Your search keyword '"Minmeng Zhao"' showing total 15 results

1. Screening of MicroRNAs with Potential Systemic Effects Released from Goose Fatty Liver

Author

Xue Fan, Ya Xing, Long Liu, Chao Zhao, Zhenzhen Chen, Mawahib K. Khogali, Minmeng Zhao, Xuming Hu, Hengmi Cui, Tuoyu Geng, and Daoqing Gong

Subjects

cell communication, diagnostic marker, fatty liver, goose, microrna, Animal culture, SF1-1100

Abstract

Communication between tissues and organs plays an important role in the maintenance of normal physiological functions as well as the occurrence and development of diseases. Communication molecules act as a bridge for interactions between tissues and organs, playing not only a local role in the tissues and organs where they are secreted but also in exerting systemic effects on the whole body via circulation. In this study, blood microRNA-omics analysis of overfed vs. normally fed (control) Landes geese revealed that the content of each of the 21 microRNAs (miRNAs) in the blood of overfed geese was significantly higher than that in the blood of control geese. These miRNAs may have systematic effects in the development of goose fatty liver as well as being candidate markers for the diagnosis of goose fatty liver. We determined the expression of miR-143, miR-455-5p, miR-222a-5p, miR-184, miR-1662, and miR-129-5p using quantitative PCR in goose fatty liver vs. that in normal liver. The expression of these miRNAs, except miR-129-5p, in goose fatty liver was also significantly higher than that in normal liver (P

Published

2021

2. Fasting and overfeeding affect the expression of the immunity- or inflammation-related genes in the liver of poultry via endogenous retrovirus

Author

Tongjun Liu, Ya Xing, Xue Fan, Zhenzhen Chen, Chao Zhao, Long Liu, Minmeng Zhao, Xuming Hu, Biao Dong, Jian Wang, Hengmi Cui, Daoqing Gong, and Tuoyu Geng

Subjects

nutrition, immunity, poultry, fatty liver, endogenous retrovirus, Animal culture, SF1-1100

Abstract

It is known that nutrition and immunity are connected, but the mechanism is not very clear. Endogenous retroviruses (ERV) account for 8 to 10% of the human and mouse genomes and play an important role in some biological processes of animals. Recent studies indicate that the activation of ERV can affect the expression of the immunity- or inflammation-related genes, and the activities of ERV are subjected to regulation of many factors including nutritional factors. Therefore, we hypothesize that nutritional status can affect the expression of the immunity- or inflammation-related genes via ERV. To verify this hypothesis, the nutritional status of animals was altered by fasting or overfeeding, and the expression of intact ERV (ERVK18P, ERVK25P) and immunity- or inflammation-related genes (DDX41, IFIH1, IFNG, IRF7, STAT3) in the liver was determined by quantitative PCR, followed by overexpressing ERVK25P in goose primary hepatocytes and determining the expression of the immunity- or inflammation-related genes. The data showed that compared with the control group (no fasting), the expression of ERV and the immunity- or inflammation-related genes was increased in the liver of the fasted chickens but decreased in the liver of the fasted geese. Moreover, compared with the control group (routinely fed), the expression of ERV and the immunity- or inflammation-related genes was increased in the liver of the overfed geese. In addition, overexpression of ERVK25P in goose primary hepatocytes can induce the expression of the immunity- or inflammation-related genes. In conclusion, these findings suggest that ERV mediate the effects of fasting and overfeeding on the expression of the immunity- or inflammation-related genes, the mediation varied with poultry species, and ERV and the immunity- or inflammation-related genes may be involved in the development of goose fatty liver. This study provides a potential mechanism for the connection between nutrition and immunity.

