A finding of highly selective synthetic inhibitor of plasma kallikrein; its action to bradykinin generation, intrinsic coagulation and experimental DIC

Theaflavin TF3 Relieves Hepatocyte Lipid Deposition through Activating an AMPK Signaling Pathway by targeting Plasma Kallikrein

Nonalcoholic fatty liver disease (NAFLD) is rapidly becoming the leading cause of chronic liver diseases throughout the world. The deficit of pharmacotherapy for NAFLD calls for an urgent need for a new drug discovery and lifestyle management. Black tea is the most popular and functional drink consumed worldwide. Its main bioactive constituent theaflavin helps to prevent obesity-a major risk factor for NAFLD. To find new targets for the development of effective and safe therapeutic drugs from natural plants for NAFLD, we found a theaflavin monomer theaflavin-3,3'-digallate (TF3), which significantly reduced lipid droplet accumulation in hepatocytes, and directly bound and inhibited the activation of plasma kallikrein (PK), which was further proved to stimulate adenosine monophosphate activated protein kinase (AMPK) and its downstream targets. Taken together, we proposed that the TF3-PK-AMPK regulatory axis is a novel mechanism of lipid deposition mitigation, and PK could be a new target for NAFLD treatment.

Mapping of human plasma kallikrein active site by design of peptides based on modifications of a Kazal-type inhibitor reactive site

Human plasma kallikrein (huPK) is a proteinase that participates in several biological processes. Although various inhibitors control its activity, members of the Kazal family have not been identified as huPK inhibitors. In order to map the enzyme active site, we synthesized peptides based on the reactive site (PRILSPV) of a natural Kazal-type inhibitor found in Cayman plasma, which is not an huPK inhibitor. As expected, the leader peptide (Abz-SAPRILSPVQ-EDDnp) was not cleaved by huPK. Modifications to the leader peptide at P'1, P'3 and P'4 positions were made according to the sequence of a phage display-generated recombinant Kazal inhibitor (PYTLKWV) that presented huPK-binding ability. Novel peptides were identified as substrates for huPK and related enzymes. Both porcine pancreatic and human plasma kallikreins cleaved peptides at Arg or Lys bonds, whereas human pancreatic kallikrein cleaved bonds involving Arg or a pair of hydrophobic amino acid residues. Peptide hydrolysis by pancreatic kallikrein was not significantly altered by amino acid replacements. The peptide Abz-SAPRILSWVQ-EDDnp was the best substrate and a competitive inhibitor for huPK, indicating that Trp residue at the P'4 position is important for enzyme action.