Your search keyword '"Yimin Zhuang"' showing total 5 results

1. Butyrate metabolism in rumen epithelium affected by host and diet regime through regulating microbiota in a goat model

Author

Yimin Zhuang, Mahmoud M. Abdelsattar, Yuze Fu, Naifeng Zhang, and Jianmin Chai

Subjects

Rumen microbiota, Rumen epithelial development, Multi-omics, Host-microbe interaction, Animal culture, SF1-1100

Abstract

The rumen is an important organ that enables ruminants to digest nutrients. However, the biological mechanism by which the microbiota and its derived fatty acids regulate rumen development is still unclear. In this study, 18 female Haimen goats were selected and slaughtered at d 30, 60, and 90 of age. Multi-omics analyses (rumen microbial sequencing, host transcriptome sequencing, and rumen epithelial metabolomics) were performed to investigate host–microbe interactions from preweaning to postweaning in a goat model. With increasing age, and after the introduction of solid feed, the increased abundances of Prevotella and Roseburia showed positive correlations with volatile fatty acid (VFA) levels and morphological parameters (P

Published

2024

2. Dietary β-hydroxybutyric acid improves the growth performance of young ruminants based on rumen microbiota and volatile fatty acid biosynthesis

Author

Jianmin Chai, Zeyue Liu, Jun Wu, Yuan Kang, Mahmoud M. Abdelsattar, Wei Zhao, Shiqin Wang, Shuli Yang, Feilong Deng, Ying Li, Yimin Zhuang, and Naifeng Zhang

Subjects

β-hydroxybutyric acid, rumen microbiota, goats, growth, volatile fatty acids, Microbiology, QR1-502

Abstract

IntroductionThe ketone body β-hydroxybutyric acid (BHB) plays critical roles in cellular proliferation and metabolic fuel utilization; however, its effects on the rumen microbiota remain unknown.MethodsHere, three doses of BHB (low, medium, and high) were supplemented to early-weaned goat kids.ResultsCompared with controls, the beneficial effects of BHB on growth and rumen development were observed in goats at 90 days of age (d). The low dose of dietary BHB increased the concentration of rumen acetate, propionate, and butyrate on d90. The sequencing results of the rumen microbiota revealed marked shifts in rumen microbial community structure after early-weaned goat kids consumed BHB for 2 months. The signature bacterial ASVs for each treatment were identified and were the main drivers contributing to microbial interactions in the rumen. The bacteria associated with rumen weight were also correlated with body weight. Some classified bacterial signatures, including Prevotella, Olsenella umbonate, and Roseburia faecis, were related to rumen volatile fatty acids and host development.ConclusionOverall, dietary BHB altered rumen microbiota and environments in young goats, which contributed to rumen development and growth.

Published

2024

3. The Signature Microbiota Drive Rumen Function Shifts in Goat Kids Introduced to Solid Diet Regimes

Author

Xiaokang Lv, Jianmin Chai, Qiyu Diao, Wenqin Huang, Yimin Zhuang, and Naifeng Zhang

Subjects

goats, rumen microbiota, solid diet, rumen development, neutral detergent fibers, volatile fatty acids, Biology (General), QH301-705.5

Abstract

The feeding regime of early, supplementary solid diet improved rumen development and production in goat kids. However, the signature microbiota responsible for linking dietary regimes to rumen function shifts are still unclear. This work analyzed the rumen microbiome and functions affected by an early solid diet regime using a combination of machine learning algorithms. Volatile fatty acids (i.e., acetate, propionate and butyrate) fermented by microbes were found to increase significantly in the supplementary solid diet groups. Predominant genera were found to alter significantly from unclassified Sphingobacteriaceae (non-supplementary group) to Prevotella (supplementary solid diet groups). Random Forest classification model revealed signature microbiota for solid diet that positively correlated with macronutrient intake, and linearly increased with volatile fatty acid production. Bacteria associated with carbohydrate and protein metabolism were also identified. Utilization of a Fish Taco analysis portrayed a set of intersecting core species contributed to rumen function shifts by the solid diet regime. The core community structures consisted of the specific, signature microbiota and the manipulation of their symbiotic partners are manipulated by extra nutrients from concentrate and/or forage, and then produce more volatile fatty acids to promote rumen development and functions eventually host development. Our study provides mechanisms of the microbiome governed by a solid diet regime early in life, and highlights the signature microbiota involved in animal health and production.

