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Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus) exposed for different time periods to susceptible water temperatures
Accepted Manuscript Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus) exposed for different time periods to susceptible water temperatures Myung-Hwa Jung, Chamilani Nikapitiya, Tharabenahalli-Nagaraju Vinay, Jehee Lee, Sung-Ju Jung PII:
S1050-4648(17)30557-0
DOI:
10.1016/j.fsi.2017.09.038
Reference:
YFSIM 4828
To appear in:
Fish and Shellfish Immunology
Received Date: 5 June 2017 Revised Date:
23 August 2017
Accepted Date: 14 September 2017
Please cite this article as: Jung M-H, Nikapitiya C, Vinay T-N, Lee J, Jung S-J, Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus) exposed for different time periods to susceptible water temperatures, Fish and Shellfish Immunology (2017), doi: 10.1016/j.fsi.2017.09.038. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus)
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exposed for different time periods to susceptible water temperatures
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Myung-Hwa Jung a, Chamilani Nikapitiya b, Tharabenahalli-Nagaraju Vinay c, Jehee Lee b,
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Sung-Ju Jung a,*
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Department of Aqualife Medicine, Chonnam National University, Republic of Korea.
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Department of Marine Life Sciences, Jeju National University, Republic of Korea.
ICAR-Indian Institute of Agricultural Biotechnology, India.
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*Corresponding author at: Department of Aqualife Medicine, Chonnam National University,
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San 96-1 Dunduck Dong, Yeosu, Jeonnam 550-749 Republic of Korea
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Tel.: +82-61-659-7175
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Fax: +82-61-659-7179
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E-mail address: [email protected] (S.-J. Jung).
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ACCEPTED MANUSCRIPT Abstract
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Rock bream iridovirus (RBIV) is a member of the Megalocytivirus genus that causes severe
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mortality to rock bream. Water temperature is known to affect the immune system and
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susceptibility of fish to RBIV infection. In this study, we evaluated the time dependent virus
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replication pattern and time required to completely eliminate virus from the rock bream body
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against RBIV infection at different water temperature conditions. The rock bream was
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exposed to the virus and held at 7 (group A1), 4 (group A2) and 2 days (group A3) at 23 °C
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before the water temperature was reduced to 17 °C. A total of 28% mortality was observed 24
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to 35 days post infection (dpi) in only the 7 day exposure group at 23 °C. In all 23°C
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exposure groups, virus replication peaked at 20 to 22 dpi (106–107/µl). In recovery stages (30
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to 100 dpi), the virus copy number was gradually reduced, from 106 to 101 with faster
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decreases in the shorter exposure period group at 23 °C. When the water temperature was
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increased in surviving fish from 17 to 26 °C at 70 dpi, they did not show any mortality or
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signs of disease and had low virus copy numbers (below 102/µl). Thus, fish need at least 50
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days from peaked RBIV levels (approximately 20 to 25 dpi) to inhibit the virus. This
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indicates that maintaining the fish at low water temperature (17 °C) for 70 days is sufficient
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to eradicate RBIV from fish body. Thus, RBIV could be eliminated slowly from the fish body
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and the virus may be completely eliminated under the threshold of causing mortality.
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Key word: rock bream iridovirus, rock bream, virus replication, eliminate of virus, water
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temperature
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1. Introduction Iridoviridae is a family of large double-stranded DNA virus (120–300 nm) with an
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icosahedral morphology [1]. The family includes five genera: Iridovirus, Chloriridovirus,
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Ranavirus, Lymphocystivirus and Megalocytivirus. Megalocytiviruses have been the cause of
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disease in >50 fish species and currently threaten the aquaculture industry, causing great
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economic losses in Korea, Japan, China and Southeast Asia [2-10]. Rock bream iridovirus
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(RBIV), which belongs to the genus Megalocytivirus [11] remains an important health
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problem in rock bream (Oplegnathus fasciatus).
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Water temperature is known to affect the immune system and susceptibility of fish to virus
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infection [12-20]. In Korea, RBIV outbreaks typically occur in cultured rock bream from
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August to September, when water temperature between 23 and 27 °C [10]. Recently, several
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studies have demonstrated a clear correlation between mortality and the water temperature
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against RBIV infection in rock bream; i) rock bream injected with RBIV and held at 29, 26,
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25, 23, 21, 20 or 18 °C had 100% mortality, but no mortality at 17 or 13 °C [21-25], ii)
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mortality due to RBIV in rock bream at 23 °C could be controlled by reducing water
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temperature to 17 °C during very early stages of infection [21]. Furthermore, it was observed
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that the survivors of high virus dose injections in rock bream gained protective immunity.
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Thus, water temperature plays a critical role not only for mortality, but also to obtain the
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protective immunity in rock bream against RBIV infection.
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Several other experimental studies on fish viral diseases have demonstrated the effect of
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water temperature regulations on protective immunity of survivors against infectious
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haematopoietic necrosis virus (IHNV), koi herpesvirus (KHV), viral haemorrhagic
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septicaemia virus (VHSV) and nervous necrosis virus (NNV) [12,18,19,26,27]. Recent
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studies reported the long-term kinetics of NNV infectivity in sevenband grouper, injected
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with a live NNV at 17.3 °C and reared at natural seawater temperature [28]. The NNV
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107.43±0.35TCID50/g. However, NNV was under the detection limit (≤102.8TCID50/g) between
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42 and 128 days; hence, it was suggested that fish need at least 42 days from initial infection
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to inhibit the active virus, thus completely eliminating it from their body. Therefore,
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identifying a time period in which the virus has been completely eliminated from the fish’s
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body to prevent the mortality due to viral infection is essential. However, the time-dependent
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virus replication pattern and time required to completely eliminate the virus from the fish’s
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body has not been demonstrated in rock bream against RBIV infection.
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In the present study, RBIV was artificially infected to rock bream at different water
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temperature conditions, and the virus replication pattern was evaluated in the rock bream
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from 2 to 100 days post infection (dpi) to determine the influence of water temperature on
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RBIV replication. Additionally, time points/period in which the virus was completely
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eliminated from survivors due to RBIV infection were investigated.
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2. Materials and Methods
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2.1. Experimental fish
RBIV free rock bream were obtained from a local farm and reared at the Fisheries Science
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Institute at Chonnam National University. Approximately 500 fish (7.4 ± 1.0 cm/9.1 ± 1.3 g)
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were maintained in large tanks (10 ton) with a continuous seawater supply with aeration. The
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required number of fish for the experiments was transferred to the experimental infection
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facility.
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2.2. Source of RBIV The virus used in the present study was originally isolated from RBIV infected rock bream in 2010 as explained earlier [29].
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2.3. Determination of viral copy number in the spleen and spleen index For the analysis of the RBIV copy number, the spleen was obtained from RBIV infected
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fish at several sampling points. Genomic DNA was isolated from the whole spleen (20–150
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mg) of each fish using an AccuPrep®Genomic DNA extraction kit (Bioneer, Korea)
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according to the manufacturer’s instructions. Real-time polymerase chain reaction (PCR)
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was carried out in an Exicycler 96 Real-Time Quantitative Thermal Block (Bioneer, Korea)
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using an AccuPre®2x Greenstar qPCR Master mix (Bioneer, Korea) as described previously
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[29]. A standard curve was generated to determine the RBIV major capsid protein (MCP)
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gene copy number by qRT-PCR as described previously [29]. RBIV MCP gene specific
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primer set (F 5’ tgcacaatctagttgaggaggtg 3’ and R 5’ aggcgttccaaaagtcaagg 3’) was used to
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yield 90 bp product, and reaction conditions were similar to those previously described [29].
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The virus copy number was determined from 1 µl of DNA from 100 µl of total DNA that
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was extracted from a whole spleen. The detection limit of RBIV MCP copy number was 1.0
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× 101/µl. The spleen indexes were calculated according to the following formula:
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Spleen index = (Spleen weight (g)/ Fish weight (g)) × 100.
