A Strategy for Rapid Discovery of Marker Peptides Associated with Fibrinolytic Efficacy of Based on Bioinformatics Combined with Parallel Reaction Monitoring

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2022 May 14

PMID 35566002

Authors

Ting-Ting Feng

Jing-Xian Zhang

Yong-Peng Zhang

Jian Sun

Hong Yu

Xiang Tao

Xiu-Hong Mao

Qing Hu

Shen Ji

Affiliations

Soon will be listed here.

Abstract

Quality control of animal-derived traditional Chinese medicines has improved dramatically as proteomics research advanced in the past few decades. However, it remains challenging to identify quality attributes with routine proteomics approaches since protein with fibrinolytic activity is rarely reported in pheretima, a typical animal-derived traditional medicine. A novel strategy based on bioinformatics combined with parallel reaction monitoring (PRM) was developed here to rapidly discover the marker peptides associated with a fibrinolytic effect. Potential marker peptides were found by lumbrokinase sequences' alignment and in silico digestion. The fibrinogen zymography was used to visually identify fibrinolytic proteins in pheretima. As a result, it was found that the fibrinolytic activity varied among different portions of pheretima. Fibrinolytic proteins were distributed regionally in the anterior and anterior-mid portion and there was no significant fibrinogenolytic activity observed in the mid-posterior and posterior portion. Finally, PRM experiments were deployed to validate and quantify selected marker peptides and a total of 11 peptides were identified as marker peptides, which could be potentially used in quality control of pheretima. This strategy provides a robust workflow to benefit the quality control of other animal-derived traditional medicines.

Citing Articles

An Integrated Strategy of Chemical Fingerprint and Network Pharmacology for the Discovery of Efficacy-Related Q-Markers of .

Shang Y, Liu S, Liang C, Du K, Chen S, Li J Int J Anal Chem. 2022; 2022:8774913.

PMID: 36245784 PMC: 9553678. DOI: 10.1155/2022/8774913.

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