蛋鸡肠黏膜损伤后抵御再次损伤的可能机制

doi:10.16431/j.cnki.1671-7236.2026.01.038

Abstract

Abstract:

Objective This study aimed to investigate whether the intestinal mucosa of laying hens developed enhanced resistance to secondary injury after initial injury and to explore the underlying mechanisms， thereby promoting new perspectives for developing approaches to repair intestinal mucosal damage in laying hens. Method Seventy-eight 7-day-old Hyline White chicks were divided into 13 treatment groups （6 chicks per group）. Six chicks were radomly selected and received an intraperitoneal injection of PBS as the first negative control group （1^st NC）. The remaining 72 chicks were subjected to intestinal mucosal injury via intraperitoneal injection of lipopolysaccharide （LPS， 10 mg/kg BW）. Six chicks were radomly selected， euthanized and sampled at 1， 2， 4， 6， 8 and 24 hours post-injection （hpi）， designated as 1^st Xhpi groups （X represents the time of sampling after injection）. At 48 hours post-injection， six chicks from the LPS-injected group were radomly selected and injected with PBS as the second negative control group （2^nd NC， equivalent to the 1^st 48hpi group）， the remaining chicks received a second injection of the same dose of LPS. Six chicks were radomly selected， euthanized and sampled at 1， 2， 4， 6 and 8 hours post the second LPS challenge， designated as 2^nd Xhpi groups. Blood， duodenal tissues were collected， and intestinal crypts were isolated for analysis of barrier function， intestinal stem cells （ISCs） activity， and crypt niche changes. Result Following the first LPS challenge， inflammatory cell infiltration， decreased villus height/crypt depth， increased permeability， and decreased mucus layer thickness were observed in the intestinal mucosa of the 1^st 4hpi group. At 48 hours post injection， the degree of injury in the 2^nd NC group was reduced， and the barrier function was enhanced， which was manifested as the expression level of the tight junction Ocln gene， the density of goblet cells， the thickness of the mucus layer， and the expression level of the mucin Muc2 gene were all higher than those in the 1^st NC group. After the second LPS challenge， compared with 2^nd NC group，in the 2^nd 4hpi group， inflammatory cell infiltration and permeability did not significantly increase， but Claudin-1 and complement protein C5 gene levels were markedly upregulated （P<0.05）. The ISCs analysis results showed that the activity of active intestinal stem cells （aISCs） in the 1^st 4hpi group decreased and then gradually recovered， returning to normal at 48 hours post injury.The reserve ISCs （rISCs） in the 2^nd 4hpi group could be rapidly activated and maintain high activity. The analysis results of intestinal crypts showed that the Notch signal pathway of intestinal crypts was inhibited in both injury processes. Conclusion Following initial injury and repair， the intestinal mucosa exhibited enhanced barrier function and suppressed Notch signaling pathway in crypts. Secondary injury triggered rapid activation of rISCs and promoted differentiation of ISCs into secretory epithelial cells.

Key words: laying hens; intestinal mucosal repair; intestinal barrier function; intestinal stem cells

CLC Number:

S831.9

QI Sichao, YU Haolin, ZHANG Lingzhi, HUA Yuping, CHEN Leixiao, WANG Huanan, LI Jian. Potential Mechanisms of Intestinal Mucosal Defense Against Secondary Injury in Laying Hens[J]. China Animal Husbandry & Veterinary Medicine, 2026, 53(1): 427-438.