Published

2021

3. Involvement of IGFBP5 in the Development of Goose Fatty Liver via p38 Mitogen-Activated Protein Kinase (MAPK)

Author

Diego Jauregui, Mawahib K. Khogali, Ya Xing, Xiang Fan, Kang Wen, Long Liu, Minmeng Zhao, Tuoyu Geng, and Daoqing Gong

Subjects

goose, fatty liver, insulin-like growth factor-binding protein 5, rapid amplification of cDNA end, p38 MAPK, Agriculture (General), S1-972

Abstract

Previous studies showed that insulin-like growth factor-binding protein 5 (IGFBP5) plays a role in non-alcoholic fatty liver disease; however, its expression and function in goose fatty liver remain unknown. To address this, we obtained a full-length mRNA sequence of the goose IGFBP5 gene using a 5′-rapid amplification of cDNA ends assay and nested polymerase chain reaction (PCR). Additionally, using the newly acquired sequence of 5’-untraslated region, we determined the missing sequence of the first intron. Bioinformatics analysis revealed three exons and three introns in the goose IGFBP5 gene. Quantitative PCR analysis indicated that the mRNA abundance of IGFBP5 was significantly lower in goose fatty liver than in the normal liver. Comparison of transcriptomes of goose primary hepatocytes transfected with IGFBP5 overexpression vector versus those transfected with empty vector identified 777 differentially expressed genes (DEGs). The enriched Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways indicated the focal adhesion, ECM-receptor interaction, regulation of the actin cytoskeleton, mitogen-activated protein kinase (MAPK) signaling, and GnRH signaling pathways. Immunoblotting revealed the induction of the p38 MAPK pathway by IGFBP5 overexpression, which is in line with the suppressed expression of IGFBP5 and p38 MAPK in goose fatty liver than in normal liver. These findings suggest that IGFBP5 is involved in the development of goose fatty liver via the p38 MAPK pathway.

Published

2022

4. Fasting and overfeeding affect the expression of the immunity- or inflammation-related genes in the liver of poultry via endogenous retrovirus

Author

Tuoyu Geng, Zhenzhen Chen, Long Liu, Xue Fan, Minmeng Zhao, Chao Zhao, Jian Wang, Biao Dong, Hengmi Cui, Tongjun Liu, Xuming Hu, Daoqing Gong, and Ya Xing

Subjects

Endogenous retrovirus, Inflammation, Hyperphagia, Metabolism and Nutrition, 03 medical and health sciences, Mice, Goose, Immunity, endogenous retrovirus, biology.animal, medicine, Animals, Gene, 030304 developmental biology, fatty liver, lcsh:SF1-1100, 0303 health sciences, biology, poultry, Fatty liver, Endogenous Retroviruses, 0402 animal and dairy science, 04 agricultural and veterinary sciences, General Medicine, Fasting, medicine.disease, 040201 dairy & animal science, immunity, Real-time polymerase chain reaction, nutrition, Liver, Immunology, IRF7, Animal Science and Zoology, lcsh:Animal culture, medicine.symptom, Chickens

Abstract

It is known that nutrition and immunity are connected, but the mechanism is not very clear. Endogenous retroviruses (ERV) account for 8 to 10% of the human and mouse genomes and play an important role in some biological processes of animals. Recent studies indicate that the activation of ERV can affect the expression of the immunity- or inflammation-related genes, and the activities of ERV are subjected to regulation of many factors including nutritional factors. Therefore, we hypothesize that nutritional status can affect the expression of the immunity- or inflammation-related genes via ERV. To verify this hypothesis, the nutritional status of animals was altered by fasting or overfeeding, and the expression of intact ERV (ERVK18P, ERVK25P) and immunity- or inflammation-related genes (DDX41, IFIH1, IFNG, IRF7, STAT3) in the liver was determined by quantitative PCR, followed by overexpressing ERVK25P in goose primary hepatocytes and determining the expression of the immunity- or inflammation-related genes. The data showed that compared with the control group (no fasting), the expression of ERV and the immunity- or inflammation-related genes was increased in the liver of the fasted chickens but decreased in the liver of the fasted geese. Moreover, compared with the control group (routinely fed), the expression of ERV and the immunity- or inflammation-related genes was increased in the liver of the overfed geese. In addition, overexpression of ERVK25P in goose primary hepatocytes can induce the expression of the immunity- or inflammation-related genes. In conclusion, these findings suggest that ERV mediate the effects of fasting and overfeeding on the expression of the immunity- or inflammation-related genes, the mediation varied with poultry species, and ERV and the immunity- or inflammation-related genes may be involved in the development of goose fatty liver. This study provides a potential mechanism for the connection between nutrition and immunity.

