Introduction

Moringa oleifera (MO) is known as the “Miracle tree” and is mostly available in several tropical and sub-tropical countries throughout the world1. It has several therapeutic and health benefits due to its anti-inflammatory, hepatoprotection, antimicrobial, and antioxidant effects2,3,4,5,6. Its leaves contain high crude protein levels and essential amino acids7,8. The leaves are also abundant in several essential vitamins, minerals (like potassium, iron, and calcium)9, and phytochemicals (like carotenoids, flavonoids, phenolics, alkaloids, and terpenoids10. Due to the above-mentioned nutritive values, studies elucidated that MO-based meals could be proficiently consumed by poultry11, goats, cattle12,13, and fish14,15. The presence of anti-nutrient (anti-nutritional) factors may hinder the digestibility of MO-based diets, and in this case, it requires several processing techniques14. In aquaculture studies, it has been found that MO-supplied diets could enhance the growth of rohu carp16 and Nile tilapia17, nutrient digestibility of Pangasius bocourti18, strengthen the antioxidant ability19, and attenuate starvation stress17. MO leaf extract could also potentiate innate immune responses and increase the defense against the challenged pathogenic agents20.

Fipronil (FIP) is classified as a phenylpyrazole insecticide that is active against various insects and pests that infest agriculture crops21,22. Its insecticidal effects were performed through binding to γ-aminobutyric acid (GABA) receptors and playing as a glutamate-gated chloride (Glu-Cl) and GABA-gated chloride (GABA-gated-Cl) channels in the CNS of insects producing neuronal paralysis, hyperexcitability, and insect death23. This insecticide has been detected in the aquatic environments between 0.5 and 9 μg L−1 in the treated rice fields water surfaces24 and up to 12.6 μg L−1 in urban domestic runoff25. The continuous use and unhygienic disposal of this hazardous material will lead to its disposition in the aquatic ecosystems and subsequently induce serious risk to the exposed fish26.

Studies showed that fish exposure to FIP, even at the environmentally relevant levels, induced hazardous toxic effects. For instance, sub-lethal FIP dose (0.65 μg L−1) induced oxidative stress via alteration of the antioxidant enzyme system of common carp27. The exposure of Prochilodus lineatus to environmentally relevant levels of FIP provoked oxidative stress in the exposed gills28. FIP exposure also caused histopathological lesions and immune suppression in Nile tilapia29,30, impaired embryonic development of Japanese Medaka31, and hematological, genotoxic, and histopathological effects of common carp32,33. FIP also induced hepato-renal failure and histopathological damage of rohu carp34, deterioration of the metabolic and physiological biomarkers of European seabass35, and oxidative stress damage and genotoxic effects in rainbow trout36,37.

Some reports showed that MO could modulate the sub-lethal toxic impacts of several toxicants, such as CuONPs in common carp38 and hydrogen peroxide in gilthead seabream39. Reports published in Nile tilapia showed that dietary MO could ameliorate and reduces the sub-lethal toxic effects of several toxicants such as chlorpyrifos40, pendimethalin41, and aflatoxin B1 (AFB1)42. However, the literature on the potential efficacy of MO leaves extract as a feed supplement to lessen or mitigate the sub-lethal toxic effects of FIP is scarce. Thus, this study was planned to assess the long-term sub-lethal toxic impacts of FIP on stress factors, growth, water quality, chemical analysis of the fish body, serum biochemistry (particularly hepato-renal bioindicators and lipid profile), immunity, and antioxidant state of Nile tilapia. Moreover, the attenuating effects of dietary MO leaf extract were also examined.

Materials and methods

Ethical statement

All experimental works in the present study were performed following the Local Experimental Animal Care Committee guidelines and approved by the Institutional Ethics Committee of the Faculty of Agriculture, Zagazig University, Egypt and all methods were performed in accordance with the relevant guidelines and regulations (Approval number: ZUIACUC/2/F/110/2022).

