Prospect of Hydroxyl Radical Exposure during Seawater Bathing to Treat Amoebic Gill Disease in Atlantic Salmon

. Tis study aims to undertake hydroxyl ( . OH) radical-based preliminary investigations with a view to utilising seawater as a viable alternative to freshwater for the treatment of amoebic gill disease (AGD) in aquaculture industries. Te study presents in vitro viability studies of clonal amoebae species to examine the efects of . OH radicals on both parasites and hosts. Te study also assesses the toxicity to Chinook salmon cell lines (CHSE-214) in freshwater and 35 ppt seawater via continuous dosing of 35mM . OH radicals and hydrogen peroxide (H 2 O 2 ) for 1.5 to 4hr, separately at 18 ° C and 15 ° C. Comparatively high viability of CHSE-214 (60% in . OH and 50% in H 2 O 2 ) for a prolonged treatment of up to 4 hr in seawater at 15 ° C indicates suitability of low seawater temperature while using either . OH or H 2 O 2 during bathing. Te viability of CHSE-214 remained relatively stable in seawater (55%–60% in . OH and 50%–60% in H 2 O 2 ), at both temperatures of 18 ° C and 15 ° C. However, at 15 ° C, a drastic reduction of viability of CHSE-214 in freshwater (from 80% to 48% in . OH and from 70% to 58% in H 2 O 2 ) has indicated high variations in toxicity levels in freshwater at low temperature. Using DNA staining agents in fow cytometry, the in vitro viability study results in > 22.5% mortality of clonal Neoparamoeba perurans (NP), an AGD causative agent, in 35 ppt seawater containing 35mM . OH radicals via one-of dosing for 1 hour at 15 ° C. In addition, fast radical consumption is more pronounced in the case of . OH radicals as compared to H 2 O 2 in both freshwater and seawater due to extreme reactivity of the former. Hence, this study suggests that . OH radicals are detrimental to the viability of NP in seawater, and thereby, establishes grounds for further in vivo investigations of using seawater supplemented with continuous dosing of . OH radicals for Atlantic salmon bathing as a treatment of AGD.


Introduction
Atlantic salmon is a large international aquaculture industry valued at $13.7 billion US dollars annually.In 2015, the annual economic loss reported for treatment costs related to amoebic gill disease (AGD) in Atlantic salmon primarily caused by Neoparamoeba perurans (NP) ranged between 5 and 81 million US dollars for aquaculture farms in Tasmania, Ireland, Norway, and Scotland [1].More than 11 amoebozoans within 6 amoebae genera, namely, Neoparamoeba, Paramoeba, Vexillifera, Pseudoparamoeba, Vannella, and Nolandella were classifed as prevalent in AGD infected gills of Atlantic salmon by English et al. [2], although the correlations between AGD and other amoebae species except for NP are not fully understood yet.Freshwater bathing of Atlantic salmon for 2-4 hr is the current recommended treatment for AGD [3].Te recurrence of AGD after initial bathing and the presumed stress on the fsh resulting from the long bathing time of 2 ̶ 3 hr are key challenges in freshwater bathing of Atlantic salmon.Additionally, collection of large volumes of freshwater from rivers and lakes up to 120 ML/month [4] may place pressure on freshwater resources.To date, alternative bathing approaches to treat AGD have been investigated including oxidisers, such as hydrogen peroxide (H 2 O 2 ) [5], peracetic acid (PAA) [6], and sodium percarbonate (SPC) [7].Preliminary studies of H 2 O 2 and PAA have shown positive prospects for freshwater bathing of Atlantic salmon, whilst SPC did not demonstrate any positive outcome.Adams et al. [8] investigated various concentrations of H 2 O 2 (500, 1000, and 1500 ppm) along with diferent bathing durations (10,20,30, and 60 minutes) in seawater for AGD treatment of Atlantic salmon.Whilst these studies have reported on bathing efcacies resulting from diferent dosing concentrations of oxidisers, the nature of dosing, in terms of one-of or continuous dosing of oxidisers, has