Published

2021

5. Maintaining intestinal structural integrity is a potential protective mechanism against inflammation in goose fatty liver

Author

Gu Wang, Long Liu, Zhang Jun, Shuo Li, Kang Wen, Tuoyu Geng, Tongjun Liu, Minmeng Zhao, Daoqing Gong, Chunchi Yan, and Cheng Xu

Subjects

medicine.medical_specialty, Genetics and Molecular Biology, Inflammation, Ileum, Biology, digestive system, Jejunum, 03 medical and health sciences, Cecum, Goose, Internal medicine, biology.animal, Geese, Nonalcoholic fatty liver disease, medicine, Animals, lcsh:SF1-1100, 030304 developmental biology, 0303 health sciences, Fatty liver, apoptosis, 0402 animal and dairy science, 04 agricultural and veterinary sciences, General Medicine, goose fatty liver, medicine.disease, 040201 dairy & animal science, Fatty Liver, Intestines, intestinal barrier, medicine.anatomical_structure, Endocrinology, sphingolipid metabolism, Animal Science and Zoology, lcsh:Animal culture, Steatosis, medicine.symptom

Abstract

Overfeeding causes severe steatosis but not inflammation in goose liver, suggesting existence of protective components. Previous studies have shown that some intestinal microbes and their metabolites damage intestinal structural integrity and function, thus causing inflammation in the development of human and mouse nonalcoholic fatty liver disease. Therefore, this study hypothesizes that intestinal structural integrity of goose is maintained during overfeeding, which may provide goose fatty liver a protective mechanism against inflammation. To test this hypothesis, 48 seventy-day-old healthy Landes male geese were overfed (as overfeeding group) or normally fed (as control group). Blood and intestine (jejunum, ileum, and cecum) samples were harvested on the 12th and 24th d of overfeeding. Data showed that goose fatty liver was successfully induced by 24 d of overfeeding. Hematoxylin-eosin staining analysis indicated that the arrangement of villi and crypts in the intestine was orderly, and the intestinal structure was intact with no pathological symptoms in the 2 groups. Enzyme-linked immunosorbent assay and quantitative PCR analysis indicated no significant differences in the expression of tight junction and inflammation-related genes as well as plasma lipopolysaccharide concentration between the groups. Ileal hypertrophy and cecal atrophy were observed in the overfed vs. control geese, probably because of change of sphingolipid metabolism. Activation of apoptotic pathway may help cecum avoid necrosis-induced inflammation. In conclusion, healthy and intact intestine provides a layer of protection for goose fatty liver against inflammation. Sphingolipid metabolism may be involved in the adaptation of ileum and cecum to overfeeding. The hypertrophy of ileum makes it an important contributor to the development of goose fatty liver. The atrophy and decline in the function of cecum may be caused by apoptosis induced by overfeeding.

Published

2020

6. Research Note: Increase of bad bacteria and decrease of good bacteria in the gut of layers with vs. without hepatic steatosis

Author

Zhang Jun, Shuo Li, Tuoyu Geng, Cheng Xu, Chunchi Yan, Kang Wen, Long Liu, Tongjun Liu, Daoqing Gong, and Minmeng Zhao

Subjects

chicken, Population, Physiology, Ileum, Gut flora, digestive system, Metabolism and Nutrition, 03 medical and health sciences, Cecum, Nonalcoholic fatty liver disease, medicine, Animals, education, Poultry Diseases, 030304 developmental biology, lcsh:SF1-1100, 0303 health sciences, Fatty liver hemorrhagic syndrome, education.field_of_study, biology, Bacteria, gut microbiota, 0402 animal and dairy science, 04 agricultural and veterinary sciences, General Medicine, Biodiversity, biology.organism_classification, medicine.disease, metabolic disease, 040201 dairy & animal science, Gastrointestinal Microbiome, fatty liver hemorrhagic syndrome, Fatty Liver, medicine.anatomical_structure, Animal Science and Zoology, Female, lcsh:Animal culture, Steatosis, Chickens

