Abstract
Stress enhances the disease susceptibility in fish by altering the innate immune responses, which are essential defense mechanisms. The use of probiotics is increasingly popular in the aquaculture industry. Yellow perch is a promising candidate for aquaculture. We investigated the efficiency of a mixed Bacillus species in minimizing the potential problems resulting from husbandry practices such as hypoxia and exposure to air in yellow perch. We showed that hypoxia and air exposure conditions induced a significant reduction in the early innate immune response (lysozyme activity, interferon-induced-GTP-binding protein-Mx1 [mx], interleukin-1β [il1β], serum amyloid-A [saa]), and a substantial increase in cortisol, heat shock protein (Hsp70), glutathione peroxidase (Gpx), superoxide dismutase (Sod1) that associated with a decline in insulin-like growth factor-1 (Igf1). Mixed Bacillus species administration improved the early innate responses, reduced cortisol, Hsp70, Gpx and Sod1, and elevated Igf1 levels. Bacillus species treated group showed faster recovery to reach the baseline levels during 24 h compared to untreated group. Therefore, mixed Bacillus species may enhance yellow perch welfare by improving the stress tolerance and early innate immune response to counterbalance the various husbandry stressors. Further studies are warranted to investigate the correlations between the aquaculture practices and disease resistance in yellow perch.
Similar content being viewed by others
Introduction
The innate immune system is a key defense missile of invertebrates and an essential defense mechanism of fish to maintain the homeostasis1. The early innate immune response in fish is regularly associated with the initiation of the inflammatory cascades such as interferon-induced GTP-binding protein-Mx1 (Mx), interleukin 1β (IL-1β), and serum amyloid-A (SAA)2 in response to a particular stressor1,3. Whereas Mx transcript is a direct marker of type I interferon (IFNα and IFNβ) activation, IL-1β is a proinflammatory cytokine, and SAA is acute phase protein primary synthesized in liver4,5. Moreover, the lysozyme triggers the complement system and phagocytic cells to fight against various pathogens1.
Probiotics can enhance the stress tolerance, immune responses and pathogen antagonism6,7,8,9. Stress is a contributing factor in the high mortality and diseases in aquaculture and fisheries stock enhancement10. Probiotics can enhance the stress tolerance in fish and other aquatic species by priming fish in advance to counteract environmental and husbandry stressors11, which sharply impact plasma cortisol levels in fish12,13. Cortisol is the primary corticosteroid hormone in fish and its levels are increased in response to various stressors10,13 to supplying the energy through glycogen, lipids and protein catabolism for metabolic adaptation14.
In fish, stress response occurs at the cellular level, which comprises various heat shock proteins (HSP), which have a protective role in maintaining the hemostasis10. Many studies reported a correspondence between increased levels of HSP and exposure to stressors, indicating that HSP are play a significant role in the survival and health of the stressed fish15,16. Stress has a negative impact on fish growth and the expression of insulin like growth factor (Igf). Stressors enhance the production of reactive oxygen species (ROS), which can endorse physiological dysregulation in fish due to high energy requirement and possible imbalance of the antioxidant defenses17,18. Fish possess antioxidant enzymes to counterbalance the cell damage and enzyme inactivation. These enzymes include superoxide dismutase (Sod1), which catalyzes the dismutation of superoxide radicals to hydrogen peroxide and oxygen. Glutathione peroxidase (Gpx) is a selenium-dependent enzyme, which crumbles peroxides using the peptide glutathione as their co-substrate that establish the antioxidant enzymatic defense10.
Yellow perch is a freshwater species that has economic importance in North America13. However, the physiological and immune responses of yellow perch have not been well studied and are poorly understood. Thus, we investigated the potential efficiency of commercial water-soluble probiotic product (Fishery PrimeTM, Keeton Industries, USA), which is a mixed bacillus species, in the early innate immune responses and stress tolerance in yellow perch in response to hypoxia and exposure to air stress.