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2.4. Experimental infection at shifted water temperature (group A)
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Fish (11.7 ± 1.7 cm/34.1 ± 2.1 g) were intraperitoneally (i.p.) injected with 100 µl/fish
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containing 1.1 × 107 MCP gene copies. The control group was i.p. injected with 100 µl/fish of
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phosphate-buffered saline (PBS). Each group of fish at 23 °C for 7 (60 fish of group A1), 4
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(80 fish of group A2) and 2 days (80 fish of group A3) was reduced to 17 °C and maintained
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in aquaria containing 250 L of UV-treated seawater. The cumulative mortality of group A1
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has previously published [29]. The overall daily water exchange rate was 10% of system
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volume per day (25 L/day).
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To determine RBIV replication pattern in water temperature shifting group, spleens were
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collected from 5 virus injected fish and 5 control fish at 2, 4, 7, 10, 15, 20, 22, 25, 28, 30, 40,
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50, 60, 70 and 100 days post infection (dpi). Spleens were stored at –80 °C after being flash
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frozen in liquid nitrogen. Table 1 summarizes the experimental conditions.
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2.5. Experimental infection at 17 °C (group B)
To evaluate virus copy number at different time points of RBIV infected fish at 17 °C, 50
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fish in each group (12.0 ± 1.2 cm/35.0 ± 2.8 g) was i.p. injected in the same manner as the
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water temperature shifting group. Control group was i.p. injected with 100 µl/fish of PBS.
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The fish were maintained in aquaria containing 250 L of UV-treated seawater. The overall
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daily water exchange rate was 10% of system volume per day (25 L/day). Spleens were
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collected from 5 virus-injected fish and 5 control fish at 2, 4, 7, 10, 15, 20, 25, 30 and 40 dpi.
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Spleens were stored at –80 °C after being flash frozen in liquid nitrogen. Table 1 summarizes
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the experimental conditions.
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2.6. Influence of increased water temperature on mortality At 70 dpi, survivors were randomly selected from group A1 (5 fish), A2 (10 fish) and A3
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(10 fish), then the water temperature was increased again to the highly susceptible water
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temperature of 26 °C (1 °C/day) to determine whether the virus remaining the can be re-
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activated and cause fish mortality, or whether immunity can supress virus replication in the
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fish body. Those fish were observed for 50 more days (until 120 dpi), and MCP gene copy
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number of all survived fish was analyzed at the end of the experiment at 120 dpi. All fish
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were maintained in aquaria containing 30 L of UV-treated seawater. The overall daily water
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exchange rate was 50% of system volume per day (15 L/day).
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2.7. Ethics statement
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All rock bream experiments were carried out in strict accordance with the
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recommendations of the Institutional Animal Care and Use Committee of Chonnam
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National University (permit number: CNU IACUC-YS-2015-4) .
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3. Results and Discussion
In fixed water temperatures of higher than 23 °C, rock bream mortality was extreme at 100% [21-25]. For this reason, shifting the water temperature from 23 °C to 17 °C was attempted to
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obtain survivors determine the RBIV replication effect on water temperature, and evaluate
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the virus elimination for a recovery stage from RBIV infection. Rock bream infected with
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RBIV and held for 7, 4 and 2 days at 23 °C before the water temperature was reduced to
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17 °C had mortality rates of 28% (group A1), 0% (group A2) and 0% (group A3),
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respectively (Fig. 1). This indicates that the fish mortality by RBIV infection was highly
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dependent on period of exposure days into susceptible water temperature. Although fish
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mortality was observed in only group A1, with 1 fish dying at 24, 25, 26, 27 and 35 dpi (virus
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copy number was 107–108/µl) (Fig. 1 and 3), the fish of groups A2 and A3 had a similar virus
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copy ranges to group A1 (Fig. 2A, 2B and 2C). In groups A1, A2 and A3, the acute stage of
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RBIV infection occurred from 7 to 22 dpi, when virus replication reached its peak at 20 to 22
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dpi (average range of 105–107/µl), then reduced at 25 dpi. Individual differences were high
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between 25 and 30 dpi, with 20 fish exhibiting low virus copy numbers (<103) and 5 fish
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exhibiting high virus copy numbers (>106) (Fig. 2A, 2B and 2C; Supplementary Table 1, 2
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and 3). Between 20 and 25 dpi, important immune responses occurred that determined fish
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survival or death; most of the fish could drastically eliminate the virus from the host body,
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with a few fish that failed to eliminate the virus succumbing to death. Therefore, immune
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responses at approximately 20 to 25 dpi may be important in evaluating factor(s) for survival.
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showed no clinical signs of RBIV and gradual decrease of virus copy numbers (average 107
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reduced to under detection limit level as below 101/µl) (Fig. 2B and 2C). Moreover, our
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results further suggest that reduced virus replication was responsible for the alterations of
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major clinical signs of RBIV infection in fish (i.e. enlarged spleen size) (Supplementary
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Table 1, 2, 3 and 4). Therefore, this time period (30 to 100 dpi) was regarded as a recovery
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stage from infection. RBIV could be eliminated slowly from the fish body, and the virus was
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completely eliminated under the threshold (>101) of causing mortality in group A2 from 100
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dpi and in group A3 from 70 dpi (Fig. 2B and 2C). This observation suggests that the once
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RBIV is replicate at highly susceptible water temperature (over 23 °C); it is difficult to
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inactivate in fish body. However, we found that the virus was inhibited in the fish body when
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fish were first maintained at 23 °C (highly susceptible condition), and then the reduced water
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temperature to 17 °C (non-susceptible condition). Similar to this results, VHSV and hirame
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rhabdovirus (HIRRV)-infected olive flounder (Paralichthys olivaceus) at 20 °C (non-
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susceptible condition) can reduce viral loads in the fish body [30,31]. They observed early
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and effective apoptosis, interferon and inflammatory cytokines-related immune responses at
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20 °C compared to the fish infected at 10 or 15 °C (highly susceptible condition). Thus, we
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hypothesised that rock beam immune responses also regulated by water temperature-
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dependent and activate some unknown factor(s) for inhibition of virus replication. Therefore,
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for the further study, evaluation of antiviral immune responses to inhibit virus replication
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may be necessary to identify important factor(s) for survival and water temperature/virus
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replication-dependent immune defence mechanism in rock bream that recover from RBIV.
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This study showed that when the virus copy levels were stable at 70 dpi in group A2 and A3
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(1.68 × 102 and 4.28 × 100/µl, respectively) (Fig. 2B and 2C), all surviving fish (5 fish of
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water temperature of 17 °C, which was then increased from 17 °C to 26 °C, and they did not
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show any mortality or clinical signs of disease (Fig. 1) and had low virus copy numbers
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(below 102 at 120 dpi) (Fig. 3). Our previous study reported that almost all surviving RBIV-
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infected fish obtained by water temperature shifting (23 °C to 17 °C) that were re-exposed at
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the highly susceptible water temperature of 26 °C at 100 dpi (average virus copy number at
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2.7 × 102/µl) survived until 50 days post increasing water temperature [21]. However, the risk
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of reoccurrence and mortality remained, although the possibility is very low. Thus, in this
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study, to determine whether the remaining virus in the fish can be re-activated and cause fish
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mortality, a time point 30 days earlier than that of the previous experiment was chosen.
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Therefore, at 70 dpi, the virus copy number at 1.68 × 102 and 4.28 × 100/µl in group A2 and
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A3, respectively, was a minimal and once the number of virus decrease below the threshold
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to cause mortality, there is a lower possibility of fish mortality occurring in susceptible water
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temperatures of 26 °C. This suggests that 70 days is sufficient to eradicate RBIV from the
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fish body. Further, it could suggest that fish need at least 50 days from the peak virus level
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(approximately 20 to 25 dpi) to avoid re-activation of the virus, thus completely eliminating it
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from the fish’s body. Hereby we suggest monitoring of the viral load in the fish body post
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recovery from RBIV infection in rock bream farms, as the RBIV may exist in latent form in
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the fish’s body for more than 50 days.
