-110-4 mutant at 1 × 10²–1 × 10³ TCID50/mL, held for 14 d, then challenged with the homologous wild-type strain at 1 × 10⁵ TCID50/mL showed relative percent survival of 95–100% (P < 0.005). There was no significant difference (P > 0.05) in protection among fish exposed to the RB-1 vaccine strain at a dose of 1 × 10⁵ TCID50/mL for periods of either 1, 12, or 24 h, held for 14 d, and then challenged with the wild-type RB isolate, although the 1-h exposure seemed to be somewhat less effective. Fish were vaccinated with the RB-1 strain at 1 × 10³–1 × 10⁵ TCID50/mL for 24 h then challenged after 1, 7, 14, or 21 d with the wild-type RB isolate. No significant (P > 0.1) protection was observed at 1 d postvaccination, but the relative percent survival increased progressively at each subsequent challenge period, becoming statistically significant by day 7 (P < 0.001) and beyond. These results suggested that resistance to challenge with wild-type virus resulted from development of IHNV-specific immunity and not from viral interference or interferon induction, and they reinforce the potential of an attenuated vaccine to control this important disease.     

Distribution of Myxobolus cerebralis in Salmonid Fishes in Montana

Abstract

Over an approximately 2-year period, 20,974 fish (trout and other salmonid species) from 230 separate waters (creeks, rivers, lakes, reservoirs, ponds, hatcheries, and irrigation ditches) within 21 of the 22 major drainages in Montana were examined for Myxobolus cerebralis. Nine of the major river drainages have waters containing infected fish: Beaverhead, Big Hole, Blackfoot, Clark Fork above the Bitterroot River, Flathead below the south fork of the Flathead River, Jefferson, Madison, Missouri above the Marias River, and Yellowstone above the Bighorn River. The Beaverhead, Clark Fork above the Bitterroot River, Jefferson, Madison, and Missouri above the Marias River have the greatest number of waters containing fish infected with M. cerebralis. Comparisons of infection levels (number of pooled samples that contain fish infected with M. cerebralis) between species among these drainages show significantly lower levels of infection in brown trout Salmo trutta and rainbow trout Oncorhynchus mykiss in the Missouri above the Marias River drainage and significantly higher levels of infection of rainbow trout in the Jefferson. Comparisons of differences in infection levels between drainages among species show that, in the Beaverhead, Clark Fork above the Bitterroot River, and Madison, infection levels in brown trout are significantly higher than in rainbow trout. This is partially attributed to losses of juvenile rainbow trout because of M. cerebralis infection, leading to biased samples. Histopathologic studies showed lesions were consistently less severe in brown trout than other species and occurred in a different location (gill arches versus ventral calvarium). In six of the nine affected drainages (Beaverhead, Blackfoot, Clark Fork above the Bitterroot River, Flathead below the South Fork, Jefferson, and Madison), infected fish were found at or near the time that intensive sampling was initiated in the spring of 1995. In the three remaining affected drainages (Missouri above the Marias River, Yellowstone above the Bighorn River, and the Big Hole), infected fish were not identified until at least 15 months after the initiation of widespread testing. This indicates that in the first six drainages listed above, the infection was well established prior to 1995 but spread into the last three drainages in the ensuing months. Methods of transmission and the sources of infection are unknown, although the absence of infected fish in state, private, and federal hatcheries in Montana indicates hatchery fish from these sources are not likely to be responsible.     

Survivability of Infectious Hematopoietic Necrosis Virus in Fertilized Eggs of Masu and Chum Salmon

Abstract

The possibility of vertical transmission of infectious hematopoietic necrosis virus (IHNV) was studied with the eggs of masu (cherry) salmon Oncorhynchus masou and chum salmon O. keta. The surfaces of eggs and sperm were contaminated with IHNV (10^3.8-10^4.8 50% tissue culture infective dose [TCID50]/egg) and then the eggs were fertilized. Eggs just after fertilization and embryonated eggs also were infected by injection with IHNV (10^3.8 TCID50/egg) directly into the yolk. During incubation, eggs were held in running water at 10°C. Mortality of the eggs or hatched progeny was determined and isolation of IHNV on the surface or inside of the eggs was determined during the incubation period. No mortality occurred and no virus was detected in fertile eggs from contaminated gametes. For injected eggs, IHNV was not detected on the surface of masu and chum salmon eggs after 1 d of incubation. Infectivity of IHNV inside the eggs decreased gradually and could not be detected after 1 month of incubation. This rate of IHNV reduction in the fertilized egg was similar to that found in a mixture of IHNV and homogenized yolk contents. Several individual yolk components also showed anti-IHNV activity. When eyed eggs were injected with IHNV, the embryos of both masu and chum salmon became infected, and the concentration of virus increased rapidly and reached more than 10^6.5 TCID50/fish. The cumulative mortality of eggs injected at the eyed stage for both masu and chum salmon was 90%. The susceptibilities of hatched-out larvae of masu and chum salmon to IHNV were different; cumulative mortality was more than 90% in masu salmon and 20–30% in chum salmon artificially infected with the virus. We concluded that vertical transmission of IHNV is doubtful because the virus is apparently unable to survive in eggs before the eyed stage.     

