The nuclear lamina (NL) interacts with hundreds of large genomic regions termed lamina associated domains (LADs). The dynamics of these interactions and the relation to epigenetic modifications are poorly understood. We visualized the fate of LADs in single cells using a "molecular contact memory" approach. In each nucleus, only ~30% of LADs are positioned at the periphery; these LADs are in intermittent molecular contact with the NL but remain constrained to the periphery. Upon mitosis, LAD positioning is not detectably inherited but instead is stochastically reshuffled. Contact of individual LADs with the NL is linked to transcriptional repression and H3K9 dimethylation in single cells. Furthermore, we identify the H3K9 methyltransferase G9a as a regulator of NL contacts. Collectively, these results highlight principles of the dynamic spatial architecture of chromosomes in relation to gene regulation.
CCCTC-binding factor (CTCF) is critical to three-dimensional genome organization. Upon differentiation, CTCF insulates active and repressed genes within Hox gene clusters. We conducted a genome-wide CRISPR knockout (KO) screen to identify genes required for CTCF-boundary activity at the HoxA cluster, complemented by biochemical approaches. Among the candidates, we identified Myc-associated zinc-finger protein (MAZ) as a cofactor in CTCF insulation. MAZ colocalizes with CTCF at chromatin borders and, similar to CTCF, interacts with the cohesin subunit RAD21. MAZ KO disrupts gene expression and local contacts within topologically associating domains. Similar to CTCF motif deletions, MAZ motif deletions lead to derepression of posterior Hox genes immediately after CTCF boundaries upon differentiation, giving rise to homeotic transformations in mouse. Thus, MAZ is a factor contributing to appropriate insulation, gene expression and genomic architecture during development.
CCCTC-binding factor (CTCF) and MAZ are recognized insulators required for shielding repressed posterior genes from active anterior genes within the Hox clusters during motor neuron (MN) differentiation. CTCF and MAZ interact independently with cohesin and regulate three-dimensional genome organization. Here, we followed cohesin re-location upon CTCF and MAZ depletion in mouse embryonic stem cells (mESCs) to identify novel insulators. Cohesin relocated to DNA motifs for various transcription factors, including PATZ1 and other zinc finger proteins (ZNFs). Moreover, PATZ1 and ZNFs co-localized with CTCF, MAZ, and cohesin with apparent overlapping specificity as dictated by the site to be insulated. Similar to CTCF and MAZ, PATZ1 interacted with RAD21. Patz1 KO mESCs exhibited altered global gene expression. While the absence of MAZ impacts anterior CTCF-boundaries as shown previously1, Patz1 KO led to de-repression of posterior Hox genes, resulting in cervicothoracic transformation of motor neuron (MN) fate during differentiation. These findings point to a varied, combinatorial binding of known and newly defined accessory factors as being critical for positional identity and cellular fate determination during differentiation.
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