not been explicitly investigated.In most cases, a one-of dosing at the start of the bath has been used as a benchmark for reporting bathing efcacies resulting from various concentrations of oxidisers.However, oxidisers decompose in water resulting in attenuation of the initial dosing concentration during the progression of a bath.An alternative approach would be a continuous dosing scheme that ensures a relatively stable concentration of oxidisers during the AGD bathing of Atlantic salmon.In this context, the continuous dosing of potent radicals such as hydroxyl ( .OH) radicals is quite challenging compared to other oxidisers, due to limited capacity for scalable production and lack of data regarding its efcacy in deactivation of NP.Recently, Mahbub et al. [9] demonstrated a portable and inexpensive technique capable of scalable production (between 40-90 mM) of .OH radicals from relatively low concentrations of H 2 O 2 (between 0.1-5 M) in aqueous solution using a single continuous fow photoreactor.Te direct use of seawater with the .OH radicals or H 2 O 2 in aqueous solutions is an attractive approach which has the potential to reduce the use of natural freshwater from rivers and lakes for AGD treatment, depending on their toxicity to NP and Atlantic salmon.Recently, the authors in [10] observed that in vitro cold temperature (as low as 3 °C) acts as a stressor to NP by increasing their detachment from gills irrespective of the seawater or freshwater media.An important fact in this regard is that the average surface seawater temperature (SST) in southern Tasmania varies between 13 °and 16 °C [11].Terefore, in vitro addition of .OH radicals or H 2 O 2 in aqueous seawater solutions at an average SST range is expected to enhance seawater's capability to act as an efective stressor to NP.
Flow cytometry studies of amoebae species have previously been reported.For example, Collins et al. [12] have sorted Neoparamoeba perurans (syn.Paramoeba) by cell size in clonal cultures to separate amoebae from the heterogeneous microorganism population using natural red (NR) staining and fow cytometry.Te viability of Acanthamoeba spp. was reported by Borazjani et al. [13] using propidium iodide (PI) for staining the cytometric samples.Mi-Ichi et al. [14] employed calcofuor (CF) and Evans blue (EB) stains in a fow cytometric method to study the percentage of cysts during encystation caused by Entamoeba histolytica during an amoebiasis infection in humans.In this context, this study presents fow cytometry-based viability studies of NP and salmon cell lines subjected to .OH radicals and H 2 O 2 prepared in freshwater or seawater solutions to provide a preliminary analysis of the toxicity of these oxidisers and potential as alternative treatments for AGD in Atlantic salmon. in a New Brunswick Galaxy ® 170 R CO 2 incubator.Te primary reason for using CHSE-214 cell lines was their easy availability and quick culture protocol as well as use of this cell line by other researchers during their investigations of loss of virulence of clonal NP [15].

Wild Amoebae Including NP Collection and Transfer from
Gills.Te gill basket of six farmed Tasmanian Atlantic salmon (Huon Aquaculture Pty Ltd) that displayed clinical signs of AGD with a gill index greater than 3 [16] were dissected, placed in 50 mL falcon tubes containing seawater, and transported to Victoria University, Melbourne, on the same day of collection at 2-4 °C.Seawater was collected from the same sea cages for amoebae culture media preparation in the laboratory.Te pH and salinity of the seawater during collection were recorded as 8 and 35 ppt, respectively.Gills were transferred to T75 culture fasks in 25 mL seawater and placed on an orbital shaker for 60 min.Gill mucus was scraped of the gill surface with a sterile scraper and collected in the T75 fask.Te remaining gill tissue was discarded.NPs were allowed to attach to the culture fask by simply leaving the fask still for 