Suppression of DNA Double-Strand Break Formation by DNA Polymerase ß in Active DNA Demethylation Is Required for Development of Hippocampal Pyramidal Neurons.

Genome stability is essential for brain development and function, as de novo mutations during neuronal development cause psychiatric disorders. However, the contribution of DNA repair to genome stability in neurons remains elusive. Here, we demonstrate that the base excision repair protein DNA polymerase ß (Polß) is involved in hippocampal pyramidal neuron differentiation via a TET-mediated active DNA demethylation during early postnatal stages using Nex-Cre/Polß fl/fl mice of either sex, in which forebrain postmitotic excitatory neurons lack Polß expression. Polß deficiency induced extensive DNA double-strand breaks (DSBs) in hippocampal pyramidal neurons, but not dentate gyrus granule cells, and to a lesser extent in neocortical neurons, during a period in which decreased levels of 5-methylcytosine and 5-hydroxymethylcytosine were observed in genomic DNA. Inhibition of the hydroxylation of 5-methylcytosine by expression of microRNAs miR-29a/b-1 diminished DSB formation. Conversely, its induction by TET1 catalytic domain overexpression increased DSBs in neocortical neurons. Furthermore, the damaged hippocampal neurons exhibited aberrant neuronal gene expression profiles and dendrite formation, but not apoptosis. Comprehensive behavioral analyses revealed impaired spatial reference memory and contextual fear memory in adulthood. Thus, Polß maintains genome stability in the active DNA demethylation that occurs during early postnatal neuronal development, thereby contributing to differentiation and subsequent learning and memory.SIGNIFICANCE STATEMENT Increasing evidence suggests that de novo mutations during neuronal development cause psychiatric disorders. However, strikingly little is known about how DNA repair is involved in neuronal differentiation. We found that Polß, a component of base excision repair, is required for differentiation of hippocampal pyramidal neurons in mice. Polß deficiency transiently led to increased DNA double-strand breaks, but not apoptosis, in early postnatal hippocampal pyramidal neurons. This aberrant double-strand break formation was attributed to active DNA demethylation as an epigenetic regulation. Furthermore, the damaged neurons exhibited aberrant gene expression profiles and dendrite formation, resulting in impaired learning and memory in adulthood. Thus, these findings provide new insight into the contribution of DNA repair to the neuronal genome in early brain development.

Identification of the cluster control region for the protocadherin-beta genes located beyond the protocadherin-gamma cluster.

The clustered protocadherins (Pcdhs), Pcdh-α, -ß, and -γ, are transmembrane proteins constituting a subgroup of the cadherin superfamily. Each Pcdh cluster is arranged in tandem on the same chromosome. Each of the three Pcdh clusters shows stochastic and combinatorial expression in individual neurons, thus generating a hugely diverse set of possible cell surface molecules. Therefore, the clustered Pcdhs are candidates for determining neuronal molecular diversity. Here, we showed that the targeted deletion of DNase I hypersensitive (HS) site HS5-1, previously identified as a Pcdh-α regulatory element in vitro, affects especially the expression of specific Pcdh-α isoforms in vivo. We also identified a Pcdh-ß cluster control region (CCR) containing six HS sites (HS16, 17, 17', 18, 19, and 20) downstream of the Pcdh-γ cluster. This CCR comprehensively activates the expression of the Pcdh-ß gene cluster in cis, and its deletion dramatically decreases their expression levels. Deleting the CCR nonuniformly down-regulates some Pcdh-γ isoforms and does not affect Pcdh-α expression. Thus, the CCR effect extends beyond the 320-kb region containing the Pcdh-γ cluster to activate the upstream Pcdh-ß genes. Thus, we concluded that the CCR is a highly specific regulatory unit for Pcdh-ß expression on the clustered Pcdh genomic locus. These findings suggest that each Pcdh cluster is controlled by distinct regulatory elements that activate their expression and that the stochastic gene regulation of the clustered Pcdhs is controlled by the complex chromatin architecture of the clustered Pcdh locus.

Relationship between DNA methylation states and transcription of individual isoforms encoded by the protocadherin-alpha gene cluster.

The protocadherin-alpha (Pcdh-alpha) gene encodes diverse transmembrane proteins that are differentially expressed in individual neurons in the vertebrate central nervous system. The Pcdh-alpha genomic structure contains variable first exons, each regulated by its own promoter. Here, we investigated the effect of DNA methylation on gene regulation in the Pcdh-alpha gene cluster. We studied two mouse cell lines, C1300 and M3, that expressed different combinations of Pcdh-alpha isoforms and found that 1) the transcription of specific Pcdh-alpha isoforms correlated significantly with the methylation state of the promoter and the 5' (but not the 3') region of the first exon and 2) mosaic or mixed methylation states of the promoters were associated with both active and inactive transcription. Demethylation of C1300 cells up-regulated all of the Pcdh-alpha isoforms, and, in a promoter assay, hypermethylation of the promoters repressed their transcriptional activity. Cell lines subcloned from the demethylated C1300 cells transcribed different combinations of Pcdh-alpha isoforms than the parental, nondemethylated cells, and the promoters showed differential mosaic or mixed methylation patterns. In vivo, the promoter and 5'-regions of the Pcdh-alphaC1 and alphaC2 exons, which are transcribed in all neurons, were extensively hypomethylated. In contrast, the promoters of the Pcdh-alpha1 to -alpha12 isoforms, which are transcribed differentially by individual Purkinje cells, exhibited mosaic methylation patterns. Overall, our results demonstrated that mosaic or mixed DNA methylation states in the promoter and 5'-region of the first exon may help regulate differential Pcdh-alpha transcription and that hypermethylation is sufficient to repress transcription.

Developmental pluripotency of the nuclei of neurons in the cerebral cortex of juvenile mice.

Nuclei isolated from green fluorescent protein-marked neurons in the cerebral cortex of juvenile mice (14-21 d after birth) were injected into enucleated oocytes that were allowed to develop into blastocysts. Embryonic stem (ES) cell lines were established from the inner cell mass of 76 cloned blastocysts after injecting 2026 neuronal nuclei. Some ES cells were injected individually into enucleated oocytes (nuclear transfer). Other ES cells were transferred into the blastocoeles of tetraploid blastocysts (tetraploid complementation). Two-cell embryos after nuclear transfer were transferred to the oviducts of surrogate mothers. Four (1.5%) of 272 nuclear-transferred two-cell embryos developed to term, and two (0.7%) developed into fertile adults. Nineteen (1.9%) of 992 tetraploid blastocysts receiving ES cells reached term, and 10 (1.0%) developed into adults. These findings demonstrate that some of the nuclei of differentiated neurons in the cerebral cortex of juvenile mice maintain developmental pluripotency.