Abstract
In this study, the effects of Coriandrum sativum to control Aeromonas veronii infection in Oreochromis niloticus were determined. Coriandrum sativum extract (CE) was tested in vitro against A. veronii by the disc diffusion assay. In in vivo, 150 O. niloticus (from El-Abbassa, Sharkia, Egypt, weighing 34.95 ± 1.98 g) was distributed in five groups (with three replications) in glass aquariums (80 × 40 × 30 cm). The first group (control) was intraperitoneally injected with 0.2 ml of sterilized tryptic soya broth. Groups 2–5 were intraperitoneally challenged with 0.2 ml of A. veronii (4.3 × 106). The five groups were administered a basal diet until clinical signs appeared, and then therapeutic feeding (15 days) was followed: the first (CONT) and second (AV) groups were administered a normal basal diet. The third (AV+CP) and fourth (AV+CE) groups were administered diets supplemented with C. sativum powder and extract, respectively, each at 30 mg/kg. The fifth group (AV+OT) was administered a diet supplemented with oxytetracycline at 500 mg/kg diet. The results of the in vitro experiment revealed that CE has a zone of inhibition of 43 mm against A. veronii. The in vivo results showed that fish administered a therapeutic diet supplemented with CE showed a significant improvement in hematological, biochemical, and immunological parameters, as well as antioxidant capacity (P < 0.05) and the pathological findings of the liver and kidney tissues. The current findings supported that the administration of a CE-enriched diet (30 mg/kg) is an eco-friendly strategy for controlling A. veronii in O. niloticus.
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Introduction
The gram-negative, rod-shaped facultative bacteria known as aeromonads cause many outbreaks that affect farmed fish and aquaculture industry throughout the world (Dien et al. 2023; Reda et al. 2021). They also cause a disease that affects humans, resulting in sepsis, diarrhea, and wound infections (Pessoa et al. 2022). Motile aeromonads in general and Aeromonas veronii in particular are the primary causes of Motile aeromonas septicemia (MAS), which is a widespread disease that leads to severe economic losses in the global aquaculture industry (Francis-Floyd 1991; Saharia et al. 2021). Several studies have also shown that A. veronii, alone (Abd El Latif et al. 2019; Raj et al. 2019; Reda et al. 2022) and as a co-infection with other strains of bacteria (Dong et al. 2017; Youssuf et al. 2020) or virus (Amal et al. 2018; Suresh et al. 2023), cause summer mortality syndrome in tilapia farms.
To control economic losses due to fish infections, most fish farmers overuse antibiotics without professional management; they often administer antibiotics not approved for fish without a prescription (Preena et al. 2020). In aquaculture, antibiotics are typically administered orally, by immersion, or by adding them to the water. The uncontrolled use of antibiotics and the presence of non-ingested food items and fish excrement can cause antibiotics to persist in the aquatic environment (Serwecińska 2020). The overuse of antibiotics is associated with high risk to public health, including (i) the spread of antibiotic-resistant bacteria and genes; (ii) antibiotic residues in food chains, aquatic products, and ecosystems; and (iii) the elimination of the normal microbiota, which can promote the growth of opportunistic bacteria due to the absence of competition (Romero et al. 2012).
Most studies have investigated sustainable and environmentally friendly approaches to control aquaculture diseases, which can benefit public health by boosting immunity and overall health (Dien et al. 2023; Reverter et al. 2014). Plant-based approaches, often known as phytomedicines, are eco-friendly and safe for aquatic organisms (Tabuti et al. 2003). Most medicinal plants, whether fresh or dried, contain natural bioactive compounds that can be extracted from roots, leaves, bark, flowers, fruits, and seeds (Kuebutornye and Abarike 2020). Many infectious diseases in aquaculture are treated and prevented using medicinal herbs (Dien et al. 2023). Bioactive compounds, such as flavonoids, phenolics, proteoglycans, and polysaccharides, present in medicinal plants prevent aquatic diseases either by enhancing immune responses or by acting as antibacterial agents (Citarasu 2010).
