Chromatin regulates spatiotemporal gene expression during neurodevelopment, but it also mediates DNA damage repair essential to proliferating neural progenitor cells (NPCs). Here, we uncover molecularly dissociable roles for nucleosome remodeler Ino80 in chromatin-mediated transcriptional regulation and genome maintenance in corticogenesis. We find that conditional Ino80 deletion from cortical NPCs impairs DNA double-strand break (DSB) repair, triggering p53-dependent apoptosis and microcephaly. Using an in vivo DSB repair pathway assay, we find that Ino80 is selectively required for homologous recombination (HR) DNA repair, which is mechanistically distinct from Ino80 function in YY1-associated transcription. Unexpectedly, sensitivity to loss of Ino80 -mediated HR is dependent on NPC division mode: Ino80 deletion leads to unrepaired DNA breaks and apoptosis in symmetric NPC-NPC divisions, but not in asymmetric neurogenic divisions. This division mode dependence is phenocopied following conditional deletion of HR gene Brca2 . Thus, distinct modes of NPC division have divergent requirements for Ino80 -dependent HR DNA repair.
Loss-of-function mutations in chromatin remodeler gene ARID1A are a cause of Coffin-Siris syndrome, a developmental disorder characterized by dysgenesis of corpus callosum. Here, we characterize Arid1a function during cortical development and find unexpectedly selective roles for Arid1a in subplate neurons (SPNs). SPNs, strategically positioned at the interface of cortical gray and white matter, orchestrate multiple developmental processes indispensable for neural circuit wiring. We find that pancortical deletion of Arid1a leads to extensive mistargeting of intracortical axons and agenesis of corpus callosum. Sparse Arid1a deletion, however, does not autonomously misroute callosal axons, implicating noncell-autonomous Arid1a functions in axon guidance. Supporting this possibility, the ascending axons of thalamocortical neurons, which are not autonomously affected by cortical Arid1a deletion, are also disrupted in their pathfinding into cortex and innervation of whisker barrels. Coincident with these miswiring phenotypes, which are reminiscent of subplate ablation, we unbiasedly find a selective loss of SPN gene expression following Arid1a deletion. In addition, multiple characteristics of SPNs crucial to their wiring functions, including subplate organization, subplate axon-thalamocortical axon cofasciculation (“handshake”), and extracellular matrix, are severely disrupted. To empirically test Arid1a sufficiency in subplate, we generate a cortical plate deletion of Arid1a that spares SPNs. In this model, subplate Arid1a expression is sufficient for subplate organization, subplate axon-thalamocortical axon cofasciculation, and subplate extracellular matrix. Consistent with these wiring functions, subplate Arid1a sufficiently enables normal callosum formation, thalamocortical axon targeting, and whisker barrel development. Thus, Arid1a is a multifunctional regulator of subplate-dependent guidance mechanisms essential to cortical circuit wiring.
Histone variants, which can be expressed outside of S-phase and deposited DNA synthesis-independently, provide long-term histone replacement in postmitotic cells, including neurons. Beyond replenishment, histone variants also play active roles in gene regulation by modulating chromatin states or enabling nucleosome turnover. Here, we uncover crucial roles for the histone H3 variant H3.3 in neuronal development. We find that newborn cortical excitatory neurons, which have only just completed replication-coupled deposition of canonical H3.1 and H3.2, substantially accumulate H3.3 immediately postmitosis. Codeletion of H3.3-encoding genes H3f3a and H3f3b from newly postmitotic neurons abrogates H3.3 accumulation, markedly alters the histone posttranslational modification landscape, and causes widespread disruptions to the establishment of the neuronal transcriptome. These changes coincide with developmental phenotypes in neuronal identities and axon projections. Thus, preexisting, replication-dependent histones are insufficient for establishing neuronal chromatin and transcriptome; de novo H3.3 is required. Stage-dependent deletion of H3f3a and H3f3b from 1) cycling neural progenitor cells, 2) neurons immediately postmitosis, or 3) several days later, reveals the first postmitotic days to be a critical window for de novo H3.3. After H3.3 accumulation within this developmental window, codeletion of H3f3a and H3f3b does not lead to immediate H3.3 loss, but causes progressive H3.3 depletion over several months without widespread transcriptional disruptions or cellular phenotypes. Our study thus uncovers key developmental roles for de novo H3.3 in establishing neuronal chromatin, transcriptome, identity, and connectivity immediately postmitosis that are distinct from its role in maintaining total histone H3 levels over the neuronal lifespan.
Subplate neurons indispensably orchestrate the developmental assembly of cortical neural circuits. Here, by cell type-specific dissection of Arid1a function, we uncover an unexpectedly selective role for this ubiquitous chromatin remodeler in subplate neuron molecular identity and circuit wiring function. We find that pan-cortical deletion of Arid1a, but not sparse deletion, leads to mistargeting of callosal and thalamocortical connectivities reminiscent of subplate ablation. These miswiring phenotypes are concomitant with disrupted subplate neuron organization, morphogenesis, axons, and extracellular matrix. Mechanistically, Arid1a is required to establish the transcriptional identity of subplate neurons. Remarkably, cortical plate deletion of Arid1a, which spares subplate neurons, restores subplate axons and extracellular matrix, and is sufficient to extensively correct callosal and thalamocortical axon misrouting, revealing an axon guidance function of Arid1a centered on the subplate. Thus, Arid1a regulates the molecular identity and function of subplate neurons, and thereby non-cell autonomously mediates the formation of cortical connectivity during development.
Histone variants, which can be expressed outside of S-phase and deposited DNA synthesis-independently, provide replacement histones in terminally post-mitotic cells, including neurons. Histone variants can also serve active roles in gene regulation by modulating chromatin states or enabling nucleosome turnover at regulatory regions. Here, we find that newborn cortical excitatory neurons substantially accumulate the histone H3 variant H3.3 immediately post-mitosis. Co-deletion of H3.3-encoding genes H3f3a and H3f3b from new neurons abrogates this accumulation, and causes widespread disruptions in the developmental establishment of the neuronal transcriptome. These broad transcriptomic changes coincide with neuronal maturation phenotypes in acquisition of distinct neuronal identities and formation of axon tracts. Stage-dependent deletion of H3f3a and H3f3b from (1) cycling neural progenitor cells, (2) neurons immediately after terminal mitosis, or (3) several days later, reveals the first post-mitotic days as a critical window for de novo H3.3. After H3.3 accumulation within this developmental window, co-deletion of H3f3a and H3f3b from neurons causes progressive H3.3 depletion over several months without widespread transcriptional disruptions. Our study thus uncovers a key role for H3.3 in establishing neuronal transcriptome, identity, and connectivity immediately post-mitosis that is distinct from its role in maintaining total histone H3 levels over the neuronal lifespan.SignificanceDNA is tightly packaged around histones into chromatin, which compacts the genome, but also restricts access to DNA. All transactions on DNA, notably gene transcription, require chromatin reorganization that is precisely regulated, including via the use of variant forms of histones. Here, we find that during a critical developmental window for establishing post-mitotic neuronal identity, newly generated cortical excitatory neurons substantially accumulate the histone H3 variant H3.3 immediately after terminal mitosis. Conditional deletion of H3.3-encoding genes from new neurons abrogates this accumulation, and disrupts neuronal gene expression, subtype identity, and axon projections. Thus, H3.3 plays important roles in establishing neuronal transcriptome, identity, and connectivity during post-mitotic development. These functions are distinct from long-term maintenance of histone levels in mature neurons.
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