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On the other hand, fish exposed to virus at the susceptible water temperature of 23 °C for a
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short period (7, 4 and 2 days) followed by exposure at 17 °C for a longer period in modulated
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water temperature groups, high virus replication (around 105–107/µl) was maintained until 20
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to 25 dpi because RBIV can replicate slowly in fish body at the non-susceptible water
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temperature of 17 °C. At 17 °C, the virus copy number was still relatively high at 20, 25 and
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numbers at 40 dpi (average 5.34 × 101/µl) (Fig. 2D). This was evident from the previous
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report in which rock bream that did not die at non-susceptible water temperature of 13 °C, all
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fish died as a result of RBIV when the water temperature raised from 13 °C to 25 °C, after
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maintaining for 30 dpi at 13 °C [23]. This observation suggest that even though rock bream
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did not die at 13 °C, the virus load is still high at 30 dpi and the remaining virus may re-
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active, causing mortality. This indicates that the RBIV could replicate slowly in fish body
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even at low water temperature including non-mortality conditions (13 and 17 °C). This might
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be the main reason for the mass mortality in rock bream aquaculture industry due to RBIV
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infection.
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4. Conclusions
In the present study, elimination of the virus from fish body by shifting the water
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temperature at 23 °C to a non-susceptible water temperature at 17 °C after RBIV infection
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was shown. However, fish need at least 50 days from peaked RBIV level (around 20 to 25
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dpi) to not to reactivate the virus. This suggests that RBIV could be eliminated slowly from
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the fish body and virus will be completely eliminated below the threshold of causing
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mortality. Additionally, previously activated RBIV was not easily inactivated in the fish body
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because it has very strong pathogenicity against host fish, as evidenced by this long
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experimental schedule.
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Acknowledgements
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This research was a part of the project titles ‘Fish Vaccine Research Center’, funded by the
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Ministry of Oceans and Fisheries, Korea.
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ACCEPTED MANUSCRIPT References
261
[1] T. Williams, The iridoviruses, Adv. Virus. Res. 46 (1996) 345–412.
262
[2] K. Inouye, K. Yamano, Y. Maeno, K. Nakajima, M. Matsuoka, Y. Wada, et al.,
263
Iridovirus infection of cultured red sea bream, Pagrus major, Fish. Pathol. 27 (1992) 19–
264
27.
266
[3] K. Nakajima, M. Sorimachi, Biological and physico-chemical properties of the iridovirus isolated from cultured red sea bream, Pagrus major, Fish. Pathol. 29 (1994) 29–33.
SC
265
RI PT
260
[4] F.H.C. Chua, M.L. Ng, K.L. Ng, J.J. Loo, J.Y. Wee, Investigation of outbreaks of a novel
268
disease, ‘Sleepy Grouper Disease’ affecting the brown-spotted grouper, Epinephelus
269
tauvina Forskal, J. Fish. Dis. 17 (1994) 417–427.
271 272 273
[5] S. Matsuoke, K. Inouye, K. Nakajima, Cultured fish species affected by red sea bream iridoviral disease from 1991 to 1995, Fish. Pathol. 31 (1996) 233–234. [6] M. Miyata, K. Matsuno, S.J. Jung, Y. Danayadol, T. Miyazaki, Genetic similarity of iridoviruses from Japan and Thailand, J. Fish. Dis. 20 (1997) 127–134.
TE D
270
M AN U
267
[7] H.Y. Chou, C.C. Hsu, T.Y. Peng, Isolation and characterization of a pathogenic
275
iridovirus from cultured grouper (Epinephelus sp.) in Taiwan, Fish. Pathol. 33 (1998)
276
201–206.
EP
274
[8] J.W. Do, S.J. Cha, J.S. Kim, E.J. An, N.S. Lee, H.J. Choi, et al., Phylogenetic analysis of
278
the major capsid protein gene of iridovirus isolates from cultured flounders Paralichthys
279
olivaceus in Korea, Dis. Aquat. Organ. 64 (2005) 193–200.
AC C
277
280
[9] W.S. Kim, M.J. Oh, S.J. Jung, Y.J. Kim, S.I. Kitamura, Characterization of an iridovirus
281
detected from cultured turbot Scophthalmus maximus in Korea, Dis. Aquat. Organ. 64
282
(2005) 175–180.
12
ACCEPTED MANUSCRIPT 283
[10] S.J. Jung, M.J. Oh, Iridovirus-like infection associated with high mortalities of striped
284
beakperch, Oplegnathus fasciatus (Temminck et Schlegel), in southern coastal areas of
285
the Korean peninsula, J. Fish. Dis. 23 (2000) 223–226. [11] J. Kurita, K. Nakajima, Megalocytiviruses, Viruses 4 (2012) 521–538.
287
[12] D.F. Amend, Control of infectious hematopoietic necrosis virus disease by elevating the
288
RI PT
286
water temperature. J. Fish. Res. Board. Can. 27 (1970) 265–270.
[13] F.M. Hetrick, J.L. Fryer, M.D. Knittel, Effect of water temperature on the infection of
290
rainbow trout Salmo gairdneri Richardson with infectious haematopoietic necrosis virus,
291
J. Fish. Dis. 2 (1979) 253–257.
293
[14] P.E.V. Jørgensen, Egtved virus: temperature‐dependent immune response of trout to
M AN U
292
SC
289
infection with low‐virulence virus, J. Fish. Dis. 5 (1982) 47–55. [15] T. Kobayashi, T. Shiino, T. Miyazaki, The effect of water temperature on rhabdoviral
295
dermatitis in the Japanese eel, Anguilla japonica Temminck and Schlegel, Aquaculture
296
170 (1999) 7–15.
297 298
TE D
294
[16] W. Ahne, H.V. Bjorklund, S. Essbauer, N. Fijan, G. Kurath, J.R. Winton, Spring viremia of carp (SVC), Dis. Aquat. Org. 52 (2002) 261–272. [17] J.G. He, K. Zeng, S.P. Weng, S.M. Chan, Experimental transmission, pathogenicity and
300
physical–chemical properties of infectious spleen and kidney necrosis virus (ISKNV),
301
Aquaculture 204 (2002) 11–24.
AC C
EP
299
302
[18] O. Gilad, S. Yun, M.A. Adkison, K. Way, N.H. Willits, H. Bercovier, et al., Molecular
303
comparison of isolates of an emerging fish pathogen, koi herpesvirus, and the effect of
304
water temperature on mortality of experimentally infected koi, J. Gen. Virol. 84 (2003)
305
2661–2668.
13
ACCEPTED MANUSCRIPT 306
[19] M. Sano, T. Ito, T. Matsuyama, C. Nakayasu, J. Kurita, Effect of water temperature
307
shifting on mortality of Japanese flounder Paralichthys olivaceus experimentally infected
308
with viral hemorrhagic septicemia virus, Aquaculture 286 (2009) 254–258. [20] A.E. Goodwin, G.E. Merry, Mortality and carrier status of bluegills exposed to viral
310
hemorrhagic septicemia virus genotype IVb at different temperatures, J. Aquat. Anim.
311
Health. 23 (2011) 85–91.
RI PT
309
[21] M.H. Jung, S.J. Jung, T.N. Vinay, C. Nikapitiya, J.O. Kim, J.H. Lee, et al., Effects of
313
water temperature on mortality in Megalocytivirus-infected rock bream Oplegnathus
314
fasciatus (Temminck et Schlegel) and development of protective immunity, J. Fish. Dis.
315
38 (2015) 729–737.
M AN U
SC
312
316
[22] M.H. Jung, J. Lee, S.J. Jung, Low pathogenicity of FLIV (flounder iridovirus) and the
317
absence of cross-protection between FLIV and RBIV (rock bream iridovirus), J. Fish. Dis.
318
39 (2016) 1325–1333.
