GTPase-activating protein SH2-SH3 domains induce gene expression in a Ras-dependent fashion.

The p21ras GTPase-activating protein (GAP) is thought to function as both a negative regulator and a downstream target of p21ras. Here, we have investigated the role of GAP by using a transient expression assay with a fos luciferase reporter plasmid. We used GAP deletion mutants that lack the domain involved in interaction with p21ras and encode essentially only the SH2-SH3 domains. When these GAP deletion mutants were expressed, we observed a marked induction of fos promoter activity similar to induction by activated p21ras. Expression of a full-length GAP construct had no effect on the activity of the fos promoter. Activation of the fos promoter by these GAP SH2-SH3 regions was inhibited by cotransfection of a dominant inhibitory mutant of p21ras, Ras(Asn-17). Thus, the induction of gene expression by GAP SH2-SH3 domains is dependent on p21ras activity. Moreover, induction of fos promoter activity by GAP SH2-SH3 domains is increased severalfold after cotransfection of an activated mutant of p21ras, Ras(Leu-61), or insulin stimulation of A14 cells, both leading to an increase in the levels of GTP-bound p21ras. The combined effect of Ras(Leu-61) and the GAP deletion mutants was not inhibited by Ras(Asn-17), indicating that GAP SH2-SH3 domains do not function to activate endogenous p21ras but cooperate with another signal coming from active p21ras. These data suggest that GAP SH2-SH3 domains serve to induce gene expression by p21ras but that additional signals coming from p21ras are required for them to function.     

Two dominant inhibitory mutants of p21ras interfere with insulin-induced gene expression.

Insulin induces a rapid activation of p21ras in NIH 3T3 and Chinese hamster ovary cells that overexpress the insulin receptor. Previously, we suggested that p21ras may mediate insulin-induced gene expression. To test such a function of p21ras more directly, we studied the effect of different dominant inhibitory mutants of p21ras on the induction of gene expression in response to insulin. We transfected a collagenase promoter-chloramphenicol acetyltransferase (CAT) gene or a fos promoter-luciferase gene into NIH 3T3 cells that overexpressed the insulin receptor. The activities of both promoters were strongly induced after treatment with insulin. This induction could be suppressed by cotransfection of two inhibitory mutant ras genes, H-ras(Asn-17) or H-ras(Leu-61,Ser-186). In particular, insulin-induced activation of the fos promoter was inhibited completely by H-ras(Asn-17). These results show that p21ras functions as an intermediate in the insulin signal transduction route leading to the induction of gene expression.     

Tousled‐like kinase 2 regulates recovery from a DNA damage‐induced G2 arrest

In order to maintain a stable genome, cells need to detect and repair DNA damage before they complete the division cycle. To this end, cell cycle checkpoints prevent entry into the next cell cycle phase until the damage is fully repaired. Proper reentry into the cell cycle, known as checkpoint recovery, requires that a cell retains its original cell cycle state during the arrest. Here, we have identified Tousled‐like kinase 2 (Tlk2) as an important regulator of recovery after DNA damage in G2. We show that Tlk2 regulates the Asf1A histone chaperone in response to DNA damage and that depletion of Asf1A also produces a recovery defect. Both Tlk2 and Asf1A are required to restore histone H3 incorporation into damaged chromatin. Failure to do so affects expression of pro‐mitotic genes and compromises the cellular competence to recover from damage‐induced cell cycle arrests. Our results demonstrate that Tlk2 promotes Asf1A function during the DNA damage response in G2 to allow for proper restoration of chromatin structure at the break site and subsequent recovery from the arrest.     

Cutting edge: cellular Fas-associated death domain-like IL-1-converting enzyme-inhibitory protein protects germinal center B cells from apoptosis during germinal center reactions

During germinal center (GC) reactions, follicular dendritic cells are believed to select memory B lymphocytes by switching off apoptosis in the successfully binding B cells. The cellular signals involved in this process are largely unknown. Here, we show that GC B lymphocytes have a long isoform of the cellular homologue of the viral Fas-associated death domain-like IL-1-converting enzyme-like inhibitory protein (cFLIP(L)), which is capable of inhibiting death receptor-induced caspase activation. In isolated GC B cells, cFLIP(L) decays rapidly even without Fas ligation, and this results in activation of caspase activity and apoptosis. Contact with follicular dendritic cells prevents cFLIP(L) degradation and blocks all signs of apoptosis, even in the presence of anti-Fas ABS: cFLIP(L) expression is sustained by CD40 ligation as well, suggesting that at least at some stage of the GC reaction activated T cells may help selected B cells to leave the follicular dendritic cell network without becoming apoptotic.     

Polo-like kinase-1 controls recovery from a G2 DNA damage-induced arrest in mammalian cells

DNA damage triggers multiple checkpoint pathways to arrest cell cycle progression. Less is known about the mechanisms that allow resumption of the cell cycle once checkpoint signaling is silenced. Here we show that while in undamaged cells several redundant pathways can promote the onset of mitosis, this redundancy is lost in cells recovering from a DNA damage-induced arrest. We demonstrate that Plk1 is crucial for mitotic entry following recovery from DNA damage. However, Plk1 is no longer required in cells depleted of Wee1, and we could show that Plk1 is involved in the degradation of Wee1 at the onset of mitosis. Thus, our data show that the cell cycle machinery is reset in response to DNA damage and that cells become critically dependent on Plk1-mediated degradation of Wee1 for their recovery.     

The survivin/Aurora B complex: its role in coordinating tension and attachment

Proper chromosome segregation relies on the action of the spindle checkpoint. Recent data have shown that the chromosomal passenger proteins survivin and Aurora B play an important auxiliary role in spindle checkpoint surveillance. Knock-down experiments in human cells indicate that the function of the survivin/Aurora B complex is required to correct improper microtubule-kinetochore interactions. Combined data of four different groups show that the survivin/Aurora B complex is not an integral component of the spindle checkpoint, but it enables the cell to communicate lack of tension back to the attached microtubules. Moreover, they show that the affinity of BubR1 for kinetochores is directly influenced by the absence or presence of the survivin/Aurora B complex. These functions of the survivin/Aurora B complex are essential for chromosome biorientation, a prerequisite for proper chromosome segregation. As such, this complex plays an important role in the maintenance of a stable genome.     

Interactions among oscillatory pathways in NF-kappa B signaling

Background  

Sustained stimulation with tumour necrosis factor alpha (TNF-alpha) induces substantial oscillations—observed at both the single cell and population levels—in the nuclear factor kappa B (NF-kappa B) system. Although the mechanism has not yet been elucidated fully, a core system has been identified consisting of a negative feedback loop involving NF-kappa B (RelA:p50 hetero-dimer) and its inhibitor I-kappa B-alpha. Many authors have suggested that this core oscillator should couple to other oscillatory pathways.