Background: Developmental stuttering, a multifactorial speech disorder with remarkable rate of spontaneous recovery pose challenges for gene discoveries. Exonic variants in GNPTAB, GNPTG, and NAGPA involved in lysosomal pathway and AP4E1, IFNAR1, and ARMC3-signaling genes reported till date explain only ∼2.1% - 3.7% of persistent stuttering cases.
Aim: We aimed to identify additional genetic determinants of stuttering in a multiplex family by exome sequencing (n = 27) and further validation on additional extended family members (n = 21).
Materials & methods: We employed hypothesis-free and pathway-based analyses.
Results: A novel heterozygous exonic variant NM_016256.4:c.322G > A in NAGPA with reduced penetrance and predicted pathogenicity segregated with the phenotype in a large subset of the family. Reanalysis to identify additional disease-causing variant(s) revealed exonic heterozygous variants each in RIMS2 and XYLT1 in severely affected members; and IGF2R variant in a small subset of the family. Furthermore, pathway-based analysis uncovered NM_022089.4:c.3529G > A in ATP13A2 (PARK9) in affected members; and variants in GNPTAB and GNPTG of minor significance in a few affected members.
Discussion: Genotype-phenotype correlation efforts suggest that the combined effect of gene variants at multiple loci or variants in a single gene in different subsets of the pedigree (genetic heterogeneity) may be contributing to stuttering in this family. More importantly, variants identified in ATP13A2, a Parkinson's disease gene also implicated in lysosomal dysfunction, and RIMS2 suggests for the first time a likely role of dopamine signaling in stuttering.
Conclusion: Screening for these variants in independent stuttering cohorts would be astute.
Keywords: South Indian family; clinical heterogeneity; developmental stuttering genes; exome sequencing; genetic heterogeneity; speech disorder.
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