Abstract

Fatty liver hemorrhagic syndrome (FLHS), usually occurring in hens in the late laying period, can lower egg yield and even cause death. Similar to nonalcoholic fatty liver disease in humans, FLHS may begin with simple hepatic steatosis. It is known that gut microbiota is important to the development of nonalcoholic fatty liver disease, but the relationship between FLHS and gut bacteria remains unclear. In this study, bacteria compositions in the ileum and cecum were determined by 16S rDNA sequencing analysis in the groups of hens with vs. without hepatic steatosis (average liver fat contents were 0.34 mmol/g protein or 2.6% vs. 0.84 mmol/g protein or 6.0%). These hens were in the 2 tails of the liver fat content distribution with each tail accounting for 10% of the test population containing 90 66-wk-old healthy Rhode Island Red laying hens raised under routine feeding regimen. The results showed that liver weight but not the weights of the body, heart and abdominal fat were significantly different between the groups. Moreover, bacterial diversity was not significantly different between the groups, but bacterial diversity in the cecum was higher than that in the ileum. Proteobacteria was the most dominant phylum in the ileum, whereas Proteobacteria, Firmicutes, and Bacteroidetes were the most dominant phyla in the cecum. Some bacteria were common to the ileum and cecum, but some were unique. Furthermore, some bacteria were significantly different in abundance between the groups, that is the group without hepatic steatosis had more bacteria inhibiting host energy absorption or benefiting intestinal health, whereas the group with hepatic steatosis had more conditionally pathogenic or harmful bacteria. In conclusion, hepatic steatosis in laying hens is associated with intestinal bacterial composition (bacterial abundance) but not bacterial diversity. The identified common and unique bacteria are related to the functional characteristics of the ileum and cecum. The decrease of beneficial bacteria and the increase of harmful bacteria in the intestine of laying hens may increase FLHS incidence by promoting hepatic steatosis.

Published

2020

7. Glucose participates in the formation of goose fatty liver by regulating the expression of miRNA-33/CROT

Author

Xiao Lin, Ya Xing, Yihui Zhang, Biao Dong, Minmeng Zhao, Jian Wang, Tuoyu Geng, Daoqing Gong, Yun Zheng, and Long Liu

Subjects

Fatty Liver, MicroRNAs, Glucose, Liver, Geese, Animals, General Medicine, General Agricultural and Biological Sciences, Lipids

Abstract

Glucose oversupply promotes formation of fatty liver, and fatty liver is usually accompanied with hyperglycemia. However, the mechanism by which glucose promotes formation of fatty liver is not very clear. In this study, fatty liver was successfully induced in Landes goose by 19 days of overfeeding with corn-based feed, the overfed geese had a significantly higher level of blood glucose than the normally fed geese (control group). In goose primary liver cells, high level of glucose promoted fat deposition and induced the expression of SREBF2(or SREBP2), a key regulator of lipid metabolism, and its intronic gene, miR-33. Moreover, overexpression of miRNA-33(miR-33) promotes lipid accumulation in goose primary liver cells. Consistently, miR-33 inhibitor suppressed glucose induced lipid accumulation in liver cells. Interestingly, the relative abundance of miR-33 in goose fatty liver was significantly higher than that in normal liver, while the relative mRNA and protein abundances of CROT, the target gene of miR-33, in goose fatty liver were significantly lower than those in goose normal liver. Taken together, these findings suggest that miR-33 mediates glucose promotion of lipid accumulation in goose primary liver cells, and that glucose participates in formation of goose fatty liver by regulating the expression of miR-33/CROT.

Published

2021

8. MicroRNA 33 Potentially Participates in the Development of Goose Fatty Liver via Its Target Gene CROT

Author

Daoqing Gong, Yun Zheng, Ya Xing, Long Liu, Tuoyu Geng, Xiao Lin, Minmeng Zhao, Yihui Zhang, Biao Dong, and Jian Wang

Subjects

Goose, biology.animal, Fatty liver, microRNA, medicine, Biology, Target gene, medicine.disease, Cell biology

