Project description:The ERK family of MAP kinase plays a critical role in growth factor-stimulated cell cycle progression from G0/G1 to S phase. But, how sustained activation of ERK promotes G1 progression has remained unclear. Here, our systematic analysis on the temporal program of ERK-dependent gene expression shows that sustained activation of ERK is required for induction and maintenance of the decreased expression levels of a set of genes. Moreover, our cell biological analysis reveals that these ERK-dependent downregulated genes have the ability to block S phase entry. Cessation of ERK activation at mid or late G1 leads to a rapid increase of these anti-proliferative genes and results in the inhibition of S phase entry. These findings uncover an important mechanism by which the duration of ERK activation regulates cell cycle progression through dynamic changes in gene expression, and identify novel ERK target genes crucial for the regulation of cell cycle progression.

Project description:The retinoblastoma tumour suppressor, Rb, has two major functions. First, it represses genes whose products are required for S-phase entry and progression, thus stabilizing cells in G1. Second, Rb synergizes with factors that induce cell cycle exit and terminal differentiation. Dictyostelium lacks a G1 phase in its cell cycle but it has a retinoblastoma orthologue, rblA. Using mRNA-Seq transcriptional profiling, we show that rblA strongly represses hundreds of genes whose products are involved in S-phase and mitosis. Both S-phase and mitotic genes are expressed at a single point in late G2 and again in mid-development, near the time when cell cycling is reactivated. RblA also activates a set of genes unique to slime moulds that function in terminal differentiation. Like its mammalian counterpart, Dictyostelium RblA plays a dual role, regulating cell cycle progression and transcriptional events leading to terminal differentiation. In the absence of a G1 phase, however, RblA functions in late G2 controlling the expression of both S-phase and mitotic genes.

Project description:Macrophages play critical roles across health and disease. Low oxygen conditions (hypoxia) have been associated primarily with cell cycle arrest in dividing cells. Macrophages are typically quiescent in G0, though yolk sac and bone marrow derived macrophages frequently proliferate and monocyte-derived tissue macrophages are able to proliferate in response to tissue signals. Here we show that hypoxia (1% oxygen tension) results in reversible entry into the cell cycle in human monocyte derived macrophages (MDM) and mouse peritoneal macrophages. Cell cycle progression is largely limited to G1/S phase with little progression to G2/M. Mechanistically, this cell cycle transitioning is triggered by a HIF2A-directed transcriptional program. The response is accompanied by increased expression of cell cycle-associated proteins, including CDK1, and reversible activation of the canonical mitogen-activated MEK-ERK proliferation pathway. CDK1 associated SAMHD1 phosphorylation at T592 in hypoxic macrophages renders them hyper-susceptible to lentiviral transduction. Furthermore, PHD inhibitors, which activate HIFs, are able to recapitulate HIF2A-dependent cell cycle entry in macrophages, as well as susceptibility to lentiviral transduction. Finally, we demonstrate that tumour associated macrophages (TAM) in lung cancers exhibit transcriptomic profiles representing responses to low oxygen and cell cycle progression at single cell level. This work uncovers HIF2A driven macrophage cell cycle progression in low oxygen conditions that culminates in SAMHD1 phosphorylation and high susceptibility to lentiviral transduction. These findings have additional implications for inflammation and tumour progression/metastasis where low oxygen environments are common.

Project description:The retinoblastoma tumour suppressor, Rb, has two major functions. First, it represses genes whose products are required for S-phase entry and progression, thus stabilizing cells in G1. Second, Rb synergizes with factors that induce cell cycle exit and terminal differentiation. Dictyostelium lacks a G1 phase in its cell cycle but it has a retinoblastoma orthologue, rblA. Using mRNA-Seq transcriptional profiling, we show that rblA strongly represses hundreds of genes whose products are involved in S-phase and mitosis. Both S-phase and mitotic genes are expressed at a single point in late G2 and again in mid-development, near the time when cell cycling is reactivated. RblA also activates a set of genes unique to slime moulds that function in terminal differentiation. Like its mammalian counterpart, Dictyostelium RblA plays a dual role, regulating cell cycle progression and transcriptional events leading to terminal differentiation. In the absence of a G1 phase, however, RblA functions in late G2 controlling the expression of both S-phase and mitotic genes. RNA was isolated from an rblA-disruptant and the parental strain when the cells were vegetatively growing or while the cells were developing (at the early culminant stage). Total RNA was also isolated from wild type cells synchronized using the cold-shock protocol (Maeda, J Gen Microbiol 132:1189-1196 (1986)). T0 to T13 represent the hours after the shift up from 9.5C to 22C, a regime that synchronizes the cells in the cell cycle.