Fipronil

Fipronil (FIP) technical grade (97%) is commercially purchased from Jiangsu Tuoqiu Agrochemicals Co., Ltd. (China) (CAS Number: 120068-37-3). It was used to prepare the stock solution immediately before the exposure.

MO leaf extract

Fresh MO leaves were acquired from the local market, Sharkia governorate, Egypt. The ethanolic extract of MO leaf was made following the protocol illustrated in43. Moringa leaves were washed thoroughly using distilled water (DW) and then permitted to dry at room temperature (30–34 °C) for 21 days. Next, dried moringa leaves were then finely milled by a high-speed milling machine. Subsequently, the dried MO leaf powder (1 kg) was extracted in one liter of 100% ethanol for 2 days and then filtered two times using a filter paper with a 2-μm sized pore. The ethanolic extract was condensed at 50 °C by means of a rotary evaporator. MO leaf ethanolic extract yields (78.3 g kg−1 of the dried MO leaf powder). The procured MO ethanolic extract was resuspended (1 g of MO leaf extract in 10 mL DW) and was then kept at 4 °C in the refrigerator.

Fish acclimation, rearing, and management practices

Nile tilapia (14.50 ± 0.50 g) were transported to the Wet Fish Laboratory, Department of Animal Production, Faculty of Agriculture, Zagazig University, Egypt. Fish were conditioned for 12 days in glass aquaria supplied with chlorine-free tap water (stored for 48 h before receiving fish). Rearing water was provided with compressed air by a central air compressor. Fish were hand-fed with a well-balanced basal diet (contains 30% CP) (commercially purchased from Aller aqua Co., Egypt). Table S1 (supplementary materials) illustrates the nutritional elements found in this diet and its analytical constituents. Fish were fed on this diet 3 times daily (till noticeable satiation). The light schedule is maintained as 12 h light and 12 h dark. During the acclimation and experimental periods, about 35% of the rearing water was syphoned off daily to eliminate the non-eaten feed particles and faeces and later replaced with other water from the storage tanks.

Experimental design

Two hundred and forty Nile tilapia were allocated into 24 glass aquaria (35 cm × 40 cm × 70 cm) (85 L each) that were arranged into 6 groups (in quadruplicates), and each replicate holds 10 fish. Three groups were fed on prepared diets supplied with freshly prepared MO ethanolic leaf extract (0.0, 1.0, and 2.0 g kg−1 diet) and defined as control (CTR), MO1, and MO2 groups. The other three groups were fed diets provided with the same MO levels (0.0, 1.0, and 2.0 g kg−1 diet) and concomitantly subjected to a sub-lethal FIP dose (4.2 µg L−1 for 3 h only per day) and defined as FIP, FIP + MO1, and FIP + MO2 groups. The experiment has lasted for 8 weeks.

FIP exposure and water siphoning regimen

The FIP exposure dose was chosen in line with the previously performed studies on sub-lethal toxic levels of FIP in the same fish species29,30. This exposure dose was below the environmentally relevant levels of FIP in the aquatic environments24,28. More importantly, Zhao44 reviewed that in the studies where FIP will be exposed to light, its half-life will be 3.6 h in water. Therefore, the experiment was designed to allow fish exposure to a sub-lethal FIP concentration in FIP, FIP + MO1, and FIP + MO2 groups only for 3 h daily to avoid FIP degradation and to maintain its required exposure concentration. Water was siphoned daily 3 h post-exposure in FIP, FIP + MO1, and FIP + MO2 groups and replaced with new water. On the other side, water siphoning was also performed daily in the non-intoxicated groups (CTR, MO1, and MO2 groups), whereas water was exchanged with new well-aerated water from the storage tanks. The study was conducted following ARRIVE guidelines45.