Abstract

Background Previous studies indicate that microRNA33 (miR-33) and its target gene, CROT, are implicated in hepatic lipid metabolism, but it is unclear whether miR-33 participates in the development of goose fatty liver via CROT. Methods The expression of miR-33 in goose fatty liver, muscle and fat tissues, as well as the mRNA and protein expression of CROT in goose fatty liver was determined by q-PCR or Western-blot. The targeting regulatory relationship between miR-33 and CROT in goose liver cells was validated by miR-33 overexpression and interference assays. The effects of miR-33 mimic and CROT overexpression on lipid deposition and the expression of downstream genes were determined in goose primary hepatocytes. The treatment of high concentrations of glucose and insulin was performed to determine their regulation on the expression of miR-33 and CROT in goose primary hepatocytes. Results Here, data showed that miR-33 expression was significantly increased in the liver, muscle and fat tissues of overfed geese. Consistently, miR-33 mimic promoted lipid deposition in goose primary hepatocytes. Moreover, the regulatory targeting relationship between miR-33 and CROT was validated in goose primary hepatocytes. Consistently, the mRNA and protein expression of CROT were significantly reduced in goose fatty liver. Interestingly, CROT overexpression could induce the expression of fatty acid oxidation associated genes including CRAT, PEX5, EHHADH, CAT and ACOT8 in goose primary hepatocytes, but only the expression of PEX5 was significantly inhibited in goose fatty liver. However, it seemed conflicting that CROT overexpression increased lipid deposition and reduced lipid peroxidation in goose primary hepatocytes. Additionally, high glucose inhibited miR-33 expression and induced CROT expression in goose primary hepatocytes. Conclusions These findings suggest that miR-33 potentially participates in the development of goose fatty liver via CROT, and that miR-33/CROT may partially mediate the effect of glucose in goose liver cells.

Published

2021

9. Complement C3 participates in the development of goose fatty liver potentially by regulating the expression of FASN and ETNK1

Author

Daoqing Gong, Minmeng Zhao, Tuoyu Geng, Xiao Lin, Cheng Xu, Long Liu, and Ya Xing

Subjects

Male, medicine.medical_treatment, Gene Expression, Inflammation, Mice, Goose, Immune system, Downregulation and upregulation, Non-alcoholic Fatty Liver Disease, biology.animal, Geese, medicine, Animals, KEGG, Cells, Cultured, Poultry Diseases, biology, Insulin, Fatty liver, Gene Expression Regulation, Developmental, Complement C3, General Medicine, medicine.disease, Cell biology, Fatty Acid Synthase, Type I, Phosphotransferases (Alcohol Group Acceptor), Hepatocytes, Steatosis, medicine.symptom, General Agricultural and Biological Sciences

Abstract

Non-alcoholic fatty liver disease (NAFLD) occurs in humans, domestic animals and poultry. Different from upregulation of complement C3 in human NAFLD, C3 expression is inhibited in goose fatty liver (GFL), implying a specific role of C3 in GFL. This study was mainly focused on uncovering the uniqueness of goose liver cells in the regulation of C3 expression and identifying the downstream genes of C3 to improve understanding on the specific role of C3 in GFL. The results showed that C3 expression was inhibited in the liver, muscle and fat tissues of the overfed versus control (normally fed) geese. Oleate and insulin could inhibit C3 expression in goose primary hepatocytes but induce it in mouse primary hepatocytes. A total of 1,123 differentially expressed genes (DEGs) were affected by C3 overexpression and were mainly enriched in immune response/inflammation and catabolism-related KEGG pathways. Additionally, the representative downstream genes (FASN and ETNK1) of C3 could mediate the role of C3 in the development of GFL. In conclusion, the suppression of C3 in GFL is at least partially attributed to hyperinsulinemia, hyperlipidemia and uniqueness of goose liver cells. Complement C3 does not only affect hepatic steatosis but also affect inflammation/immune response in GFL.

