DHAV-3感染对不同日龄雏鸭胆汁分泌通路的影响

doi:10.16431/j.cnki.1671-7236.2025.06.035

Abstract

Abstract: 【Objective】 Duck hepatitis A virus genotype 3 (DHAV-3) was one of the primary pathogens causing acute lethal hepatitis in ducklings,with pathogenicity exhibiting significant age-dependent characteristics.This study aimed to elucidate the regulatory mechanisms of bile secretion pathway in ducklings of different ages infected with DHAV-3 and reveal the impact of host age factors on the viral pathogenic process.【Method】 Z2 strain Pekin ducks were used as the experimental subjects,divided into three experimental groups of 7,14 and 21 days of age (50/group),along with corresponding control groups (15/group).The ducklings in infected groups were administered 0.2 mL DHAV-3 (10^-8.83 ELD₅₀/0.2 mL) via intramuscular injection,while the ducklings in control groups were injected with an equivalent volume of PBS.The ducks were raised separately until 18 hours post-infection,at which point blood,liver and ileum samples were collected.The following parameters were analyzed:Plasma biochemical indices,viral load,total bile acid (TBA) content,and the expression of bile secretion pathway-related genes.【Result】 The viral load in liver of ducklings in all age groups was significantly higher than that in ileum (P＜0.05),and the viral load in the liver of 7-day-old ducklings was significantly higher than that of 14- and 21-day-old ducklings (P＜0.05).The activity of aspartate aminotransferase (AST) and the level of total cholesterol (CHOL) in the plasma of ducklings showed a significantly decrease with increasing age in control group (P＜0.05).After DHAV-3 infection,the CHOL levels in the plasma of 7-day-old ducklings in infected group were significantly reduced compared to control group (P＜0.05),while they were significantly increased at 14 and 21 days of age (P＜0.05),accompanied by a significant increase in immunoglobulin Y (IgY) levels (P＜0.05).Bile acid metabolism displayed tissue-specific regulation.In control group,TBA level in liver decreased with advancing age,while in ileum,it increased with increasing age.Following DHAV-3 infection,the TBA in liver and ileum of ducklings in the 7-day-old infected group were significantly decreased (P＜0.05).In the 14-day-old group,a reverse regulation pattern was observed,with liver TBA level increasing and ileal TBA level decreasing (P＜0.05).In the 21-day-old group,both liver and ileum TBA levels significantly increased (P＜0.05).The bile secretion pathway-related genes cholesterol-7α-hydroxylase (CYP7A1),ATP binding cassette transporter G5 (ABCG5) and ABCG8 were significantly upregulated with advancing age in liver of ducklings in control group (P＜0.05).After DHAV-3 infection,CYP7A1 gene transcription levels in the 14- and 21-day-old ducks were significantly decreased (P＜0.05),while ABCG5 and ABCG8 genes were significantly upregulated in ileum of the 7- and 14-day-old ducks (P＜0.05) and downregulated in liver at 14-day-old (P＜0.05).Farnesoid X receptor (FXR) gene expression in liver of ducklings in control group was significantly increased with advancing age (P＜0.05),while in ileum,it significantly decreased (P＜0.05).After infection,FXR gene expression in liver of 21-day-old ducklings and FXR gene expression in ileum of 14-day-old ducklings were significantly downregulated compared to control group (P＜0.05).【Conclusion】 This study described the age-dependent characteristics of host metabolism and immune response in Pekin ducks infected with DHAV-3,and for the first time,elucidated that DHAV-3 infection induced age-dependent pathological damage by interfering with the bile secretion pathway.These findings provided new insights into the metabolic-immune cross-regulation of age susceptibility in duck viral hepatitis and suggest that the bile acid negative feedback pathway mediated by nuclear receptors might be a key clue in exploring the age-dependent mechanisms of DHAV-3 infection.

Key words: duck; age; DHAV-3; gut-liver axis; bile acid

CLC Number:

S834⁺.81

LU Meixi, LI Huihui, TANG Yi, LIANG Suyun, HOU Shuisheng. Effect of DHAV-3 Infection on the Bile Secretion Pathway in Ducklings of Different Ages[J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(6): 2830-2838.

