Yeast nucleotide enhances barrier function by regulating the intestinal microbiota and metabolic pathways of fish to alleviate virus-induced intestinal damage

Yong Shi; Qiushi Zhang; Gaofeng Cheng; Yan Zhang; Peng Yang; Chang Cai; Fayuan Gong; Jianhua Yi; Qianqian Zhang; Weiguang Kong; Zhen Xu

doi:10.1007/s42995-025-00330-9

Marine Life Science & Technology ›› :1 -18. DOI: 10.1007/s42995-025-00330-9

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Yeast nucleotide enhances barrier function by regulating the intestinal microbiota and metabolic pathways of fish to alleviate virus-induced intestinal damage

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Abstract

Yeast nucleotides are known to modulate host immunity and gut microbiota. In teleosts, the intestinal mucosa represents a principal portal of viral entry, compromising barrier integrity, yet the mechanisms by which yeast nucleotides potentiate antiviral defenses remain to be elucidated. Herein, this study performed an eight-week feeding trial of coho salmon with graded yeast nucleotide levels (0, 125, 250, 500, and 1000 mg/kg), followed by intraperitoneal IHNV challenge with sampling at four days post-infection, and an in vitro assessment of intestinal mucus from the control and 500 mg/kg groups co-incubated with EPC cells and IHNV to evaluate antiviral efficacy. Coho salmon showed a biphasic growth response to dietary yeast nucleotides, with the 500 mg/kg group achieving the highest growth among all treatments. Yeast nucleotide enhanced intestinal tight junction integrity by upregulating proteins, such as Occludin, and potentiated mucosal immunity via modulation of NF-κB p65. Notably, yeast nucleotides reshaped gut microbiota and were associated with changes in lipid metabolism and increased levels of bioactive metabolites, with taxa such as Romboutsia, Bacillus, Turicibacter and Clostridium sensu stricto 1 showing significant correlations with these metabolic and immune parameters, although direct functional roles remain to be confirmed. Upon IHNV challenge, the 500 mg/kg group demonstrated significantly reduced cumulative mortality and ameliorated virus-induced disruption of intestinal barrier function compared to the control group. Finally, intestinal mucus from 500 mg/kg yeast nucleotides-fed fish conferred antiviral protection in vitro by upregulating host antiviral gene expression in EPC cells. These findings highlight dietary yeast nucleotides as key modulators of antiviral defense and intestinal barrier integrity potentially through microbiota-associated lipid metabolism and bioactive metabolite profiles, while acknowledging that further functional studies are required to establish causality, offering promising nutritional strategies against virus‐induced gut injury.

Keywords

Yeast nucleotides / Gut microbiota / Mucosal immunity / Intestinal barrier function / Metabolome

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Yong Shi, Qiushi Zhang, Gaofeng Cheng, Yan Zhang, Peng Yang, Chang Cai, Fayuan Gong, Jianhua Yi, Qianqian Zhang, Weiguang Kong, Zhen Xu. Yeast nucleotide enhances barrier function by regulating the intestinal microbiota and metabolic pathways of fish to alleviate virus-induced intestinal damage. Marine Life Science & Technology 1-18 DOI:10.1007/s42995-025-00330-9

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References

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[1]	Ahluwalia B, Magnusson K, Öhman L. Mucosal immune system of the gastrointestinal tract: maintaining balance between the good and the bad. Scand J Gastroenterol, 2017, 52: 1185-1193

[2]	Aleksandrova M, Rahmatova F, Russell A, Bonfio C. Ring opening of glycerol cyclic phosphates leads to a diverse array of potentially prebiotic phospholipids. J Am Chem Soc, 2023, 145: 25614-25620

[3]	Alwin A, Karst M. The influence of microbiota-derived metabolites on viral infections. Curr Opin Virol, 2021, 49: 151-156