Published

2021

10. GC-TOF-MS-Based Metabolomics Analyses of Liver and Intestinal Contents in the Overfed vs. Normally-Fed Geese

Author

Tuoyu Geng, Daoqing Gong, Ya Xing, Minmeng Zhao, Xiang Fan, Long Liu, and L Liu

Subjects

0301 basic medicine, 030209 endocrinology & metabolism, Pentose phosphate pathway, Fatty acid degradation, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Goose, biology.animal, CYP27A1, lcsh:Zoology, medicine, Glycolysis, lcsh:QL1-991, lcsh:Veterinary medicine, General Veterinary, biology, Fatty liver, non-alcoholic fatty liver disease, intestinal tracts, medicine.disease, metabolomics, 030104 developmental biology, chemistry, Biochemistry, Gluconeogenesis, lcsh:SF600-1100, Animal Science and Zoology, Arachidonic acid, goose

Abstract

No overt pathological symptoms are observed in the goose liver with severe steatosis, suggesting that geese may host unique protective mechanisms. Gas chromatography time-of-flight mass spectrometry-based metabolomics analyses of liver and intestinal contents in overfed vs. normally fed geese (26 geese in each treatment) were investigated. We found that overfeeding significantly changed the metabolic profiles of liver and intestinal contents. The differential metabolites mainly belong to fatty acids, amino acids, organic acids, and amines. The differential metabolites were involved in glycolysis/gluconeogenesis, glycerolipid metabolism, the pentose phosphate pathway, fatty acid degradation, the sphingolipid signaling pathway, and the biosynthesis of unsaturated fatty acids. Moreover, we determined the biological effects of arachidonic acid (ARA) and tetrahydrocorticosterone (TD) in goose primary hepatocytes and intestinal cells. Data showed that the mRNA expression of arachidonate 5-lipoxygenase (ALOX5) in goose primary intestinal cells was significantly induced by 0.50 mM ARA treatment. Cytochrome P-450 27A1 (CYP27A1) mRNA expression was significantly inhibited in goose primary hepatocytes by 1 &micro, M TD treatment. In conclusion, the formation of goose fatty liver is accompanied by significant changes in the metabolic profiles of liver and intestinal contents, and the changes are closely related to the metabolisms of glucose and fatty acids, oxidative stress, and inflammatory reactions.

Published

2020

11. Screening of MicroRNAs with Potential Systemic Effects Released from Goose Fatty Liver

Author

Mawahib K. Khogali, Tuoyu Geng, Xue Fan, Minmeng Zhao, Xuming Hu, Zhenzhen Chen, Daoqing Gong, Ya Xing, Chao Zhao, Long Liu, and Hengmi Cui

Subjects

Cell signaling, biology, microRNA, diagnostic marker, Fatty liver, Diagnostic marker, cell communication, Full Papers, medicine.disease, Goose, biology.animal, Cancer research, medicine, Animal Science and Zoology, goose, fatty liver

Abstract

Communication between tissues and organs plays an important role in the maintenance of normal physiological functions as well as the occurrence and development of diseases. Communication molecules act as a bridge for interactions between tissues and organs, playing not only a local role in the tissues and organs where they are secreted but also in exerting systemic effects on the whole body via circulation. In this study, blood microRNA-omics analysis of overfed vs. normally fed (control) Landes geese revealed that the content of each of the 21 microRNAs (miRNAs) in the blood of overfed geese was significantly higher than that in the blood of control geese. These miRNAs may have systematic effects in the development of goose fatty liver as well as being candidate markers for the diagnosis of goose fatty liver. We determined the expression of miR-143, miR-455-5p, miR-222a-5p, miR-184, miR-1662, and miR-129-5p using quantitative PCR in goose fatty liver vs. that in normal liver. The expression of these miRNAs, except miR-129-5p, in goose fatty liver was also significantly higher than that in normal liver (P

Published

2020

12. Increase of E3 ubiquitin ligase NEDD4 expression leads to degradation of its target proteins PTEN/IGF1R during the formation of goose fatty liver

Author

Long Liu, Tuoyu Geng, Shuo Li, Tongjun Liu, Daoqing Gong, Chunchi Yan, Cheng Xu, and Minmeng Zhao