Figures/Tables 9

Fig.1

Table 1

Fig.2

Fig.3

Fig.4

Fig.5

Fig.6

Fig.7

Fig.8

References 29

[1]	NAIK S， LARSEN S B， GOMEZ N C， et al. Inflammatory memory sensitizes skin epithelial stem cells to tissue damage［J］. Nature， 2017，550（7677）：475-480.
[2]	LYNCH T J， ANDERSON P J， ROTTI P G， et al. Submucosal gland myoepithelial cells are reserve stem cells that can regenerate mouse tracheal epithelium［J］. Cell Stem Cell， 2018，22（5）：653-667.
[3]	YU L， XIE X， JIANG K， et al. Paneth cells mediated the response of intestinal stem cells at the early stage of intestinal inflammation in the chicken［J］. Poultry Science， 2021，100（2）：615-622.
[4]	BU P， WANG L， CHEN K Y， et al. A miR-34a-numb feedforward loop triggered by inflammation regulates asymmetric stem cell division in intestine and colon cancer［J］. Cell Stem Cell， 2016，18（2）：189-202.
[5]	MA Y， LANG X， YANG Q， et al. Paeoniflorin promotes intestinal stem cell-mediated epithelial regeneration and repair via PI3K-Akt-mTOR signalling in ulcerative colitis［J］. International Immunopharmacology， 2023，119：110247.
[6]	BHANJA P， NORRIS A， GUPTA-SARAF P， et al. BCN057 induces intestinal stem cell repair and mitigates radiation-induced intestinal injury［J］. Stem Cell Research & Therapy， 2018，9（1）：26.
[7]	TIAN H， BIEHS B， WARMING S， et al. A reserve stem cell population in small intestine renders Lgr5-positive cells dispensable［J］. Nature， 2011，478（7368）：255-259.
[8]	STEWART A S， SCHAAF C R， LUFF J A， et al. HOPX^＋ injury-resistant intestinal stem cells drive epithelial recovery after severe intestinal ischemia［J］. American Journal of Physiology-Gastrointestinal and Liver Physiology， 2021，321（5）：G588-G602.
[9]	LI N， ZHANG Y， NEPAL N， et al. Dental pulp stem cells overexpressing hepatocyte growth factor facilitate the repair of DSS-induced ulcerative colitis［J］. Stem Cell Research & Therapy， 2021，12（1）：30.
[10]	SAILAJA B S， HE X C， LI L. The regulatory niche of intestinal stem cells［J］. Journal of Physiology-London， 2016，594（17）：4827-4836.
[11]	YANG S， YU M. Role of goblet cells in intestinal barrier and mucosal immunity［J］. Journal of Inflammation Research， 2021，14：3171-3183.
[12]	VENUGOPAL S， ANWER S， SZASZI K. Claudin-2： Roles beyond permeability functions［J］. International Journal of Molecular Sciences， 2019，20（22）：5655.
[13]	VUONG C N， MULLENIX G J， KIDD M T， et al. Research note： Modified serum fluorescein isothiocyanate dextran （FITC-d） assay procedure to determine intestinal permeability in poultry fed diets high in natural or synthetic pigments［J］. Poultry Science， 2021，100（6）：101138.
[14]	KANG J， ZHOU Y， ZHU C， et al. Ginsenoside Rg1 mitigates porcine intestinal tight junction disruptions induced by LPS through the p38 MAPK/ NLRP3 inflammasome pathway［J］. Toxics， 2022，10（6）：285.
[15]	GUO C， GUO D， FANG L， et al. Ganoderma lucidum polysaccharide modulates gut microbiota and immune cell function to inhibit inflammation and tumorigenesis in colon［J］. Carbohydrate Polymers， 2021，267：118231.
[16]	MA J， ZHANG J， WANG Y， et al. Modified Gegen Qinlian decoction ameliorates DSS-induced chronic colitis in mice by restoring the intestinal mucus barrier and inhibiting the activation of gammadeltaT17 cells［J］. Phytomedicine， 2023，111：154660.
[17]	BERGSTROM K S， KISSOON-SINGH V， GIBSON D L， et al. Muc2 protects against lethal infectious colitis by disassociating pathogenic and commensal bacteria from the colonic mucosa［J］. PLoS Pathogens， 2010，6（5）：e1000902.
[18]	LAUMONNIER Y， KORKMAZ R U， NOWACKA A A， et al. Complement-mediated immune mechanisms in allergy［J］. European Journal of Immunology， 2023，53（10）：e2249979.
[19]	GUO J， ZHANG Q Y， XU L， et al. Icariin ameliorates LPS-induced acute lung injury in mice via complement C5a-C5aR1 and TLR4 signaling pathways［J］. International Immunopharmacology， 2024，131：111802.
[20]	RADPOUR M， KHOSHKROODIAN B， ASGARI T， et al. Interleukin 4 reduces brain hyperexcitability after traumatic injury by downregulating TNF-alpha， upregulating IL-10/TGF-beta， and potential directing macrophage/microglia to the M2 anti-inflammatory phenotype［J］. Inflammation， 2023，46（5）：1810-1831.
[21]	GAO S， ZHOU J， LIU N， et al. Curcumin induces M2 macrophage polarization by secretion IL-4 and/or IL-13［J］. Journal of Molecular and Cellular Cardiology， 2015，85：131-139.
[22]	YU L， QI S， WEI G， et al. Kruppel-like factor 5 activates chick intestinal stem cell and promotes mucosal repair after impairment［J］. Cell Cycle， 2023，22（19）：2142-2160.
[23]	MORALES R A， RABAHI S， DIAZ O E， et al. Interleukin-10 regulates goblet cell numbers through Notch signaling in the developing zebrafish intestine［J］. Mucosal Immunology， 2022，15（5）：940-951.
[24]	MEURETTE O， MEHLEN P. Notch signaling in the tumor microenvironment［J］. Cancer Cell， 2018，34（4）：536-548.
[25]	ZHANG S， ZHANG S， HOU Y， et al. Porcine Deltacoronavirus infection disrupts the intestinal mucosal barrier and inhibits intestinal stem cell differentiation to goblet cells via the Notch signaling pathway［J］. Journal of Virology， 2023，97（6）：e0068923.
[26]	LI C， MA D， ZHOU H， et al. Effects of different doses lipopolysaccharides on the mucosal barrier in mouse intestine［J］. Research in Veterinary Science， 2020，133：75-84.
[27]	ALVARADO D M， CHEN B， ITICOVICI M， et al. Epithelial indoleamine 2，3-dioxygenase 1 modulates aryl hydrocarbon receptor and Notch signaling to increase differentiation of secretory cells and alter mucus-associated microbiota［J］. Gastroenterology， 2019，157（4）：1093-1108.
[28]	AHMED S， MALDERA J A， KRUNIC D， et al. Fitness trade-offs incurred by ovary-to-gut steroid signalling in Drosophila ［J］. Nature， 2020，584（7821）：415-419.
[29]	VELARDI E， TSAI J J， HOLLAND A M， et al. Sex steroid blockade enhances thymopoiesis by modulating Notch signaling［J］. Journal of Experimental Medicine， 2014，211（12）：2341-2349.