Results
A mixed Bacillus Species enhances the lysozyme activity in Yellow perch subjected to experimental hypoxia and exposure to air stressors
In naive conditions, the absence of stressors, the mixed bacillus sp. administration significantly elevated the plasma lysozyme activity compared to control group (Fig. 1A,B). Furthermore, yellow perch that subjected to experimental hypoxia and air exposure stressors showed a significant decrease in plasma lysozyme activity compared to the control groups (Fig. 1A,B). Yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus species showed a significant increase in plasma lysozyme activity compared to hypoxic and air exposed groups (Fig. 1A,B). Moreover, the mixed bacillus species administration accelerated the return of lysozyme to the proper range over the time within 24 h (Fig. 1A,B).
A mixed Bacillus Species induces hepatic gene expression of early innate immune mediators in Yellow perch subjected to experimental hypoxia and exposure to air stressors
The experimental hypoxia and air exposure stressors in yellow perch resulted in a significant increase in hepatic gene expression of il1β, mx, and saa compared to the control groups (Fig. 2A–C). Interestingly, yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus sp. enhanced the increase of il1β, mx and saa levels compared to hypoxic and air exposed groups (Fig. 2A–C). Moreover, the mixed bacillus species administration accelerated the return of hepatic mRNA levels of il1β, mx, and saa to the normal range compared to untreated hypoxic and air exposed groups (Fig. 2A–C). In naive conditions, unstressed yellow perch, the mixed bacillus sp. did not have any significant effect on their levels (Fig. 2A–C).
A mixed Bacillus Species attenuates cortisol-stress response in Yellow perch subjected to experimental hypoxia and exposure to air stressors
Yellow perch that subjected to experimental hypoxia and air exposure stressors showed a significant elevation of plasma cortisol levels compared to the control groups (Fig. 3A,B). Interestingly, yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus sp. showed a significant decrease in the plasma cortisol levels compared to hypoxic and air exposed groups (Fig. 3A,B). Moreover, the mixed bacillus species administration accelerated the return of cortisol levels to be within the normal range (Fig. 3A,B). In naive conditions, unstressed yellow perch, the mixed bacillus sp. did not have any significant effect on the cortisol levels (Fig. 3A,B).
A mixed Bacillus Species promotes plasma and hepatic Igf1 expression in naive yellow perch and that subjected to experimental hypoxia and exposure to air stressors
In naive conditions, unstressed yellow perch, the mixed bacillus sp. administration significantly increased plasma Igf1 protein level and hepatic mRNA expression compared to control group (Fig. 4). Furthermore, yellow perch that subjected to experimental hypoxia and air exposure stressors showed a significant reduction not only in plasma Igf1 levels but also hepatic igf1 mRNA expression compared to the control groups (Fig. 4). Remarkably, yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus sp. showed a significant increase in plasma protein level of Igf1 (Fig. 4A,B) and upregulation in hepatic igf1 mRNA expression compared to hypoxic and air exposed groups (Fig. 4C,D). Moreover, the mixed bacillus species administration accelerated the elevation of Igf1 protein and mRNA levels to be within the normal range over the time-dependent manner (Fig. 4).
A mixed Bacillus Species reduces plasma and hepatic Hsp70 response in Yellow perch subjected to experimental hypoxia and exposure to air stressors
Yellow perch that subjected to experimental hypoxia and air exposure stressors showed a significant elevation of plasma Hsp70 protein level and hepatic hsp70 mRNA expression compared to the control groups (Fig. 5). Fascinatingly, yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus sp. showed a significant decline in the plasma Hsp70 protein level and hepatic hsp70 mRNA expression compared to hypoxic and air exposed groups (Fig. 5). Moreover, the mixed bacillus species administration accelerated the return of plasma Hsp70 protein levels and hepatic hsp70 mRNA expression to be within the normal range over the time-dependent manner (Fig. 5). In naive conditions, unstressed yellow perch, the mixed bacillus sp. The probiotics did not have any significant effect on Hsp70 levels (Fig. 5).
A mixed Bacillus Species decreases oxidative stress response in Yellow perch subjected to experimental hypoxia and exposure to air stressors
Yellow perch that subjected to experimental hypoxia and air exposure stressors showed a significant elevation of plasma Gpx and Sod1 protein levels as well as their hepatic mRNA expression compared to the control groups (Figs 6 and 7). Excitingly, yellow perch that subjected to experimental hypoxia and air exposure and received the mixed bacillus sp. showed a significant reduction in the plasma Gpx and Sod1 protein level and hepatic gpx and sod1 mRNA expression compared to hypoxic and air exposed groups (Figs 6 and 7). Moreover, the mixed bacillus species administration accelerated the return of oxidative stress markers to be within the normal range over the time-dependent manner (Figs 6 and 7). In naive conditions, unstressed yellow perch, the mixed bacillus sp. The probiotics did not have any significant effect on Gpx and Sod1 levels (Figs 6 and 7).