15-20 min.Te seawater, foating mucus, and other gill debris were discarded and replaced with 18 mL fresh 35 ppt seawater.Te gill transport seawater in 50 mL falcon tubes was centrifuged at 3000 × g for 5 minutes to collect NP dislodged during transport.Te supernatant was discarded and pellets were resuspended in 2 mL 35 ppt seawater and added to the previous T75 fask.Finally, 200 µL 10X MYB (1 g malt, 1 g yeast, 1 L sterile seawater) was added to the T75 fask and incubated at 14 °C in a 23 L Kogan ® thermoelectric fridge.Media were changed every fve days, and NP passaged every three weeks by centrifugation at 3000 × gfor 5 min.Experiments were undertaken on fasks when NP confuence reached 80%.Two days before the experiments, T75 fasks were subjected to 10X penicillin/ streptomycin (Sigma Aldrich, Australia) to reduce any bacterial load in seawater.In order to investigate the impact of diferent ( .OH) radical concentrations on the DNA of wild NP, this study undertook quantitative PCR (qPCR) by utilising a universal primer (based on 18S ribosomal RNA, please refer to qPCR methods and Table S1 in supplementary information) for eukaryotes, especially amoeba in the sample.Due to the presence of diferent amoebozoans in AGD infected gills along with wild NP as mentioned earlier in introduction, this study does not claim that the qPCR results specifcally represented wild NP DNAs exposed to 2 Aquaculture Research various ( .OH) radicals.Nonetheless, as the aim of this study was to investigate the prospect of using seawater as a generalised remedy of AGD targeting a wide range of wild amoebae that could be present in the salmon gills, the qPCR methods and results are presented in supplementary information for interested readers.In order to maintain the specifcity of the impact of ( .OH) radicals on NP, clonal NP cell lines were employed in the subsequent investigations.

Clonal Neoparamoeba perurans (NP) Cell Line.
A clonal NP cell line cultured in seawater was provided by the Commonwealth Scientifc and Industrial Research Organisation (CSIRO) [17].Falcon tubes containing the clonal NP were gently shaken before transfer of 25 mL to two T75 culture fasks.Te media were converted to 1X MYB with the addition of 200 µL 10X MYB (1 g malt, 1 g yeast, and 1 L sterile seawater) to the T75 fask.NP was incubated at 14 °C in a 23 L Kogan ® thermoelectric fridge.Media were changed every fve days, and NP passaged every three weeks by centrifugation at 3000 × g for 5 min.Experiments were undertaken when the NP fasks reached 80% confuence.Two days before experiments, T75 fasks were subjected to 10X penicillin/streptomycin as previously described.

Toxicity of Hydroxyl Radicals and Hydrogen Peroxide to
Cell Lines.As Huon aquaculture currently employs freshwater sourced from nearby rivers for bathing of Atlantic salmon, a safe maximum limit for exposure of CHSE-214 cell lines at various concentrations of aqueous H 2 O 2 was assessed by replacing growth media with H 2 O 2 in 20 mL of raw freshwater sourced from the Huon River in Tasmania for a maximum of 4 hours at 18 °C (more discussions of the safe maximum limit are provided later in Section 3.1).Te use of freshwater also ensured maximum exposure of CHSE-214 cell lines to H 2 O 2 , as the bacterial load is generally expected to be lower in freshwater than that in seawater [18].CHSE-214 cells were 80% confuent with a density of approximately 716,000 cell/mL as determined by counting using a hemocytometer.CHSE-214 cell lines were observed by microscopy at 100× magnifcation using a Kern microscope camera (ODC832, Kern and Sohn GMBH, Germany).CHSE-214 cell lines were then also exposed to .OH radicals from 1 to 50 mM produced from the parent material of 50 mM H 2 O 2 in aqueous solutions using a custom built continuous fow photoreactor as previously described by Mahbub et al. [9].Wild amoebae extracted from gills were exposed to 10 mM-50 mM .OH radicals for 1 hr as detailed in Table 1.
