Understanding plant-vector-pathogen interactions is essential for explaining the persistence of stolbur diseases associated with the plant pathogenic bacterium ‘
Candidatus
Phytoplasma solani’ (CaPsol) in agroecosystems. This study investigates the role of crop-associated
Reptalus
planthoppers (Insecta: Hemiptera: Cixiidae) in shaping CaPsol epidemiology within a four-crop rotation system (sunflower, wheat, sugar beet, and maize) in Serbia under field and experimental conditions. Over a three-year period (2023–2025), nymphal surveys, adult monitoring, emergence-cage experiments, molecular identification of planthoppers, assessment of CaPsol in crops, and vector transmission assays were conducted, with a particular focus on the sunflower-wheat sequence. Sunflower was identified as a developmental host for
Reptalus quinquecostatus
and
Reptalus panzeri
, with high CaPsol infection rates detected in both the host plant and associated vectors. In contrast, wheat appeared to primarily support nymphal overwintering, while its significance as a CaPsol reservoir remains inconclusive. Furthermore, the maize-wheat sequence supported the development of
R. quinquecostatus
while confirming its role in the life cycle of
R. panzeri
. Experimental trials demonstrated efficient CaPsol transmission to sunflower but limited transmission to wheat. Despite high infection levels under field conditions, sunflower remained asymptomatic, suggesting its role as a cryptic pathogen reservoir. The findings indicate that the sunflower-wheat sequence may sustain CaPsol-infected
Reptalus
spp. populations across seasons, facilitating pathogen persistence within cropping systems. The study highlights the importance of integrating vector life cycle dynamics into epidemiological frameworks of stolbur diseases, particularly in crop rotations where major cultivated hosts may support in-field CaPsol pathosystems.