基因 Genes	引物序列 Primer sequences （5'→3'）	产物长度 Product length/bp	GenBank登录号 GenBank accession No.
GAPDH	F： GATGGGTGTCAACCATGAGAAA	116	NM_204305.1
	R： CAATGCCAAAGTTGTCATGGA
Claudin-1	F： GTGTTTGTTGCTGTGACGGG	153	NM_001013611.2
	R： AGCCACTCTGTTGCCATACC
Ocln	F： ACAGCCCTCAATACCAGGATGTG	133	XM_052699761.1
	R： ACCATGCGCTTGATGTGGAA
Muc2	F： TACTTCACCTTCAACCATTACAAC	161	NM_001318434.1
	R： CATAGTCACCACCATCTTCTTCA
C5	F： CCTCCATCCAGGCCTTTCAG	85	XM_025141495.3
	R： GCCATCTGAAGGGAAAGAACC
TLR4	F： GGATCTTTCAAGGTGCCACA	134	NM_001030693.2
	R： GCGACGTTAAGCCATGGAAG
IL-4	F： TGCTTACAGCTCTCAGTGCC	79	NM_001007079.2
	R： TCTTGACGCAGGAAACCTCTC

Potential Mechanisms of Intestinal Mucosal Defense Against Secondary Injury in Laying Hens