Tese amoebae were cultured in 35 ppt seawater in a similar manner as the clonal NP as described in the previous section.After 1 hr of treatment in various concentrations of .OH radicals, we removed the media with fresh seawater.So, there were no residual .OH radicals left in the culture media.Cells were counted using a hemocytometer and transferred to a 24-well plate (SIAL 0524, Sigma ® cell culture plate) at ∼20,000 cells/mL.Two days before the treatment with .OH radicals, wells were treated with 10X penicillin/streptomycin as previously described.At the end of the 4 hr bath, the media were poured into 50 mL falcon tubes and 2 mL 0.25% trypsin was added to each T75 culture fasks.After shaking for 5 min, culture fasks were supplemented with 5 mL of MEM enriched with 10 X nonessential amino acids, 10X FBS, and 50X penicillin/ streptomycin.Detached cells were collected in 10 mL Falcon tubes by centrifugation at 500 × g for 5 min.Te supernatant was then discarded, and cells were resuspended in 2 mL of either freshwater or seawater.

Adherent NP and CHSE-214 Hydroxyl Radical and
2.6.Flow Cytometry.Flow cytometry was undertaken to measure the percentage viability of CSIRO clonal NP cells after treatment with .OH radicals.Tree replicate cytometer tubes representing each experiment were prepared following the similar protocol described as follows.Culture fasks containing NP were pretreated with 10X penicillin/streptomycin as previously described.Te concentration of NP was measured using a hemocytometer for a fnal concentration of 100,000-300,000 cells/mL in the T75 fasks.Each experiment was accompanied with a "control" fask, which was not subject to any treatment, but the media were replaced with an equal volume of either 0.25 µm fltered seawater or freshwater at the start of the treatment at corresponding temperatures.NP was detached from culture fasks by gently shaking the fask for 5 min, ensuring all NPs were resuspended in seawater.NP was centrifuged at 3000 × g for 5 min, the supernatant was discarded, NP was resuspended in 2 mL seawater, and 0.3 mL were transferred to 5 mL cytometry tubes.Te NP was then treated with 35 mM .OH solution prepared in situ using our photoreactor by dispensing 0.7 mL .OH radicals @100 µL/min for 7 min and then left for 60 min treatment.Te NP sample was then injected with 10 µL SYBR safe nucleic acid DNA staining agent (Termo Fischer Scientifc S33102) (excitation at 280 nm and 510 nm and emission at 530 nm) 5 min before Aquaculture Research  [19].Samples were injected with 10 µL PI (excitation at 540 nm and emission at 630 nm) for each 1 mL sample from each experiment and allowed 5 min to stain nuclear DNA of the salmon cells.Samples were injected onto a BD AccuriTM C6 Plus fow cytometer with a fuid fow rate of 10 µL/min and a core size of 10 µm.A control sample without treatment was also included.Flow cytometry data were analysed using the BD AccuriTM C6 Plus built-in software package.Viabilities of both clonal NP and CHSE-214 at 35 mM .OH radicals in seawater for 1 hr through fow cytometry were investigated on two separate days in order to determine the repeatability of the in vitro treatment process.Results of these repeat experiments are given in the supplementary information.

Safe Limit of Hydrogen Peroxide as a Parent Reagent.
Caution needs to be exercised in extrapolating in vitro toxicity of H 2 O 2 , particularly due to the fact that a lethal in vitro dose to amoebae may not be safe for CHSE-214 [5].Terefore, initially, a safe maximum limit of parent material (i.e., H 2 O 2 ) was established in aqueous solution for CHSE-214 cell lines for a maximum 4 hr bathing time by replacing the growth media within 1 mM-100 mM concentration ranges of H 2 O 2 in freshwater in the T75 culture fasks (as described in methods and Table 1), and we observed the CHSE-214 cells by microscopy (Figure 1).Tis initial concentration range was chosen to include concentrations of H 2 O 2 investigated in previous studies (e.g., [8]) of AGD treatment.