[4]	Anwar F, Altayb N, Al-Abbasi A, Al-Malki L, Kamal A, Kumar V. Antiviral effects of probiotic metabolites on COVID-19. J Biomol Struct Dyn, 2021, 39: 4175-4184

[5]	Berkes J, Viswanathan K, Savkovic D, Hecht G. Intestinal epithelial responses to enteric pathogens: effects on the tight junction barrier, ion transport, and inflammation. Gut, 2003, 52: 439-451

[6]	Brown M, Clardy J, Xavier J. Gut microbiome lipid metabolism and its impact on host physiology. Cell Host Microbe, 2023, 31: 173-186

[7]	Chen C, Huang Q, Tang W, Zhang L, Lin F. Effects of dietary nucleotides on growth performance, immune response, intestinal morphology and disease resistance of juvenile largemouth bass, Micropterus salmoides. J Fish Biol, 2022, 101: 204-212

[8]	Colombo M, Roy K, Mraz J, Wan H, Davies J, Tibbetts M, Øverland M, Francis S, Rocker M, Gasco L, Spencer E. Towards achieving circularity and sustainability in feeds for farmed blue foods. Rev Aquacult, 2023, 15: 1115-1141

[9]	Coulombe F, Jaworska J, Verway M, Tzelepis F, Massoud A, Gillard J, Wong G, Kobinger G, Xing Z, Couture C, Joubert P. Targeted prostaglandin E2 inhibition enhances antiviral immunity through induction of type I interferon and apoptosis in macrophages. Immunity, 2014, 40: 554-568

[10]	Coyte Z, Schluter J, Foster R. The ecology of the microbiome: networks, competition, and stability. Science, 2015, 350: 663-666

[11]	Dawood A. Nutritional immunity of fish intestines: important insights for sustainable aquaculture. Rev Aquacult, 2021, 13: 642-663

[12]	Dawood A, Koshio S, Esteban Á. Beneficial roles of feed additives as immunostimulants in aquaculture: a review. Rev Aquacult, 2018, 10: 950-974

[13]	Di Tommaso N, Gasbarrini A, Ponziani R. Intestinal barrier in human health and disease. Int J Environ Res Public Health, 2021, 18 12836

[14]	Ducarmon R, Zwittink D, Hornung V, Van Schaik W, Young B, Kuijper J. Gut microbiota and colonization resistance against bacterial enteric infection. Microbiol Mol Biol Rev, 2019, 83 10–1128

[15]	Ghetas A, Arafa A, Eissa E, Khallaf A. Effects of glucans and nucleotides on the immunity, health, and growth of fish. A review with special reference to the Egyptian situation. J Curr Vet Res, 2025, 7: 63-78

[16]	Gong Y, Zhou X, Shi Z, Chen H, Dan Z. Supplementation of Saccharomycopsis fibuligera nucleotides in soybean-based diets enhanced growth, intestinal health, and reduced inflammatory responses of turbot juveniles (Scophthalmus maximus L.). Aquac Rep, 2024, 37 102198

[17]	Gu M, Pan S, Li Q, Qi Z, Deng W, Bai N. Protective effects of glutamine against soy saponins-induced enteritis, tight junction disruption, oxidative damage and autophagy in the intestine of Scophthalmus maximus L. Fish Shellfish Immunol, 2021, 114: 49-57

[18]	Guo X, Ran C, Zhang Z, He S, Jin M, Zhou Z. The growth-promoting effect of dietary nucleotides in fish is associated with an intestinal microbiota-mediated reduction in energy expenditure. J Nutr, 2017, 147: 781-788

[19]	Guo J, Han X, Huang W, You Y, Jicheng Z. Interaction between IgA and gut microbiota and its role in controlling metabolic syndrome. Obes Rev, 2021, 22 e13155

[20]	Guo Q, Jin Y, Chen X, Ye X, Shen X, Lin M, Zeng C, Zhou T, Zhang J. NF-κB in biology and targeted therapy: new insights and translational implications. Sig Transduct Target Ther, 2024, 9: 53