The time effect, group effect and their interactions on all investigated parameters showed statistical significance (P < 0.0001).
Discussion
The present study provides an evidence on the beneficial features of water-soluble mixed bacillus species on the physiological and molecular early innate immune and stress responses in yellow perch, which is an important aquaculture species in North America. This study showed that mixed bacillus species enhanced the lysozyme activity and the mediators of acute phase response that are critical as the first line of defense against various pathogens. Furthermore, the mixed bacillus species minimized the stress responses that exhibited a decrease in cortisol, Hsp70 signaling, and oxidative stress-related markers and an increase in the growth-related factor (Igf1). These consequences are beneficial, where aquaculture species could be treated in advance with probiotics to face critical hypoxia and exposure to air that weakened the immune defense mechanisms.
The innate immune system, including physical barriers, and cellular and humoral components, functions as a defense weapon in invertebrates11. Early innate immunity (lysozyme activity and acute phase inflammatory mediators [il1β, mx, saa]) is the first line of defense in fish and provides the initial resistance to pathogens within the first hours2,19. We found that mixed bacillus species, a probiotic, enhanced the early innate responses of yellow perch in response to hypoxia and air stress. Air exposure stress and hypoxia can result in several physiological and behavioral consequences of catch-and-release angling such as mucus removal, which is critical in the defense mechanism20. Therefore, our study show that mixed bacillus species can increase early innate immunity and compensate the mucus removal. Several reports also linked the beneficial effects of probiotics with the upregulation of immune related genes, which refer to appropriate functions of the innate immune response8,9,21,22. However, an aberrant immune activation results in detrimental effects that impact overall health11,23,24,25,26 supporting the potential immunomodulatory of mixed bacillus species by accelerating the recovery from the acute phase innate immune response in this study.
Cortisol plays critical roles in osmoregulation and to mitigate various infectious and non-infectious stressors27,28,29 by regulating the metabolic energy, hydromineral balance, oxygen uptake, hemostasis, and immune competence14,30. However, chronic increase in cortisol levels is harmful to fish31. Our study showed that mixed bacillus species reduced the plasma cortisol levels in yellow perch that subjected to hypoxic and air exposure stress. We showed previously that yellow perch subjected to handling and thermal stress elevated cortisol levels13. Probiotics attenuate the high cortisol levels in fish species subjected to different stressors32,33. These results can explain that the use of prophylaxis probiotics may elevate energy accessibility to supply with the metabolic support and expand the stress coping capability of fish34. Although we only investigated the cortisol levels but also sympathetic-chromaffin cells system plays central roles in the stress responses to establish the paracrine immune-endocrine interactions in fish35. Catecholamines secretion from fish chromaffin cells is mediated by a host of cholinergic and non-cholinergic pathways that warrant sufficient dynamics in the secretion process to permit harmonized responses to a wide array of stressors36. Therefore, the probiotics might be beneficial in mitigating the deleterious effects of various stressors by regulating hypothalamic-pituitary-interrenal (HPI) and sympathetic-chromaffin cells systems.