Figures 1(a)-1(c) demonstrate the exposure of the CHSE-214 cell lines to a low concentration of H 2 O 2 (1 mM or 34 ppm) in the T75 culture fasks by replacing growth media with freshwater.No visible sign of distress was observed to the salmon cells during the treatment for up to 60 min by microscopy (Figures 1(a)-1(c)).Exposure of CHSE-214 cells to 50 mM H 2 O 2 for 4 hours was harmless (Figure 1(d)); however, 100 mM H 2 O 2 resulted in extensive damage and detachment of the cell lines from the bottom of the fask which is visible from the beginning of the exposure period (Figure 1(e)).Nowak et al. [20] have previously advised caution when extrapolating in vitro to in vivo results in their study of in vitro exposure of 3000 NP cells/mL to 1000 ppm or 29.4 mM H 2 O 2 for 10-20 minutes in seawater which resulted in 0-20% survival rates at the end of treatment; however, in vivo exposure of AGD-infected salmons to 1250 ppm or 36.8 mM H 2 O 2 at 12 and 18 °C for 15 minutes indicated osmoregulatory stress in salmons.Such caution also applies to the in vitro scale.Other in vivo experiments have shown that Atlantic salmon exposed to H 2 O 2 as high as 1250 ppm at 16 °C do not afect aerobic performance of salmon and have a negligible impact on their hypoxia tolerance [21].Te high degree of variability in the efcacy of H 2 O 2 bathing may be attributed to the variable reactivity of H 2 O 2 in the presence of divalent metal cations, catalysts, exposure to direct sunlight as well as presence of inhibitors in the aqueous solutions [22].Reactivity of H 2 O 2 is quite slow at moderate temperatures without the presence of any catalyst [23].To the contrary, reactivity of H 2 O 2 speeds up at increased temperature, which triggers the thermal decomposition of H 2 O 2 .In contrast, hydroxyl radicals ( .OH) are extremely reactive irrespective of temperature (1.6× more than H 2 O 2 based on standard reduction potentials; [24]).Terefore, in our subsequent in vitro investigation of wild amoebae as well as clonal NP presented in the following sections, 50 mM H 2 O 2 was employed as the parent material converted into various concentrations of hydroxyl radicals (10 mM to 50 mM .OH radicals) using our scalable photoreactor described elsewhere [9].

Toxicity Results on Clonal Neoparamoeba perurans Adhering to CHSE-214 Cells.
Our study investigated the efect of 35 mM (595 ppm) .OH radical on the clonal NP supplied by CSIRO adhering to the CHSE-214 salmon cells in 24-well culture plates.Based on the in vitro toxicity data for wild amoebae from salmon gills (provided as supplementary information in sections S2 and S3.1), 35 mM (595 ppm) .OH radicals were applied as a conservative approach in all of our subsequent experiments.Figure 2 shows clonal NP cells adhering to CHSE-214 cells before and after treatment with 35 mM .OH radicals in seawater.Te room temperature during the treatment was 17 °C, and the seawater temperature was 15 °C.Te transfer protocol of clonal NP cells allowing them to adhere to the CHSE-214 cell lines is provided in the ESI.
A previous in vitro study by Cano et al. [25] using sophisticated polyester membrane-based transfer wells showed adherence of NP to rainbow trout gill cell lines in seawater in 20 min.In our investigation, it was also observed that the NP cells adhered to the CHSE-214 within 5 min of transfer (Figure 2) using a less sophisticated cohabitation Aquaculture Research experimentation method.NP cells formed a cyst-like morphology after application of 35 mM (595 ppm) .OH radicals for 60 min.However, the CHSE-214 salmon cells remained visibly unharmed at the end of 60 min (Figure 2).Te density of live CHSE-214 cell lines before treatment was 760,000-1,000,000 cells/mL (in Figure 2(a)) as determined by counting via a hemocytometer from three replicate culture fasks, which remained approximately 700,000-960,000 cells/mL (in Figure 2(b)) after 1 hr of treatment in 35 mM .OH radicals in seawater.To the contrary, the count of live clonal NP before treatment was ∼53,000 cells/mL (in Figure 2(a)), whilst viability reduced to ∼40,000 cells/mL in Figure 2(b) (considering the cyst-like morphology of clonal NP after treatment was still viable).Tis roughly accounts for ∼25% of the clonal NP as dead after the 1 hr treatment in 35 mM .OH radicals in seawater at 15 °C.

Viability of Neoparamoeba perurans Assessed by Flow
Cytometry.Te fate of clonal NP after a one-of dose of 35 mM .OH radicals in seawater for 60 min at 15 °C is presented in this section.Figure 3 illustrates the cytometer outputs in the control sample.