Water quality measurements

The water measurements, such as water temperature and pH values, have been examined every week by AD8000 Professional Multi-Parameter pH-ORP-Conductivity-TDS-TEMP Bench Meter. Dissolved oxygen (DO) was evaluated by AD130 Proof PH-ORP-TEMP Portable Meter ADWA (Adwa Instruments, Inc. 6726 Szeged, Alsó-Kikötő sor 11.C, Hungary). Total ammonia nitrogen (TAN) was measured by Hach Kit model HI 83205 (Multiparameter Bench Photometer, Hanna Instruments, and Romania), and then the unionized ammonia (NH3) levels were assessed.

Growth parameters and equations

Fish (in each group) was individually weighed to evaluate the growth and feed efficiency indexes following the calculations published in46,47,48.

$${ {\text{WG}}}\;{{\text{(g)}}} = {{\text{ FBW }}} - {{\text{IBW}}}$$
$${{\text{FI}}}\;( {{{\text{g }}}\;{{\text{feed/fish}}}} ) = {{\text{ The total amount of the feed eaten by fish in the experiment by their total number}}}$$
$${\text{FCR }} = {\text{ FI/WG}}$$
$${{\text{SGR}}}\; ( {\% /{\text{day}}} ) = [ {( {{{\text{Ln FBW }}} - {{\text{Ln IBW}}}} )/{\text{T}}} ] \, \times \, 100$$
$${{\text{SR}}}\;{{{(\% ) }}} = 100 \, \times \, ( {{{\text{The fish number at the end of the experiment/their initial number}}}} )$$

WG = weight gain, FBW: final body weight, IBW: initial body weight, FI = feed intake, FCR = feed conversion ratio, SGR = specific growth rate, SR = survival rate, and T = feeding period.

Analysis of the fish body composition

The methods used to evaluate the chemical constituents such as crude protein (CP), crude fiber (CF), crude lipids (CL), ash, and moisture of the whole body of the fish, as well as the basal diet, were evaluated49. Moisture (%) was measured by oven-drying of the fish samples (at 110 °C) to constant weight (JSON-100, Gongju-City, Republic of Korea). The CP (%) was assessed by the procedures described in the Kjeldahl Distillation Unit (UDK 129, VelpScientifica, Usmate Velate, Italy). The CL (%) was obtained by the Soxhlet extraction method. Moreover, the ash (%) was measured by incineration of the samples in a Muffle furnace at high temperatures (550 °C) for 6 h (Barnstead/Thermolyne Benchtop 47900, Thermo Scientific, Massachusetts, USA).

Blood sampling and serum collection

Fish were prevented from feeding for one day before sampling of blood. Three samples were collected from 3 fish per replicate (12 fish/group). After the fish were anesthetized by MS-222, the blood was sampled from the fish caudal veins using disposable sterile syringes. Blood samples were apportioned into two parts; one was assembled with heparin (as an anticoagulant) for hematological indexes. The second part was left at room temperature for the collection of the serum. Blood samples were centrifuged at 3500×g for 20 min. The collected serum was then preserved in the refrigerator at − 20 °C.

Haemato-biochemical indices

Erythrocytes and leukocyte counts were deliberated by a hemocytometer. Hemoglobin (Hb) concentrations were calculated in accordance with Collier50. Serum samples were examined for the blood proteins such as total protein (TP) and albumin (ALB) values which were established using specific diagnostic kits (Bio diagnostic Co., Dokki, Giza, Egypt). Globulin (GLO) concentrations were evaluated by subtracting ALB from TP concentrations. Kidney function markers such as blood urea nitrogen, creatinine, and uric acid levels were also measured. Liver enzymes such as alanine transaminase (ALT), lactate dehydrogenase (LDH), and aspartate transaminase (AST) activities were carried out colorimetrically using specific diagnostic kits (Bio diagnostic Co., Dokki, Giza, Egypt). Serum lipid profile including triglycerides (TG), very-low-density lipoprotein (VLDL-c), total cholesterol (TC), high-density lipoprotein (HDL-c), and low-density lipoprotein (LDL-c) was evaluated Bio diagnostic kits (Bio diagnostic Co., Dokki, Giza, Egypt).

