SAP54 and PHYL1 are orthologs of pathogen effectors from phytoplasmas. These effectors can cause plant leafy flowers symptoms. To study plant flowers become leafy flower, we develop a viral vector to overcome seedless problem in transgenic plants. TuGK vector from mild strain virus of turnip mosaic virus (TuMV) is a good viral vector for carrying PHYL1 or SAP54 gene. TuGK did not interfere with plant development and it can infect Arabidopsis with rapidly expressing PHYL1 or SAP54 protein. We successfully obtained large amounts of leafy flower tissues for PHYL1 or SAP54 studies from viral vector infected Arabidopsis plants. The TuGK is a suitable viral vector because it loses posttranscriptional gene silencing (PTGS) suppression ability. PTGS is one of the plant antivirus mechanism and to counteract PTGS, plant viruses have also encoded viral suppressors to interrupt PTGS by repressing the regulation of microRNA (miRNA) and short-interfering RNA (siRNA) pathways. In Potyvirus, P1/HC-Pro is the first identified viral suppressor. The HC-Pro protein gets released by the self-cleaving activity of P1. Though the entire function of P1 protein remained unclear. In this study, we investigated the mechanism of P1 enhancing PTGS suppression by identifying P1-interacting proteins using proteomic analysis approach. Moreover, we discovered several novel genes that might relate to P1/HC-Pro-mediated PTGS suppression through transcriptomes and comparative network analysis. To summaries the findings in this study, the AGO1 protein was found to be specifically degraded in turnip mosaic virus (TuMV) P1/HC-Pro transgenic plants (P1/HCTu plant). Also, it was interesting to find that P1 directly interacts with VERNALIZATION INDEPENDENCE 3/SUPERKILLER (VIP3/SKI8) that might enhance HC-Pro-mediated PTGS suppression. VIP3/SKI8 is an RNA exosome and can interfere with the degradation of RNA induced silencing complex (RISC) 5'-cleavage fragment. Furthermore, through the transcriptome approach, we discovered potentially critical genes in PTGS by the comparative network analysis, containing miRNA targets, calcium signaling genes, hormone (JA, ET, and ABA) signaling genes, and defense response genes. Taken together, through these genetic and omics methods, we exposed many critical genes related to PTGS. These new discoveries allow us to better understand viral suppressor P1/HC-Pro interaction with host PTGS mechanism.