Phytoplasma, a wall-less obligate bacterial plant parasite, can cause symptoms of witches’-broom, virenscence, as well as phyllody, and result in economic losses. Understanding plant-phytoplasma interactions should help us to develop new control strategies of this pathogen. We found that when Catharanthus roseus (periwinkle) plants are infected with periwinkle leaf yellowing (PLY) phytoplasma, they show systemic defense responses, which was proven by the finding of CrPR1a induction in non-symptomatic shoots. Previously, potential CrPR1a regulatory transcription factors, including 5 ARFs, 3 bZIP, 2 AP2/ERF and 1 WRKY, have been identified using virus-induced gene silencing (VIGS). In this study, I further confirmed whether changes of their transcript abundance affect plant defense against phytoplasma in periwinkle using VIGS. Silencing of CrWRKY31 and CrTINY2 changed the accumulation of SA and resulted in repression of TRV accumulation in periwinkles; however, symptom progression of PLY was accelerated in these plants when inoculated with PLY phytoplamsa. It is possible that CrTINY2 and CrWRKY31 could be involved in a SA-independent defense pathway that is also important for plant to defend against phytoplasma. Previously, it was found that silencing of CrARF17 repressed CrPR1a indcution and accelerated symptom progression of PLY. To understand more about CrARF17 in plant defense responses, it was ectopically expressed in Arabidopsis thaliana and compared its function with its counterpart, AtARF17. It is found that ectopic expression of CrARF17 resulted in curly leaves and short siliques. The phenotypical changes were resemble the phenotype of transgenic plants harbored 35S::5mARF17. These results suggest that CrARF17 shares similar functions with AtARF17. The transgenic plants showed strong immune responses and induction of AtPR1; however, no significant changes in CMV accumulation in these transgenic plants.