Immunity biomarkers

The fish serum lysozyme (LZ) activities were evaluated by the turbidimetric assay by freeze-dried Micrococcus lysodeikticus (Sigma-Aldrich, St. Louis, MO) as a substrate51. One unit of the serum LY activity was outlined as the decline of 0.001 of optical density OD520 /min. The fish complement C3 contents were measured by quantitative sandwich ELISA by utilizing special fish kits (named the Fish Complement Component 3) (Catalog #MBS005953) (MyBioSource, Inc. San Diego, CA, USA). The total immunoglobulin M (IgM) levels were measured using ELISA kits. Serum nitric oxide (NO) levels were assessed spectrophotometrically by commercial kits (BioChain, Inc., USA) (in line with the technical information obtained from the manufacturer).

Antioxidant bioindicators

Catalase (CAT) enzyme, superoxide dismutase (SOD) enzyme, and reduced glutathione (GSH) levels were measured colorimetrically by specific diagnostic kits (Bio diagnostic Co., Giza, Egypt). Serum malondialdehyde (MDA) contents were colorimetrically measured by a commercial kit that measured free and total MDA compounds (LPO, OXIS Int., USA). Total antioxidant capacity (T-AOC) is evaluated in fish serum using specific kits (Bio diagnostic Co., Giza, Egypt). One unit of T-AOC was expressed as the amount of sample produced an increase in absorbance of 0.001 per min.

Statistical assessment

The data in the excel sheets were examined by one-way ANOVA. Tukey's test was done as a post-hoc test to evaluate the differences between the means in each experimental group, whereas P < 0.05 was statistically significant. Analyses were achieved by SPSS program 22.

Results

Water quality parameters

The weekly mean values of water quality parameters in the rearing aquaria in which fish were fed diets supplemented with MO leaf extract and/or intoxicated with sub-lethal FIP dose for 8 weeks were described in Table 1. Results showed that dietary supplementation with MO leaf extract significantly (P < 0.05) decreased the un-ionized ammonia and increased the DO levels. The opposite trend was observed in all FIP-intoxicated groups. The lowest DO and the uppermost unionized ammonia levels were noticed in the FIP group. Interestingly, MO groups exposed to FIP showed improved DO and ammonia levels than FIP only. Water temperature and pH values were not significantly influenced (P > 0.05; Table 1).

Table 1 Water quality parameters in the rearing aquaria of Nile tilapia groups during the present study.

Growth and feed utilization parameters

Growth, feed utilization, and SR of fish fed diets supplied with MO leaf extract and/or intoxicated with sub-lethal FIP dose for 8 weeks were illustrated in Table 2. Daily feed intake, total feed intake, body mass gain, FBW, WG, and SGR were increased (P < 0.05) significantly in all MO groups, and their uppermost values were found in the MO2 group. FCR levels decreased significantly (P < 0.05) in all MO groups, and their lowest values were found in the MO2 group. On the other hand, all growth and feed utilization indexes were significantly (P < 0.05) decreased, and FCR values were (P < 0.05) increased in the FIP-intoxicated group, suggesting the occurrence of growth depression in this group. However, dietary supplementation with MO (FIP + MO1 and FIP + MO2 groups) significantly modulated the parameters mentioned above in comparison with the FIP group (Table 2). SR (%) was lower in the FIP group than in other experimental groups.

Table 2 Growth performance, feed utilization indices and survival rates of Nile tilapia groups during the present study.

Proximate body composition

Moisture and CP (%) were significantly (P < 0.05) elevated, combined with a significant (P < 0.05) decline of the CL (%) in MO groups compared to other groups (Table 3). The opposite trend was observed in the FIP group. However, significant modulation of these parameters was noticed in groups fed MO diets and consequently exposed to FIP. However, no differences were found in the ash (%) among all groups (Table 3).