Initially, in the NP sample tube of the cytometer, a signifcant presence of live NP cells was observed (Figure 3(a)) which is confrmed by the fuorescence intensity plot (Figure 3(c)).Tere are some dots scattered around the ,000,000 10,500,000 Forward Scatter Height 0 500,000 1,000,000 1,500,000 2,000,000 Side Scatter Height (a) 0 5,000,000 10,500,000 Forward Scatter Height 0 500,000 1,000,000 1,500,000 2,000,000 Side Scatter Height     radical treatment, live NP population was observed to reduce to one-ffth of its initial percentage (i.e., 5.1% in P1 in Figure 3(a) reduced to 1.1% in P1 in Figure 3(b)), whilst dead NP population signifcantly increased in this period (i.e., 0.1% in P2 in Figure 3(a) increased to 2.2% in P2 in Figure 3(b)).Histograms also confrm a high count of live NP cells (Figure 4(a)) compared to dead NP cells (Figure 4(c)) in the cytometer tube before the start of 60 min .OH radical treatment.Tis result is expected if all NP in a culture were transferred rather than only attached NP.To the contrary, a marked decrease was observed in the counts of live NP (5203 counts in Figure 4(a) to 578 counts in Figure 4(b)) and increase of dead NP (119 counts in Figure 4(c) to 1169 counts in Figure 4(d)) via histograms after the 60 min .OH radical treatment.Te important fact to be noted here is that only NP cells within the polygons P1 and P2 in Figures 3(a) and 3(b) were accounted via cytometry.However, there is a high chance that some dead NPs might fall outside P2 as well as overlapped with P3 as evident in Figure 3(d).Nonetheless, our accounting of NP cells reveals at least 22.5% of the live NP population is confrmed dead after the 60 min .OH radical treatment.
Tus, our simple fow cytometry protocol with the SYBR safe DNA staining agent has contributed to our investigation to confrm the adverse efects of one-of dosing of 35 mM .OH radicals for 60 min on NP cells resulting in ̶ 22.5% mortality of NP.It is naturally anticipated that these singlecell NP would be under more stress if the one-of dosing is replaced with a continuous dosing of 35 mM .OH for different durations.As mentioned in the introduction, one-of dosing of other oxidisers such as H 2 O 2 , PAA, and SPC has already been investigated for AGD treatment by other researchers.Terefore, instead of repeating similar investigations involving one-of dosing of H 2 O 2 on NP, the efects of continuous dosing of .OH and H 2 O 2 only on CHSE-214 at diferent temperatures and media were rather investigated in the next section, considering the natural fact that continuous dosing of .OH radical to NP would cause much higher mortality than the one-of dosing of .OH.
Te control fask in seawater exhibited normal behaviour with the highest viability of 82 ± 2.2% and 68 ± 2.9% at 15 °C and 18 °C, respectively.In contrast, freshwater is likely to induce osmotic shock resulting in low viability (45%-60%) in the control fasks in comparison to the greater viability (68%-82%) observed in control fasks in seawater.It is also interesting to observe that the viability increased in seawater from 68% to 83% with a decrease in temperature from 18 °C to 15 °C.Tis trend was opposite in freshwater where viability increased slightly from ∼43 ± 2.9% to 62 ± 2.3% when temperature increased from 15 °C to 18 °C.While suitable pH and temperature favour the utilization of metals to enhance the viability of inhabitants in both seawater [26] and in freshwater environments [27], a markedly diferent metal distribution in these two ecosystems might afect the patterns/pathways towards viability.Although increased viability at decreased temperature can be generally expected, the relatively less abundance of divalent transition metal cations in freshwater may result in a diferent pathway towards the viability of its inhabitants.From our investigations of the viabilities of CHSE-214 in control fasks of Figure 5, it would be reasonably agreeable that, irrespective of treatment durations, the viabilities of CHSE-214 cell lines in control fasks were always higher in seawater compared to freshwater for the same temperature.
