Project description:The goal of this experiment was to identify Staufen1-bound mRNAs in prometaphase cells. Stau1 abundance fluctuates through the cell cycle: it is high in the G2 phase of the cell cycle and rapidly decreases as cells transit through mitosis. The importance of controlling Stau1 levels was underscored by the observation that its overexpression impairs mitosis as well as proliferation of transformed cell lines. As a major post-transcriptional regulator, Stau1 may exert its role(s) through the spatial and/or temporal regulation of its bound mRNAs. Therefore, to gather clues to support this possibility, we identified Stau1-bound mRNAs in prometaphase as a means to identify mRNAs that could be subjected to post-transcriptional modulation when Stau1 is partly degraded in mitosis.

Project description:The goal of this experiment was to identify Staufen1-bound mRNAs in prometaphase cells. Stau1 abundance fluctuates through the cell cycle: it is high in the G2 phase of the cell cycle and rapidly decreases as cells transit through mitosis. The importance of controlling Stau1 levels was underscored by the observation that its overexpression impairs mitosis as well as proliferation of transformed cell lines. As a major post-transcriptional regulator, Stau1 may exert its role(s) through the spatial and/or temporal regulation of its bound mRNAs. Therefore, to gather clues to support this possibility, we identified Stau1-bound mRNAs in prometaphase as a means to identify mRNAs that could be subjected to post-transcriptional modulation when Stau1 is partly degraded in mitosis. HEK293T cells were transfected with plasmids coding for Stau155-FLAG or the empty vector as control. Cells were synchronized in prometaphase with nocodazole. Stau1-bound mRNAs were isolated after immunoprecipitation using anti-FLAG antibody.

Project description:Proper chromosome segregation is required to ensure genomic and chromosomal stability. The centromere is a unique chromatin domain present throughout the cell cycle on each chromosome defined by the CENP-A nucleosome. Centromeres (CEN) are responsible for recruiting the kinetochore (KT) during mitosis, ultimately regulating spindle attachment and mitotic checkpoint function. Upregulation of many genes that encode CEN/KT proteins is commonly observed in cancer. Here, we show although FOXM1 occupies the promoters of many CEN/KT genes with MYBL2, occupancy is insufficient alone to drive the FOXM1 correlated transcriptional program. We show that CENP-F, a component of the outer kinetochore, functions with FOXM1 to coregulate G2/M transcription and proper chromosome segregation. Loss of CENP-F results in alteration of chromatin accessibility at G2/M genes, including CENP-A, and leads to reduced FOXM1-MBB complex formation. The FOXM1-CENP-F transcriptional coordination is a cancer-specific function. We observed that a few CEN/KT genes escape FOXM1 regulation such as CENP-C which when upregulated with CENP-A, leads to increased chromosome misegregation and cell death. Together, we show that the FOXM1 and CENP-F coordinately regulate G2/M gene expression, and this coordination is specific to a subset of genes to allow for proliferation and maintenance of chromosome stability for cancer cell survival.

Project description:Proper chromosome segregation is required to ensure genomic and chromosomal stability. The centromere is a unique chromatin domain present throughout the cell cycle on each chromosome defined by the CENP-A nucleosome. Centromeres (CEN) are responsible for recruiting the kinetochore (KT) during mitosis, ultimately regulating spindle attachment and mitotic checkpoint function. Upregulation of many genes that encode CEN/KT proteins is commonly observed in cancer. Here, we show although FOXM1 occupies the promoters of many CEN/KT genes with MYBL2, occupancy is insufficient alone to drive the FOXM1 correlated transcriptional program. We show that CENP-F, a component of the outer kinetochore, functions with FOXM1 to coregulate G2/M transcription and proper chromosome segregation. Loss of CENP-F results in alteration of chromatin accessibility at G2/M genes, including CENP-A, and leads to reduced FOXM1-MBB complex formation. The FOXM1-CENP-F transcriptional coordination is a cancer-specific function. We observed that a few CEN/KT genes escape FOXM1 regulation such as CENP-C which when upregulated with CENP-A, leads to increased chromosome misegregation and cell death. Together, we show that the FOXM1 and CENP-F coordinately regulate G2/M gene expression, and this coordination is specific to a subset of genes to allow for proliferation and maintenance of chromosome stability for cancer cell survival.

Project description:Proper chromosome segregation is required to ensure genomic and chromosomal stability. The centromere is a unique chromatin domain present throughout the cell cycle on each chromosome defined by the CENP-A nucleosome. Centromeres (CEN) are responsible for recruiting the kinetochore (KT) during mitosis, ultimately regulating spindle attachment and mitotic checkpoint function. Upregulation of many genes that encode CEN/KT proteins is commonly observed in cancer. Here, we show although FOXM1 occupies the promoters of many CEN/KT genes with MYBL2, occupancy is insufficient alone to drive the FOXM1 correlated transcriptional program. We show that CENP-F, a component of the outer kinetochore, functions with FOXM1 to coregulate G2/M transcription and proper chromosome segregation. Loss of CENP-F results in alteration of chromatin accessibility at G2/M genes, including CENP-A, and leads to reduced FOXM1-MBB complex formation. The FOXM1-CENP-F transcriptional coordination is a cancer-specific function. We observed that a few CEN/KT genes escape FOXM1 regulation such as CENP-C which when upregulated with CENP-A, leads to increased chromosome misegregation and cell death. Together, we show that the FOXM1 and CENP-F coordinately regulate G2/M gene expression, and this coordination is specific to a subset of genes to allow for proliferation and maintenance of chromosome stability for cancer cell survival.