[23] L.J. Jun, J.B. Jeong, J.H. Kim, J.H. Nam, K.W. Shin, J.K Kim, et al., Influence of
320
temperature shifts on the onset and development of red sea bream iridoviral disease in
321
rock bream Oplegnathus fasciatus, Dis. Aquat. Org. 84 (2009) 201–208.
TE D
319
[24] M.H. Jung, J. Lee, M. Ortega-Villaizan, L. Perez, S.J. Jung, Protective immunity against
323
Megalocytivirus infection in rock bream (Oplegnathus fasciatus) following CpG ODN
324
administration, Vaccine 35 (2017) 3691–3699.
AC C
EP
322
325
[25] M.H. Jung, S.J. Jung, Protective immunity against rock bream iridovirus (RBIV)
326
infection and TLR3-mediated type I interferon signaling pathway in rock bream
327
(Oplegnathus fasciatus) following poly (I:C) administration, Fish. Shellfish Immunol. 67
328
(2017) 293–301.
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[26] T. Nishizawa, I. Takami, M.J. Yang, M.J. Oh, Live vaccine of viral hemorrhagic
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septicemia virus (VHSV) for Japanese flounder at fish rearing temperature of 21 °C
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instead of Poly (I: C) administration, Vaccine 29 (2011) 8397–8404. [27] T. Nishizawa, H.J. Gye, I. Takami, M.J. Oh, Potentiality of a live vaccine with nervous
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necrosis virus (NNV) for sevenband grouper Epinephelus septemfasciatus at a low
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rearing temperature, Vaccine 30 (2012) 1056–1063.
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[28] M.J. Oh, H.J. Gye, T. Nishizawa, Assessment of the sevenband grouper Epinephelus
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septemfasciatus with a live nervous necrosis virus (NNV) vaccine at natural seawater
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temperature, Vaccine 31 (2013) 2025–2027.
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[29] M.H. Jung, C. Nikapitiya, J.Y. Song, J.H. Lee, J. Lee, M.J. Oh, et al., Gene expression
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of pro- and anti-apoptotic proteins in rock bream (Oplegnathus fasciatus) infected with
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Megalocytivirus (family Iridoviridae), Fish. Shellfish Immunol. 37 (2014) 122–130.
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[30] J. Zhang, X. Tang, X. Sheng, J. Xing, W. Zhan, The influence of temperature on viral
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replication and antiviral-related genes response in hirame rhabdovirus-infected flounder
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(Paralichthys olivaceus), Fish. Shellfish Immunol. 68 (2017) 260–265.
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[31] S. Avunje, W.S. Kim, M.J. Oh, I. Choi, S.J. Jung, Temperature-dependent viral
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replication and antiviral apoptotic response in viral haemorrhagic septicaemia virus
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(VHSV)-infected olive flounder (Paralichthys olivaceus), Fish. Shellfish Immunol. 32
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(2012) 1162–1170.
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Fig. 1. Cumulative mortality of rock bream intraperitoneally (i.p.) injected with 1.1 × 107
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MCP gene copy/fish of RBIV at 23 °C, with the water temperature reduced to 17 °C at 7, 4
355
and 2 dpi (2 °C/day). Cumulative mortality was calculated using the formula [number of dead
356
fish/fish population parameter × 100]. All surviving fish were subjected to water temperature
357
increase (1 °C/day) up to 26 °C at 70 dpi (arrows). The cumulative mortality of group A1 (7
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day) previously published [29] is shown for reference.
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Fig. 2. Absolute virus copy number of rock bream by different water temperature condition
361
after 1.1 × 107 MCP gene copy/fish of RBIV was injected intraperitoneally (i.p.). (A) Fish
362
were injected at 23 °C, and the water temperature was reduced to 17 °C at 7 dpi (2 °C/day).
363
(B) Fish were injected at 23 °C, and the water temperature was reduced to 17 °C at 4 dpi
364
(2 °C/day). Virus copy number and spleen index for 2 and 4 dpi were ploted using the Fig.
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2A. (C) Fish were injected at 23 °C, and the water temperature was reduced to 17 °C at 2 dpi
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(2 °C/day). Virus copy number and spleen index for 2 dpi were plotted using the Fig. 2A. (D)
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Fish were injected at 17 °C.
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Fig. 3. The MCP gene copies of all dead fish from the group A1 (23 °C reduced to 17 °C at 7
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dpi) and the MCP gene copies in all rock bream survivors from group A1 (23 °C reduced to
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17 °C at 7 dpi), A2 (23 °C reduced to 17 °C at 4 dpi) and A3 (23 °C reduced to 17 °C at 2 dpi)
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are shown. RBIV MCP copy number was 1.0 × 101/µl can be regarded as negative.
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Table 1 Experimental details of artificial infection
A1 (23 °C reduced to 17 °Cat 7 dpi)
Infection dose /fish 1.1 × 107/fish 7
No. of fish 60
2, 4, 7, 10, 15, 20, 22, 25, 28 and 30 dpi
Sampling point
Mortality (%)
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Group
28
1.1 × 10 /fish
80
7, 10, 15, 20, 25, 30, 40, 50, 60, 70 and 100 dpi
0
A3 (23 °C reduced to 17 °Cat 2 dpi)
1.1 × 107/fish
80
7, 10, 15, 20, 25, 30, 40, 50, 60, 70 and 100 dpi
0
B (17 °C)
1.1 × 107/fish
50
2, 4, 7, 10, 15, 20, 25, 30 and 40 dpi
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dpi: days post infection
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A2 (23 °C reduced to 17 °Cat 4 dpi)
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Water temperature shifting group (23 °C reduced to 17 °C) 80
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A1 (reduced to 17 °C at 7 dpi) A2 (reduced to 17 °C at 4 dpi)
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A3 (reduced to 17 °C at 2 dpi)
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30
40
50
60 70 Days post infection
80
90
100
110
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raised to 26 °C
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Cumulative mortality %
100
Fig 1
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A
10
Virus copy number
Virus copy number
10 9
10 9 10 8
10 7 10 6 10 5 4
10 3 10 2
10 5 10 4 10 3
10 0 2d
4d
7d
10d
15d
20d
22d
25d
28d
30d
Days post infection
C
10 1
2d
EP
10 8 10 7
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10 6 10 5 10 4 10 3
10
10 2
7d
10d
15d
20d
25d
30d
40d
50d
60d
70d 100d
Days post infection
Group B (17 °C)
10
Virus copy number 10 9 10 8
Absolute viral copy number
lethal
4d
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Virus copy number 9
detection limit
10 0
Group A3 (23 °C reduced to 17 °C at 2 dpi)
10
10
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detection limit
Absolute viral copy number
10 6
10 2
10 1
10
lethal 10 7
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lethal Absolute viral copy number
Absolute virus copy number
10 8
10
Group A2 (23°C reduced to 17°C at 4 dpi)
10
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10
B
Group A1 (23 °C reduced to 17 °C at 7 dpi)
10
lethal 10 7 10 6 10 5 10 4 10 3 10 2
10 1
10 1
detection limit
detection limit
10 0 2d
7d
10d
15d
20d
25d
30d
40d
Days post infection
50d
60d
70d
100d
10 0 2d
4d
7d
10d
15d
20d
Days post infection
25d
30d
40d
Fig 2
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10 1 0
Dead fish
lethal virus copy number
10 8
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10 7 10 6 10 5 10 4
Survived fish
10 1 10 0
detection limit
Group A1 (23°C for 7 d → 17°C)
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10 2
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10 3
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Absolute virus copy number
10 9
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MCP copy number in dead or survived fish
Group A1 Group A2 (23°C for 7 d (23°C for 4 d → 17°C) → 17°C)
Group A3 (23°C for 2 d → 17°C)
Groups
Fig 3
ACCEPTED MANUSCRIPT Highlights Shifting water temperature inhibited RBIV replication in rock bream. Fish mortality and virus copy number were highly dependent on period of exposure
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days at susceptible water temperatures. Virus completely eliminated under the threshold of causing mortality at the late stage.
