Project description:Nucleoskeleton is generally considered to be the grid structure involved in regulation of genome expression and maintenance in the eukaryotic nucleus. However, its actual biological functions and mechanisms remain controversial. Here, we show the nuclear mitotic apparatus protein (NuMA), an essential regulator of the spindle, serve as one of the components of nucleoskeleton to regulates genome high-order architecture. In the interphase, fast depletion of NuMA leads to changes in chromatin organization, including increased accessibility of the genome, remodeling of nucleosome fibers and changes of transcription levels in certain heterochromatin regions. These effects are probably due to NuMA and linker histone H1’s interplay. We prove that NuMA interacts with linker histone H1 and linker DNA through its C-terminal domain. Such interaction facilitates H1’s binding to DNA and promotes nucleosome stacking, and might be part of the reason that NuMA maintains the local condensed state of heterochromatin. Collectively, our results reveal new biological functions of NuMA in the interphase, and also associates nucleoskeleton with genome organization at the mono-nucleosome level for the first time. This in-depth study on the mechanism of NuMA’s regulation on H1 and nucleosomes shed new light on how nucleoskeleton regulates genome architecture and gene expression.

Project description:Nucleoskeleton is generally considered to be the grid structure involved in regulation of genome expression and maintenance in the eukaryotic nucleus. However, its actual biological functions and mechanisms remain controversial. Here, we show the nuclear mitotic apparatus protein (NuMA), an essential regulator of the spindle, serve as one of the components of nucleoskeleton to regulates genome high-order architecture. In the interphase, fast depletion of NuMA leads to changes in chromatin organization, including increased accessibility of the genome, remodeling of nucleosome fibers and changes of transcription levels in certain heterochromatin regions. These effects are probably due to NuMA and linker histone H1’s interplay. We prove that NuMA interacts with linker histone H1 and linker DNA through its C-terminal domain. Such interaction facilitates H1’s binding to DNA and promotes nucleosome stacking, and might be part of the reason that NuMA maintains the local condensed state of heterochromatin. Collectively, our results reveal new biological functions of NuMA in the interphase, and also associates nucleoskeleton with genome organization at the mono-nucleosome level for the first time. This in-depth study on the mechanism of NuMA’s regulation on H1 and nucleosomes shed new light on how nucleoskeleton regulates genome architecture and gene expression.

Project description:Nucleoskeleton is generally considered to be the grid structure involved in regulation of genome expression and maintenance in the eukaryotic nucleus. However, its actual biological functions and mechanisms remain controversial. Here, we show the nuclear mitotic apparatus protein (NuMA), an essential regulator of the spindle, serve as one of the components of nucleoskeleton to regulates genome high-order architecture. In the interphase, fast depletion of NuMA leads to changes in chromatin organization, including increased accessibility of the genome, remodeling of nucleosome fibers and changes of transcription levels in certain heterochromatin regions. These effects are probably due to NuMA and linker histone H1’s interplay. We prove that NuMA interacts with linker histone H1 and linker DNA through its C-terminal domain. Such interaction facilitates H1’s binding to DNA and promotes nucleosome stacking, and might be part of the reason that NuMA maintains the local condensed state of heterochromatin. Collectively, our results reveal new biological functions of NuMA in the interphase, and also associates nucleoskeleton with genome organization at the mono-nucleosome level for the first time. This in-depth study on the mechanism of NuMA’s regulation on H1 and nucleosomes shed new light on how nucleoskeleton regulates genome architecture and gene expression.

Project description:The nucleoskeleton protein NuMA maintains local chromatin architecture partially through promoting linker histone H1’ binding to chromatin and nucleosome stacking

Project description:The nucleoskeleton protein NuMA maintains local chromatin architecture partially through promoting linker histone H1’ binding to chromatin and nucleosome stacking [RNA-Seq]

Project description:The nucleoskeleton protein NuMA maintains local chromatin architecture partially through promoting linker histone H1’ binding to chromatin and nucleosome stacking [Hi-C]

Project description:The nucleoskeleton protein NuMA maintains local chromatin architecture partially through promoting linker histone H1’ binding to chromatin and nucleosome stacking [Cut & Tag]

Project description:The nucleoskeleton protein NuMA maintains local chromatin architecture partially through promoting linker histone H1’ binding to chromatin and nucleosome stacking [ATAC-Seq]

Project description:Linker histones are involved in the formation of higher-order chromatin structure. Although linker histones have been implicated in the regulation of specific genes, it still remains unclear what their principal binding determinants are and how their repressive function in vitro can be reconciled with presumed broad binding in vivo. We generated a full genome, high resolution binding map of linker histone H1 in Drosophila Kc cells, using DamID. H1 binds at similar levels across much of the genome, both in classical euchromatin and heterochromatin. Strikingly, there are pronounced dips of low H1 occupancy around transcription start sites of active genes and at many distant cis-regulatory sites. H1 dips are not due to lack of nucleosomes. Rather, all regions with low binding of H1 show enrichment of the histone variant H3.3 which itself has been linked to high nucleosome turnover. Upon knockdown of H3.3, we find that H1 levels increase at sites previously not covered with H1 with a concomitant increase in nucleosome repeat length. These changes are independent of transcriptional changes. Our results show that the H3.3 protein counteracts association of H1 at genomic sites with high rates of histone turnover. This antagonism provides a mechanism to keep diverse genomic sites in an open chromatin conformation. For this study, we generated DamID profiles of histone H1 and RpII18 and a FAIRE profile in Drosophila Kc167 cells. Additionally, we generated H1 profiles in cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Nucleosome positioning profiles were generated in untreated cells and cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Profiles of expression changes were generated for H3.3B RNAi and H3.3A and H3.3B RNAi.

Project description:Linker histones are involved in the formation of higher-order chromatin structure. Although linker histones have been implicated in the regulation of specific genes, it still remains unclear what their principal binding determinants are and how their repressive function in vitro can be reconciled with presumed broad binding in vivo. We generated a full genome, high resolution binding map of linker histone H1 in Drosophila Kc cells, using DamID. H1 binds at similar levels across much of the genome, both in classical euchromatin and heterochromatin. Strikingly, there are pronounced dips of low H1 occupancy around transcription start sites of active genes and at many distant cis-regulatory sites. H1 dips are not due to lack of nucleosomes. Rather, all regions with low binding of H1 show enrichment of the histone variant H3.3 which itself has been linked to high nucleosome turnover. Upon knockdown of H3.3, we find that H1 levels increase at sites previously not covered with H1 with a concomitant increase in nucleosome repeat length. These changes are independent of transcriptional changes. Our results show that the H3.3 protein counteracts association of H1 at genomic sites with high rates of histone turnover. This antagonism provides a mechanism to keep diverse genomic sites in an open chromatin conformation. For this study, we generated DamID profiles of histone H1 and RpII18 in Drosophila Kc167 cells. Additionally, we generated H1 profiles in cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Nucleosome positioning profiles were generated in untreated cells and cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Profiles of expression changes were generated for H3.3B RNAi and H3.3A and H3.3B RNAi.