Coriander (Coriandrum sativum L.) belongs to the Apiaceae family and is rich in bioactive substances with antioxidant, anti-inflammatory, and antibacterial properties (Mandal and Mandal 2015). Coriander seeds are easily available, have a low cost of production, and contain vital fatty acids such as linoleic acid, minerals, vitamin C, and linalool, which is a potent cellular antioxidant, antibacterial, and anti-inflammatory compound (Farsani et al. 2019). Several studies have investigated the inhibitory effects of C. sativum extract (CE) against various pathogenic strains in aquaculture such as Yersinia ruckeri in Oncorhynchus mykiss (Farsani et al. 2019) and Aeromonas hydrophila in Oreochromis niloticus and Catla catla (Das et al. 2023; Innocent et al. 2011).
However, information on the therapeutic benefits of dietary coriander seed extract in O. niloticus is lacking. Therefore, this study evaluated the therapeutic effect of a diet rich in coriander seed powder (CP) or extract (CE) against A. veronii in O. niloticus. Here, the antibacterial activity of an ethanolic extract of coriander seed against A. veronii in vitro was assessed. This study also determined the in vivo efficacy of CP and CE in restoring the altered hematological, biochemical, and immunological profiles, antioxidant capacity, and histopathological findings of O. niloticus that were experimentally infected with A. veronii.
Materials and methods
Aeromonas veronii strain
Aeromonas veronii (131TF-ID) used in this study was isolated from the naturally infected fries of tilapia in Idku, Beheira Governorate, Egypt. The isolate was identified as A. veronii via rRNA gene sequence and was recorded in the GenBank database (accession number: MN967136) (Reda et al. 2022). The LD50 of A. veronii was estimated in our laboratory and found to be 4.3 × 106 CFU/ml (Reda et al. 2022). Aeromonas veronii was grown in tryptic soya broth (TSB) and agar (TSA) at 30 °C. The bacterial stock was preserved in TSB containing 15% glycerol at −80 °C until needed.
Coriander (Coriandrum sativum) collection and preparation
The coriander seeds used in this study were purchased from a traditional market in Zagazig, Egypt. The seeds were thoroughly washed with water before drying for 15 days at 30 ± 2 °C away from direct sunlight. The dried seeds were milled with a pestle and mortar to a very fine powder. One part of the milled powder sample was stored in a sealed vial at 4 °C and used as a powder (CP). The other portion of the milled powder sample was used for extraction following a method described by Ahmed et al. (2020) to prepare ethanolic coriander extract (CE).
Determination of the antibacterial activity of Coriandrum sativum extract against A. veronii
The antibacterial activity of CE against A. veronii was determined using the disc diffusion method (Tenover 2019). For preparing the C. sativum extract discs (CE discs), Whatman No. 1 filter paper was used to prepare discs (5-mm diameter in diameter), which were sterilized at 121 °C for 15 min. Then, the discs were immersed in CE for 1 h and dried in the oven at 50 °C for 1 h. On the surface of TSA, 100 μl of the A. veronii cell solution (107/ml using McFarland standard tubes) was inoculated and evenly spread using a sterile glass spreader. Then, the CE discs were placed on the surface of the agar plates and incubated at 30 °C for 24 h. Discs soaked in distilled water served as the negative control, while oxytetracycline discs (30 mg; HiMedia) served as the positive control. This test was conducted in triplicate. To determine the size of the inhibition zones beyond the paper disc, the diameters of the growth-free zones around the discs were measured, and the diameter of the paper disc was subtracted from the diameter of the inhibition zone. The activity was considered to be strong when inhibition zone was more than 15 mm, moderate when the inhibition zone was 10–15 mm, and weak when the inhibition zone was less than 10 mm (Pachanawan et al. 2008).
Determination of bioactive compounds using gas chromatography-mass spectrometry (GC-MS)
The bioactive compounds in the CE were identified via GC-MS (Agilent Technologies); a gas chromatograph (7890B) and a mass spectrometer detector (5977A) were used at the Central Laboratories Network, National Research Centre, Cairo, Egypt. The compounds were identified by comparing the spectrum fragmentation pattern with those stored in Wiley and the NIST Mass Spectral Library (Dakhlaoui et al. 2022; Oprean et al. 2001).
