微生物群
计算生物学
肠道菌群
生物
肠道微生物群
益生菌
生化工程
生物信息学
细菌
遗传学
免疫学
工程类
作者
Yashika Gupta,Bhavya Sharma,Chakresh Kumar Jain
标识
DOI:10.2174/0113816128357214250221053909
摘要
The gut microbiome, a complex and diverse microbial ecosystem, plays a pivotal role in maintaining host health by regulating physiological balance and preventing disease. Probiotics, live beneficial microorganisms, have shown potential in modulating the gut microbiota through mechanisms such as competitive exclusion of pathogens, enhancement of mucosal immunity, and regulation of microbial metabolism. Recent advancements in membrane simulations offer a novel approach to studying these interactions at the molecular level. By employing molecular dynamics (MD) and coarse-grained models, these simulations provide insights into the structural and functional dynamics of bacterial membranes and their interactions with probiotics. This approach enables a deeper understanding of key processes, such as microbial metabolite transport, membrane permeability, and host response modulation, which are critical for maintaining gut homeostasis. Additionally, membrane simulations facilitate the exploration of microbial communication pathways, enhancing our knowledge of the molecular mechanisms underlying the beneficial effects of probiotics. As computational tools evolve, integrating membrane simulations with experimental approaches can accelerate the discovery of targeted probiotic therapies aimed at restoring microbial balance and optimizing gut health. This review underscores the significance of membrane simulations in advancing gut microbiome research, suggesting that future studies should focus on refining these computational models to bridge the gap between theoretical predictions and clinical applications. Through a synergistic approach, researchers can enhance the therapeutic potential of probiotics, leading to improved strategies for managing gut-related disorders with insightful knowledge of their interactions.
科研通智能强力驱动
Strongly Powered by AbleSci AI