In the treatment fasks, irrespective of temperature diferences, one common feature observed in both seawater and freshwater was that shorter treatment times always improved viability in both .OH radical (1.5  For the best-case scenario of the control fask (i.e., SW at 15 °C and 4 hr treatment), .OH radical treatment showed greater CHSE-214 viability (60%) compared to H 2 O 2 (50%).Te load of organic matter (including microorganisms) is very diferent in seawater and freshwater, with seawater potentially possessing larger concentrations of oxidisable organic load than freshwater.Hence, it is expected that highly reactive .OH radicals will be more rapidly consumed via oxidation in seawater than in freshwater, leaving less amount of .OH radical in seawater to attack the CHSE-214 cell line.Elevated pH and low temperature may be the two most important parameters to govern the rate of this oxidation.Tis is attributed to the relatively high viability of CHSE-214 cells treated with .OH radicals to the fact that .OH radicals are 1.6 times more reactive towards oxidisable matter present in the aqueous media compared to the H 2 O 2 (standard reduction potential of .OH � 2.8 eV as compared to that of H 2 O 2 � 1.78 eV).Hence, at the same concentration of 35 mM, the "contribution/tendency" of .OH radicals in deactivating the microorganisms present in either seawater or freshwater could have been much higher than that of H 2 O 2 employed for the same purpose.In other words, a signifcantly higher amount of .OH radicals compared to H 2 O 2 will be expended in deactivating the microorganisms present in aqueous solutions.Tis may have resulted in more H 2 O 2 present at the cell lines' interface compared to .OH radicals, resulting in higher viability of cell lines in .OH radical fasks.To verify this assumption, this study investigated the consumption rate of both      OH radicals in seawater as a sustainable approach for AGD treatment.In real life, there will be a considerable load of microorganisms present in both seawater and freshwater, whose cell defense mechanisms against a radical attack would likely be diferent from a whole animal model.Hence, it is anticipated that continuous dosing of .OH radicals would be more detrimental to wild amoebae species including NP in salmon gills in aqueous media than to a complete salmon.

Figure 3 :
Figure 3: (a) Live NP cells in the cytometer tube are illustrated within the red polygon (P1) in terms of forward scatter height and side scatter height of light scattered from NP cells in seawater.Te other polygons contain the presumably dead NP cells (P2) and contaminants in fresh seawater (P3).(b) Changes in viability of NP after 60 min .OH radical treatment in the cytometer tube.(c) A signifcant cluster of live NP cells through gating of P1 and P2 against the whole population of A before the start of treatment.(d) Separate clusters of live and dead NP cells after 60 min of .OH radical treatment through gating of P1 and P2 against the whole population of B.

Figure 6
the results for the remainder of the combinations of seawater (SW) and freshwater (FW) at both 18 °C and 15 °C.As expected, from 10 min to 240 min, the consumption of .OH radicals in the culture fask is 4-4.5 fold greater than that of H 2 O 2 at a CHSE-214 cell confuence of ∼80% irrespective of diferences in temperature and media.Considering our previously selected best-case scenario in Figure6(i.e., SW at 15 °C and 4 hr treatment, both .OH and H 2 O 2 ), it is observed that, after 240 minutes from the start of treatment, about 45 mM H 2 O 2 is present in the T75 culture fask compared to about only 5 mM .OH radical, and this trend is evident for other treatment durations.Terefore, this high concentration of H 2 O 2 remaining in the solution after the prolonged treatment period of 4 hr may have resulted in the low viability of CHSE-214 in seawater for SW at 15 °C treatment using H 2 O 2 .

Figure 4 :
Figure 4: Histogram of live NP cells in terms of mean fuorescence intensity height count, (a) before treatment, and (b) after treatment.Te histogram of dead NP cells in terms of mean fuorescence intensity height count, (c) before treatment, and (d) after treatment.

Figure 6 :Figure 5 :
Figure 6: Radical consumption in T75 culture fasks containing CHSE-214 salmon cell lines contained in 20 mL fresh seawater or freshwater during continuous dosing for various treatment times.Te starting reagent is 50 mM H 2 O 2 dosed continuously at 100 µL/min whilst 50 mM H 2 O 2 was converted into 50 mM .OH radical using the photoreactor and then dosed continuously.