Subjects

Male, Nedd4 Ubiquitin Protein Ligases, NEDD4, macromolecular substances, Receptor, IGF Type 1, 03 medical and health sciences, 0302 clinical medicine, Goose, biology.animal, Nonalcoholic fatty liver disease, Geese, Genetics, medicine, PTEN, Animals, Poultry Diseases, 030304 developmental biology, 0303 health sciences, Messenger RNA, biology, Chemistry, Ubiquitin, Fatty liver, PTEN Phosphohydrolase, Ubiquitination, General Medicine, medicine.disease, Molecular biology, Ubiquitin ligase, Fatty Liver, Real-time polymerase chain reaction, Gene Expression Regulation, 030220 oncology & carcinogenesis, Proteolysis, biology.protein, Animal Science and Zoology, Cell and Molecular Biology, Food Science

Abstract

Goose fatty liver may have a unique protective mechanism as it does not show a pathological injury even in the case of severe steatosis. Although neural precursor cell-expressed developmentally downregulated gene 4 (NEDD4) participates in repair and regeneration of injured liver through its target proteins, its role in nonalcoholic fatty liver disease remains unknown. Using quantitative polymerase chain reaction (PCR) and immunoblot analyses, here, we found that the messenger RNA (mRNA) and protein expressions of NEDD4 were induced in goose fatty liver compared with normal liver. The mRNA expression of the gene of phosphate and tension homology deleted on chromosome ten (PTEN) and insulin-like growth factor 1 receptor (IGF1R) was also induced in goose fatty liver; however, their protein expression was or tended to be suppressed. Moreover, the co-immunoprecipitation analysis indicated that there was a physical association between NEDD4 and PTEN in goose liver, which was consistent with the ubiquitination of PTEN in goose fatty liver. Furthermore, NEDD4 overexpression in goose primary hepatocytes suppressed the PTEN and IGF1R protein levels without a significant effect on their mRNA expression. In conclusion, the increased expression of NEDD4 leads to the degradation of PTEN and IGF1R proteins through ubiquitination in goose fatty liver, suggesting that NEDD4 may protect goose fatty liver from severe steatosis-associated injury via its target proteins during the development of goose fatty liver.

Published

2020

13. The Changes in Microbiotic Composition of Different Intestinal Tracts and the Effects of Supplemented Lactobacillus During the Formation of Goose Fatty Liver.

Author

Kang Wen, Long Liu, Minmeng Zhao, Tuoyu Geng, and Daoqing Gong

Subjects

FATTY liver, ABDOMINAL adipose tissue, GUT microbiome, GASTROINTESTINAL contents, WEIGHT loss, LACTOBACILLUS, INTESTINES

Abstract

Intestinal bacteria play an important role in the formation of fatty liver in animals by participating in the digestion and degradation of nutrients, producing variousmetabolites, and altering the barrier effect of the intestine. However, changes in the gut microbiota during the formation of goose fatty liver are unclear. In this study, 80 healthy Landes geese with similar body weights at 70 days of age were randomly divided into two groups: the control group (n = 48; fed ad libitum) and the overfeeding group (n = 32; overfed). The intestinal contents were collected at 0, 12, and 24 days of overfeeding. The 16S rRNA and metagenomic sequencing analyses showed that the dominant phyla were Firmicutes, Proteobacteria, Bacteroidetes, and Actinobacteria. At the genus level, Phyllobacterium, Bacteroides, Helicobacter, Lactobacillus, Enterococcus, and Romboutsia were the dominant genera in the goose intestine, and most of them were probiotics. In the control group, the relative abundance of Firmicutes in the jejunum and ileum gradually decreased with time, while that of Proteobacteria increased, whereas in the overfeeding group, the relative abundance of Firmicutes in the jejunum and ileum decreased and then increased with time, while that of Proteobacteria showed an opposite trend. In addition, supplementing Lactobacillus to the diet reduced body weight and fatty liver weight in overfed geese, but increased the weight of abdominal fat, suggesting that Lactobacillus supplementation might affect the transport of nascent fat from the liver to abdominal fat. In conclusion, the species of intestinal-dominant bacteria in the geese are relatively stable, but their relative abundance and function are affected by a number of factors. Overfeeding promotes the metabolism of nutrients in the jejunum and ileum and increases bacterial adaptability to environmental changes by enhancing their ability to process environmental and genetic information more efficiently. These findings suggest that the effect of overfeeding on the composition of intestinal microbiota may indirectly influence the formation of goose fatty liver through the gut/liver axis. [ABSTRACT FROM AUTHOR]

Published

2022

14. Complement C3 participates in the development of goose fatty liver potentially by regulating the expression of FASN and ETNK1.