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Fish need at least 50 days from peaked virus level to avoid re-activation of the virus.
S1050-4648(17)30557-0
DOI:
10.1016/j.fsi.2017.09.038
Reference:
YFSIM 4828
To appear in:
Fish and Shellfish Immunology
Received Date: 5 June 2017 Revised Date:
23 August 2017
Accepted Date: 14 September 2017
Please cite this article as: Jung M-H, Nikapitiya C, Vinay T-N, Lee J, Jung S-J, Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus) exposed for different time periods to susceptible water temperatures, Fish and Shellfish Immunology (2017), doi: 10.1016/j.fsi.2017.09.038. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1
Rock bream iridovirus (RBIV) replication in rock bream (Oplegnathus fasciatus)
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exposed for different time periods to susceptible water temperatures
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Myung-Hwa Jung a, Chamilani Nikapitiya b, Tharabenahalli-Nagaraju Vinay c, Jehee Lee b,
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Sung-Ju Jung a,*
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a
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b
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c
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Department of Aqualife Medicine, Chonnam National University, Republic of Korea.
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Department of Marine Life Sciences, Jeju National University, Republic of Korea.
ICAR-Indian Institute of Agricultural Biotechnology, India.
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*Corresponding author at: Department of Aqualife Medicine, Chonnam National University,
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San 96-1 Dunduck Dong, Yeosu, Jeonnam 550-749 Republic of Korea
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Tel.: +82-61-659-7175
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Fax: +82-61-659-7179
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E-mail address: [email protected] (S.-J. Jung).
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ACCEPTED MANUSCRIPT Abstract
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Rock bream iridovirus (RBIV) is a member of the Megalocytivirus genus that causes severe
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mortality to rock bream. Water temperature is known to affect the immune system and
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susceptibility of fish to RBIV infection. In this study, we evaluated the time dependent virus
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replication pattern and time required to completely eliminate virus from the rock bream body
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against RBIV infection at different water temperature conditions. The rock bream was
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exposed to the virus and held at 7 (group A1), 4 (group A2) and 2 days (group A3) at 23 °C
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before the water temperature was reduced to 17 °C. A total of 28% mortality was observed 24
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to 35 days post infection (dpi) in only the 7 day exposure group at 23 °C. In all 23°C
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exposure groups, virus replication peaked at 20 to 22 dpi (106–107/µl). In recovery stages (30
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to 100 dpi), the virus copy number was gradually reduced, from 106 to 101 with faster
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decreases in the shorter exposure period group at 23 °C. When the water temperature was
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increased in surviving fish from 17 to 26 °C at 70 dpi, they did not show any mortality or
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signs of disease and had low virus copy numbers (below 102/µl). Thus, fish need at least 50
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days from peaked RBIV levels (approximately 20 to 25 dpi) to inhibit the virus. This
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indicates that maintaining the fish at low water temperature (17 °C) for 70 days is sufficient
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to eradicate RBIV from fish body. Thus, RBIV could be eliminated slowly from the fish body
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and the virus may be completely eliminated under the threshold of causing mortality.
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Key word: rock bream iridovirus, rock bream, virus replication, eliminate of virus, water
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temperature
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1. Introduction Iridoviridae is a family of large double-stranded DNA virus (120–300 nm) with an
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icosahedral morphology [1]. The family includes five genera: Iridovirus, Chloriridovirus,
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Ranavirus, Lymphocystivirus and Megalocytivirus. Megalocytiviruses have been the cause of
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disease in >50 fish species and currently threaten the aquaculture industry, causing great
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economic losses in Korea, Japan, China and Southeast Asia [2-10]. Rock bream iridovirus
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(RBIV), which belongs to the genus Megalocytivirus [11] remains an important health
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problem in rock bream (Oplegnathus fasciatus).
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Water temperature is known to affect the immune system and susceptibility of fish to virus
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infection [12-20]. In Korea, RBIV outbreaks typically occur in cultured rock bream from
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August to September, when water temperature between 23 and 27 °C [10]. Recently, several
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studies have demonstrated a clear correlation between mortality and the water temperature
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against RBIV infection in rock bream; i) rock bream injected with RBIV and held at 29, 26,
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25, 23, 21, 20 or 18 °C had 100% mortality, but no mortality at 17 or 13 °C [21-25], ii)
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mortality due to RBIV in rock bream at 23 °C could be controlled by reducing water
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temperature to 17 °C during very early stages of infection [21]. Furthermore, it was observed
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that the survivors of high virus dose injections in rock bream gained protective immunity.
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Thus, water temperature plays a critical role not only for mortality, but also to obtain the
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protective immunity in rock bream against RBIV infection.
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Several other experimental studies on fish viral diseases have demonstrated the effect of
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water temperature regulations on protective immunity of survivors against infectious
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haematopoietic necrosis virus (IHNV), koi herpesvirus (KHV), viral haemorrhagic
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septicaemia virus (VHSV) and nervous necrosis virus (NNV) [12,18,19,26,27]. Recent
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studies reported the long-term kinetics of NNV infectivity in sevenband grouper, injected
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with a live NNV at 17.3 °C and reared at natural seawater temperature [28]. The NNV
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107.43±0.35TCID50/g. However, NNV was under the detection limit (≤102.8TCID50/g) between
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42 and 128 days; hence, it was suggested that fish need at least 42 days from initial infection
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to inhibit the active virus, thus completely eliminating it from their body. Therefore,
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identifying a time period in which the virus has been completely eliminated from the fish’s
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body to prevent the mortality due to viral infection is essential. However, the time-dependent
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virus replication pattern and time required to completely eliminate the virus from the fish’s
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body has not been demonstrated in rock bream against RBIV infection.
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In the present study, RBIV was artificially infected to rock bream at different water
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temperature conditions, and the virus replication pattern was evaluated in the rock bream
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from 2 to 100 days post infection (dpi) to determine the influence of water temperature on
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RBIV replication. Additionally, time points/period in which the virus was completely
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eliminated from survivors due to RBIV infection were investigated.
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2. Materials and Methods
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2.1. Experimental fish
RBIV free rock bream were obtained from a local farm and reared at the Fisheries Science
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Institute at Chonnam National University. Approximately 500 fish (7.4 ± 1.0 cm/9.1 ± 1.3 g)
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were maintained in large tanks (10 ton) with a continuous seawater supply with aeration. The
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required number of fish for the experiments was transferred to the experimental infection
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facility.
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2.2. Source of RBIV The virus used in the present study was originally isolated from RBIV infected rock bream in 2010 as explained earlier [29].
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2.3. Determination of viral copy number in the spleen and spleen index For the analysis of the RBIV copy number, the spleen was obtained from RBIV infected
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fish at several sampling points. Genomic DNA was isolated from the whole spleen (20–150
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mg) of each fish using an AccuPrep®Genomic DNA extraction kit (Bioneer, Korea)
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according to the manufacturer’s instructions. Real-time polymerase chain reaction (PCR)
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was carried out in an Exicycler 96 Real-Time Quantitative Thermal Block (Bioneer, Korea)
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using an AccuPre®2x Greenstar qPCR Master mix (Bioneer, Korea) as described previously
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[29]. A standard curve was generated to determine the RBIV major capsid protein (MCP)
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gene copy number by qRT-PCR as described previously [29]. RBIV MCP gene specific
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primer set (F 5’ tgcacaatctagttgaggaggtg 3’ and R 5’ aggcgttccaaaagtcaagg 3’) was used to
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yield 90 bp product, and reaction conditions were similar to those previously described [29].
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The virus copy number was determined from 1 µl of DNA from 100 µl of total DNA that
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was extracted from a whole spleen. The detection limit of RBIV MCP copy number was 1.0
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× 101/µl. The spleen indexes were calculated according to the following formula:
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Spleen index = (Spleen weight (g)/ Fish weight (g)) × 100.
