The First In Vivo Study Shows That Gyrophoric Acid Changes Behavior of Healthy Laboratory Rats.
Patrik SimkoAndrea LeskanicovaMaria Suvakova-NunhartJan KovalNela ZidekovaMartina KarasováPetra MajerovaLudmila VerboovaAlzbeta BlicharovaMartin KertysIvan BarvikAndrej KováčTerezia KiskovaPublished in: International journal of molecular sciences (2024)
Gyrophoric acid (GA), a lichen secondary metabolite, has attracted more attention during the last years because of its potential biological effects. Until now, its effect in vivo has not yet been demonstrated. The aim of our study was to evaluate the basic physicochemical and pharmacokinetic properties of GA, which are directly associated with its biological activities. The stability of the GA in various pH was assessed by conducting repeated UV-VIS spectral measurements. Microsomal stability in rat liver microsomes was performed using Ultra-Performance LC/MS. Binding to human serum albumin (HSA) was assessed using synchronous fluorescence spectra, and molecular docking analysis was used to reveal the binding site of GA to HSA. In the in vivo experiment, 24 Sprague-Dawley rats (Velaz, Únetice, Czech Republic) were used. The animals were divided as follows. The first group ( n = 6) included healthy males as control intact rats (♂INT), and the second group ( n = 6) included healthy females as controls (♀INT). Groups three and four (♂GA/ n = 6 and ♀GA/ n = 6) consisted of animals with daily administered GA (10 mg/kg body weight) in an ethanol-water solution per os for a one-month period. We found that GA remained stable under various pH and temperature conditions. It bonded to human serum albumin with the binding constant 1.788 × 10 6 dm 3 mol -1 to reach the target tissue via this mechanism. In vivo, GA did not influence body mass gain, food, or fluid intake during the experiment. No liver toxicity was observed. However, GA increased the rearing frequency in behavioral tests ( p < 0.01) and center crossings in the elevated plus-maze ( p < 0.01 and p < 0.001, respectively). In addition, the time spent in the open arm was prolonged ( p < 0.01 and p < 0.001, respectively). Notably, GA was able to pass through the blood-brain barrier, indicating its ability to permeate into the brain and to stimulate neurogenesis in the hilus and subgranular zone of the hippocampus. These observations highlight the potential role of GA in influencing brain function and neurogenesis.