Heterozygous and HomozygousRFC1 AAGGGRepeat Expansions are Common in Idiopathic Peripheral Neuropathy

  1. Zitian Tang
  2. Sinem S. Ovunc
  3. Elle Mehinovic
  4. Simone Thomas
  5. Jenna Ulibarri
  6. Zefan Li
  7. Dustin Baldridge
  8. Carlos Cruchaga
  9. Matt Johnson
  10. Jeffrey Milbrandt
  11. Brian Callaghan
  12. PNRR Study Group
  13. Ahmet Höke
  14. Peter K. Todd
  15. Sheng Chih Jin
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Abstract

Objective

Biallelic intronic AAGGG repeat expansions inRFC1cause Cerebellar Ataxia with Neuropathy and Vestibular Areflexia Syndrome and may also contribute to isolated sensory neuropathy. The clinical significance of both heterozygous and biallelicRFC1expansions in more diverse patient populations remains unclear—partly due to the absence of accurate, user-friendly computational tools specifically tailored for tandem repeat analysis.

Methods

To discern the relationship betweenRFC1expansions and idiopathic peripheral neuropathy (iPN), we performed whole-genome sequencing (WGS) followed by PCR-based confirmation in a large, well-characterized U.S. cohort consisting of 788 iPN patients (369 pure small fiber neuropathy (SFN), 266 sensorimotor, 144 pure sensory, and 9 pure motor). We developed an integrative pipeline combining ExpansionHunter Denovo and Expansion Hunter coupled with unsupervised clustering to reliably detect and genotypeRFC1expansions from short-read WGS data, achieving 98.2% concordance with repeat-primed PCR based validation.

Results

BiallelicRFC1expansions were absent in 879 controls but present in 2.8% of iPN patients (Fisher’s exactp= 5.9×10−8), including 6.2% of pure sensory, 2.2% of SFN, and 1.5% of sensorimotor neuropathy, indicating that motor nerve involvement should not exclude patients fromRFC1repeat screening. We also observed a markedly increased frequency of monoallelic expansions in iPN compared to controls (13.2% versus 2.5%; Fisher’s exactp= 3.4×10−17), without evidence of secondary mutations or expansions on the other allele.

Interpretation

Our approach provides a robust, cost-effective method for detectingRFC1expansions from WGS data. Our findings indicate that both heterozygous and homozygous AAGGG repeat expansions inRFC1can contribute to development of iPN.

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