Objective:Network pharmacology combines drug and disease targets with biological information networks based on the integrity and systematicness of the interactions between drugs and disease targets.This study aims to ...Objective:Network pharmacology combines drug and disease targets with biological information networks based on the integrity and systematicness of the interactions between drugs and disease targets.This study aims to explore the molecular basis of Hanshi Zufei formula for treatment of COVID-19 based on network pharmacology and molecular docking techniques.Methods:Using TCMSP,the chemical constituents and molecular targets of Atractylodis Rhizoma,Citri Reticulatae Pericarpium,Magnoliae Officinalis Cortex,Pogostemonis Herba,Tsaoko Fructus,Ephedrae Herba,Notopterygii Rhizoma et Radix,Zingiberis Rhizoma Recens,and Arecae Semen were investigated.The predicted targets of novel coronavirus were screened using the NCBI and Gene Cards databases.To further screen the drug-disease core targets network,the corresponding target proteins were queried using multiple databases(Biogrid,DIP,and HPRD),a protein interaction network graph was constructed,and the network topology was analyzed.The molecular docking studies were also performed between the network’s top 15 compounds and the coronavirus(SARS-Co V-2)3 CL hydrolytic enzyme and angiotensin conversion enzymeⅡ(ACE2).Results:The herb-active ingredient-target network contained nine drugs,86 compounds,and 49 drugdisease targets.Gene ontology(GO)enrichment analysis resulted in 1566 GO items(P<0.05),among which 1438 were biological process items,35 were cell composition items,and 93 were molecular function items.Fourteen signal pathways were obtained by enrichment screening of the KEGG pathway database(P<0.05).The molecular docking results showed that the affinity of the core active compounds with the SARS-CoV-23 CL hydrolase was better than for the other compounds.Conclusion:Several core compounds can regulate multiple signaling pathways by binding with 3 CL hydrolase and ACE2,which might contribute to the treatment of COVID-19.展开更多
基金supported by the Research Foundation of Administration of Traditional Chinese Medicine of Hebei Province(No.2018105)。
文摘Objective:Network pharmacology combines drug and disease targets with biological information networks based on the integrity and systematicness of the interactions between drugs and disease targets.This study aims to explore the molecular basis of Hanshi Zufei formula for treatment of COVID-19 based on network pharmacology and molecular docking techniques.Methods:Using TCMSP,the chemical constituents and molecular targets of Atractylodis Rhizoma,Citri Reticulatae Pericarpium,Magnoliae Officinalis Cortex,Pogostemonis Herba,Tsaoko Fructus,Ephedrae Herba,Notopterygii Rhizoma et Radix,Zingiberis Rhizoma Recens,and Arecae Semen were investigated.The predicted targets of novel coronavirus were screened using the NCBI and Gene Cards databases.To further screen the drug-disease core targets network,the corresponding target proteins were queried using multiple databases(Biogrid,DIP,and HPRD),a protein interaction network graph was constructed,and the network topology was analyzed.The molecular docking studies were also performed between the network’s top 15 compounds and the coronavirus(SARS-Co V-2)3 CL hydrolytic enzyme and angiotensin conversion enzymeⅡ(ACE2).Results:The herb-active ingredient-target network contained nine drugs,86 compounds,and 49 drugdisease targets.Gene ontology(GO)enrichment analysis resulted in 1566 GO items(P<0.05),among which 1438 were biological process items,35 were cell composition items,and 93 were molecular function items.Fourteen signal pathways were obtained by enrichment screening of the KEGG pathway database(P<0.05).The molecular docking results showed that the affinity of the core active compounds with the SARS-CoV-23 CL hydrolase was better than for the other compounds.Conclusion:Several core compounds can regulate multiple signaling pathways by binding with 3 CL hydrolase and ACE2,which might contribute to the treatment of COVID-19.