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2.4. Experimental infection at shifted water temperature (group A)
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Fish (11.7 ± 1.7 cm/34.1 ± 2.1 g) were intraperitoneally (i.p.) injected with 100 µl/fish
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containing 1.1 × 107 MCP gene copies. The control group was i.p. injected with 100 µl/fish of
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phosphate-buffered saline (PBS). Each group of fish at 23 °C for 7 (60 fish of group A1), 4
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(80 fish of group A2) and 2 days (80 fish of group A3) was reduced to 17 °C and maintained
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in aquaria containing 250 L of UV-treated seawater. The cumulative mortality of group A1
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has previously published [29]. The overall daily water exchange rate was 10% of system
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volume per day (25 L/day).
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To determine RBIV replication pattern in water temperature shifting group, spleens were
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collected from 5 virus injected fish and 5 control fish at 2, 4, 7, 10, 15, 20, 22, 25, 28, 30, 40,
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50, 60, 70 and 100 days post infection (dpi). Spleens were stored at –80 °C after being flash
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frozen in liquid nitrogen. Table 1 summarizes the experimental conditions.
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2.5. Experimental infection at 17 °C (group B)
To evaluate virus copy number at different time points of RBIV infected fish at 17 °C, 50
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fish in each group (12.0 ± 1.2 cm/35.0 ± 2.8 g) was i.p. injected in the same manner as the
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water temperature shifting group. Control group was i.p. injected with 100 µl/fish of PBS.
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The fish were maintained in aquaria containing 250 L of UV-treated seawater. The overall
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daily water exchange rate was 10% of system volume per day (25 L/day). Spleens were
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collected from 5 virus-injected fish and 5 control fish at 2, 4, 7, 10, 15, 20, 25, 30 and 40 dpi.
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Spleens were stored at –80 °C after being flash frozen in liquid nitrogen. Table 1 summarizes
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the experimental conditions.
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2.6. Influence of increased water temperature on mortality At 70 dpi, survivors were randomly selected from group A1 (5 fish), A2 (10 fish) and A3
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(10 fish), then the water temperature was increased again to the highly susceptible water
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temperature of 26 °C (1 °C/day) to determine whether the virus remaining the can be re-
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activated and cause fish mortality, or whether immunity can supress virus replication in the
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fish body. Those fish were observed for 50 more days (until 120 dpi), and MCP gene copy
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number of all survived fish was analyzed at the end of the experiment at 120 dpi. All fish
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were maintained in aquaria containing 30 L of UV-treated seawater. The overall daily water
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exchange rate was 50% of system volume per day (15 L/day).
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2.7. Ethics statement
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All rock bream experiments were carried out in strict accordance with the
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recommendations of the Institutional Animal Care and Use Committee of Chonnam
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National University (permit number: CNU IACUC-YS-2015-4) .
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3. Results and Discussion
In fixed water temperatures of higher than 23 °C, rock bream mortality was extreme at 100% [21-25]. For this reason, shifting the water temperature from 23 °C to 17 °C was attempted to
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obtain survivors determine the RBIV replication effect on water temperature, and evaluate
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the virus elimination for a recovery stage from RBIV infection. Rock bream infected with
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RBIV and held for 7, 4 and 2 days at 23 °C before the water temperature was reduced to
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17 °C had mortality rates of 28% (group A1), 0% (group A2) and 0% (group A3),
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respectively (Fig. 1). This indicates that the fish mortality by RBIV infection was highly
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dependent on period of exposure days into susceptible water temperature. Although fish
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mortality was observed in only group A1, with 1 fish dying at 24, 25, 26, 27 and 35 dpi (virus
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copy number was 107–108/µl) (Fig. 1 and 3), the fish of groups A2 and A3 had a similar virus
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copy ranges to group A1 (Fig. 2A, 2B and 2C). In groups A1, A2 and A3, the acute stage of
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RBIV infection occurred from 7 to 22 dpi, when virus replication reached its peak at 20 to 22
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dpi (average range of 105–107/µl), then reduced at 25 dpi. Individual differences were high
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between 25 and 30 dpi, with 20 fish exhibiting low virus copy numbers (<103) and 5 fish
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exhibiting high virus copy numbers (>106) (Fig. 2A, 2B and 2C; Supplementary Table 1, 2
167
and 3). Between 20 and 25 dpi, important immune responses occurred that determined fish
168
survival or death; most of the fish could drastically eliminate the virus from the host body,
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with a few fish that failed to eliminate the virus succumbing to death. Therefore, immune
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responses at approximately 20 to 25 dpi may be important in evaluating factor(s) for survival.
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showed no clinical signs of RBIV and gradual decrease of virus copy numbers (average 107
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reduced to under detection limit level as below 101/µl) (Fig. 2B and 2C). Moreover, our
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results further suggest that reduced virus replication was responsible for the alterations of
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major clinical signs of RBIV infection in fish (i.e. enlarged spleen size) (Supplementary
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Table 1, 2, 3 and 4). Therefore, this time period (30 to 100 dpi) was regarded as a recovery
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stage from infection. RBIV could be eliminated slowly from the fish body, and the virus was
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completely eliminated under the threshold (>101) of causing mortality in group A2 from 100
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dpi and in group A3 from 70 dpi (Fig. 2B and 2C). This observation suggests that the once
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RBIV is replicate at highly susceptible water temperature (over 23 °C); it is difficult to
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inactivate in fish body. However, we found that the virus was inhibited in the fish body when
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fish were first maintained at 23 °C (highly susceptible condition), and then the reduced water
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temperature to 17 °C (non-susceptible condition). Similar to this results, VHSV and hirame
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rhabdovirus (HIRRV)-infected olive flounder (Paralichthys olivaceus) at 20 °C (non-
185
susceptible condition) can reduce viral loads in the fish body [30,31]. They observed early
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and effective apoptosis, interferon and inflammatory cytokines-related immune responses at
187
20 °C compared to the fish infected at 10 or 15 °C (highly susceptible condition). Thus, we
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hypothesised that rock beam immune responses also regulated by water temperature-
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dependent and activate some unknown factor(s) for inhibition of virus replication. Therefore,
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for the further study, evaluation of antiviral immune responses to inhibit virus replication
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may be necessary to identify important factor(s) for survival and water temperature/virus
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replication-dependent immune defence mechanism in rock bream that recover from RBIV.
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This study showed that when the virus copy levels were stable at 70 dpi in group A2 and A3
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(1.68 × 102 and 4.28 × 100/µl, respectively) (Fig. 2B and 2C), all surviving fish (5 fish of
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196
water temperature of 17 °C, which was then increased from 17 °C to 26 °C, and they did not
197
show any mortality or clinical signs of disease (Fig. 1) and had low virus copy numbers
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(below 102 at 120 dpi) (Fig. 3). Our previous study reported that almost all surviving RBIV-
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infected fish obtained by water temperature shifting (23 °C to 17 °C) that were re-exposed at
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the highly susceptible water temperature of 26 °C at 100 dpi (average virus copy number at
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2.7 × 102/µl) survived until 50 days post increasing water temperature [21]. However, the risk
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of reoccurrence and mortality remained, although the possibility is very low. Thus, in this
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study, to determine whether the remaining virus in the fish can be re-activated and cause fish
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mortality, a time point 30 days earlier than that of the previous experiment was chosen.
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Therefore, at 70 dpi, the virus copy number at 1.68 × 102 and 4.28 × 100/µl in group A2 and
206
A3, respectively, was a minimal and once the number of virus decrease below the threshold
207
to cause mortality, there is a lower possibility of fish mortality occurring in susceptible water
208
temperatures of 26 °C. This suggests that 70 days is sufficient to eradicate RBIV from the
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fish body. Further, it could suggest that fish need at least 50 days from the peak virus level
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(approximately 20 to 25 dpi) to avoid re-activation of the virus, thus completely eliminating it
211
from the fish’s body. Hereby we suggest monitoring of the viral load in the fish body post
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recovery from RBIV infection in rock bream farms, as the RBIV may exist in latent form in
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the fish’s body for more than 50 days.