Project description:Proper chromosome segregation is required to ensure genomic and chromosomal stability. The centromere is a unique chromatin domain present throughout the cell cycle on each chromosome defined by the CENP-A nucleosome. Centromeres (CEN) are responsible for recruiting the kinetochore (KT) during mitosis, ultimately regulating spindle attachment and mitotic checkpoint function. Upregulation of many genes that encode CEN/KT proteins is commonly observed in cancer. Here, we show although FOXM1 occupies the promoters of many CEN/KT genes with MYBL2, occupancy is insufficient alone to drive the FOXM1 correlated transcriptional program. We show that CENP-F, a component of the outer kinetochore, functions with FOXM1 to coregulate G2/M transcription and proper chromosome segregation. Loss of CENP-F results in alteration of chromatin accessibility at G2/M genes, including CENP-A, and leads to reduced FOXM1-MBB complex formation. The FOXM1-CENP-F transcriptional coordination is a cancer-specific function. We observed that a few CEN/KT genes escape FOXM1 regulation such as CENP-C which when upregulated with CENP-A, leads to increased chromosome misegregation and cell death. Together, we show that the FOXM1 and CENP-F coordinately regulate G2/M gene expression, and this coordination is specific to a subset of genes to allow for proliferation and maintenance of chromosome stability for cancer cell survival.

Project description:The goal of this experiment was to compare the transcriptome of cells that overexpressed the RNA-binding protein Staufen1 to that of cells that expressed the empty vector as control. Stau1 abundance fluctuates through the cell cycle: it is high in the G2 phase of the cell cycle and rapidly decreases as cells transit through mitosis. The importance of controlling Stau1 levels was underscored by the observation that its overexpression impairs mitosis as well as proliferation of transformed cell lines. As a major post-transcriptional regulator, Stau1 may exert its role(s) through the spatial and/or temporal regulation of its bound mRNAs. Therefore, to gather clues to support this possibility, we determined if Stau1 overexpression significantly modified the transcriptome of transformed cells in prometaphase explaining the observed impairment in mitosis transit and/or cell proliferation. HEK293T cells were transfected with plasmids coding for Stau155-FLAG or the empty vector as control. Cells were synchronized in prometaphase with nocodazole.

Project description:Gene expression must be reconfigured rapidly during the subsequent phases of the cell cycle to execute the cellular functions specific of each phase. Post-transcriptional regulation has a predominant role in modulating gene expression during the mitotic cell cycle, including among other mechanisms, protein phosphorylation and ubiquitination, differential protein stability and mRNA localization and translatability. Regulation at the transcriptional level is also important, as studies conducted in synchronized plant cell suspension cultures have identified hundreds of genes with periodic patterns of genes expression across the phases of the cell cycle. We describe here an alternative strategy to cell suspension cultures to profile the transcriptome of Arabidopsis root cells in the G2/M phase of the cell cycle. Through fluorescence activated cell sorting we first isolated cells in G2/M using CYCB1;1-GFP, a reporter of a mitotic cyclin. The analysis of the transcriptome of these cells allowed us to identify hundreds of genes whose expression is depleted or enriched in G2/M cells.

Project description:Stringent post-transcriptional regulation of mRNA fate is critical for proper cell division. To detect proteins involved in such regulation, we analyzed the composition of intact polysomal complexes from mitotic and interphase cells by quantitative mass-spectrometry. Using this approach, we detected increased association of several mRNA-binding proteins, including heterogeneous nuclear ribonucleoprotein C (hnRNP C), with mitotic polysomes. Immunofluorescence analysis, puromycin-sensitivity assays and nascent-chain pulldowns confirmed that hnRNP C interacts with polysome-bound mRNA during mitosis. Using a combination of pulsed SILAC and metabolic labeling, we found that knockdown of hnRNP C has a pervasive effect on both global and transcript-specific translation rates. Furthermore, ribosome profiling revealed that hnRNP C is involved in translation of mRNAs encoding components of the translation machinery and other mRNAs harboring a 5' terminal oligopyrimidine tract (5’ TOP). Taken together, these results suggest that hnRNP C is crucial for ribogenesis during mitosis; in its absence, production of ribosomal proteins and translation factors is impaired and translation rates are reduced during subsequent phases of the cell cycle.

Project description:The goal of this experiment was to compare the transcriptome of cells that overexpressed the RNA-binding protein Staufen1 to that of cells that expressed the empty vector as control. Stau1 abundance fluctuates through the cell cycle: it is high in the G2 phase of the cell cycle and rapidly decreases as cells transit through mitosis. The importance of controlling Stau1 levels was underscored by the observation that its overexpression impairs mitosis as well as proliferation of transformed cell lines. As a major post-transcriptional regulator, Stau1 may exert its role(s) through the spatial and/or temporal regulation of its bound mRNAs. Therefore, to gather clues to support this possibility, we determined if Stau1 overexpression significantly modified the transcriptome of transformed cells in prometaphase explaining the observed impairment in mitosis transit and/or cell proliferation.