Cortisol is the primary hormonal reactions during the primary stage of the stress response14,30. However, Cortisol alone does not afford definitive explanations for the stress responses14. Thus, we investigated the plasma protein and hepatic mRNA expression levels of of Hsp70. Interestingly, we found that water-soluble mixed Bacillus species decreased the levels of Hsp70 significantly in time dependent manner. A characteristic feature of fish with stress response can be reflected by various Hsp changes37,38, which play important roles in stress physiology and endocrinology, stress tolerance, and acclimation39 by regulating glucocorticoid receptors40,41. IGF-I is extremely vital for the regulation of growth and cell functions42. Stress is reported to have severe negative effects on growth43. Our study showed that mixed bacillus species induced the release of plasma Igf1 and hepatic igf1 mRNA levels in yellow perch that subjected to hypoxic and air exposure stress. Moreover, in naive condition, yellow perch that received mixed Bacillus spp. showed an elevated Igf1 level to compared to control group suggesting an increase in the growth performance parameters. Our results in accordance with that the administration of probiotics promotes Igf1 expression44 and correlates with the growth performance45. Stress induces oxidative tissue damage by enhancing the production of reactive oxygen species (ROS), which further promotes protein damage and activate the antioxidant system (Gpx and Sod1) to neutralize the impact of ROS46. Attractively, we found that water-soluble mixed Bacillus species diminished Gpx and Sod1 levels. The anti-oxidative properties of probiotics help to counteract oxidative stresses by promoting the early innate immune system17 as we showed in this study. A mixture of multi-species probiotic acts beneficially in mitigating the stressful effects in a tropical freshwater fish46. Furthermore, probiotics administration led to a significant decrease of Sod1 and gpx gene expression17,47.
This study is, up to our knowledge, the first example of the evaluation of beneficial effects of a mixed bacillus species on the kinetics of early innate immune and stress responses of yellow perch in response to hypoxia and exposure to air stressors. To cope with stress, fish need to be immunologically ready to meet the demand and quickly restore the normal physiological conditions. This can be achieved through preparing the fish in advance with probiotic treatment to mitigate the common aquaculture stressors. This study is a positive step to find more alternative ways to increase immune function and stress tolerance and improve yellow perch aquaculture. Further studies are required to understand how exactly mixed Bacillus spp enhanced the immune response and stress tolerance by investigating the involved intracellular signaling pathways.
Material and Methods
Animal ethics
The experiments were designed and conducted at the Aquaculture Research Center, The Ohio State University South Centers, Piketon, OH, USA. All experimental procedures involving animals were approved by the Ohio State University Institutional Animal Care and Use Committee and were carried out in compliance with the U.S. regulations governing biological research with vertebrates.
Experimental Fish
Yellow Perch (20 ± 2.5 g) were obtained from the Aquaculture Research Center, Ohio State University South Centers, Ohio, USA. Before transfer, fish were grown together in 1000-L tanks and fed twice daily to satiation with a commercial diet, AquaMaxTM basal diet (Crude Protein Minimum 45–50.0%, Crude Fat Minimum 16.0%, Crude Fiber Maximum 3.0%, Phosphorous (P) Minimum 1.3%, Sodium (NA) Minimum 0.1%, Sodium (NA) Maximum 0.5%). Two weeks before experimentation, fish were transferred to twenty-four 400-L tanks (60 fish/tank) to acclimate to the experimental system that has a single bio-filter in a recirculating water system. Salinity was maintained near physiological optimum at 2–3% and the water temperature was kept at 20 °C13.
Probiotic administration
After acclimation, one of the experimented group, three replicates, depended on the natural water supply and served as a control (19 ± 2.5 g). The other group, three replicates, received (20 ± 1.5 g) the commercial mixed Bacillus species probiotic (Fishery PrimeTM, Keeton Industries, USA) which is water soluble beneficial microbes’ product (Non-pathogenic naturally occurring bacteria on a food-grade cornmeal base Bacillus Species (Bacillus subtilis, Bacillus pumlis, Bacillus amyloliqueficiens and Bacillus licheniformis) and 70% water solubility). The probiotic applied directly into the water at rate 5 g daily for the Probiotic-Treated group for six weeks.
Experimental design
Acute hypoxia
Air supply and water flow were stopped to three tanks from the probiotic receiving group and three tanks from the control group (An interval of 30-min between the tanks). Oxygen levels were monitored using a YSI-55 dissolved oxygen meter (YSI Inc., Yellow Springs, Ohio). After 5 h, when dissolved oxygen levels decreased to 1 mg/L, random three fish per replicate (9/group) were collected for blood and tissue sampling. The remaining fish were transferred into new, oxygenated tanks. Fish samples were collected at 0, 1, 2, 4, 6 and 24 h post-exposure to air.
Exposure to Air
Fish groups were subjected to air exposure stress by netting fish out of the tank for 60 seconds, and three fish per replicate were collected for further analysis (n = 9 fish/group) (with 30-min intervals between tanks). Fish samples were collected at 0, 1, 2, 4, 6 and 24 h post-exposure to air.
