Expanding GABAergic Neuronal Diversity in PSC-Derived Disease Models

GABAergic interneurons comprise diverse molecular and functional subtypes that contribute to neural circuit assembly and are implicated in a range of neurodevelopmental and neuropsychiatric disorders. Traditional approaches for differentiating human pluripotent stem cells (PSCs) into neurons often face challenges such as incomplete neural differentiation, prolonged culture periods, and variability across PSC lines, which can constrain their application in disease modeling. To address these limitations, we developed a strategy that combines inducible expression of the transcription factors (TFs) ASCL1 and DLX2 with dual-SMAD and WNT inhibition to efficiently drive differentiation of human PSCs into diverse, region-specific GABAergic neuronal types. Using single-cell sequencing, we characterized the cellular heterogeneity of GABAergic induced neurons (iNs) generated with the patterning factors (patterned iNs) and those derived solely with TFs (PSC-derived iNs), revealing distinct interneuron subtype compositions and the regulatory programs that govern their fate specification. Patterned iNs exhibited gene expression features corresponding to multiple brain regions, particularly the ganglionic eminence (GE) and neocortex, whereas GABAergic PSC-derived iNs predominantly resembled hypothalamic and thalamic neurons. Both iN types were enriched for genes relevant to neurodevelopmental and psychiatric disorders, with patterned iNs more specifically linked to neural lineage genes, highlighting their utility for disease modeling. We further applied this protocol to investigate the impact of a recurrent ADNP syndrome-associated mutation (p.Tyr719*) on GABAergic neuron differentiation, revealing that this mutation disrupts GABAergic fate specification and synaptic transmission. Overall, this study expands the toolkit for disease modeling by demonstrating the complementary advantages of GABAergic PSC-derived iNs and patterned iNs in representing distinct GABAergic neuron subtypes, brain regions, and disease contexts. Together, these approaches provide a flexible platform for investigating molecular and cellular mechanisms relevant to neurodevelopmental and neuropsychiatric disorders.