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Nuclear speckles (NS) and paraspeckles (PS) are adjacent yet distinct nuclear condensates that undergo stress-induced reorganization. Here, we identify a dual role for the splicing factor SRSF5 in coordinating the crosstalk between both condensates. Super-resolution imaging shows that SRSF5, while enriched in NS, also overlaps with the shell of a subset of PS. SRSF5 binds purine-rich sequences at the 5' end of NEAT1₂ promoting its alignment to PS shells and the formation of large PS cluster during stress. We propose that SRSF5 binding occurs transiently during PS maturation and must later be removed from NEAT1₂ by nuclear helicases. Inhibition of this remodeling by rocaglamide A, which locks helicases onto purine-rich RNA leads to the aberrant fusion of PS and NS, which can be partially rescued by acute SRSF5 depletion. Surprisingly, while short-term SRSF5 loss impairs PS formation, prolonged depletion activates a feedback loop involving intron retention and premature polyadenylation of TARDBP, reduction of TDP-43 levels and NEAT1₂ isoform switching, ultimately restoring PS clusters. Our findings reveal that SRSF5 serves both architectural and regulatory roles in PS biogenesis and that helicase-mediated remodeling is essential to maintain PS identity and function under stress. These insights uncover fundamental principles of nuclear body dynamics.
Okuda et al. (Sat,) studied this question.