Blood Plasma and tissue sampling
Fish were gently captured and immediately immersed in a bucket containing a lethal dose of tricaine methanesulfonate (400 mg/L) (Syndel Laboratories Ltd., Vancouver, British Columbia). Blood samples were collected from the caudal vein using a 5-ml heparinized syringe. Plasma was separated by centrifugation (1000 g for 10 min) at 4 °C, removed and stored in 1.5-ml microcentrifuge tubes at −80 °C for subsequent analysis. Fish were carefully dissected, and whole livers were collected.
Plasma Lysozyme activity
Lysozyme activity was quantified using Lysozyme Detection kit’s (Sigma-Aldrich, USA) as described in the manufacture’s protocol. Each blood plasma sample was measured with three parallels, and their average was used for the analysis. Briefly, lysozyme activity was measured using a Microplate Spectrophotometer (BioTek’s Epoch™, USA) at 450 nm and using the following formula: Lysozyme activity (U/ml) = [(ΔA450/min Test − ΔA450/min Blank) × (dilution factor)]/[(0.001) × (0.03)].
Cortisol and protein Assays
Plasma cortisol levels were determined using an enzyme-linked immunosorbent assay (ELISA) kit (NEOGEN®, Lexington, Kentucky) according to the manufacturer’s instructions. Briefly, 50 μL of standards or samples were added to the appropriate wells in duplicate, and then 50 μL of the diluted enzyme conjugate was added to each well and mixed by shaking plate gently then incubated for 1 h then washing. 150 μL of substrate were added and incubated at room temperature for 30 minutes. Plate was gently shaked before taking a reading to ensure uniform color throughout each well. Plates were read with BioTek microplate reader at an absorbance of 490–630 nm. Finally, absorbance values were calculated for standards and samples and the concentration of each sample was determined using the standard curve. The protein levels of Hsp70, Igf1, Gpx and Sod148 in plasma were measured spectrophotometrically (BioTek’s Epoch™, USA) using colorimetric kits (Cayman Chemical, USA) and (MyBioSource, Inc. San Diego, CA, USA)48.
Gene expression analysis
Total RNA was extracted from liver samples using following the TRIzol Reagent (Invitrogen, USA) protocol. The quality and quantity of RNA were assessed. Synthesis of cDNA was carried out using a High Capacity cDNA Reverse Transcription Kit (Applied Biosystem®, USA) following the manufacturer’s instruction in a Bio-Rad® Thermo cycler. A quantitative real-time polymerase chain reaction (RT-qPCR) was performed using the real-time PCR 7500 system (Applied Biosystem®, USA) to quantify il1β, mx, saa, hsp70, igf1, gpx3, sod1 and β-actin mRNA expressions. The sequence of primers was used as published previously2,49 (Table 1). Primers were tested and validated using NCBI BLAST and Integrated DNA Technologies’ Oligoanalyzer 3.1. PCR efficiencies of the primers were between 90 and 100%. PCR amplifications were performed for each primer, and then the products were run on 1% agarose gels stained with SYBR® safe (Invitrogen™, USA) to confirm that the primers amplified single products. Each amplification reaction mixture (20 μl) contained 100 ng of cDNA; 1× SYBR® Green Master Mixes (Applied biosystem, USA); 200 nM of each primer. The quantitative gene expression levels were calculated and analyzed50,51. All measurements were performed in triplicate. The specific quantities were normalized against the amount of β-actin amplified.
Statistical analysis
Two-Way repeated measure analysis of variance (ANOVA) followed by multiple comparison tests was used for testing mean differences between groups at the different time points at significance levels (P ≤ 0.05). GraphPad Prism version 6 was used for all statistical analysis & creating the graphs.
References
Magnadóttir, B. Innate immunity of fish (overview). Fish & shellfish immunology 20, 137–151 (2006).
Olson, W. et al. Expression kinetics of key genes in the early innate immune response to Great Lakes viral hemorrhagic septicemia virus IVb infection in yellow perch (Perca flavescens). Developmental & Comparative Immunology 41, 11–19 (2013).
Bayne, C., Gerwick, L., Fujiki, K., Nakao, M. & Yano, T. Immune-relevant (including acute phase) genes identified in the livers of rainbow trout, Oncorhynchus mykiss, by means of suppression subtractive hybridization. Developmental & Comparative Immunology 25, 205–217 (2001).