Preparation and experimental protocol of the medicated diet
Four experimental diets were administered that met the nutritional needs of tilapia fish, as recommended by the National Research Council (NRC 2011) (Table 1). The first diet (CONT) served as the control basal diet without any supplementation. The second and third diets were supplemented with CP and CE, respectively, each at 30 mg/kg. The CP and CE levels administered were established based on the findings of study on Nile tilapia by Ahmed et al. (2020). The fourth (OT) diet was the antibiotic diet, which was supplemented with 500 mg/kg oxytetracycline (Pharma Sweed, Egypt) (Hashem et al. 2022). Each diet component was mixed, ground, and pelletized to a diameter of 1.5 mm and dried for a day at room temperature. The pellets were stored at 4 °C until use.
One hundred and fifty O. niloticus (mean ± SE; 34.95 ± 1.98 g), all of which appeared to be in good health, were obtained from a private fish farm in El-Abbassa, Sharkia, Egypt. The fish were placed in glass aquariums (80 × 40 × 30 cm) with 60 L of dechlorinated tap water to acclimate for 15 days. After acclimatization, the fish were divided into five groups of three, each with 10 fish (10 fish/replicate, 30 fish/group). The first group (CONT) was injected with 0.2 ml of sterilized tryptic soya broth. Similarly,0.2 ml of A. veronii (4.3 × 106) was intraperitoneally injected into the fish in the other four experimental groups (Reda et al. 2022). The five groups were administered a basal diet until clinical symptoms manifested (such as hemorrhagic spots, loss of scales, and fin rot). After clinical signs appeared, the fish were fed a medicated diet as follows: the first group (CONT) and the second group (AV) were administered a normal basal diet without any supplementation. The third (AV+CP), fourth (AV+CE), and fifth (AV+OT) groups were administered CP, CE, and OT diets, respectively. Based on the number of surviving fish, the amount of food provided in each aquarium was calculated as 3% of the total live fish weight/aquarium and provided to the fish three times daily (800, 1200, and 1600 h). All fish were fed by hand very slowly to ensure ingestion of the introduced pellets until no fish accepted any more pellets (Wang et al. 2006). The amount of actual food consumed daily/aquarium was calculated by subtracting the calculated amount of food/aquarium from the actual food that was eaten/aquarium.
During the experiment, the water parameters were monitored and kept within recommended values following the method described by Boyd and Tucker (2014). The dissolved oxygen (electronic oxygen-meter, Oxi-330, Entech Co., Thailand) was adjusted to 6 ± 0.5 mg/L; the water temperature (digital thermometer WT-2, T-Bota Scietech Instruments & Equipment Co., China) was 27.5 ± 1 °C; and the concentration of unionized ammonia (DREL/2 HACH kits, HACH Co., Loveland, CO, USA) was 0.23 ± 0.05 mg/L.
The clinical signs and postmortem findings were recorded daily. The behavior of the fish was monitored during the 15-day trial between 800 and 1600 h each day using a stopwatch and a video camera to record and score its frequency (Altmann 1974). Gross measurements of the changes in swimming activity, such as whether quick or sluggish, were recorded by measuring the mean swimming frequency and the mean time (s) for 8 h daily. Additionally, if there were any changes in the position of the fish in the water column as surfacing swimming or resting on the bottom were recorded (Chen et al. 2001; Little and Finger 1990). The startle reflex was also examined, including fish reflexes to unexpected tapping on one side of the aquarium and attempts to catch them with a net (Fetcho 2009; Neo et al. 2015). Fish feeding behavior and feed consumption are used to assess appetite (Wei et al. 2021; White et al. 2016). The actual feed consumption was calculated, and the feeding behavior was scored following the method described by Wei et al. (2021) as follows: (−) indicated that the fish consumed all available pellets and moved freely around the pellets; (+) indicated that most fish moved toward the pellets and then returned to their position; (++) indicated that most fish only consumed pellets that fell in front of them; and (+++) indicated that most fish did not respond to food.