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On the other hand, fish exposed to virus at the susceptible water temperature of 23 °C for a
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short period (7, 4 and 2 days) followed by exposure at 17 °C for a longer period in modulated
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water temperature groups, high virus replication (around 105–107/µl) was maintained until 20
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to 25 dpi because RBIV can replicate slowly in fish body at the non-susceptible water
218
temperature of 17 °C. At 17 °C, the virus copy number was still relatively high at 20, 25 and
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numbers at 40 dpi (average 5.34 × 101/µl) (Fig. 2D). This was evident from the previous
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report in which rock bream that did not die at non-susceptible water temperature of 13 °C, all
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fish died as a result of RBIV when the water temperature raised from 13 °C to 25 °C, after
223
maintaining for 30 dpi at 13 °C [23]. This observation suggest that even though rock bream
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did not die at 13 °C, the virus load is still high at 30 dpi and the remaining virus may re-
225
active, causing mortality. This indicates that the RBIV could replicate slowly in fish body
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even at low water temperature including non-mortality conditions (13 and 17 °C). This might
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be the main reason for the mass mortality in rock bream aquaculture industry due to RBIV
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infection.
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4. Conclusions
In the present study, elimination of the virus from fish body by shifting the water
232
temperature at 23 °C to a non-susceptible water temperature at 17 °C after RBIV infection
233
was shown. However, fish need at least 50 days from peaked RBIV level (around 20 to 25
234
dpi) to not to reactivate the virus. This suggests that RBIV could be eliminated slowly from
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the fish body and virus will be completely eliminated below the threshold of causing
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mortality. Additionally, previously activated RBIV was not easily inactivated in the fish body
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because it has very strong pathogenicity against host fish, as evidenced by this long
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experimental schedule.
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Acknowledgements
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This research was a part of the project titles ‘Fish Vaccine Research Center’, funded by the
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Ministry of Oceans and Fisheries, Korea.
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ACCEPTED MANUSCRIPT References
261
[1] T. Williams, The iridoviruses, Adv. Virus. Res. 46 (1996) 345–412.
262
[2] K. Inouye, K. Yamano, Y. Maeno, K. Nakajima, M. Matsuoka, Y. Wada, et al.,
263
Iridovirus infection of cultured red sea bream, Pagrus major, Fish. Pathol. 27 (1992) 19–
264
27.
266
[3] K. Nakajima, M. Sorimachi, Biological and physico-chemical properties of the iridovirus isolated from cultured red sea bream, Pagrus major, Fish. Pathol. 29 (1994) 29–33.
SC
265
RI PT
260
[4] F.H.C. Chua, M.L. Ng, K.L. Ng, J.J. Loo, J.Y. Wee, Investigation of outbreaks of a novel
268
disease, ‘Sleepy Grouper Disease’ affecting the brown-spotted grouper, Epinephelus
269
tauvina Forskal, J. Fish. Dis. 17 (1994) 417–427.
271 272 273
[5] S. Matsuoke, K. Inouye, K. Nakajima, Cultured fish species affected by red sea bream iridoviral disease from 1991 to 1995, Fish. Pathol. 31 (1996) 233–234. [6] M. Miyata, K. Matsuno, S.J. Jung, Y. Danayadol, T. Miyazaki, Genetic similarity of iridoviruses from Japan and Thailand, J. Fish. Dis. 20 (1997) 127–134.
TE D
270
M AN U
267
[7] H.Y. Chou, C.C. Hsu, T.Y. Peng, Isolation and characterization of a pathogenic
275
iridovirus from cultured grouper (Epinephelus sp.) in Taiwan, Fish. Pathol. 33 (1998)
276
201–206.
EP
274
[8] J.W. Do, S.J. Cha, J.S. Kim, E.J. An, N.S. Lee, H.J. Choi, et al., Phylogenetic analysis of
278
the major capsid protein gene of iridovirus isolates from cultured flounders Paralichthys
279
olivaceus in Korea, Dis. Aquat. Organ. 64 (2005) 193–200.
AC C
277
280
[9] W.S. Kim, M.J. Oh, S.J. Jung, Y.J. Kim, S.I. Kitamura, Characterization of an iridovirus
281
detected from cultured turbot Scophthalmus maximus in Korea, Dis. Aquat. Organ. 64
282
(2005) 175–180.
12
ACCEPTED MANUSCRIPT 283
[10] S.J. Jung, M.J. Oh, Iridovirus-like infection associated with high mortalities of striped
284
beakperch, Oplegnathus fasciatus (Temminck et Schlegel), in southern coastal areas of
285
the Korean peninsula, J. Fish. Dis. 23 (2000) 223–226. [11] J. Kurita, K. Nakajima, Megalocytiviruses, Viruses 4 (2012) 521–538.
287
[12] D.F. Amend, Control of infectious hematopoietic necrosis virus disease by elevating the
288
RI PT
286
water temperature. J. Fish. Res. Board. Can. 27 (1970) 265–270.
[13] F.M. Hetrick, J.L. Fryer, M.D. Knittel, Effect of water temperature on the infection of
290
rainbow trout Salmo gairdneri Richardson with infectious haematopoietic necrosis virus,
291
J. Fish. Dis. 2 (1979) 253–257.
293
[14] P.E.V. Jørgensen, Egtved virus: temperature‐dependent immune response of trout to
M AN U
292
SC
289
infection with low‐virulence virus, J. Fish. Dis. 5 (1982) 47–55. [15] T. Kobayashi, T. Shiino, T. Miyazaki, The effect of water temperature on rhabdoviral
295
dermatitis in the Japanese eel, Anguilla japonica Temminck and Schlegel, Aquaculture
296
170 (1999) 7–15.
297 298
TE D
294
[16] W. Ahne, H.V. Bjorklund, S. Essbauer, N. Fijan, G. Kurath, J.R. Winton, Spring viremia of carp (SVC), Dis. Aquat. Org. 52 (2002) 261–272. [17] J.G. He, K. Zeng, S.P. Weng, S.M. Chan, Experimental transmission, pathogenicity and
300
physical–chemical properties of infectious spleen and kidney necrosis virus (ISKNV),
301
Aquaculture 204 (2002) 11–24.
AC C
EP
299
302
[18] O. Gilad, S. Yun, M.A. Adkison, K. Way, N.H. Willits, H. Bercovier, et al., Molecular
303
comparison of isolates of an emerging fish pathogen, koi herpesvirus, and the effect of
304
water temperature on mortality of experimentally infected koi, J. Gen. Virol. 84 (2003)
305
2661–2668.
13
ACCEPTED MANUSCRIPT 306
[19] M. Sano, T. Ito, T. Matsuyama, C. Nakayasu, J. Kurita, Effect of water temperature
307
shifting on mortality of Japanese flounder Paralichthys olivaceus experimentally infected
308
with viral hemorrhagic septicemia virus, Aquaculture 286 (2009) 254–258. [20] A.E. Goodwin, G.E. Merry, Mortality and carrier status of bluegills exposed to viral
310
hemorrhagic septicemia virus genotype IVb at different temperatures, J. Aquat. Anim.
311
Health. 23 (2011) 85–91.
RI PT
309
[21] M.H. Jung, S.J. Jung, T.N. Vinay, C. Nikapitiya, J.O. Kim, J.H. Lee, et al., Effects of
313
water temperature on mortality in Megalocytivirus-infected rock bream Oplegnathus
314
fasciatus (Temminck et Schlegel) and development of protective immunity, J. Fish. Dis.
315
38 (2015) 729–737.
M AN U
SC
312
316
[22] M.H. Jung, J. Lee, S.J. Jung, Low pathogenicity of FLIV (flounder iridovirus) and the
317
absence of cross-protection between FLIV and RBIV (rock bream iridovirus), J. Fish. Dis.
318
39 (2016) 1325–1333.
