Oyster-derived dipeptides RI, IR, and VR promote testosterone synthesis by reducing oxidative stress in TM3 cells.
Yongqiu YanMingliang LiYing WeiFuhuai JiaYanying ZhengGang TaoFeifei XiongPublished in: Food science & nutrition (2023)
Short peptides have gained widespread utilization as functional constituents in the development of functional foods due to their remarkable biological activity. Previous investigations have established the positive influence of oysters on testosterone biosynthesis, although the underlying mechanism remains elusive. This study aims to assess the impact of three dipeptides derived from oysters on the oxidative stress state of TM3 cells induced by AAPH while concurrently examining alterations in cellular testosterone biosynthesis capacity. The investigation encompasses an analysis of reactive oxygen species (ROS) content, antioxidant enzyme activity, apoptotic status, and expression levels of crucial enzymes involved in the testosterone synthesis pathway within TM3 cells, thus evaluating the physiological activity of the three dipeptides. Additionally, molecular docking was employed to investigate the inhibitory activity of the three dipeptides against ACE. The outcomes of this study imply that the oxidative stress state of cells impedes the synthesis of testosterone by inhibiting the expression of essential proteins in the testosterone synthesis pathway. These three dipeptides derived from oysters ameliorate cellular oxidative stress by directly scavenging excess ROS or reducing ROS production rather than enhancing cellular antioxidant capacity through modulation of antioxidant enzyme activity. These findings introduce a novel avenue for developing and utilizing antioxidant peptides derived from food sources.
Keyphrases
- oxidative stress
- induced apoptosis
- dna damage
- reactive oxygen species
- cell cycle arrest
- signaling pathway
- cell death
- replacement therapy
- molecular docking
- endoplasmic reticulum stress
- ischemia reperfusion injury
- poor prognosis
- anti inflammatory
- type diabetes
- drinking water
- molecular dynamics simulations
- insulin resistance
- skeletal muscle
- binding protein