Hydrogen Peroxide Studies.After gently shaking for 5 min, confuent clonal NP was transferred by pouring to T75 fasks containing 80% confuent CHSE-214 cell lines for experiments after discarding the media.NP was visually observed by microscopy for settlement on the CHSE-214 cell lines.Hydroxyl ( .OH) radicals and H 2 O 2 exposure experiments were started immediately on settlement.Culture media were replaced with either 5 mL of seawater or freshwater and 11.9 mL of 50 mM .OH radicals or 11.9 mL and 50 mM 30% (w/w) H 2 O 2 (Sigma Aldrich 216763) added for a fnal concentration of 35 mM at the start of bathing.Experiments were carried out at controlled ambient temperature of 15 °C and 18 °C inside a CO 2 incubator (New Brunswick Galaxy ® 170 R).A 1.5 mL sample was collected from each fask at the start of bathing to measure residual H 2 O 2 in each fask.Culture fasks were continuously dosed with 200 µL/min of either 35 mM .OH or 35 mM H 2 O 2 , and 1.5 mL samples were collected at 1 hr, 1.5 hr, 2 hr, and 4 hr to check H 2 O 2 and .OH radical levels.Culture fasks were visually observed by microscopy at 100× magnifcation using a Kern microscope camera (ODC832, Kern and Sohn GMBH, Germany) at each time point.

Table 1 :
Experimental conditions for CHSE-214, wild amoebae, and clonal NP. samples into a BD AccuriTM C6 Plus fow cytometer with a fuid fow rate of 10 µL/min and a core size of 10 µm.A control sample tube without treatment was also included.Flow cytometry data were analysed using the BD AccuriTM C6 Plus built-in software package.Polygon gating and histogram functions of cytometry software were utilised to interpret the cytometry data.Flow cytometry was also undertaken to measure the toxicity towards CHSE-214 cells through continuous dosing of 35 mM (595 mgL −1 ) .OH radicals and 35 mM (1191 mgL −1 ) H 2 O 2 in both seawater and freshwater at 15 °C and 18 °C for 1.5 to 4 h as previously described.Propidium iodide (PI) (Termo Fisher Scientifc P1304 MP) was used to diferentiate live and dead populations of CHSE-214 cells in four diferent treatment conditions consisting of freshwater at 15 °C (FW15 °C), freshwater at 18 °C (FW18 °C), seawater at 15 °C (SW15 °C), and seawater at 18 °C (SW18 °C) for each treatment group.PI is a membrane-impermeable fuorescent DNA stain.It is used to stain apoptotic cells for detection via fow cytometry .
. OH and H 2 O 2 in the T75 culture fasks containing the CHSE-214 cell lines during the four diferent treatment scenarios.Machine 8 Aquaculture Research malfunction prevented recording of the .OH and H 2 O 2 consumption in seawater at 18 °C ( .OH SW18 and H 2 O 2 SW18).
Tis study has established preliminary grounds for implementing continuous dosing of .OH radicals in seawater for AGD treatment.Te in vitro investigations showed that seawater supplemented with .OH radicals at 15 °C to 18 °C has the potential to be a sustainable alternative to freshwater bathing of Atlantic salmon for the treatment of AGD.Flow cytometric studies of clonal NP showed signifcant mortality (>22.5%) on exposure to a single one-of dosing with 35 mM .OH radicals for 1 hour at 15 °C in 35 ppt seawater.At 15 °C in 35 ppt seawater, CHSE-214 cell lines demonstrated increased viability (up to 82%) during the continuous dosing of 35 mM .OH radicals compared to 35 mM H 2 O 2 .Tis in vitro study also demonstrated higher reactivity of .OH in both seawater and freshwater towards clonal NP and CHSE-214 compared to the reactivity of H 2 O 2 .Terefore, 35 mM .OH radicals can be implemented in large-scale studies of continuous dosing of .