References

[1] 潘好卿,赵兴国,赵杰，等.当前鸭病流行动态及防控措施[J].中国动物保健,2023,25(5):76-78.PAN H Q,ZHAO X Q,ZHAO J,et al.Current epidemic dynamics and prevention and control measures of duck disease[J].China Animal Health,2023,25(5):76-78.(in Chinese)
[2] 王四清,廖晓君.雏鸭病毒性肝炎流行病学调查[J].养禽与禽病防治,2022,405(5):22-23.WANG S Q,LIAO X J.Epidemiological investigation of viral hepatitis in duckling[J]. Poultry Husbandry and Disease Control,2022,405(5):22-23.(in Chinese)
[3] ZHANG Y,WU S,LIU W,et al.Current status and future direction of Duck hepatitis A virus vaccines[J].Avian Pathology，2023，52(2):89-99.
[4] ZHOU S,LI S,WANG Y,et al.Duck hepatitis A virus prevalence in mainland China between 2009 and 2021:A systematic review and Meta-analysis[J].Preventive Veterinary Medicine，2022，208:105730.
[5] LIANG S,LU M,YU D,et al.Effects of age on differential resistance to Duck hepatitis A virus genotype 3 in Pekin ducks by 16S and transcriptomics[J].Computational and Structural Biotechnology Journal,2024,23:771-782.
[6] MEMON N,GRIFFIN I J,LEE C W,et al.Developmental regulation of the gut-liver (FGF19-CYP7A1) axis in neonates[J].The Journal of Maternal-fetal & Neonatal Medicine,2020,33(6):987-992.
[7] YANG G Y,LIU R,REZAEI S,et al.Uncovering the gut-liver axis biomarkers for predicting metabolic burden in mice[J].Nutrients,2023,15(15):3406.
[8] WU Y,LI J,QIN X,et al.Proteome and microbiota analysis reveals alterations of liver-gut axis under different stocking density of Peking ducks[J].PLoS One,2018,13(10):e0198985.
[9] GRVNER N,MATTNER J.Bile acids and microbiota:Multifaceted and versatile regulators of the liver-gut axis[J].International Journal of Molecular Sciences,2021,22(3):1397.
[10] TAO W,FAN Q,WEI J.Gut-liver axis as a therapeutic target for drug-induced liver injury[J].Current Issues in Molecular Biology,2024,46(2):1219-1236.
[11] SONG J,LU X,LIU D,et al.Fucogalactan sulfate (FS) from Laminaria japonica regulates lipid metabolism in diet-induced humanized dyslipidemia mice via an intestinal FXR-FGF19-CYP7A1/CYP8B1 pathway[J].Journal of Agricultural and Food Chemistry,2023,71(38):14027-14037.
[12] YDE J,WU Q,BORG J F,et al.A systems-level analysis of bile acids effects on rat colon epithelial cells[J].Gastrointestinal and Liver Physiology,2022,322(1):G34-G48.
[13] SKARDA L,KOWAL J,LOCHER K P.Structure of the Human cholesterol transporter ABCG1[J].Journal of Molecular Biology,2021,433(21):167218.
[14] 高畅鸿.FXR对脂肪肝奶牛肝脂代谢调控机制研究[D].大庆：黑龙江八一农垦大学,2023.GAO C H.Regulation mechanism of liver fat metabolism by FXR in dairy cows with fatty liver[D].Daqing:Heilongjiang Bayi Agricultural University,2023.(in Chinese)
[15] CHAMBERS K F,DAY P E,ABOUFARRAG H T,et al.Polyphenol effects on cholesterol metabolism via bile acid biosynthesis,CYP7A1:A review[J]. Nutrients,2019,11(11):2588.
[16] DU X,LIU M,TREVISI E,et al.Expression of hepatic genes involved in bile acid metabolism in dairy cows with fatty liver[J].Journal of Dairy Science,2024,107(10):8629-8641.
[17] BYDLOWSKI S P,LEVY D.Association of ABCG5 and ABCG8 transporters with sitosterolemia[J]. Advances in Experimental Medicine and Biologye，2024,1440:31-42.
[18] SU L,WANG R,QIU T,et al.The protective effect of baicalin on Duck hepatitis A virus type 1-induced duck hepatic mitochondria dysfunction by activating nuclear erythroid 2-related factor 2/antioxidant responsive element signaling pathway[J].Poultry Science,2021,100(5):101032.
[19] TAN Z,CHEN Y,ZHOU Y.Palygorskite improves growth performance and prevents liver damage in avian pathogenic Escherichia coli-challenged broiler chickens at an early age[J].Journal of Animal Science,2024,102:skae302.
[20] SUN D,XU C,LIU Y,et al.The influence of relative humidity during the first 21 days post-hatch on the production performance,biochemical indices,and meat quality of Pekin ducks[J].Poultry Science,2024,103(12):104473.
[21] QI J,LIU H,ZHOU Z,et al.Genome-wide association study identifies multiple loci influencing duck serum biochemical indicators in the laying period[J].British Poultry Science,2024,65(1)：8-18.
[22] XIA D,YANG L,CUI J,et al.Combined analysis of the effects of exposure to blue light in ducks reveals a reduction in cholesterol accumulation through changes in methionine metabolism and the intestinal microbiota[J].Frontiers in Nutrition，2021，8:737059.
[23] CHIANG J Y.Bile acids:Regulation of synthesis[J].Journal of Lipid Research，2009，50(10):1955-1966.

Effect of DHAV-3 Infection on the Bile Secretion Pathway in Ducklings of Different Ages

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