κ-Carrageenan oligosaccharides induce microglia autophagy through AMPK/ULK1 pathway to regulate their immune response.

Microglia are the main effector cells of immune response in central nervous system and are important targets for disease prevention and treatment. Κ-carrageenan Oligosaccharide (KOS), obtained by enzymatic hydrolysis from carrageenan of marine red algae, can inhibit the release of inflammatory factors from the over-activated microglia. The mechanism of microglia autophagy induced by KOS and its relationship with inflammation were studied to explore the development prospect of KOS in the research and treatment of inflammatory related diseases. The effect of KOS on inducing autophagy was detected by the secretion of cytokines by lipopolysaccharide (LPS)-activated microglia, respectively. The protein expression of autophagy-related signaling pathways were detected by Western Blot. The results showed that KOS could significantly protect the microglia from over-activated inflammatory by inducing the autophagy and inhibiting the release of inflammatory cytokines. And KOS could reduce the expression of the protein that related to the AMPK/ULK1 pathways in microglia, so as to regulate the autophagy pathway, and inhibit the inflammatory response of over-activated microglia. The study on the effect of KOS on microglia autophagy and excessive inflammatory response will provide a theoretical basis for further studies on the inhibition of nerve injury by regulating microglia autophagy and inflammatory response.

Design, synthesis and PPAR agonist activities of novel L-tyrosine derivatives containing phenoxyacetyl moiety / 药学学报

The design, synthesis and bioevaluation of a series of novel L-tyrosine derivatives as peroxisome proliferator-activated receptor (PPAR) agonists are reported. Four intermediates and twenty L-tyrosine derivatives containing phenoxyacetyl moiety TM1 were synthesized starting from L-tyrosine via four step reactions including the esterification of carboxyl group, phenoxyacetylation of a-amino group, bromoalkylation of phenolic hydroxyl group and then nucleophilic substitution reaction with various heterocyclic amines in 21%-75% overall yield. Subsequently TM1 were hydrolyzed to give sixteen corresponding target compounds TM2 in 77%-99% yield. The chemical structures of the thirty-nine new compounds were identified using 1H NMR, 13C NMR techniques and thirty-five were confirmed by HR-MS techniques. Screening results in vitro showed that the PPAR relative activation activities of the target molecules are weak overall, while compound TM2i reaches 50.01%, which hints that the molecular structures of these obtained compounds need to be modified further.