@article{22295,
  abstract     = {Despite the functional diversity of over 100 causal genes1,2,3, phenotypic convergence across models may reveal common neurobiological processes in autism spectrum disorder (ASD). Here we profiled 251 samples from 11 monogenic mouse models of ASD using single-nucleus multi-omic sequencing across three developmental stages, both sexes and two brain regions. Despite genetic heterogeneity, ASD-linked mutations converged on perturbations of the radial glial cell lineage. These alterations reflect a transient developmental delay rather than lasting lineage misspecification and resolve by postnatal stages. Molecularly, the largest transcriptional differences emerged in neurons at early postnatal stages. These changes included downregulation of synaptic and ion channel-related genes, consistent with homeostatic adaptation or delayed maturation. Network analysis showed molecular convergence across models within each developmental stage, suggesting that diverse mutations linked to ASD impinge on common, stage-specific processes. Convergence becomes less pronounced by postnatal day 14, highlighting the dynamic nature of ASD-associated changes. Cross-genotype heterogeneity is superimposed on stage-specific effects. Electrophysiology corroborated this pattern: mutants generally showed altered neuronal excitability and synaptic properties with model-specific nuances. Our study also highlighted sex-specific gene expression alterations, with female mice often displaying larger effect sizes than male mice. Together, our findings provide a comprehensive view of developmental cellular and molecular dynamics across models of ASD.},
  author       = {Schwarz, Lena A and Dotter, Christoph and Isaev, Sergey and Lisi, Michela and Malzl, Daniel and Büschl, Christoph and Ladstätter, Sabrina and Oliveira, Bárbara and Barel, Matteo and Basilico, Bernadette and Chintaluri, Chaitanya and Gorkiewicz, Sarah and Goudarzi, Mohammad and Belinova, Tereza and Reichl, Stephan and Sendžikaitė, Gintarė and Arcot Jayaram, Satish and Koppensteiner, Peter and Sommer, Christoph M and Vogels, Tim P and Menche, Jörg and Adameyko, Igor and Kharchenko, Peter Vasili and Bock, Christoph and Novarino, Gaia},
  issn         = {1476-4687},
  journal      = {Nature},
  publisher    = {Springer Nature},
  title        = {{Cortical development dynamics across autism spectrum disorder mouse models}},
  doi          = {10.1038/s41586-026-10679-1},
  year         = {2026},
}

@phdthesis{19557,
  author       = {Schwarz, Lena A},
  issn         = {2663-337X},
  pages        = {124},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Mapping developmental dynamics of autism spectrum disorder mouse models at single-cell resolution}},
  doi          = {10.15479/AT-ISTA-19557},
  year         = {2025},
}

@phdthesis{12364,
  abstract     = {Autism spectrum disorders (ASDs) are a group of neurodevelopmental disorders characterized by behavioral symptoms such as problems in social communication and interaction, as
well as repetitive, restricted behaviors and interests. These disorders show a high degree
of heritability and hundreds of risk genes have been identifed using high throughput
sequencing technologies. This genetic heterogeneity has hampered eforts in understanding
the pathogenesis of ASD but at the same time given rise to the concept of convergent
mechanisms. Previous studies have identifed that risk genes for ASD broadly converge
onto specifc functional categories with transcriptional regulation being one of the biggest
groups. In this thesis, I focus on this subgroup of genes and investigate the gene regulatory
consequences of some of them in the context of neurodevelopment.
First, we showed that mutations in the ASD and intellectual disability risk gene Setd5 lead
to perturbations of gene regulatory programs in early cell fate specifcation. In addition,
adult animals display abnormal learning behavior which is mirrored at the transcriptional
level by altered activity dependent regulation of postsynaptic gene expression. Lastly,
we link the regulatory function of Setd5 to its interaction with the Paf1 and the NCoR
complex.
Second, by modeling the heterozygous loss of the top ASD gene CHD8 in human cerebral
organoids we demonstrate profound changes in the developmental trajectories of both
inhibitory and excitatory neurons using single cell RNA-sequencing. While the former
were generated earlier in CHD8+/- organoids, the generation of the latter was shifted to
later times in favor of a prolonged progenitor expansion phase and ultimately increased
organoid size.
Finally, by modeling heterozygous mutations for four ASD associated chromatin modifers,
ASH1L, KDM6B, KMT5B, and SETD5 in human cortical spheroids we show evidence of
regulatory convergence across three of those genes. We observe a shift from dorsal cortical
excitatory neuron fates towards partially ventralized cell types resembling cells from the
lateral ganglionic eminence. As this project is still ongoing at the time of writing, future
experiments will aim at elucidating the regulatory mechanisms underlying this shift with
the aim of linking these three ASD risk genes through biological convergence.},
  author       = {Dotter, Christoph},
  issn         = {2663-337X},
  pages        = {152},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Transcriptional consequences of mutations in genes associated with Autism Spectrum Disorder}},
  doi          = {10.15479/at:ista:12094},
  year         = {2022},
}

