Project description:This dataset consists of 26 raw MS files and associated peak lists and result files, acquired on a TripleTOF 6600 mass spectrometer operated in Data Dependent Acquisition mode. Samples were generated by Rasim Barutcu and Mingkun Wu (some clones also generated by Boris Dyakov). Streptavidin affinity purification and mass spectrometric acquisition was performed by Zhen-Yuan Lin. Mass Spectrometry data analysis was performed by Boris Dyakov. The files are associated with a manuscript submitted for publication by Barutcu et al. that identifies functionally distinct proteins and retained intron RNAs associated with nuclear domains (speckles and lamina) using APEX2-mediated proximity labeling. ("Systematic mapping of nuclear domain associated transcripts reveals speckles and lamina as hubs of functionally distinct populations of retained introns") Benjamin Blencowe is the corresponding author of the manuscript (b.blencowe@utoronto.ca). Anne-Claude Gingras should be contacted for questions about this dataset (gingras@lunenfeld.ca).

Project description:Systematic mapping of nuclear domain-associated transcripts reveals speckles and lamina as hubs of functionally distinct retained introns

Project description:APEX2 based identification of RNA and DNA at the nuclear lamina

Project description:Nuclear speckles are membraneless organelles that associate with active transcription sites and participate in post-transcriptional mRNA processing. During mitosis, nuclear speckles dissolve following phosphorylation of their protein components. Here, we identify PP1 phosphatases as responsible for counteracting kinase-mediated dissolution. Their overexpression increases speckle cohesion and leads to retention of polyadenylated RNA within speckles and the nucleus. By performing APEX2 proximity labeling combined with RNA-sequencing, we characterized the association of specific RNAs with nuclear speckles depending on their cohesion state. We find that many transcripts are preferentially enriched within nuclear speckles compared to the nucleoplasm, particularly chromatin- and nucleus-associated transcripts. While total polyadenylated RNA retention increased with greater nuclear speckle cohesion, the ratios of most mRNA species to each other were constant, indicating non-selective, or proportional, retention. We then explored whether nuclear speckle cohesion changes in response to environmental perturbations associated with changes in kinase or phosphatase activity. We found that cellular responses to heat shock, oxidative stress, and hypoxia include changes to the cohesion of nuclear speckles and mRNA retention. Our results demonstrate that tuning the material properties of nuclear speckles provides a mechanism for the acute control of mRNA localization.

Project description:Nuclear speckles are membraneless organelles that associate with active transcription sites and participate in post-transcriptional mRNA processing. During mitosis, nuclear speckles dissolve following phosphorylation of their protein components. Here, we identify PP1 phosphatases as responsible for counteracting kinase-mediated dissolution. Their overexpression increases speckle cohesion and leads to retention of polyadenylated RNA within speckles and the nucleus. By performing APEX2 proximity labeling combined with RNA-sequencing, we characterized the association of specific RNAs with nuclear speckles depending on their cohesion state. We find that many transcripts are preferentially enriched within nuclear speckles compared to the nucleoplasm, particularly chromatin- and nucleus-associated transcripts. While total polyadenylated RNA retention increased with greater nuclear speckle cohesion, the ratios of most mRNA species to each other were constant, indicating non-selective, or proportional, retention. We then explored whether nuclear speckle cohesion changes in response to environmental perturbations associated with changes in kinase or phosphatase activity. We found that cellular responses to heat shock, oxidative stress, and hypoxia include changes to the cohesion of nuclear speckles and mRNA retention. Our results demonstrate that tuning the material properties of nuclear speckles provides a mechanism for the acute control of mRNA localization.

Project description:Nuclear compartments are thought to play a role in three-dimensional genome organization and gene expression. In mammalian brain, the architecture and dynamics of nuclear compartment-associated genome organization is not known. In this study, we developed Genome Organization using CUT and RUN Technology (GO-CaRT) to map genomic interactions with two nuclear compartments—the nuclear lamina and nuclear speckles—from different regions of the developing mouse, macaque and human brain. Lamina-associated domain (LAD) architecture in cells in vivo is distinct from that of cultured cells, including major differences in LADs previously considered to be cell type invariant. In the mouse and human forebrain, dorsal and ventral neural precursor cells have differences in LAD architecture that correspond to their regional identity. LADs in the human and mouse cortex contain transcriptionally highly active sub-domains characterized by broad depletion of histone-3-lysine-9 dimethylation. Evolutionarily conserved LADs in human, macaque and mouse brain are enriched for transcriptionally active neural genes associated with synapse function. By integrating GO-CaRT maps with genome-wide association study data, we found speckle-associated domains to be enriched for schizophrenia risk loci, indicating a physical relationship between these disease-associated genetic variants and a specific nuclear structure. Our work provides a framework for understanding the relationship between distinct nuclear compartments and genome function in brain development and disease.

Project description:CTCF supports preferentially short lamina-associated domains

Project description:Gene regulatory loops at lamina-associated domains

Project description:Current models posit that nuclear speckles (NSs) serve as reservoirs of splicing factors and facilitate post-transcriptional processing of mRNA. Here, we discovered that ribotoxic stress leads to a profound reorganization of NSs with enhanced recruitment of factors required for 5' and 3' splice site recognition including the RNA-binding protein TIAR, U1 snRNP proteins and U2-associated factor 65, as well as serine 2 phosphorylated RNA polymerase II. NS reorganization is dependent on the stress-activated p38 mitogen activated protein kinase (MAPK), and goes along with splicing activation of both pre-existing and nascent pre-mRNAs. In particular, ribotoxic stress causes targeted excision of retained introns from pre-mRNAs of immediate early genes (IEGs), whose transcription is induced during the stress response. Importantly, enhanced splicing of the IEGs ZFP36 and FOS is accompanied by re-localization of the corresponding mRNAs to NSs. Our study reveals NSs as a dynamic compartment that is remodeled under stress conditions to promote the excision of retained introns and thereby enhance the expression and processing of IEG mRNAs.

Project description:Current models posit that nuclear speckles (NSs) serve as reservoirs of splicing factors and facilitate post-transcriptional processing of mRNA. Here, we discovered that ribotoxic stress leads to a profound reorganization of NSs with enhanced recruitment of factors required for 5' and 3' splice site recognition including the RNA-binding protein TIAR, U1 snRNP proteins and U2-associated factor 65, as well as serine 2 phosphorylated RNA polymerase II. NS reorganization is dependent on the stress-activated p38 mitogen activated protein kinase (MAPK), and goes along with splicing activation of both pre-existing and nascent pre-mRNAs. In particular, ribotoxic stress causes targeted excision of retained introns from pre-mRNAs of immediate early genes (IEGs), whose transcription is induced during the stress response. Importantly, enhanced splicing of the IEGs ZFP36 and FOS is accompanied by re-localization of the corresponding mRNAs to NSs. Our study reveals NSs as a dynamic compartment that is remodeled under stress conditions to promote the excision of retained introns and thereby enhance the expression and processing of IEG mRNAs.