Author

Ya Xing, Cheng Xu, Xiao Lin, Minmeng Zhao, Daoqing Gong, Long Liu, and Tuoyu Geng

Subjects

COMPLEMENT (Immunology), NON-alcoholic fatty liver disease, FATTY liver, GEESE, ADIPOSE tissues

Abstract

Non-alcoholic fatty liver disease (NAFLD) occurs in humans, domestic animals and poultry. Different from upregulation of complement C3 in human NAFLD, C3 expression is inhibited in goose fatty liver (GFL), implying a specific role of C3 in GFL. This study was mainly focused on uncovering the uniqueness of goose liver cells in the regulation of C3 expression and identifying the downstream genes of C3 to improve understanding on the specific role of C3 in GFL. The results showed that C3 expression was inhibited in the liver, muscle and fat tissues of the overfed versus control (normally fed) geese. Oleate and insulin could inhibit C3 expression in goose primary hepatocytes but induce it in mouse primary hepatocytes. A total of 1,123 differentially expressed genes (DEGs) were affected by C3 overexpression and were mainly enriched in immune response/inflammation and catabolism-related KEGG pathways. Additionally, the representative downstream genes (FASN and ETNK1) of C3 could mediate the role of C3 in the development of GFL. In conclusion, the suppression of C3 in GFL is at least partially attributed to hyperinsulinemia, hyperlipidemia and uniqueness of goose liver cells. Complement C3 does not only affect hepatic steatosis but also affect inflammation/immune response in GFL. [ABSTRACT FROM AUTHOR]

Published

2021

15. Research Note: Increase of bad bacteria and decrease of good bacteria in the gut of layers with vs. without hepatic steatosis.

Author

Shuo Li, Chunchi Yan, Tongjun Liu, Cheng Xu, Kang Wen, Long Liu, Minmeng Zhao, Jun Zhang, Tuoyu Geng, and Daoqing Gong

Subjects

*FATTY liver, *FATTY degeneration, *HENS, *BACTERIAL diversity, *INTESTINAL absorption

Abstract

Fatty liver hemorrhagic syndrome (FLHS), usually occurring in hens in the late laying period, can lower egg yield and even cause death. Similar to nonalcoholic fatty liver disease in humans, FLHS may begin with simple hepatic steatosis. It is known that gut microbiota is important to the development of nonalcoholic fatty liver disease, but the relationship between FLHS and gut bacteria remains unclear. In this study, bacteria compositions in the ileum and cecum were determined by 16S rDNA sequencing analysis in the groups of hens with vs. without hepatic steatosis (average liver fat contents were 0.34 mmol/g protein or 2.6% vs. 0.84 mmol/g protein or 6.0%). These hens were in the 2 tails of the liver fat content distribution with each tail accounting for 10% of the test population containing 90 66-wk-old healthy Rhode Island Red laying hens raised under routine feeding regimen. The results showed that liver weight but not the weights of the body, heart and abdominal fat were significantly different between the groups. Moreover, bacterial diversity was not significantly different between the groups, but bacterial diversity in the cecum was higher than that in the ileum. Proteobacteria was the most dominant phylum in the ileum, whereas Proteobacteria, Firmicutes, and Bacteroidetes were the most dominant phyla in the cecum. Some bacteria were common to the ileum and cecum, but some were unique. Furthermore, some bacteria were significantly different in abundance between the groups, that is the group without hepatic steatosis had more bacteria inhibiting host energy absorption or benefiting intestinal health, whereas the group with hepatic steatosis had more conditionally pathogenic or harmful bacteria. In conclusion, hepatic steatosis in laying hens is associated with intestinal bacterial composition (bacterial abundance) but not bacterial diversity. The identified common and unique bacteria are related to the functional characteristics of the ileum and cecum. The decrease of beneficial bacteria and the increase of harmful bacteria in the intestine of laying hens may increase FLHS incidence by promoting hepatic steatosis. [ABSTRACT FROM AUTHOR]

Published

2020