Short RNA chaperones promote aggregation-resistant TDP-43 conformers to mitigate neurodegeneration
Summary
Aberrant aggregation of the prion-like RNA binding protein TDP-43 drives several fatal neurodegenerative proteinopathies, including amyotrophic lateral sclerosis (ALS). In this work, we define how short, specific RNAs solubilize TDP-43. These short RNAs engage and stabilize the TDP-43 RNA recognition motifs, which allosterically destabilizes a conserved helical region in the prion-like domain, thereby promoting aggregation-resistant conformers. Sequence-space mining identified short RNA ch
Content
# Short RNA chaperones promote aggregation-resistant TDP-43 conformers to mitigate neurodegeneration
*Published: 2026 May 7*
Aberrant aggregation of the prion-like RNA binding protein TDP-43 drives several
fatal neurodegenerative proteinopathies, including amyotrophic lateral sclerosis
(ALS). In this work, we define how short, specific RNAs solubilize TDP-43. These
short RNAs engage and stabilize the TDP-43 RNA recognition motifs, which
allosterically destabilizes a conserved helical region in the prion-like domain,
thereby promoting aggregation-resistant conformers. Sequence-space mining
identified short RNA chaperones with enhanced activity against TDP-43 and
disease-linked variants. Enhanced short RNA chaperones mitigated aberrant TDP-43
phenotypes in optogenetic models and in ALS patient-derived and control motor
neurons. In mice with cytoplasmic TDP-43 aggregation and motor neuron loss, an
enhanced short RNA chaperone reduced pathological aggregation, restored TDP-43
function, and conferred neuroprotection. These results define a mechanistic and
therapeutic framework for RNA-based strategies to counter TDP-43
proteinopathies.
DOI: 10.1126/science.adv3301