[21]	Horrocks V, King G, Yip Y, Marques M, McDonald A. Role of the gut microbiota in nutrient competition and protection against intestinal pathogen colonization. Microbiology, 2023, 169 001377

[22]	Hossain S, Koshio S, Ishikawa M, Yokoyama S, Sony M. Dietary nucleotide administration influences growth, immune responses and oxidative stress resistance of juvenile red sea bream (Pagrus major). Aquaculture, 2016, 455: 41-49

[23]	Hossain S, Koshio S, Kestemont P. Recent advances of nucleotide nutrition research in aquaculture: a review. Rev Aquacult, 2020, 12: 1028-1053

[24]	Huang Z, Zhan M, Cheng G, Lin R, Zhai X, Zheng H, Wang Q, Yu Y, Xu Z. Ihnv infection induces strong mucosal immunity and changes of microbiota in trout intestine. Viruses, 2022, 14: 1838

[25]	Huang W, Xiao X, Hu W, Tang T, Bai J, Zhao S, Ao Z, Wei Z, Gao W, Zhang W. Effects of dietary nucleotide and yeast cell wall on growth performance, feed utilization, anti-oxidative and immune response of grass carp (Ctenopharyngodon idella). Fish Shellfish Immunol, 2023, 134 108574

[26]	Kennedy G, Ahern B, Iannotti L, Vie S, Sherburne L, Thilsted H. Considering the food environment can help to promote the consumption of aquatic foods for healthy diets. Front Sustain Food Syst, 2023, 7: 1241548

[27]	Kobayashi M, Yamamoto M. Molecular mechanisms activating the Nrf2-Keap1 pathway of antioxidant gene regulation. Antioxid Redox Signal, 2005, 7: 385-394

[28]	Lee Y, Tsolis M, Bäumler J. The microbiome and gut homeostasis. Science, 2022, 377 eabp9960

[29]	Li Q, Verma M. NF-κB regulation in the immune system. Nat Rev Immunol, 2002, 2: 725-734

[30]

Li S, Yuan N, Guo W, Chai Y, Song Y, Zhao Y, Zeng M, Wu H. Antioxidant and anti-inflammatory protective effects of yellowtail (Seriola quinqueradiata) milt hydrolysates on human intestinal epithelial cells in vitro and dextran sodium sulphate-induced mouse colitis in vitro. Food Funct, 2022, 13: 9169-9182

[31]	Liu Y, Hou Y, Wang G, Zheng X, Hao H. Gut microbial metabolites of aromatic amino acids as signals in host–microbe interplay. Trends Endocrinol Metab, 2020, 31: 818-834

[32]	Liu H, Chen B, Cao Y, Geng Y, Ouyang P, Chen D, Li L, Huang X. High starch diets attenuate the immune function of Micropterus salmoides immune organs by modulating Keap1/Nrf2 and MAPK signaling pathways. Fish Shellfish Immunol, 2023, 142 109079

[33]	Ma C, Liang Z, Wang Y, Luo H, Yang X, Yao B, Tu T. P-hydroxycinnamic acids: advancements in synthetic biology, emerging regulatory targets in gut microbiota interactions, and implications for animal health. J Nutr, 2025, 155: 1041-1056

[34]	Martens C, Neumann M, Desai S. Interactions of commensal and pathogenic microorganisms with the intestinal mucosal barrier. Nat Rev Microbiol, 2018, 16: 457-470

[35]	Medina-Félix D, Garibay-Valdez E, Vargas-Albores F, Martínez-Porchas M. Fish disease and intestinal microbiota: a close and indivisible relationship. Rev Aquacult, 2023, 15: 820-839

[36]	Pereiro P, Figueras A, Novoa B. Compilation of antiviral treatments and strategies to fight fish viruses. Rev Aquacult, 2021, 13: 1223-1254