Table 3 Whole body composition (% on dry weight basis) of Nile tilapia groups during the present study.

Haemato-biochemical indices

In comparison with the CTR group, MO leaves extract did not significantly alter erythrocyte count, Hb, TP, ALB, ALT, AST, creatinine, and blood urea nitrogen levels except for a significant increase in leukocyte count and GLO levels (Table 4). Conversely, Hb levels, erythrocytes, leukocyte count, TP, ALB, and GLO values were the lowest in the FIP group. Furthermore, ALT, AST, blood urea nitrogen, and creatinine levels were the highest in the FIP group, and these results indicated the occurrence of hepato-renal damage. Interestingly, dietary supplementation with MO leaf ethanolic extract in FIP-intoxicated groups significantly modulated these parameters compared with the FIP-intoxicated group alone without moringa supplementation. Oppositely, no statistical differences were recorded in LDH and uric acid levels among all groups (P > 0.05; Table 4). Regarding the lipid profile of treated fish, it was noticed that HDL-c, TG, LDL-c, TC, and VLDL-c levels were decreased significantly in both MO groups (P < 0.05; Table 5). However, the reverse trend was observed in the FIP-intoxicated group, which indicates hypercholesteremia, hypertriglyceridemia, and disturbance of lipid metabolism in the FIP group. However, significant modulations of these indices were noticed in the FIP + MO1 and FIP + MO2 groups compared to FIP alone (Table 5).

Table 4 Haemato-biochemical measurements of Nile tilapia groups during the present study.
Table 5 Lipid profile of Nile tilapia groups during the present study.

Serum immunological assays

Serum immune assays of Nile tilapia fed diets provided with MO leaf extract and/or intoxicated with sub-lethal FIP level for 8 weeks were shown in Table 6. Total IgM, complement C3, and LYZ levels (P < 0.05) increased significantly in all MO groups than the FIP and CTR groups. Contrariwise, their levels were the lowest in the FIP-intoxicated group, suggesting the immune-suppressive effects of FIP intoxication.

Table 6 Serum immune and antioxidant biomarkers of Nile tilapia groups during the present study.

Antioxidant biomarkers

Serum antioxidant biomarkers of Nile tilapia that fed diets supplied with MO leaf extract and/or intoxicated with sub-lethal FIP dose for 8 weeks were shown in Table 6. It was found that antioxidant enzyme activities (SOD and CAT activities), NO values, and T-AOC levels were significantly increased, combined with a decline (P < 0.05) of MDA levels in MO-supplied groups than the FIP group. These positive effects of dietary MO suggest the potent antioxidant potential of dietary MO. The reverse trend was observed in the FIP group, which indicates the oxidative stress injury of FIP toxicity. Attractively, FIP + MO1 and FIP + MO2 groups showed significant attenuation of these parameters compared with FIP alone. However, no significant differences were observed in the GSH levels amongst experimental groups (P > 0.05; Table 6).

Discussion

Fipronil (FIP) is a highly effective insecticide against a wide range of agriculture pests22. Its disposition in the aquatic ecosystems will induce hazardous effects on the exposed aquatic organisms26. Literature indicated that exposure to environmentally relevant levels of FIP could induce fish toxicity signs. Herein, we have evaluated the long-term sub-lethal toxicity of FIP in Nile tilapia. Also, we assessed the possible attenuating effects of dietary MO leaf ethanolic extract. We found improved water parameters in tanks, whereas fish was reared on MO leaf extract-supplemented diets compared to the FIP-intoxicated group. These findings were similar to those obtained by52, who found that the water quality measurements were improved in tanks where Nile tilapia was reared on diets supplied with a powder prepared from MO leaves for two months. These results might be accredited to the reduced nutrient load in the water, consequently leading to a decreased deterioration of water and accumulation of toxicants53. The deteriorated physicochemical parameters of water in which fish were exposed to pesticides may be because of increased organic material in the water, as declared by Sweilum54. Nonetheless, the precise mechanisms by which MO attenuated water parameters are unclear and necessitate further studies.