Blood sample collection and hematological analysis
To collect samples, the fish were sedated using 100 mg/L benzocaine solution (Al-Nasr Pharmaceutical Chemicals, Co.). The complete blood count was examined in nine samples per group, which were collected using 1-mlethylenediaminetetraacetic acid-rinsed syringes and a Sysmex XT-2000iV automated hematology analyzer. For analyzing the biochemical and immunological parameters, nine blood samples were collected from the caudal peduncle without using any anticoagulant for serum separation by centrifugation at 3000× g.
Biochemical analysis
Following the method described by Reitman and Frankel (1957), the activity of the serum enzymes alanine aminotransferase (ALT), aspartate transaminase (AST), and alkaline phosphatase (ALP) was measured. Urea and creatinine levels were determined by the Colorimetric method described by Patton and Crouch (1977) and Owen et al. (1954), respectively.
Antioxidant activity and non-specific immune parameters
Using commercial enzyme-linked immunosorbent assay (ELISA) test kits (Cusabio Biotech Co., Ltd.) and following the manufacturer’s recommendations to measure the blood levels of total antioxidant capacity (TAC), superoxide dismutase (SOD), and catalase (CAT), spectrophotometric analysis was performed to measure the concentration of nitric oxide (NO (Rajaraman et al. 1998). The serum lysozyme activity (LYZ) was measured using a turbidimetric technique described by Ellis (1990).
Histopathological examination
Regarding the histopathological evaluation, the fish were humanly euthanized by an overdose of benzocaine solution. The representative hepatic and renal tissue specimens from 10 randomly selected tilapias per group were sampled, rinsed in normal saline, and fixed in 10% neutral-buffered formalin solution for 24 h. After fixation, the specimens were thoroughly washed in distilled water, dehydrated by passing through ascending series of ethyl alcohol (70–100%), cleared in Histo-Clear II (Scientific Laboratory Supplies Ltd., UK), impregnated and embedded in paraffin wax, sectioned into slices (4 μm thick), and stained with hematoxylin and eosin (Suvarna et al. 2018). The slides were examined under a light microscope, and five randomly selected non-overlapping fields (10×) per fish were captured using a digital camera. Next, these images were analyzed to determine the frequency of lesions (FQ), establish a quantitative multiparametric lesion scoring method, and calculate the liver and kidney indices (the higher the index the worse the pathological condition of the organ) among the groups following the method suggested by Bernet et al. (1999). The recoded hepatic and renal histopathological alterations (alt) were classified into five reaction patterns (rp), including inflammatory, circulatory, regressive, progressive, and neoplastic. Next, every alteration within each pattern was assigned a score value (a) and an importance factor (w), where the score value denoted the degree of the alteration and its value ranged between zero (absence of the lesion) and six (diffuse lesion), whereas the importance factor denoted the seriousness of the alteration and its value ranged between one (minor importance) and three (major importance). Finally, the frequency of lesions and liver and kidney indices were calculated by the following formulae:
FQ (%) = Nlesion × Ntotal−1 × 100.
here, Nlesion, fish exhibited a lesion; Ntotal, the total number of fish in the group.
Organ index (Iorgan) = Σrp Σalt (aorg rp alt × worg rp alt).
Statistical analysis
The Shapiro-Wilks test was conducted to determine the normality and homogeneity of all data before statistical analysis was performed. Using IBM® SPSS® Statistics version 25, the data were evaluated via ANOVA followed by Duncan’s post hoc analysis to determine significant differences between the experimental groups. The results are presented as the mean ± standard error (SE). All differences between groups were considered to be statistically at P < 0.05.
Results
Coriandrum sativum seed extract GC-MS analysis
In Table 2, the principal bioactive compounds identified by GC-MS analysis in the CE are listed together with their retention times (RT) and area percentages. Many bioactive compounds have been found in the CE, according to the chromatograms GC-MS results. The results indicated that L-linalool was the main bioactive compound with the highest peak area % (92.52) at 10.107 retention time (RT, min).
Antibacterial activity of C. sativum extract
By quantifying the diameter of growth inhibition zones (mm), the antibacterial activity of CE was assessed using the disc diffusion method. CE was proven to be efficient against the fish disease A. veronii. The extract of C. sativum has a 43-mm zone of inhibition. Oxytetracycline, an antibiotic used in sensitivity testing, produced a zone of inhibition measurement of 48.3 mm (Fig. 1).