Effects of Salinity on Yersinia ruckeri Infection of Rainbow Trout and Brown Trout

Abstract

Juvenile rainbow trout Oncorhynchus mykiss and brown trout Salmo trutta acclimated to freshwater or salinities of 9.0‰ or less were exposed to Yersinia ruckeri, the bacterial pathogen that causes enteric redmouth disease (ERM). Both species of fish were kept in the same recirculating systems after bacterial exposure. Rainbow trout mortality was significantly (P < 0.05) different in each salinity: 96.5% in freshwater, 89.5% in water of 1.1‰ salinity, 81.3% in 3.0‰ salinity, and 75.0% in 9.0‰ salinity (model SE = 1.0). All deaths occurred between 3 and 12 d after exposure to Y. ruckeri. Only 2.3% of brown trout in all salinities died, and differences among treatments were not significant. For both fish species, Y. ruckeri was isolated from liver, spleen, and trunk kidney of fish dying during this experiment, and lesions of rainbow trout were consistent with ERM. Yersinia ruckeri was not isolated from brown trout surviving for 21 d after bacterial exposure but was isolated from 3 of 24 surviving rainbow trout; a polymerase chain reaction assay detected the DNA of Y. ruckeri in 3 additional rainbow trout survivors. Neither the lesions of fish with ERM nor the percentage of surviving fish subclinically infected with Y. ruckeri was affected by salinity. Bacterial growth in vitro was not affected by low (≤9.0‰) salinity; however, bacterial adhesion to polystyrene was significantly reduced as salinity increased. Although mortality caused by Y. ruckeri was significantly lower for rainbow trout in water with slightly increased salinity, none of the salinities tested was effective in preventing serious losses caused by this pathogen in recirculating systems.     

Serological Properties of Neutralizing Antibodies Induced by Vaccination of Rainbow Trout with Distinct Strains of Infectious Pancreatic Necrosis Virus

Abstract

Adult rainbow trout Oncorhynchus mykiss were immunized with formalin-inactivated, concentrated infectious pancreatic necrosis virus (IPNV). Although the immune response was variable among fish inoculated with a given virus type, sera were obtained that contained high titers of antibodies against known representatives of each of the three major serotypes and several unclassified field isolates of IPNV. Preparations of semipurified macroglobulins from the rainbow trout were subsequently used for comparative cross-neutralization testing of viruses. Cross-reactions were generally low between serotypes; however, diversity and heterogeneity existed among viral isolates from North American hatcheries (e.g., within serotype 1). For example, the Jasper subtype was clearly serologically distinguishable from other western Canadian isolates and from typical eastern Canadian isolates, which were similar to U.S. isolate VR 299. Specific salmonid immunoglobulin is suggested as a possible supplemental reagent, together with mammalian polyclonal and monoclonal antibody, for determining the epidemiology of IPNV in North America.     

Detection of Infectious Pancreatic Necrosis Virus from the Leeches Hemiclepsis marginata and Hirudo medicinalis

Leeches have been reported to harbor several important fish pathogens, including spring viremia of carp virus, infectious hematopoietic necrosis virus (IHNV), and viral hemorrhagic septicemia virus (VHSV), and also may contain blood protozoa. In the present study, leeches were collected from water bodies located in Kurdistan province, Iran. The specimens were tested for IHNV, VHSV, and infectious pancreatic necrosis virus (IPNV) using the PCR method. The results showed that two different species of leeches, Hemiclepsis marginata and Hirudo medicinalis, were infected by IPNV among the seven species studied. The infected leeches were found in areas that were polluted with untreated sewage coming from upstream fish farms culturing Rainbow Trout Oncorhynchus mykiss. In addition, the fish at fish farms in the vicinity had been infected with IPNV 9 months previously. Our results showed that the virus causing infectious pancreatic necrosis is present in the leeches H. marginata and H. medicinalis, suggesting that leeches are a potential source of IPNV in fish farms.

Received October 14, 2015; accepted June 1, 2016 Published online September 29, 2016     

Glycoprotein from Infectious Hematopoietic Necrosis Virus (IHNV) Induces Protective Immunity against Five IHNV Types

Abstract

Infectious hematopoietic necrosis virus (IHNV) is a fish pathogen that kills young salmon and trout. Outbreaks of the disease among hatchery-reared fish are a problem in the northwestern USA from northern California to Alaska. At least five biochemical types and several strains of differing host specificity of IHNV exist. Any vaccine developed to immunize fish must be able to elicit a response that will neutralize all strains of IHNV. This report shows that a single type of IHNV can induce a protective immune response in vivo to the five biochemical types of IHNV and indicates that, of the IHNV isolates examined, there is at least one common major neutralization epitope. Therefore, a vaccine developed against this common neutralization epitope will provide cross-protective immunity against these IHNV variants.