[23] L.J. Jun, J.B. Jeong, J.H. Kim, J.H. Nam, K.W. Shin, J.K Kim, et al., Influence of
320
temperature shifts on the onset and development of red sea bream iridoviral disease in
321
rock bream Oplegnathus fasciatus, Dis. Aquat. Org. 84 (2009) 201–208.
TE D
319
[24] M.H. Jung, J. Lee, M. Ortega-Villaizan, L. Perez, S.J. Jung, Protective immunity against
323
Megalocytivirus infection in rock bream (Oplegnathus fasciatus) following CpG ODN
324
administration, Vaccine 35 (2017) 3691–3699.
AC C
EP
322
325
[25] M.H. Jung, S.J. Jung, Protective immunity against rock bream iridovirus (RBIV)
326
infection and TLR3-mediated type I interferon signaling pathway in rock bream
327
(Oplegnathus fasciatus) following poly (I:C) administration, Fish. Shellfish Immunol. 67
328
(2017) 293–301.
14
ACCEPTED MANUSCRIPT 329
[26] T. Nishizawa, I. Takami, M.J. Yang, M.J. Oh, Live vaccine of viral hemorrhagic
330
septicemia virus (VHSV) for Japanese flounder at fish rearing temperature of 21 °C
331
instead of Poly (I: C) administration, Vaccine 29 (2011) 8397–8404. [27] T. Nishizawa, H.J. Gye, I. Takami, M.J. Oh, Potentiality of a live vaccine with nervous
333
necrosis virus (NNV) for sevenband grouper Epinephelus septemfasciatus at a low
334
rearing temperature, Vaccine 30 (2012) 1056–1063.
RI PT
332
[28] M.J. Oh, H.J. Gye, T. Nishizawa, Assessment of the sevenband grouper Epinephelus
336
septemfasciatus with a live nervous necrosis virus (NNV) vaccine at natural seawater
337
temperature, Vaccine 31 (2013) 2025–2027.
SC
335
[29] M.H. Jung, C. Nikapitiya, J.Y. Song, J.H. Lee, J. Lee, M.J. Oh, et al., Gene expression
339
of pro- and anti-apoptotic proteins in rock bream (Oplegnathus fasciatus) infected with
340
Megalocytivirus (family Iridoviridae), Fish. Shellfish Immunol. 37 (2014) 122–130.
M AN U
338
[30] J. Zhang, X. Tang, X. Sheng, J. Xing, W. Zhan, The influence of temperature on viral
342
replication and antiviral-related genes response in hirame rhabdovirus-infected flounder
343
(Paralichthys olivaceus), Fish. Shellfish Immunol. 68 (2017) 260–265.
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[31] S. Avunje, W.S. Kim, M.J. Oh, I. Choi, S.J. Jung, Temperature-dependent viral
345
replication and antiviral apoptotic response in viral haemorrhagic septicaemia virus
346
(VHSV)-infected olive flounder (Paralichthys olivaceus), Fish. Shellfish Immunol. 32
347
(2012) 1162–1170.
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Fig. 1. Cumulative mortality of rock bream intraperitoneally (i.p.) injected with 1.1 × 107
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MCP gene copy/fish of RBIV at 23 °C, with the water temperature reduced to 17 °C at 7, 4
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and 2 dpi (2 °C/day). Cumulative mortality was calculated using the formula [number of dead
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fish/fish population parameter × 100]. All surviving fish were subjected to water temperature
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increase (1 °C/day) up to 26 °C at 70 dpi (arrows). The cumulative mortality of group A1 (7
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day) previously published [29] is shown for reference.
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Fig. 2. Absolute virus copy number of rock bream by different water temperature condition
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after 1.1 × 107 MCP gene copy/fish of RBIV was injected intraperitoneally (i.p.). (A) Fish
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were injected at 23 °C, and the water temperature was reduced to 17 °C at 7 dpi (2 °C/day).
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(B) Fish were injected at 23 °C, and the water temperature was reduced to 17 °C at 4 dpi
364
(2 °C/day). Virus copy number and spleen index for 2 and 4 dpi were ploted using the Fig.
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2A. (C) Fish were injected at 23 °C, and the water temperature was reduced to 17 °C at 2 dpi
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(2 °C/day). Virus copy number and spleen index for 2 dpi were plotted using the Fig. 2A. (D)
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Fish were injected at 17 °C.
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Fig. 3. The MCP gene copies of all dead fish from the group A1 (23 °C reduced to 17 °C at 7
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dpi) and the MCP gene copies in all rock bream survivors from group A1 (23 °C reduced to
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17 °C at 7 dpi), A2 (23 °C reduced to 17 °C at 4 dpi) and A3 (23 °C reduced to 17 °C at 2 dpi)
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are shown. RBIV MCP copy number was 1.0 × 101/µl can be regarded as negative.
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Table 1 Experimental details of artificial infection
A1 (23 °C reduced to 17 °Cat 7 dpi)
Infection dose /fish 1.1 × 107/fish 7
No. of fish 60
2, 4, 7, 10, 15, 20, 22, 25, 28 and 30 dpi
Sampling point
Mortality (%)
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Group
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1.1 × 10 /fish
80
7, 10, 15, 20, 25, 30, 40, 50, 60, 70 and 100 dpi
0
A3 (23 °C reduced to 17 °Cat 2 dpi)
1.1 × 107/fish
80
7, 10, 15, 20, 25, 30, 40, 50, 60, 70 and 100 dpi
0
B (17 °C)
1.1 × 107/fish
50
2, 4, 7, 10, 15, 20, 25, 30 and 40 dpi
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dpi: days post infection
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A2 (23 °C reduced to 17 °Cat 4 dpi)
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Water temperature shifting group (23 °C reduced to 17 °C) 80
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A1 (reduced to 17 °C at 7 dpi) A2 (reduced to 17 °C at 4 dpi)
60
A3 (reduced to 17 °C at 2 dpi)
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40 20 0 20
30
40
50
60 70 Days post infection
80
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100
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raised to 26 °C
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Cumulative mortality %
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Fig 1
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A
10
Virus copy number
Virus copy number
10 9
10 9 10 8
10 7 10 6 10 5 4
10 3 10 2
10 5 10 4 10 3
10 0 2d
4d
7d
10d
15d
20d
22d
25d
28d
30d
Days post infection
C
10 1
2d
EP
10 8 10 7
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10 6 10 5 10 4 10 3
10
10 2
7d
10d
15d
20d
25d
30d
40d
50d
60d
70d 100d
Days post infection
Group B (17 °C)
10
Virus copy number 10 9 10 8
Absolute viral copy number
lethal
4d
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Virus copy number 9
detection limit
10 0
Group A3 (23 °C reduced to 17 °C at 2 dpi)
10
10
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detection limit
Absolute viral copy number
10 6
10 2
10 1
10
lethal 10 7
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lethal Absolute viral copy number
Absolute virus copy number
10 8
10
Group A2 (23°C reduced to 17°C at 4 dpi)
10
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10
B
Group A1 (23 °C reduced to 17 °C at 7 dpi)
10
lethal 10 7 10 6 10 5 10 4 10 3 10 2
10 1
10 1
detection limit
detection limit
10 0 2d
7d
10d
15d
20d
25d
30d
40d
Days post infection
50d
60d
70d
100d
10 0 2d
4d
7d
10d
15d
20d
Days post infection
25d
30d
40d
Fig 2
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10 1 0
Dead fish
lethal virus copy number
10 8
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10 7 10 6 10 5 10 4
Survived fish
10 1 10 0
detection limit
Group A1 (23°C for 7 d → 17°C)
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10 2
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10 3
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Absolute virus copy number
10 9
SC
MCP copy number in dead or survived fish
Group A1 Group A2 (23°C for 7 d (23°C for 4 d → 17°C) → 17°C)
Group A3 (23°C for 2 d → 17°C)
Groups
Fig 3
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days at susceptible water temperatures. Virus completely eliminated under the threshold of causing mortality at the late stage.
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Fish need at least 50 days from peaked virus level to avoid re-activation of the virus.