Clinical signs, behavioral observations, and postmortem findings
Comparatively to other treatment groups, the AV group displayed observable clinical symptoms and distress manifestations (Fig. 2 and Table 3). Fish showed high mucus secretion, eye turbidity, erosion of the operculum, loss of the scales, hemorrhagic spots, erection in the pectoral fin, and fin rot. These fish also do not respond to knocking on one side of the aquarium, swim in surface water, and are easily caught. Additionally, the amount (g) of actual feed consumed by the AV group was significantly lower (4.02 ± 0.31) than it was for the CONT group (10.15 ± 0.25), and most fish do not respond to food (52.63%). The significant postmortem findings of the AV group included pale gills and an enlarged and congested liver, spleen, and kidney. In the treated groups, the symptoms and postmortem findings listed above were noticeably diminished in AV+CE followed by AV+CP and AV+OT. AV+CE group showed a significant increase in the amount (g) of actual feed consumed (8.45 ± 0.41) followed by AV+CP (6.05 ± 0.48) and AV+OT (6.20 ± 0.28) compared with CONT. The AV group had the highest mortality rate (36.66%), followed by the AV+CP (20%) and AV+OT (16.66%) groups, while the lowest rate (10%) was recorded in the AV+CE group.
Hematological and biochemical parameters
The RBCs, Hct, Hgb, total protein, globulin, WBCs, lymphocyte, and neutrophil levels in AV group showed a significant decreasing trend from the control non-infected group (Table 4). In contrast, as compared to the CONT group, the levels of the same pervious mentioned parameters were restored in AV+CE followed by AV+CP and AV+OT but not reaching CONT group levels.
The A. veronii-infected untreated group (AV) has significantly elevated levels of ALT, AST, ALP, urea, and creatinine than the CONT group. Significant improvements were observed in the levels of ALT, AST (Fig. 3), and creatinine (Fig. 4) in AV+CE, but these improvements were not at the same levels as those shown in the CONT group. Although the levels of urea and ALP in AV+CP, AV+CE, and AV+OT have improved noticeably, there are no discernible variations between the levels of these parameters in these groups.
Oxidant/antioxidant status
TAC, SOD, and CAT levels were significantly lower in fish in the AV group than in the CONT group. Contrarily, these same parameters showed a considerable elevation in line with the patterns AV+CE> AV+CP and AV+OT but did not reach to the CONT group recorded values (Fig. 5).
Immunological parameters
In comparison to the CONT group, the AV group showed a considerable drop in NO and LYZ activity. The NO and LYZ activities greatly improved in AV+CE, then AV+CP, and AV+OT, but they did not reach the levels seen in the CONT group. There were no significant differences seen in NO and LYZ activities between AV+CP and AV+OT groups (Fig. 6).
Histopathological findings
The microscopic examination and image analysis of the livers of the control group declared normal hepatopancreatic architectures (Fig. 7A). Infection with A. veronii (AV group) induced a vast array of hepatopathic alterations mostly of inflammatory and circulatory nature with the absence of any neoplastic or preneoplastic changes. These alterations included but were not limited to notable inflammatory cell infiltrates, marked vascular and sinusoidal congestion, multifocal necrotic foci occasionally filled with extravasated blood, minute hemorrhages, intense lipoidal cytoplasmic vacuolations with cellular swelling and nuclear pyknosis, single-cell necrosis, and hyperplasia of the melanomacrophage aggregates (Figs. 7B1, B2, and B3). Supplementation with CP exerted weak hepatoprotective effects against the A. veronii-induced hepatopathy, as the same lesions recorded in the infected nontreated group were evident in the AV+CP-treated fish, but with lower severities (Figs. 7C1, C2, and C3). Supplementation with CE showed variable rescue effects against the A. veronii-induced hepatopathy, as a significant reduction in the inflammatory alterations, a moderate reduction in the circulatory and degenerative alterations, besides no effect on the hyperplasia of the melanomacrophage aggregates were observed in the AV+CE-treated fish compared to the infected nontreated group (Figs. 6D1, D2, and D3). Treatment with OT exhibited a sharp decline in the frequencies and severities of the inflammatory and circulatory alterations and the hyperplasia of the melanomacrophage aggregates, yet it somewhat increased the retrogressive alterations particularly the hepatocyte vacuolation and single-cell necrosis (Figs. 7E1, E2, and E3). The lesion frequencies, scores, and liver index of all groups were summarized in Table 5.