Tafalla, C., Coll, J. & Secombes, C. Expression of genes related to the early immune response in rainbow trout (Oncorhynchus mykiss) after viral haemorrhagic septicemia virus (VHSV) infection. Developmental & Comparative Immunology 29, 615–626 (2005).
Goetz, F. W. et al. Analysis of genes isolated from lipopolysaccharide-stimulated rainbow trout (Oncorhynchus mykiss) macrophages. Molecular immunology 41, 1199–1210 (2004).
Shaheen, A., Eissa, N., Abou-Elgheit, E., Yao, H. & Wang, H.-P. Probiotic effect on molecular antioxidant profiles in yellow perch, Perca flavescens. Global Journal of Fisheries and Aquaculture Researches 1, 16–29 (2014).
Shaheen, A., Eissa, N., Abou-Elgheit, E., Yao, H. & Wang, H.-P. Effect of probiotic on growth performance and growth-regulated genes in yellow perch (Perca flavescens). Global Journal of Fisheries and Aquaculture Researches 1, 01–15 (2014).
Eissa, N. & Abou-ElGheit, E. Dietary Supplementation Impacts of Potential Non-Pathogenic Isolates on Growth Performance, Hematological Parameters and Disease Resistance in Nile Tilapia (Oreochromis Niloticus). J. Vet. Adv 4, 712–719 (2014).
Eissa, N., Abou El-Gheit, N. & Shaheen, A. A. Protective effect of Pseudomonas fluorescens as a probiotic in controlling fish pathogens. American Journal of BioScience 2, 175–181 (2014).
Eissa, N. & Wang, H.-P. Transcriptional stress responses to environmental and husbandry stressors in aquaculture species. Reviews in Aquaculture 8, 61–88, https://doi.org/10.1111/raq.12081 (2016).
Nayak, S. Probiotics and immunity: a fish perspective. Fish & shellfish immunology 29, 2–14 (2010).
Acerete, L., Balasch, J., Espinosa, E., Josa, A. & Tort, L. Physiological responses in Eurasian perch (Perca fluviatilis, L.) subjected to stress by transport and handling. Aquaculture 237, 167–178 (2004).
Eissa, N. & Wang, H.-P. Physiological Stress Response of Yellow Perch Subjected to Repeated Handlings and Salt Treatments at Different Temperatures. North American Journal of Aquaculture 75, 449–454 (2013).
Barton, B. A. Stress in fishes: a diversity of responses with particular reference to changes in circulating corticosteroids. Integrative and comparative biology 42, 517–525 (2002).
Yamashita, M., Yabu, T. & Ojima, N. Stress protein HSP70 in fish. Aqua-BioScience Monographs 3, 111–141 (2010).
Sinha, A. K. et al. Expression pattern of potential biomarker genes related to growth, ion regulation and stress in response to ammonia exposure, food deprivation and exercise in common carp (Cyprinus carpio). Aquatic Toxicology 122–123, 93–105, https://doi.org/10.1016/j.aquatox.2012.05.013 (2012).
Tovar-Ramírez, D. et al. Dietary probiotic live yeast modulates antioxidant enzyme activities and gene expression of sea bass (Dicentrarchus labrax) larvae. Aquaculture 300, 142–147 (2010).
Buetler, T. M., Krauskopf, A. & Ruegg, U. T. Role of superoxide as a signaling molecule. Physiology 19, 120–123 (2004).
Kim, D.-H. & Austin, B. Innate immune responses in rainbow trout (Oncorhynchus mykiss, Walbaum) induced by probiotics. Fish & shellfish immunology 21, 513–524 (2006).
Hannan, K. D., Zuckerman, Z. C., Haak, C. R. & Shultz, A. D. Impacts of sun protection on feeding behavior and mucus removal of bonefish, Albula vulpes. Environmental Biology of Fishes 98, 2297–2304 (2015).
Eissa, N. & AbouElgheit, E. Efficacy of Pseudomonas fluorescens as Biological Control Agent against Aeromonas hydrophila Infection in Oreochromis niloticus. World J. Fish Marine Sci 3, 564–569 (2011).
