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One of the most devastating threats to global honey bee health is the ectoparasitic mite and viral vector Varroa destructor, yet the transmission dynamics of viruses carried by mites are poorly understood. RNA interference (RNAi) is a major antiviral defence mechanism in invertebrates including Varroa, where actively replicating viruses are degraded into virus-derived small interfering RNAs (vsiRNAs). Insects typically produce 20-22 nt vsiRNAs with sense and antisense polarity, however established viral infections in V. destructor lead to the production of 24-nt antisense vsiRNA fragments, which could indicate the presence of secondary siRNA synthesis. To better understand viral infection and transmission dynamics in V. destructor, we conducted small RNA sequencing of male and female mites throughout development, from egg to reproductive stages. Viral community structure was largely driven by developmental stage, with younger and older life stages clustering separately. We identified five viruses that are consistently degraded into antisense 24-nt vsiRNA across all developmental stages, suggesting that these viruses are transmitted vertically and form part of Varroa's core virome. This includes the highly diverse Varroa destructor virus 2 (VDV-2), for which we observe eight distinct VDV-2 strains that simultaneously co-infect individual mites throughout development. In contrast, sense and antisense 23-nt vsiRNA fragments are generated in response to the honey bee pathogen, Iflavirus aladeformis (deformed wing virus A, DWV-A) in eggs, but the vsiRNA size profile transitions to 24-nt antisense fragments at later life stages. Our results suggest that once a virus is first acquired by Varroa, a primary 23-nt sense and antisense antiviral response precedes the production of secondary 24-nt antisense vsiRNAs as the infection progresses. We confirm this observation using synthetic dsRNA, which show both primary and secondary siRNA processing, revealing how exogenous dsRNA processing occurs in Varroa. These results show distinct primary and secondary antiviral RNAi responses across V. destructor life stages and demonstrate how vsiRNA profiles can be used to infer virus transmission routes and long term persistence within vector populations.