The microscopic examination and image analysis of the kidneys of the control group declared normal renal architectures (Fig. 8F). Infection with A. veronii induced numerous nephropathic morphological alterations. Most of these alterations are less severe, but few tissue sections exhibited notable degenerative changes, collectively, these alterations included glomerulopathy (atrophy, lobulation, and necrosis), tubulopathy (vacuolation, necrosis, and cast formation), and the interstitial tissue lesions (edema, congestion, inflammatory cell infiltration, and hyperplasia of the melanomacrophage aggregates) (Figs. 8G1, G2, and G3). Supplementation with CP exerted non-significant rescue effects on the renal histology as most of the A. veronii-induced renal lesions were evident in the AV+CP-treated fish, with nearly the same reactive nature (Figs. 8H1, H2, and H3). Interestingly, supplementation with CE remarkably rescue the renal parenchyma in the AV+CE-treated fish against the A. veronii-induced nephropathic alterations, and many tubules showed regenerative reactions, yet the kidneys did not regain their normal histology. Numerous but mild lesions were still evident including atrophy of the glomerular tufts, vacuolation, detachment, and necrosis of the tubular epithelium, congestion of the interstitial vasculatures, and hyperplasia of the melanomacrophage aggregates (Figs. 8I1, I2, and I3). Treatment with OT possessed pros and cons effect, as it notably reduced both the severities and frequencies of the inflammatory, progressive, and most of the circulatory alterations caused by A. veronii infection, but it exaggerated the nephropathic degenerative alterations (Figs. 8J1, J2, and J3). The lesion frequencies, scores, and kidney index of all groups were summarized in Table 6.
Discussion
Coriander leaves and seeds are rich sources of bioactive constituents (Laribi et al. 2015). The GC-MS analysis in this study showed that the methanolic extract of C. sativum included a large amount of L-linalool (92.52%), cis-linalool oxide (1.73%), trans-linalool oxide (1.7%), and other bioactive compounds, which indicated that the C. sativum seeds have bioactive compounds. Similar results were recorded in the CE, although the seeds were obtained from different localities. For example, seed extract from Kanpur contains 83.21% linalool (Bankar et al. 2011), seed extract from Tunisia contains 87.54% linalool (Msaada et al. 2007), and seed extract from Bangladesh contains 37.7% linalool (Bhuiyan et al. 2009). The differences in the extract of bioactive compounds can be related to the plant maturity stage (Msaada et al. 2007) as well as seasonal fluctuations, soil conditions, and environmental factors (Heywood 2002).
The CE demonstrated a large inhibition zone in this study against A. veronii, which indicated that the extract had a strong antibacterial effect. CE has bactericidal and antibacterial effects against several pathogens such as A. veronii, A. hydrophila, Staphylococcus caseolyticus, S. aureus, Chromobacterium violaceum, Klebsiella pneumoniae, Pasteurella multocida, Escherichia coli, and Campylobacter spp. (Abbas et al. 2022; Das et al. 2023; Duarte et al. 2016). The antibacterial effect of CE might be related to linalool and other bioactive components, which can damage the bacterial cell membrane and cause cell death as mentioned by Silva et al. (2011).