The growth and feed utilization parameters were improved in MO groups in relation to the FIP group. Moreover, growth indices were improved considerably upon combined dietary supplementation with MO leaf extract with FIP exposure. These findings agreed with those declared by Elabd et al.17, who found that 1.5% MO leaf meal considerably improved Nile tilapia growth after three months of feeding experiment. Those authors also found that MO meal efficiently mitigated the growth performance after starvation stress. Another study demonstrated by52 illustrated that supplementing diets with MO leaves powder increased monosex tilapia growth after 2 months of the feeding experiment. Dietary 7% MO seeds or 10% MO leaves substantially normalized the growth performance to the control values in chlorpyrifos-intoxicated Nile tilapia40. Abdelhiee et al.42 recently showed that 0.5% MO seed extract efficiently enhanced the growth performance of Nile tilapia exposed to a sub-lethal AFB1 level. Several studies also demonstrate the efficacy of some natural supplements to lessen the toxic effects of FIP on the fish growth. For instance, e.g., vitamin C modulated the growth performance of common carp intoxicated with combined exposure to FIP and buprofezin55. Moreover, β-glucan recuperated the growth of FIP-intoxicated Nile tilapia30. To discuss this point in-depth, it was reported that the growth-stimulating impacts of dietary MO could be accredited to several reasons, such as (a) the presence of essential nutrients such as vitamins (vitamin C, alpha-tocopherol, and vitamin A), minerals (iron, potassium, and iron), and high-quality CP8, (b) a plentiful amount of flavonol glycosides (kaempferol and quercetin), and alkaloids (moringinine) in MO leaves, which might enhance the voluntary feed intake via controlling glucose homeostasis56, (c) reports also showed that MO leaf powder noticeably enhanced the intestinal morphometry (especially the intestinal villi length) which may be linked with improved growth52, and (d) polyphenols such as phenolic acids and flavonoids with prominent growth-stimulating effects57.

Regarding the fish body composition analysis, it was found that moisture and CP were considerably increased, combined with a significant decline of the CL in MO groups in relation to other groups. Arsalan et al.58 also found that MO leaf meal increased the CP and CL (%) in rohu’s body. In a similar sense, Ganzon-Naret59 found increased CP (%) in the body of barramundi fed on a diet supplied with a 10% MO leaf meal. The highest CP (%) in rohu’s body was found in groups fed on a diet supplemented with 15% MO leaf meal60,61. Supplementing fermented MO leaves markedly decreased the CL (%) in the gibel carp’s body62. In contrast, Dongmeza et al.7 reported that supplementing diets with dehydrated MO methanolic extracts showed no significant in the ash, moisture, and CP (%) of Nile tilapia than in the CTR group. These discrepancies may be accredited to fish species, dietary inclusion dose, or MO inclusion forms.

