Distinct Gut Microbiota and Arachidonic Acid Metabolism in Obesity-Prone and Obesity-Resistant Mice with a High-Fat Diet.
Study Goal
The researchers aimed to explore the role of arachidonic acid (AA) metabolism in obesity susceptibility by comparing obesity-prone and obesity-resistant mice models.
Results Summary
The study found that AA metabolism was significantly reduced in obesity-resistant mice and was the most enriched pathway in KEGG analysis, suggesting a strong link between AA metabolites, gut microbiota, and obesity resistance.
Population
Male C57BL/6J mice fed high-fat diets.
Effective Dosage
Not specified
Duration
16 weeks
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
high-fat diet feeding | decrease | lower body weight | obesity-resistant male C57BL/6J mice | - | showed | #1 |
high-fat diet feeding | decrease | lower liver weight | obesity-resistant male C57BL/6J mice | - | showed | #2 |
high-fat diet feeding | decrease | lower adipose accumulation | obesity-resistant male C57BL/6J mice | - | showed | #3 |
high-fat diet feeding | decrease | lower pro-inflammatory cytokine levels | obesity-resistant male C57BL/6J mice | - | showed | #4 |
high-fat diet feeding | neutral | fecal microbiome's structural composition and biodiversity | obesity-prone and obesity-resistant male C57BL/6J mice | - | found that the fecal microbiome's structural composition and biodiversity had changed | #5 |
high-fat diet feeding | increase | genera Allobaculumbiota, SMB53, Desulfovibrio and Clostridium | obesity-prone male C57BL/6J mice | - | increased | #6 |
high-fat diet feeding | increase | genera Streptococcus, Odoribacter and Leuconostoc | obesity-resistant male C57BL/6J mice | - | were enriched | #7 |
high-fat diet feeding | neutral | 166 differential metabolites | obesity-prone and obesity-resistant male C57BL/6J mice | 166 | found | #8 |
high-fat diet feeding | decrease | products involved in arachidonic acid (AA) metabolism | obesity-resistant male C57BL/6J mice | - | were significantly reduced | #9 |
high-fat diet feeding | increase | AA metabolism | obesity-prone and obesity-resistant male C57BL/6J mice | - | exhibited that AA metabolism was the most enriched pathway | #10 |
high-fat diet feeding | neutral | significantly altered bacteria and obesity-related parameters, as well as AA metabolites | obesity-prone and obesity-resistant male C57BL/6J mice | - | exhibited strong correlations | #11 |
high-fat diet feeding | neutral | phenotypes of the obesity-prone and obesity-resistant mice | male C57BL/6J mice | - | were linked to | #12 |
An imbalance of energy intake and expenditure is commonly considered as the fundamental cause of obesity. However, individual variations in susceptibility to obesity do indeed exist in both humans and animals, even among those with the same living environments and dietary intakes. To further explore the potential influencing factors of these individual variations, male C57BL/6J mice were used for the development of obesity-prone and obesity-resistant mice models and were fed high-fat diets for 16 weeks. Compared to the obesity-prone mice, the obesity-resistant group showed a lower body weight, liver weight, adipose accumulation and pro-inflammatory cytokine levels. 16S rRNA sequencing, which was conducted for fecal microbiota analysis, found that the fecal microbiome's structural composition and biodiversity had changed in the two groups. The genera Allobaculumbiota, SMB53, Desulfovibrio and Clostridium increased in the obesity-prone mice, and the genera Streptococcus, Odoribacter and Leuconostoc were enriched in the obesity-resistant mice. Using widely targeted metabolomics analysis, 166 differential metabolites were found, especially those products involved in arachidonic acid (AA) metabolism, which were significantly reduced in the obesity-resistant mice. Moreover, KEGG pathway analysis exhibited that AA metabolism was the most enriched pathway. Significantly altered bacteria and obesity-related parameters, as well as AA metabolites, exhibited strong correlations. Overall, the phenotypes of the obesity-prone and obesity-resistant mice were linked to gut microbiota and AA metabolism, providing new insight for developing an in-depth understanding of the driving force of obesity resistance and a scientific reference for the targeted prevention and treatment of obesity.