In this study, the clinical and postmortem results of the AV fish group were analyzed. These findings showed an increase in mucus secretion, eye turbidity, hemorrhagic patches with abnormalities in their swimming behavior, and congestion in hemopoietic organs (including the liver, spleen, and kidneys). These results are similar to those reported by Reda et al. (2022), Youssuf et al. (2020), Abd El Latif et al. (2019), and Raj et al. (2019) for O. niloticus, Cai et al. (2012) for the Chinese long-snout catfish, and Zhu et al. (2016) for the loach Misgurnus anguillicaudatus. The pathogenic symptoms and findings could be returned to cytotoxic and hemolytic activity and several exoenzymes (such as lipase, amylase, DNase, gelatinase, lecithinase, caseinase, and chitinase) produced by A. veronii (Sreedharan et al. 2011). In contrast, administering 30 mg/kg CE to the fish diet improved their health status and reduced A. veronii symptoms in the fish of the AV+CE group. This was the first study to show the protective effects of C. sativum against A. veronii in O. niloticus. Several studies have shown the prophylactic efficacy of CE against infection with numerous pathogenic bacteria in fish, such as A. hydrophila in O. niloticus and Catla catla (Das et al. 2023; Innocent et al. 2011) and Yersinia ruckeri in Oncorhynchus mykiss (Farsani et al. 2019). The results of the antibacterial activity showed that CE could significantly decrease the mortality rate and improve the general health conditions of the fish in the AV+CE group. In this study, A. veronii adversely affected the hematological parameters in the AV group, where significant declines in RBCs, HCT, Hgb, total protein, albumin, and globulin as well as leukopenia, neutropenia, and lymphopenia were observed. The decline in hematological parameters might be related to congestion and hemorrhage in hematopoietic organs, induced by A. veronii via the production of the hemolysin enzyme (Chandrarathna et al. 2018; Liu et al. 2022). Tort (2011) found that leukopenia and a considerable decrease in the differential leukocyte count are caused by prolonged and/or high stress (e.g., stress caused by A. veronii infection). Similar results were recorded in O. niloticus and Cyprinus carpio infected with A. hydrophila (Harikrishnan et al. 2003; Mukherjee et al. 2022). The current results showed considerable improvement in the hematological parameters of the infected group that was administered a diet supplemented with CE (AV+CE), followed by the groups that were administered AV+CP and AV+OT. This improvement might be due to the high levels of linalool present, which have antioxidant, anti-inflammatory, and antibacterial properties that mitigate the effects of A. veronii-induced hematologic alterations and promote the restoration of the functions of hematopoietic organs (Das et al. 2023; Laribi et al. 2015). Previous studies that performed coriander supplementation in fish diets as a prophylactic measure either found an increase in hematological markers or no change compared to the corresponding levels of the markers in the control groups. Das et al. (2023) recorded a significant increase in Hgb, MCV, MCH, and the thrombocyte count in O. niloticus that were administered a diet enriched with 2% coriander oil for 60 days, while no change occurred in the levels of WBC, RBC, HCT, and MCHC compared to their respective values in the control group. Innocent et al. (2011) found a substantial increase in the Hb content and serum protein level of Catla catla that were administered a diet supplemented with 2 g/kg CP for 14 days.
In the current results, the fish samples from the AV group exhibited a substantial increase in ALT, AST, ALP, urea, and creatinine compared to the control group. These results match those recorded by Reda et al. (2022) and Moustafa et al. (2020), who found that O. niloticus challenged by A. veronii and A. hydrophila, respectively, exhibited a significant increase in AST and ALT levels. In contrast, the current study found that the biochemical markers of the fish in the AV+CE group were significantly restored compared to the levels of the biochemical markers in the fish from the control, non-challenged group (CONT). Several studies have shown that an ethanolic extract of coriander enriched in flavonoids (isoquercetin and quercetin), phenolic compounds, and alkaloids has hepatic and renal protective effects (Laribi et al. 2015; Momin et al. 2012; Pandey et al. 2011).