The values of Hb levels, erythrocytes, leukocyte count, and blood protein were significantly lowered in the FIP-intoxicated group. These results proposed the occurrence of anemia and immune suppression. Moreover, liver biomarkers such as ALT and AST enzymes and kidney indices such as blood urea nitrogen and creatinine levels significantly increased in the FIP-intoxicated group. These results suggest the occurrence of hepatotoxicity, liver dysfunction, and hepato-renal damage in the FIP-exposed fish63,64. In a similar concern, Gupta et al.65 found decreased Hb and serum TP contents alongside a significant increase of AST levels in common carp intoxicated with sub-lethal FIP. Hb levels and leukocyte count were considerably decreased alongside increased serum ALT and AST levels in FIP-intoxicated Nile tilapia29. Hb, erythrocyte count, TP, and globulin values were also decreased in FIP-intoxicated common carp33. Similarly, exposure of common carp to sub-lethal FIP toxicity resulted in a noticeable decrease in erythrocyte count, Hb, and hematocrit values combined with increased blood urea and creatinine levels32. ALT and AST enzyme activities were also increased in the serum of rohu exposed to sub-lethal FIP toxicity34. On the other side, it was noticed that supplementing diets with MO leaves extract in FIP-intoxicated groups significantly modulated the aforementioned parameters compared with FIP intoxicated group alone. Mbokane and Moyo66 illustrated that supplementing diets with MO leaves essential oil significantly increased packed cell volume, Hb, erythrocyte count, and leukocyte counts of African catfish compared to the CTR group. Serum uric acid, ALT, creatinine, AST, and urea were declined in Nile tilapia fed on moringa leaves meal up to 1.5% than the CTR group67. Elabd et al.17 illuminated that supplementing diets with MO leaf meal increased the PCV, Hb, erythrocyte count, and leukocyte count than the CTR fish. Also, those authors found a noticeable decline in AST and ALT levels than the CTR group. Furthermore, Monir and coauthors19 declared that Nile tilapia fed on MO-supplied diets had significantly elevated TP and GLO concentrations combined with a significant decline in urea, ALT, creatinine, and AST contents. An increase in the PCV, erythrocytes, and leukocyte counts, Hb, and hematocrit levels were recorded in Mozambique tilapia fed on moringa diets68. Similarly, Adeshina et al.69 found that PCV, Hb, erythrocytes, leukocytes, AST, and ALT values were improved in common carp-fed MO leaves meals. Recently, Abdelkhalek et al.70 found that dietary curcumin could alleviate the increased AST and ALT levels in FIP-intoxicated monosex tilapia.

TC and TG levels were increased in the FIP-intoxicated Nile tilapia. TG and TC values were also increased in FIP-intoxicated common carp32. However, HDL-c, TG, LDL-c, TC, and VLDL-c values were significantly decreased in MO groups. Monir et al.19 described a noticeable decline in serum TG and TC values that Nile tilapia fed on MO-based diets. Furthermore, a noticeable reduction of TC, TG, and LDL-c values was recorded in Nile tilapia fed 5% and 10% MO leaf powder52. The reduced serum TC levels may be due to the presence of β-sitosterol57, which decreases the absorption of endogenous cholesterol and enhance its secretion from the gastrointestinal tract and excretion as neutral steroids71. Moreover, reduced lipoprotein levels (especially LDL-c values) may inhibit cholesterol synthesis, causing the hepatic intracellular sterols to be diminished71.

The IgM, complement C3, and LZ levels were decreased in the FIP-intoxicated group. These results suggest that FIP toxicity induced immune suppression in the exposed fish. These findings were parallel to those recorded by El-Murr et al.29 and El-Murr et al.30, who revealed a considerable decline in LZ and IgM values in the FIP-intoxicated tilapia. A similar decrease in LZ levels was also noticed in monosex Nile tilapia intoxicated with sub-lethal FIP level70. Alternatively, the total IgM, complement C3, and LZ were elevated in all MO groups in relation to the FIP and CTR groups. These results were harmonious with those obtained by Mansour et al.72, who noticed that diets supplied with 5% MO leaves led to an increment of LZ, and total IgM in gilthead seabream. Moreover, dietary fermented MO leaves improved the immunity biomarkers in gibel carps, especially LZ, IgM levels, and complement component 3 levels62. Furthermore, Abd El-Gawad and coauthors73 illustrated that MO leaf powder increased LZ activities and IgM of Nile tilapia. The potentiation of the non-specific immune indices of fish fed on MO meals may be accredited to various factors. For example (a) the great number of phytochemicals as polyphenols, carotenoids, and vitamins which possess immune-stimulating functions74,75, (b) the secondary metabolites present in MO leaf extract as phenolics (caffeic, p-coumaric, ellagic, protocatechuic, ferulic, and salicylic acids), flavonoids (kaempferol, rutin, quercetin, catechin, apigenin, epicatechin, isorhamnetin, and myricetin), saponins, carotenoids, tannins, alkaloids, terpenoids, β-sitosterol, coumarins, anthocyanins, anthraquinones, and proanthocyanins9,76, which are helpful to provoke the fish immune responses, and (c) isothiocyanate can positively contribute to the enhancement of the fish immunity77.