Eissa, N., El-Ghiet, A. & E. N., S. Characterization of Pseudomonas Species Isolated from Tilapia” Oreochromis niloticus” in Qaroun and Wadi-El-Rayan Lakes, Egypt. Global Veterinaria 5, 116–121 (2010).
Eissa, N. et al. Chromogranin-A Regulates Macrophage Function and the Apoptotic Pathway in Murine DSS colitis. Journal of Molecular Medicine 96, 183–198, https://doi.org/10.1007/s00109-017-1613-6 (2018).
Abdelhamid, L., Hussein, H., Ghanem, M. & Eissa, N. Retinoic acid-mediated anti-inflammatory responses in equine immune cells stimulated by LPS and allogeneic mesenchymal stem cells. Research in veterinary science 114, 225–232 (2017).
Eissa, N. et al. Chromofungin (CHR: CHGA47–66) is downregulated in persons with active ulcerative colitis and suppresses pro-inflammatory macrophage function through the inhibition of NF-κB signaling. Biochemical pharmacology 145, 102–113 (2017).
Eissa, N. et al. Chromofungin ameliorates the Progression of colitis by regulating alternatively activated Macrophages. Frontiers in immunology 8, 1131 (2017).
Midwood, J. D. et al. Does cortisol manipulation influence outmigration behaviour, survival and growth of sea trout? A field test of carryover effects in wild fish. Mar Ecol Prog Ser 496, 135–144 (2014).
Koakoski, G. et al. Agrichemicals chronically inhibit the cortisol response to stress in fish. Chemosphere 112, 85–91 (2014).
Fatira, E., Papandroulakis, N. & Pavlidis, M. Diel changes in plasma cortisol and effects of size and stress duration on the cortisol response in European sea bass (Dicentrarchus labrax). Fish physiology and biochemistry 40, 911–919 (2014).
Wendelaar Bonga, S. E. The stress response in fish. Physiol Rev 77, 591–625 (1997).
Pickering, A. D., Pottinger, T. G., Carragher, J. & Sumpter, J. P. The effects of acute and chronic stress on the levels of reproductive hormones in the plasma of mature male brown trout, Salmo trutta L. General and Comparative Endocrinology 68, 249–259, https://doi.org/10.1016/0016-6480(87)90036-0 (1987).
Varela, J. et al. Dietary administration of probiotic Pdp11 promotes growth and improves stress tolerance to high stocking density in gilthead seabream Sparus auratus. Aquaculture 309, 265–271 (2010).
Gonçalves, A. T., Maita, M., Futami, K., Endo, M. & Katagiri, T. Effects of a probiotic bacterial Lactobacillus rhamnosus dietary supplement on the crowding stress response of juvenile Nile tilapia Oreochromis niloticus. Fisheries Science 77, 633–642 (2011).
Moloney, R. D., Desbonnet, L., Clarke, G., Dinan, T. G. & Cryan, J. F. The microbiome: stress, health and disease. Mammalian Genome 25, 49–74 (2014).
Nardocci, G. et al. Neuroendocrine mechanisms for immune system regulation during stress in fish. Fish & shellfish immunology 40, 531–538 (2014).
Perry, S. F. & Capaldo, A. The autonomic nervous system and chromaffin tissue: neuroendocrine regulation of catecholamine secretion in non-mammalian vertebrates. Autonomic Neuroscience: Basic and Clinical 165, 54–66 (2011).
Multhoff, G. Heat shock protein 70 (Hsp70): membrane location, export and immunological relevance. Methods 43, 229–237 (2007).
Keller, J. M., Escara-Wilke, J. F. & Keller, E. T. Heat stress-induced heat shock protein 70 expression is dependent on ERK activation in zebrafish (Danio rerio)cells. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 150, 307–314 (2008).
Basu, N. et al. Heat shock protein genes and their functional significance in fish. Gene 295, 173–183 (2002).
Grad, I. & Picard, D. The glucocorticoid responses are shaped by molecular chaperones. Molecular and cellular endocrinology 275, 2–12 (2007).
Tripathi, G. & Verma, P. Pathway-specific response to cortisol in the metabolism of catfish. Comparative Biochemistry and Physiology Part B: Biochemistry and Molecular Biology 136, 463–471 (2003).