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 9

References 29

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	WANG Huixin, GAO Qingtao, LI Jiaheng, ZHANG Shunfen, ZHONG Ruqing, WANG Yang, CHEN Liang, ZHANG Hongfu. Effects of Lactobacillus plantarum Selenium on Tissue Morphology， Antioxidant Function and Inflammatory Indices in Ovary and Oviduct of Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2026, 53(2): 682-691.
[2]	HAO Zhilei, ZHANG Hongrui, MA Yun. Effects of Different Oil Sources on Laying Performance， Egg Quality， and Fatty Acid Composition of Egg Yolk [J]. China Animal Husbandry & Veterinary Medicine, 2026, 53(2): 703-710.
[3]	ZOU Yinghao, WANG Yong, SUN Lihua, CHEN Xing, WANG Jie, LIU Guohua, WANG Kun, ZHENG Aijuan, ZHENG Shugui. The Effects of Different Levels of Fat Powder on the Egg-laying Performance and Egg Quality of Hy-Line Brown Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2026, 53(1): 233-244.
[4]	WANG Yuyan, LI Menglin, CAO Qingyun, ZHOU Qiaoyi, ZHANG Xingyue, XIAO Yaqi, HUANG Shirui, ZHANG Zhiying, HU Tiesheng, SHI Dayou. Effect of Femented Tea on Laying Performance of Laying Hens After Forced Moulting [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(8): 3574-3583.
[5]	BA Hongli, MA Ning. Research Progress on the Mechanism and Application of Bacillus subtilis in Regulating Intestinal Health of Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(8): 3976-3986.
[6]	LI Jianing, JIANG Zhihui, XING Yueteng, MA Shengming. Effects of 1, 8-cineole Supplementation in Diet on the Antioxidant Capacity of Laying Hens and Eggs [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(7): 3016-3030.
[7]	WANG Beibei, HAO Erying, ZHANG Haihua, ZHANG Haijun, QIU Kai, WU Shugeng. Effects of Dietary Organic Manganese-Iron-Copper-Zinc Compound Preparations on the Production Performance,Blood Biochemical Indices, Follicle Development and Tibia Quality of Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(5): 2012-2022.
[8]	LAN Zhongqi, LI Peng, SHEN Shuang, JIANG Jinfeng, QIN Hongdeng, XIANG Yuting, WANG Jiaxiang. Effects of Dietary Epidermal Growth Factor Supplementation on Morphology, Hormone Content and Expression of Apoptosis Factors of Ovaries in Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(5): 2035-2044.
[9]	WANG Yuanzhuo, LIU Tong, WANG Guizhen, HAN Kunliang, GUO Hua. Effects of Compound Chinese Herb Ultrafine Powder on Immune Function and Related Gene Expression of Xinyang Black-feathered Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(12): 5661-5669.
[10]	ZHANG Ming, GU Yan, AO Xiang, ZHOU Jianchuan. Research Progress on Application of Phytase in Low-phosphorus Diets of Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(10): 4627-4640.
[11]	QIU Kai, CHANG Xinyu, GAO Shan, ZHANG Haihua, ZHANG Haijun, WU Shugeng. Effects of Dietary Calcium Formate Supplementation on Production Performance and Egg Quality of Elderly Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(8): 3320-3328.
[12]	CHAN Yanzi, WANG Xinyue, LI Sihan, WANG Junkai, WANG Yuyan, HU Tiesheng, MO Guifen, LIANG Dehong, SHI Dayou. Effects of Compound Traditional Chinese Medicine on Production Performance and Reproductive Function of Forced Molting Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(3): 1151-1159.
[13]	HUANG Jing, ZHAO Na, GUO Wanzheng, JIN Feng, CHEN Fang, ZHU Wei, FAN Qiwen, DU Encun, TAO Wenjing, HUANG Shaowen, WEI Jintao. Effects of Feed Mulberry on Production Performance,Egg Quality and Intestinal Tissue Morphology of Laying Hens [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(2): 540-548.
[14]	GUO Fangchao, JIA Ling, CHEN Wenfeng, CHEN Liang, MU Qingqing, XU Shuying, WANG Yongjuan. Effects of Fermented Soybean Meal on the Production Performance,Antioxidant Capacity and Gut Microbiota Diversity of Laying Hens in the Late Laying Period [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(12): 5244-5253.
[15]	QIU Kai, GUAN Xiaofeng, SANG Yang, LIU Zhiyun, LIU Guohua. Effects of Lactobacillus acidophilus Post-Biotic on Production Performance, Blood Indexes and Egg Quality of Laying Hens in the Initial Laying Stage [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(11): 4824-4832.