MDM2 can bind to p53 and promote its ubiquitination and subsequent degradation by the proteasome. Current models propose that nuclear export of p53 is required for MDM2-mediated degradation, although the function of MDM2 in p53 nuclear export has not been clarified. Here we show that MDM2 can promote the nuclear export of p53 in transiently transfected cells. This activity requires the nuclear-export signal (NES) of p53, but not the NES of MDM2. A mutation within the MDM2 RING-finger domain that inhibits p53 ubiquitination also inhibits the ability of MDM2 to promote p53 nuclear export. Finally, inhibition of nuclear export stabilizes wild-type p53 and leads to accumulation of ubiquitinated p53 in the nucleus. Our results indicate that MDM2-mediated ubiquitination, or other activities associated with the RING-finger domain, can stimulate the export of p53 to the cytoplasm through the activity of the p53 NES.
Cullins (CULs) are subunits of a prominent class of RING ubiquitin ligases. Whereas the subunits and substrates of CUL1-associated SCF complexes and CUL2 ubiquitin ligases are well established, they are largely unknown for other cullin family members. We show here that S. pombe CUL3 (Pcu3p) forms a complex with the RING protein Pip1p and all three BTB/POZ domain proteins encoded in the fission yeast genome. The integrity of the BTB/POZ domain, which shows similarity to the cullin binding proteins SKP1 and elongin C, is required for this interaction. Whereas Btb1p and Btb2p are stable proteins, Btb3p is ubiquitylated and degraded in a Pcu3p-dependent manner. Btb3p degradation requires its binding to a conserved N-terminal region of Pcu3p that precisely maps to the equivalent SKP1/F box adaptor binding domain of CUL1. We propose that the BTB/POZ domain defines a recognition motif for the assembly of substrate-specific RING/cullin 3/BTB ubiquitin ligase complexes.
The COP9 signalosome (CSN) is known to bind cullin-RING ubiquitin ligases (CRLs) and to promote their activity in vivo. The mechanism of this stimulation has remained enigmatic because CSN's intrinsic and associated enzymatic activities paradoxically inhibit CRL activity in vitro. Reconciling this paradox, we show here that Csn5-catalysed cullin (Cul) deneddylation and Ubp12-mediated deubiquitination cooperate in maintaining the stability of labile substrate adapters, thus facilitating CRL function. Various fission-yeast csn and ubp12 deletion mutants have lower levels of the Cul3p adapter Btb3p. This decrease is due to increased autocatalytic, Cul3p-dependent, ubiquitination and the subsequent degradation of Btb3p. The CSN-Ubp12p pathway also maintains the stability of the Cul1p adapter Pop1p, a mechanism required for the efficient destruction of its cognate substrate Rum1p. Emphasizing the physiological importance of this mechanism, we found that the dispensable csn5 and ubp12 genes become essential for viability when adapter recruitment to Cul1p is compromised. Our data suggest that maintenance of adapter stability is a general mechanism of CRL control by the CSN.
VEGF causes translocation of Syx from endothelial cell junctions, promoting junction disassembly, whereas Angtiopoietin-1 maintains Syx at the junctions and stabilizes them.
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