Ubiquitin‐mediated proteolysis has emerged as a key mechanism of regulation in eukaryotic cells. During cell division, a multi‐subunit ubiquitin ligase termed the anaphase promoting complex (APC) targets critical regulatory proteins such as securin and mitotic cyclins, and thereby triggers chromosome separation and exit from mitosis. Previous studies in the yeast Saccharomyces cerevisiae identified the conserved WD40 proteins Cdc20 and Hct1 (Cdh1) as substrate‐specific activators of the APC, but their precise mechanism of action has remained unclear. This study provides evidence that Hct1 functions as a substrate receptor that recognizes target proteins and recruits them to the APC for ubiquitylation and subsequent proteolysis. By co‐immunoprecipitation, we found that Hct1 interacted with the mitotic cyclins Clb2 and Clb3 and the polo‐related kinase Cdc5, whereas Cdc20 interacted with the securin Pds1. Failure to interact with Hct1 resulted in stabilization of Clb2. Analysis of Hct1 derivatives identified the C‐box, a motif required for APC association of Hct1 and conserved among Cdc20‐related proteins. We propose that proteins of the Cdc20 family are substrate recognition subunits of the ubiquitin ligase APC.
The relevance of angiogenesis in tumor biology and as a therapeutic target is well established. MFG-E8 (also termed lactadherin) and developmental endothelial locus 1 (Del1) constitute a two-gene family of A v B 3 /B 5 ligands that regulate angiogenesis. After detecting MFG-E8 mRNA in murine tumor cell lines, we sought to determine if MFG-E8 influenced tumorigenesis in Rip1-Tag2 transgenic mice, a cancer model in which angiogenesis is critical. MFG-E8 mRNA and protein were increased in angiogenic islets and tumors in Rip1-Tag2 mice compared with normal pancreas. Frequencies of angiogenic islets and tumor burdens were decreased in MFG-E8-deficient Rip1-Tag2 mice compared with those in control Rip1-Tag2 mice. Invasive carcinomas were modestly underrepresented in MFG-E8-deficient mice, but tumor frequencies and survivals were comparable in these two strains. Absence of MFG-E8 also led to decreases in tumor vascular permeability without obvious changes in vascular morphology. Decreased proliferation was noted in angiogenic islets and increases in apoptotic cells were detected in islets and tumors. Compensatory increases in mRNA encoding proangiogenic proteins, including FGF2, in angiogenic islets, and Del1, in angiogenic islets and tumors, were also detected in MFG-E8-deficient mice. MFG-E8 and its homologue Del1 may represent relevant targets in cancer and other diseases in which angiogenesis is prominent. [Cancer Res 2007;67(14):6777-85]
To identify novel regulators of endoplasmic reticulum (ER)-linked protein degradation and ER function, we determined the entire inventory of membrane-spanning RING finger E3 ubiquitin ligases localized to the ER. We identified 24 ER membraneanchored ubiquitin ligases and found Nixin/ZNRF4 to be central for the regulation of calnexin turnover. Ectopic expression of wild type Nixin induced a dramatic down-regulation of the ER-localized chaperone calnexin that was prevented by inactivation of the Nixin RING domain. Importantly, Nixin physically interacts with calnexin in a glycosylation-independent manner, induces calnexin ubiquitination, and p97-dependent degradation, indicating an ER-associated degradation-like mechanism of calnexin turnover.The endoplasmic reticulum (ER) 3 is a major cellular site for production, folding, quality control, and distribution of proteins. Many regulatory mechanisms are in place to keep these processes in balance and therefore to ensure cellular fitness and survival, with ubiquitin-dependent protein degradation playing an important part (1). One major challenge the ER faces is an overload with unfolded or folding proteins. An excess of folding proteins in the ER triggers a cellular response called the unfolded protein response (UPR) (2, 3). UPR entails lowering of the protein load by the attenuation of protein translation and the up-regulation of chaperones thereby increasing the protein folding capacity of the cells. If the capacity of UPR is exceeded, the cell utilizes ER-associated degradation (ERAD), a system for the recognition of terminally misfolded proteins and their disposal (4). Misfolded proteins destined for ERAD are ubiquitinated by the RING domain containing ubiquitin ligases (5), Hrd1 (6), and Doa1 (7, 8), retrotranslocated across the ER membrane into the cytosol by the AAA-ATPase p97 (9), and then degraded by the 26 S proteasome.Upon entry into the ER, most nascent polypeptides are recognized by glycosidases and modified on specific asparagine residues (Asn-Xaa-(Thr/Ser)) with the N-glycan GlcNAc 2 Man 9 Gluc 3 (10). Core glycosylation of nascent polypeptides decreases their overall hydrophobicity. Trimming of the terminal two glucose residues by glucosidase I allows for binding of the lectins/chaperones calreticulin and calnexin thereby facilitating the proper folding of the newly synthesized protein (10,11).Although the importance of regulated degradation of ER resident proteins is firmly established, only a small number of RING finger-containing ubiquitin ligases are known to be involved in such processes to date, namely SYVN1/hHrd1 (6, 12), AMFR/gp78 (13), TEB4/MARCH6 (14), RNF5/Rma1 (15), RNF77/TRIM13 (16), and RNF13 (17). Given the importance of protein metabolism and degradation in the ER and the vast number of ubiquitin ligases encoded in the human genome, we asked whether other ubiquitin ligases are involved in the regulation of ER-related degradation processes.Based on the assumption that the ER lumen is devoid of E1 and E2 ubiquitination activity and on the...
Ubiquitination, the covalent attachment of the small protein modifier ubiquitin to a substrate protein is involved in virtually all cellular processes by mediating the regulated degradation of proteins. Aside from proteasomal degradation, ubiquitination plays important roles in transcriptional regulation, protein trafficking, including endocytosis and lysosomal targeting, and activation of kinases involved in signalling processes. A three-tiered enzymatic cascade consisting of E1 or ubiquitin-activating enzyme, E2 or ubiquitin-conjugating enzyme, and E3, or ubiquitin ligases, is necessary to achieve the many forms of ubiquitination known to date. In this chapter, we summarize the current knowledge on the enzymatic machinery necessary for ubiquitin activation and ligation, as well as its removal, and provide some insight into the complexity of regulatory processes governed by ubiquitination.
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