[37]

Piazzon C, Calduch-Giner A, Fouz B, Estensoro I, Simó-Mirabet P, Puyalto M, Karalazos V, Palenzuela O, Sitjà-Bobadilla A, Pérez-Sánchez J. Under control: how a dietary additive can restore the gut microbiome and proteomic profile, and improve disease resilience in a marine teleostean fish fed vegetable diets. Microbiome, 2017, 5: 164

[38]	Qu Z, Tian P, Wang L, Jin X, Guo M, Lu J, Zhao J, Chen W, Wang G. Dietary nucleotides promote neonatal rat microbiota–gut–brain axis development by affecting gut microbiota composition and metabolic function. J Agric Food Chem, 2023, 71: 19622-19637

[39]	Rahman A, Ashrafudoulla M, Akter S, Park H, Ha D. Probiotics and biofilm interaction in aquaculture for sustainable food security: a review and bibliometric analysis. Crit Rev Food Sci Nutr, 2024, 64: 12319-12335

[40]	Ramasubburayan R, Prakash S, Immanuel G, Mubarakali D, Rajakumar G, Thirumurugan D, Palavesam A. The transformative role of prebiotics, probiotics, and microbiomes in biofloc systems for sustainable aquaculture: a comprehensive review. Rev Aquacult, 2025, 17 e13000

[41]	Ran C, Xie M, Li J, Xie Y, Ding Q, Li Y, Zhou W, Yang Y, Zhang Z, Olsen E, Zhou Z. Dietary nucleotides alleviate hepatic lipid deposition via exogenous AMP-mediated AMPK activation in zebrafish. J Nutr, 2021, 151: 2986-2996

[42]	Reda M, Selim M, Mahmoud R, El-Araby E. Effect of dietary yeast nucleotide on antioxidant activity, non-specific immunity, intestinal cytokines, and disease resistance in Nile tilapia. Fish Shellfish Immunol, 2018, 80: 281-290

[43]	Shi Y, Hu Y, Wang Z, Zhou J, Zhang J, Zhong H, Fu G, Zhong L. The protective effect of taurine on oxidized fish-oil-induced liver oxidative stress and intestinal barrier-function impairment in juvenile ictalurus punctatus. Antioxidants, 2021, 10: 1690

[44]	Shi Y, Zhong L, Liu Y, Xu S, Dai J, Zhang Y, Hu Y. Dietary sanguinarine supplementation recovers the decrease in muscle quality and nutrient composition induced by high-fat diets of grass carp (Ctenopharyngodon idella). Anim Nutr, 2024, 17: 208-219

[45]	Shi Y, Kong W, Gong F, Cai C, Zhang Y, Cheng G, Yang P, Yi J, Xu Z. Yeast β-glucan enhances the intestinal immune function in coho salmon via the modulation of gut microbiota-mediated lipid metabolism. Aquaculture, 2025, 599 742123

[46]	Shu Z, Ding D, Xue M, Cai W, Deng H. Direct and indirect effects of pathogenic bacteria on the integrity of intestinal barrier. Therap Adv Gastroenterol, 2023, 16: 17562848231176427

[47]	Sun Y, Zhang S, Nie Q, He H, Tan H, Geng F, Ji H, Hu J, Nie S. Gut firmicutes: relationship with dietary fiber and role in host homeostasis. Crit Rev Food Sci Nutr, 2023, 63: 12073-12088

[48]	Tian J, Lei X, Ji H, Kaneko G, Zhou S, Yu B, Li Y, Yu M, Xie J. Comparative analysis of effects of dietary arachidonic acid and EPA on growth, tissue fatty acid composition, antioxidant response and lipid metabolism in juvenile grass carp, Ctenopharyngodon idellus. Br J Nutr, 2017, 118: 411-422

