Author
Listed:
- Yonatan Perez
(San Francisco
San Francisco)
- Dmitry Velmeshev
(San Francisco
San Francisco
Duke University)
- Li Wang
(San Francisco
San Francisco)
- Matthew L. White
(San Francisco
San Francisco)
- Clara Siebert
(San Francisco
San Francisco)
- Jennifer Baltazar
(San Francisco
San Francisco)
- Guolong Zuo
(San Francisco
San Francisco)
- Juan Andrés Moriano
(San Francisco
San Francisco)
- Songcang Chen
(San Francisco
San Francisco)
- David M. Steffen
(San Francisco)
- Natalia Garcia Dutton
(San Francisco
San Francisco)
- Shaohui Wang
(San Francisco
San Francisco)
- Brittney Wick
(University of California)
- Maximilian Haeussler
(University of California)
- Stormy Chamberlain
(400 Farmington Avenue)
- Arturo Alvarez-Buylla
(San Francisco)
- Arnold Kriegstein
(San Francisco
San Francisco)
Abstract
Duplication 15q (dup15q) syndrome is a leading genetic cause of autism spectrum disorder, offering a key model for studying autism-related mechanisms. Using single-cell and single-nucleus RNA sequencing of cortical organoids from dup15q patient-derived iPSCs and post-mortem brain samples, we identify increased glycolysis, disrupted layer-specific marker expression, and aberrant morphology in deep-layer neurons during fetal-stage organoid development. In adolescent-adult postmortem brains, upper-layer neurons exhibit heightened transcriptional burden related to synaptic signaling, a pattern shared with idiopathic autism. Using spatial transcriptomics, we confirm these cell-type-specific disruptions in brain tissue. By gene co-expression network analysis, we reveal disease-associated modules that are well preserved between postmortem and organoid samples, suggesting metabolic dysregulation that may lead to altered neuron projection, synaptic dysfunction, and neuron hyperexcitability in dup15q syndrome.
Suggested Citation
Yonatan Perez & Dmitry Velmeshev & Li Wang & Matthew L. White & Clara Siebert & Jennifer Baltazar & Guolong Zuo & Juan Andrés Moriano & Songcang Chen & David M. Steffen & Natalia Garcia Dutton & Shaoh, 2025.
"Single-cell analysis of dup15q syndrome reveals developmental and postnatal molecular changes in autism,"
Nature Communications, Nature, vol. 16(1), pages 1-16, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-61184-4
DOI: 10.1038/s41467-025-61184-4
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