The formation of reactive oxygen species (ROS) in response to microbial invaders is one of the first responses of the innate immune system of the host, which can stop bacteria from colonizing tissues (Spooner and Yilmaz 2011). Oxidative stress occurs when ROS production exceeds the antioxidant capacity, resulting in a cascade of biochemical and physiological alterations (Vani et al. 2021). Fish with septicemic diseases caused by A. veronii exhibit immunological suppression and oxidative damage due to very high levels of ROS-generating cytotoxicity (Krzymińska et al. 2011; Liu et al. 2022; Yang et al. 2020; Zhu et al. 2022). This clarified the findings of this study and the drop in the levels of TAC, SOD, and CAT enzymes in the AV group. Kurhalyuk and Tkachenko (2011) found that infections caused by A. hydrophila in sea trout (Salmo trutta L.) increased oxidative stress and compromised the hepatic antioxidant defense system. Baldissera et al. (2018) reported an alteration in the hepatic and renal antioxidant/oxidant balance in silver catfish following experimental infection with A. caviae. The most effective protection against oxidative stress-related cell damage is provided by antioxidant enzymes, which are catalyze the transformation of ROS and their byproducts into stable harmless compounds (Sáez and Están-Capell 2017). Antioxidant enzymes including SOD, glutathione peroxidase (GPx), and CAT are used by the innate defense mechanisms to combat ROS (Tang et al. 2013). Several studies have reported the antioxidant properties of CE, including its capacity to suppress ROS and absorb and neutralize free radicals (Wangensteen et al. 2004). Tannins, phenols, and flavonoids in CE have antiradical properties and can transform free radicals into more stable molecules through varies of mechanisms, for example, by acting as hydrogen and electron donors (Msaada et al. 2017). Therefore, the fish in the AV+CE group showed a greater improvement in the activities of the antioxidant enzymes, followed by those in the AV+CP and AV+OT groups.
The current findings showed in O. niloticus that were administered a diet supplemented with CE (AV+CE), the serum had higher levels of NO and lysozyme activity. This result might be related to the presence of linalool and other phenolic compounds in the CE, which was previously shown to play a key role in stimulating the fish immune system and the production of bioactive molecules (Abbas et al. 2022; Ahmed et al. 2020; Chang and Shen 2014; Das et al. 2023). Some studies that used CE as a prophylactic measure in aquafeeds also reported its ability to increase the immune capacity of fish to fight pathogenic bacteria in aquaculture. These studies reported an increase in the immune resistance of O. niloticus and Catla catla against A. hydrophila infection (Das et al. 2023; Innocent et al. 2011) and the resistance of O. mykiss against Y. ruckeri infection (Farsani et al. 2019).
In this study, the results of the histopathological analysis showed that the fish in the AV group had greater frequency of lesions and higher liver and kidney indices than those in the other infected groups that were administered therapy. Similar histopathological lesions were observed in the liver and kidneys of several fish species infected with A. veronii, including the Nile tilapia (Dong et al. 2017), crucian carp (Chen et al. 2019), largemouth bass (Pei et al. 2021), and channel catfish (Qin et al. 2022). In contrast, histopathological lesions in the liver and kidneys improved in the other infected groups that were administered therapy in the following order: AV+CE, followed by AV+OT and AV+CP. The improvement in the liver and kidney tissues of fish treated with CE might be related to the action of linalool, which has been shown in other studies to be a preventive and therapeutic agent against infection and chemical and drug-induced liver and kidney damage via its antioxidant and antibacterial effects (An et al. 2021; Bandeira Junior et al. 2021; Duarte et al. 2016; Mazani et al. 2022).
Conclusion
The findings of this study indicated that A. veronii is one of the most harmful infections that seriously threatens the aquaculture industry, as it interferes with liver and kidney functions and weakens the antioxidant and immunological defense of O. niloticus. Administering 30 mg/kg coriander extract was effective in treating A. veronii infection in O. niloticus. These findings provided a new method for treating aquaculture diseases using a safe plant product that is readily available, eco-friendly, affordable, and not hazardous to human health. However, further studies need to be conducted to determine the extent to which coriander extract can be used for treating different life stages of fish and diseases in hatcheries in the presence of various stress factors, particularly overstocking in the ponds and climatic change.
Data availability
All data generated or analyzed during this study are included in this published article.
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Said, A.A., Reda, R.M., Metwally, M.M.M. et al. Therapeutic efficacy of coriander (Coriandrum sativum) enriched diets in Oreochromis niloticus: effect on hepatic-renal functions, the antioxidant-immune response and resistance to Aeromonas veronii. Fish Physiol Biochem 49, 687–709 (2023). https://doi.org/10.1007/s10695-023-01220-6
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DOI: https://doi.org/10.1007/s10695-023-01220-6