Phytoplasmas are prokaryotic plant pathogens causing considerable loss in many economical crops globally. Recently, an increasing number of phytoplasma diseases were reported on new plant hosts, indicating the traditional control strategies will need an improvement. Previously, we found that a systemic resistance is activated by PLY phytoplasma infection. Therefore, we aimed to investigate NPR1, a critical gene in SAR activation, to realize the effects of SAR on phytoplasma pathogenesis. Because a functional analysis system was lacking for periwinkle, a system based on virus-induced gene silencing (VIGS) was proposed for periwinkle. Tobacco rattle virus (TRV)-based VIGS system was tested in periwinkle and several potentially influential factors (plant cultivar, temperature, plant age, and plant organ) were analyzed to optimize the system. Based on silencing frequency and survival rate, Titan was the most appropriated cultivar for VIGS. In addition, high temperature showed negative effects on VIGS efficacy while VIGS was not significantly affected by plant age. Though VIGS reached to all plant organs, young leaves and flowers showed a more pronounced silencing effect than other organs. The differences of silencing efficacy were strongly associated with TRV2 concentration; therefore TRV2 should be critical for silencing. Moreover, because TRV infection did not greatly influence symptom development of phytoplasma, the system should be useful for plant-phytoplasma interaction studies. Using this system, CrNPR1 and CrNPR3 were respectively silenced to understand their roles in phytoplasma resistance. Silencing of either genes repressed induction of CrPR1 in TRV-infected plants. However, disease symptoms developed fastest in CrNPR1-silenced plants, and slowest in CrNPR3-silenced plants among all groups. CrNPR1 should be a critical element in defense against phytoplasma, and CrNPR3 may counteract its activity in the defense. Consistently, CrNPR1 but not CrNPR3 was induced by phytoplasma infection as well as SA treatment. The study highlights the importance of NPR1- and SA-mediated signaling pathway for resistance to phytoplasma in periwinkle, and gain more insights about plant-phytoplasma interactions to improve the disease control strategies.