Oxidative stress is an overproduction of radicals as reactive oxygen species (ROS), and the body's endogenous antioxidant mechanisms could not scavenge the effects of these ROS78,79. In fish, oxidative stress occurs due to exposure to pollutants and xenobiotics80,81. The existing study found a meaningful reduction in serum SOD and CAT enzyme activities and T-AOC levels and a substantial rise of MDA concentrations in the FIP-intoxicated group. Similarly, it was found that FIP induced oxidative stress damage in the exposed common carp and silver catfish27,82. Moreover, Ghazanfar et al.55 described a noticeable reduction in SOD and CAT enzymes in the gills, liver, kidney, and brain of FIP-intoxicated common carp. Furthermore, FIP toxicity induced a decrease in SOD, glutathione peroxidase (GPX), and CAT enzymes and increased MDA contents in the gills and hepatic tissues of rainbow trout36,37. Interestingly, Abdelkhalek et al.70 also found FIP toxicity is characterized by elevated MDA and NO levels in renal and hepatic tissues of monosex tilapia. Herein, we found that MO leaves extract significantly elevated SOD and CAT enzyme activities and T-AOC levels alongside a considerable decrease of MDA compared with the FIP group. These findings were in harmony with Elabd et al.17, who found that MO leaf meal elevated GPX, SOD, and CAT enzymes in Nile tilapia exposed to stress of starvation. In the same sense, supplementing diets with MO leaf extract efficiently modulated pendimethalin-induced oxidative stress injury in Nile tilapia via a substantial elevation of hepatic GPX, SOD, CAT activities, and T-AOC levels as well as a decrease of hepatic MDA levels of the treated fish41. Moreover, supplementing diets with 7% MO seeds modulated chlorpyrifos-caused oxidative stress in Nile tilapia via increased hepatic CAT and SOD levels and decreased hepatic MDA contents in treated fish40. Dietary supplementation with MO leaf ethanolic extracts significantly counteracted the oxidative stress caused by sub-chronic toxicity by sodium fluoride in Nile tilapia83. Recently, MO leaves meals substantially elevated SOD, CAT, GPX enzymes and decreased MDA concentrations in Nile tilapia19,73. Several reports also showed that herbal supplements could modulate the antioxidant status of fish. For example, Khafaga et al.64 illustrated that supplementing diets with Origanum vulgare essential oil ameliorated cypermethrin-caused oxidative stress in common carp. Similarly, dietary curcumin considerably alleviated FIP-induced tissue oxidative stress in monosex tilapia70. The antioxidative effects of MO are associated with the presence of ascorbic acid, carotenoids, flavonoids, and vitamin E84. Moreover, the relatively plentiful amounts of phenolics can confer the greatest antioxidant effects by stabilizing the free radicals in cells via donation or accepting the electrons6. The presence of glucosinolates also plays a pivotal role in increasing the fish's antioxidant abilities85.

Conclusions

In summary, it can be concluded that long-term exposure to a sub-lethal FIP dose caused growth retardation, changes in the body composition, haemato-biochemical changes, immune depression, and oxidative stress of Nile tilapia. Moreover, using MO leaf ethanolic extract as a natural feed supplement can be considered an important herbal phyto-additive for its protecting functions against the negative impacts of sub-lethal FIP. Endorsements for regular supplementation of MO ethanolic extract at a dose rate of 1.0 g/kg as prophylaxis in aquafeed are important for improving the general health of fish against serious toxicological impacts of some emerging aquatic pollutants.