Solberg, M. F., Kvamme, B. O., Nilsen, F. & Glover, K. A. Effects of environmental stress on mRNA expression levels of seven genes related to oxidative stress and growth in Atlantic salmon Salmo salar L. of farmed, hybrid and wild origin. BMC research notes 5, 672 (2012).
Bertotto, D. et al. Whole body cortisol and expression of HSP70, IGF-I and MSTN in early development of sea bass subjected to heat shock. General and Comparative Endocrinology 174, 44–50 (2011).
Carnevali, O. et al. Growth improvement by probiotic in European sea bass juveniles (Dicentrarchus labrax, L.), with particular attention to IGF-1, myostatin and cortisol gene expression. Aquaculture 258, 430–438 (2006).
Avella, M. A., Olivotto, I., Silvi, S., Place, A. R. & Carnevali, O. Effect of dietary probiotics on clownfish: a molecular approach to define how lactic acid bacteria modulate development in a marine fish. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology 298, R359–R371 (2010).
Castex, M., Lemaire, P., Wabete, N. & Chim, L. Effect of dietary probiotic Pediococcus acidilactici on antioxidant defences and oxidative stress status of shrimp Litopenaeus stylirostris. Aquaculture 294, 306–313 (2009).
Gioacchini, G. et al. The Influence of Probiotics on Zebrafish Danio Rerio Innate Immunity and Hepatic Stress. Zebrafish 11, 98–106 (2014).
Eissa, N. et al. Expression of Hsp70, Igf1, and Three Oxidative Stress Biomarkers in Response to Handling and Salt Treatment at Different Water Temperatures in Yellow Perch, Perca flavescens. Frontiers in physiology 8, 683 (2017).
Martin, J. D., Colson, T. L. L., Langlois, V. S. & Metcalfe, C. D. Biomarkers of exposure to nanosilver and silver accumulation in yellow perch (Perca flavescens). Environmental toxicology and chemistry 36, 1211–1220 (2017).
Eissa, N. et al. Stability of Reference Genes for Messenger RNA Quantification by Real-Time PCR in Mouse Dextran Sodium Sulfate Experimental Colitis. Plos One 11, e0156289 (2016).
Eissa, N., Kermarrec, L., Hussein, H., Bernstein, C. N. & Ghia, J.-E. Appropriateness of reference genes for normalizing messenger RNA in mouse 2, 4-dinitrobenzene sulfonic acid (DNBS)-induced colitis using quantitative real time PCR. Scientific Reports 7 (2017).
Acknowledgements
We thank Dean Rapp and Paul O’Bryant for their assistance in managing experimental fish, and Joy Bauman for her comments on the manuscript. The National Institute of Food and Agriculture (NIFA), U.S. Department of Agriculture, under Agreement No. 2009-38879-19835, and National Institute of Oceanography & Fisheries, Ministry of Higher Education and Scientific Research, Egypt supported this work. Salaries and research support were provided by state and federal funds appropriated to The Ohio State University, Ohio Agricultural Research, and Development Center.
Author information
Authors and Affiliations
Contributions
Concept and design of the experiments: H.P.W., N.E. Conduction of the wet lab experiments and data analysis: N.E. Data collection & handling: N.E. Performed research: H.Y., E.A. Wrote the manuscript N.E., H.P.W. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Competing Interests
The authors declare no competing interests.
Additional information
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Eissa, N., Wang, HP., Yao, H. et al. Mixed Bacillus Species Enhance the Innate Immune Response and Stress Tolerance in Yellow Perch Subjected to Hypoxia and Air-Exposure Stress. Sci Rep 8, 6891 (2018). https://doi.org/10.1038/s41598-018-25269-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-018-25269-z
This article is cited by
-
Integrated mRNA and miRNA analysis reveals the regulatory network of oxidative stress and inflammation in Coilia nasus brains during air exposure and salinity mitigation
BMC Genomics (2024)
-
Effects of Dietary Supplementation with Bacillus amyloliquefaciens US573 on Intestinal Morphology and Gut Microbiota of European Sea Bass
Probiotics and Antimicrobial Proteins (2023)
-
Mechanisms and the role of probiotic Bacillus in mitigating fish pathogens in aquaculture
Fish Physiology and Biochemistry (2020)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.