Tropical postbiotics alleviate the disorders in the gut microbiota and kidney damage induced by ochratoxin A exposure.

Ochratoxin A (OTA), commonly found in various foods, significantly impacts the health of humans and animals, especially their kidneys. Our study explores OTA's effects on the gut microbiota and kidney damage while examining how postbiotics offer protection. Using metagenomic sequencing, we observed that OTA increased the potential gut pathogens such as Alistipes, elevating detrimental metabolites and inflammation. Also, OTA inhibited the Nrf2/HO-1 pathway, reducing kidney ROS elimination and leading to cellular ferroptosis and subsequent kidney damage. Postbiotics mitigate OTA's effects by downregulating the abundance of the assimilatory sulfate reduction IV pathway and virulence factors associated with iron uptake and relieving the inhibition of OTA on Nrf2/HO-1, restoring ROS-clearing capabilities and thereby alleviating chronic OTA-induced kidney damage. Understanding the OTA-gut-kidney link provides new approaches for preventing kidney damage, with postbiotics showing promise as a preventive treatment.

Arecoline alleviated loperamide induced constipation by regulating gut microbes and the expression of colonic genome.

This study aimed to investigate the effects of arecoline on constipation by intervening at different times to explore its preventive and therapeutic effects. Symptoms related to constipation, gut microbes, short-chain fatty acid (SCFA) content in the cecum, and gene expression in the colon were measured to examine the effect of arecoline on relieving constipation. The results showed that arecoline intervention alleviated loperamide-induced constipation, as evidenced by significantly shortened intestinal transit time, increased fecal water content, improved small bowel propulsion, and increased defecation frequency. In addition, arecoline significantly reduced the levels of gastrointestinal regulatory peptides such as somatostatin and vasoactive intestinal peptide in the serum, thereby regulating intestinal peristalsis. Histopathological analysis showed that arecoline ameliorated intestinal injury caused by constipation. Gut microbial analysis indicated that arecoline altered the taxonomic composition and levels of its metabolite SCFAs in the gut microbiota. Furthermore, the colonic transcriptome results indicated that genes expression related to intestinal diseases were significantly down-regulated by arecoline intervention. In conclusion, the results of the correlation analysis propose a possible mechanism of arecoline in alleviating constipation by modulating the gut microbes and their metabolites and regulating the gut genome.

Short-term arecoline exposure affected the systemic health state of mice, in which gut microbes played an important role.

Arecoline is a critical bioactive component in areca nuts with toxicity and pharmacological activities. However, its effects on body health remain unclear. Here, we investigated the effects of arecoline on physiologic and biochemical parameters in mouse serum, liver, brain, and intestine. The effect of arecoline on gut microbiota was investigated based on shotgun metagenomic sequencing. The results showed that arecoline promoted lipid metabolism in mice, manifested as significantly reduced serum TC and TG and liver TC levels and a reduction in abdominal fat accumulation. Arecoline intake significantly modulated the neurotransmitters 5-HT and NE levels in the brain. Notably, arecoline intervention significantly increased serum IL-6 and LPS levels, leading to inflammation in the body. High-dose arecoline significantly reduced liver GSH levels and increased MDA levels, which led to oxidative stress in the liver. Arecoline intake promoted the release of intestinal IL-6 and IL-1ß, causing intestinal injury. In addition, we observed a significant response of gut microbiota to arecoline intake, reflecting significant changes in diversity and function of the gut microbes. Further mechanistic exploration suggested that arecoline intake can regulate gut microbes and ultimately affect the host's health. This study provided technical help for the pharmacochemical application and toxicity control of arecoline.

Two sides of the same coin: Meta-analysis uncovered the potential benefits and risks of traditional fermented foods at a large geographical scale.

Traditional fermented foods, which are well-known microbial resources, are also bright national cultural inheritances. Recently, traditional fermented foods have received great attention due to their potential probiotic properties. Based on shotgun metagenomic sequencing data, we analyzed the microbial diversity, taxonomic composition, metabolic pathways, and the potential benefits and risks of fermented foods through a meta-analysis including 179 selected samples, as well as our own sequencing data collected from Hainan Province, China. As expected, raw materials, regions (differentiated by climatic zones), and substrates were the main driving forces for the microbial diversity and taxonomic composition of traditional fermented foods. Interestingly, a higher content of beneficial bacteria but a low biomass of opportunistic pathogens and antibiotic resistance genes were observed in the fermented dairy products, indicating that fermented dairy products are the most beneficial and reliable fermented foods. In contrast, despite the high microbial diversity found in the fermented soy products, their consumption risk was still high due to the enrichment of opportunistic pathogens and transferable antibiotic resistance genes. Overall, we provided the most comprehensive assessment of the microbiome of fermented food to date and generated a new view of its potential benefits and risks related to human health.