Project description:Expression and differential expression analysis of long non-coding RNAs and protein-coding genes. HFF cells were synchronised by serum starvation and reside in G0 phase or G1 phase of mitotic cell cycle.

Project description:Expression and differential expression analysis of custom probes for genomic regions that have been found to be differentially expressed (i) throughout cell cycle progression, (ii) in response to the anti-proliferative and pro-apoptotic p53 pathway, and (iii) the anti-apoptotic and pro-proliferative STAT-3 pathway. In addition, the Agilent custom array (244K) interrogates probes for genomic regions predicted to contain a conserved secondary structure identified by RNAz (Washietl et al. "Fast and reliable prediction of noncoding RNAs." Proc Natl Acad Sci USA. 102:2454-9, 2005.) or Evofold (Pedersen et al. "Identification and classification of conserved RNA secondary structures in the human genome." PLoS Comput Biol. 2:e33, 2006.), as well as known non-coding RNAs from public databases, and the Agilent mRNA probe sets 014850. HFF cells were synchronised by serum starvation and reside in G0 phase or G1 phase of mitotic cell cycle. We analyzed three arrays each for HFF cells in G0 phase and cells in G1 phase

Project description:Expression and differential expression analysis of long non-coding RNAs and protein-coding genes. HFF cells were synchronised by serum starvation and reside in G0 phase or G1 phase of mitotic cell cycle. We analyzed three arrays each for HFF cells in G0 phase and cells in G1 phase

Project description:E2F transcription factors are known to be important for timely activation of G1/S and G2/M genes required for cell cycle progression, but transcriptional mechanisms for deactivation of cell cycle regulated genes are unknown. Here, we show that E2F7 is highly expressed during mid to late S-phase, occupies promoters of G1/S regulated genes and represses its transcription. ChIP-seq analysis revealed that E2F7 binds preferentially to genomic sites containing the TTCCCGCC motif, which closely resemble the E2F consensus site. We identified 89 target genes that carry E2F7 binding sites close to the transcriptional start site and that are directly repressed by short term induction of E2F7. Most of these target genes are known to be activated by E2Fs and are involved in DNA replication, metabolism and DNA repair. Importantly, induction of E2F7 during G0-G1/S resulted in S-phase arrest and DNA damage, whereas expression of E2F7 during G2/M failed to disturb cell cycle progression. These findings provide strong evidence that E2F7 controls directly the downswing of oscillating G1/S genes during S-phase progression.

Project description:E2F transcription factors are known to be important for timely activation of G1/S and G2/M genes required for cell cycle progression, but transcriptional mechanisms for deactivation of cell cycle-regulated genes are unknown. Here, we show that E2F7 is highly expressed during mid to late S-phase, occupies promoters of G1/S-regulated genes and represses their transcription. ChIP-seq analysis revealed that E2F7 binds preferentially to genomic sites containing the TTCCCGCC motif, which closely resemble the E2F consensus site. We identified 89 target genes that carry E2F7 binding sites close to the transcriptional start site and that are directly repressed by short term induction of E2F7. Most of these target genes are known to be activated by E2Fs and are involved in DNA replication, metabolism and DNA repair. Importantly, induction of E2F7 during G0-G1/S resulted in S-phase arrest and DNA damage, whereas expression of E2F7 during G2/M failed to disturb cell cycle progression. These findings provide strong evidence that E2F7 directly controls the downswing of oscillating G1/S genes during S-phase progression.

Project description:NIH3T3 in the middle of G0 to G1 transion consists of the cells which is still staying G0 phase and the cells which enters G1. Monitoring the expressions of p27 and Cdt1 enables to distinguish these two; p27+/Cdt1+ cells as the cells in G0 phase and p27-Cdt1+ cells as G1 phase We sorted p27+Cdt1+ (G0) NIH3T3 cells and p27-Cdt1+ (G1) NIH3T3 cells in the middle of G0-G1 transition, 5 hours after serum addition following the serum addition using mVenus-p27K- and mCherry-hCdt1(30/120) . We compared the expression profiles of these NIH3T3 cells in G0 and G1 phases and identified the genes upregulated in G0 or G1 phases.