[49]	Tsui Y, Wu X, Zhang X, Peng Y, Mok K, Chan K, Ng C, Tun M. Short-chain fatty acids in viral infection: the underlying mechanisms, opportunities, and challenges. Trends Microbiol, 2025, 33: 302-320

[50]	Verdegem M, Buschmann H, Latt W, Dalsgaard A, Lovatelli A. The contribution of aquaculture systems to global aquaculture production. J World Aquacult Soc, 2023, 54: 206-250

[51]	Vogt L, Peña-Díaz J, Finlay B. Chemical communication in the gut: effects of microbiota-generated metabolites on gastrointestinal bacterial pathogens. Anaerobe, 2015, 34: 106-115

[52]	Wang X, Yang S, Li S, Zhao L, Hao Y, Qin J, Zhang L, Zhang C, Bian W, Zuo I, Gao X. Aberrant gut microbiota alters host metabolome and impacts renal failure in humans and rodents. Gut, 2020, 69: 2131-2142

[53]	Wang B, Thompson D, Wangkahart E, Yamkasem J, Bondad-Reantaso G, Tattiyapong P, Jian J, Surachetpong W. Strategies to enhance tilapia immunity to improve their health in aquaculture. Rev Aquacult, 2023, 15: 41-56

[54]	Wen Z, Liu W, Li X, Chen W, Liu Z, Wen J, Liu Z (2019) A protective role of the NRF2-Keap1 pathway in maintaining intestinal barrier function. Oxid Med Cell Longev 1:1759149

[55]	Wilde J, Slack E, Foster R. Host control of the microbiome: mechanisms, evolution, and disease. Science, 2024, 385 eadi3338

[56]	Xia R, Hao Q, Xie Y, Zhang Q, Ran C, Yang Y, Zhou W, Chu F, Zhang X, Wang Y, Zhang Z. Effects of dietary Saccharomyces cerevisiae on growth, intestinal and liver health, intestinal microbiota and disease resistance of channel catfish (Ictalurus punctatus). Aquacult Rep, 2022, 24101157

[57]	Xie M, Hao Q, Xia R, Olsen E, Ringø E, Yang Y, Zhang Z, Ran C, Zhou Z. Nuclease-treated stabilized fermentation product of Cetobacterium somerae improves growth, non-specific immunity, and liver health of zebrafish (Danio rerio). Front Nutr, 2022, 9 918327

[58]	Xu L, Ran C, He S, Zhang J, Hu J, Yang Y, Du Z, Yang Y, Zhou Z. Effects of dietary yeast nucleotides on growth, non-specific immunity, intestine growth and intestinal microbiota of juvenile hybrid tilapia Oreochromis niloticus♀× Oreochromis aureus♂. Anim Nutr, 2015, 1: 244-251

[59]	Yang G, Bibi S, Du M, Suzuki T, Zhu J. Regulation of the intestinal tight junction by natural polyphenols: a mechanistic perspective. Crit Rev Food Sci Nutr, 2017, 57: 3830-3839

[60]

Zhao S, Chen Z, Zheng J, Dai J, Ou W, Xu W, Ai Q, Zhang W, Niu J, Mai K, Zhang Y. Citric acid mitigates soybean meal induced inflammatory response and tight junction disruption by altering TLR signal transduction in the intestine of turbot, Scophthalmus maximus L. Fish Shellfish Immunol, 2019, 92: 181-187

[61]	Zhong L, Wu C, Zhao Y, Huang B, Luo Z, Wu Y. Inflammatory responses and barrier disruption in the trachea of chicks following Mycoplasma gallisepticum infection: a focus on the TNF-α-NF-κB/MLCK pathway. Vet Res, 2024, 55: 8

[62]	Złotek U, Szymanowska U, Pecio Ł, Kozachok S, Jakubczyk A. Antioxidative and potentially anti-inflammatory activity of phenolics from lovage leaves Levisticum officinale Koch elicited with jasmonic acid and yeast extract. Molecules, 2019, 24: 1441