Published

2019

4. Solid diet manipulates rumen epithelial microbiota and its interactions with host transcriptomic in young ruminants

Author

Xiaokang Lv, Chai Jianmin, Hunter Usdrowski, Yimin Zhuang, Qiyu Diao, Kai Cui, Wenqin Huang, and Naifeng Zhang

Subjects

animal structures, Rumen, Host (biology), Microbiota, food and beverages, Ruminants, Biology, biology.organism_classification, Microbiology, Animal Feed, Early life, Epithelium, Diet, Transcriptome, fluids and secretions, medicine.anatomical_structure, Food supplement, Rumen microbiota, medicine, Animals, Food science, Ecology, Evolution, Behavior and Systematics, Bacteria

Abstract

Solid diet supplementation in the early life stages of ruminants could improve rumen microbiota and tissue development. However, most studies focus on bacteria in the rumen content community. The microbiota attached on rumen epithelium are rarely investigated, and their correlations with rumen content bacteria and host transcripts are unknown. In this study, rumen digesta attached in the epithelium from goats in three diet regimes (milk replacer only, milk replacer supplemented concentrate and milk replacer supplemented concentrate plus alfalfa pellets) were collected for measurement of the epithelial microbiota using next generation sequencing. Correspondingly, the rumen tissues of the same animals were measured with the host transcriptome. The distinct microbial structures and compositions between rumen content and epithelial communities were associated with solid diet supplementation. Regarding rumen development in pre-weaning ruminants, a solid diet, especially its accompanying neutral detergent fibre nutrients, was the most significant driver that influenced the rumen microbiota and epithelium gene expression. Compared with content bacteria, rumen epithelial microbiota had a stronger association with the host transcriptome. The host transcriptome correlated with host phenotypes were associated with rumen epithelial microbiota and solid diet. This study reveals that the epithelial microbiota is crucial for proper rumen development, and solid diet could improve rumen development through both the rumen content and epithelial microbiota.

Published

2021

5. The Signature Microbiota Drive Rumen Function Shifts in Goat Kids Introduced to Solid Diet Regimes

Author

Naifeng Zhang, Yimin Zhuang, Wenqin Huang, Chai Jianmin, Qiyu Diao, and Xiaokang Lv

Subjects

Microbiology (medical), goats, Protein metabolism, Butyrate, Biology, Microbiology, Article, 03 medical and health sciences, Rumen, chemistry.chemical_compound, Nutrient, Virology, rumen microbiota, Prevotella, Microbiome, Food science, lcsh:QH301-705.5, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, neutral detergent fibers, rumen development, 030306 microbiology, volatile fatty acids, Fatty acid, biology.organism_classification, lcsh:Biology (General), chemistry, Propionate, solid diet

Abstract

The feeding regime of early, supplementary solid diet improved rumen development and production in goat kids. However, the signature microbiota responsible for linking dietary regimes to rumen function shifts are still unclear. This work analyzed the rumen microbiome and functions affected by an early solid diet regime using a combination of machine learning algorithms. Volatile fatty acids (i.e., acetate, propionate and butyrate) fermented by microbes were found to increase significantly in the supplementary solid diet groups. Predominant genera were found to alter significantly from unclassified Sphingobacteriaceae (non-supplementary group) to Prevotella (supplementary solid diet groups). Random Forest classification model revealed signature microbiota for solid diet that positively correlated with macronutrient intake, and linearly increased with volatile fatty acid production. Bacteria associated with carbohydrate and protein metabolism were also identified. Utilization of a Fish Taco analysis portrayed a set of intersecting core species contributed to rumen function shifts by the solid diet regime. The core community structures consisted of the specific, signature microbiota and the manipulation of their symbiotic partners are manipulated by extra nutrients from concentrate and/or forage, and then produce more volatile fatty acids to promote rumen development and functions eventually host development. Our study provides mechanisms of the microbiome governed by a solid diet regime early in life, and highlights the signature microbiota involved in animal health and production.

Published

2019