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Paraspeckle condensation is controlled via TDP-43 polymerization and linked to neuroprotection

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SCHOOL OF MEDICINE
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Hodgson, R. E.
Huang, W.
Lang, R.
Kumar, V.
An, H.
Stender, E. G. P.
Chalakova, Z. P.
Driver, M. D.
Sanchez Avila, A.
Ellis, B. C. S.

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eng

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Abstract

The paraspeckle is a disease-relevant biomolecular condensate assembled from long non-coding RNA (lncRNA) NEAT1_2 ribonucleoprotein particles. Paraspeckle biogenesis is suppressed in normal tissues, yet it can be rapidly upregulated under stress. Here we demonstrate that a neurodegeneration-linked RNA-binding protein TDP-43 inhibits NEAT1_2 ribonucleoprotein particle condensation into the paraspeckle, in a concentration-dependent manner, which requires its intact polymerization and RNA binding. This effect is counterbalanced by core paraspeckle proteins such as FUS. Below disruptive concentrations, TDP-43 can be recruited into paraspeckles, forming non-liquid clusters. Under stress, TDP-43 sequestration into de novo nuclear condensates alleviates paraspeckle suppression and increases their dynamism. NEAT1_2 middle-part and 3′-end UG repeats mediate paraspeckle regulation by TDP-43 cotranscriptionally and post assembly, respectively. The deletion of the 3′-end UG repeat increases paraspeckle stability and cytoprotection in stressed human neurons. Consistently, longer 3′-end UG repeats are linked to shorter survival in the neurodegenerative disease amyotrophic lateral sclerosis. Thus, TDP-43 is a critical regulator of paraspeckle condensates linked to cytoprotection. Hodgson, Huang, Lang et al. show that TDP-43 limits ribonucleoprotein particle condensation into paraspeckles in a concentration- and polymerization-dependent manner. They also link paraspeckle condensation to stress response and neuroprotection.

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Nature

Subject

Cell biology

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Nature Cell Biology

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10.1038/s41556-026-01895-y

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