Substrate-binding sites of UBR1, the ubiquitin ligase of the N-end rule pathway.

Substrates of a ubiquitin-dependent proteolytic system called the N-end rule pathway include proteins with destabilizing N-terminal residues. N-recognins, the pathway's ubiquitin ligases, contain three substrate-binding sites. The type-1 site is specific for basic N-terminal residues (Arg, Lys, and His). The type-2 site is specific for bulky hydrophobic N-terminal residues (Trp, Phe, Tyr, Leu, and Ile). We show here that the type-1/2 sites of UBR1, the sole N-recognin of the yeast Saccharomyces cerevisiae, are located in the first approximately 700 residues of the 1,950-residue UBR1. These sites are distinct in that they can be selectively inactivated by mutations, identified through a genetic screen. Mutations inactivating the type-1 site are in the previously delineated approximately 70-residue UBR motif characteristic of N-recognins. Fluorescence polarization and surface plasmon resonance were used to determine that UBR1 binds, with a K(d) of approximately 1 microm, to either type-1 or type-2 destabilizing N-terminal residues of reporter peptides but does not bind to a stabilizing N-terminal residue such as Gly. A third substrate-binding site of UBR1 targets an internal degron of CUP9, a transcriptional repressor of peptide import. We show that the previously demonstrated in vivo dependence of CUP9 ubiquitylation on the binding of cognate dipeptides to the type-1/2 sites of UBR1 can be reconstituted in a completely defined in vitro system. We also found that purified UBR1 and CUP9 interact nonspecifically and that specific binding (which involves, in particular, the binding by cognate dipeptides to the UBR1 type-1/2 sites) can be restored either by a chaperone such as EF1A or through macromolecular crowding.

The metalloprotease disintegrin ADAM8. Processing by autocatalysis is required for proteolytic activity and cell adhesion.

ADAMs (a disintegrin and metalloprotease domains) are metalloprotease and disintegrin domain-containing transmembrane glycoproteins with proteolytic, cell adhesion, cell fusion, and cell signaling properties. ADAM8 was originally cloned from monocytic cells, and its distinct expression pattern indicates possible roles in both immunology and neuropathology. Here we describe our analysis of its biochemical properties. In transfected COS-7 cells, ADAM8 is localized to the plasma membrane and processed into two forms derived either by prodomain removal or as remnant protein comprising the extracellular region with the disintegrin domain at the N terminus. Proteolytic removal of the ADAM8 propeptide was completely blocked in mutant ADAM8 with a Glu(330) to Gln exchange (EQ-A8) in the Zn(2+) binding motif (HE(330)LGHNLGMSHD), arguing for autocatalytic prodomain removal. In co-transfection experiments, the ectodomain but not the entire MP domain of ADAM8 was able to remove the prodomain from EQ-ADAM8. With cells expressing ADAM8, cell adhesion to a substrate-bound recombinant ADAM8 disintegrin/Cys-rich domain was observed in the absence of serum, blocked by an antibody directed against the ADAM8 disintegrin domain. Soluble ADAM8 protease, consisting of either the metalloprotease domain or the complete ectodomain, cleaved myelin basic protein and a fluorogenic peptide substrate, and was inhibited by batimastat (BB-94, IC(50) approximately 50 nm) but not by recombinant tissue inhibitor of matrix metalloproteinases 1, 2, 3, and 4. Our findings demonstrate that ADAM8 processing by autocatalysis leads to a potential sheddase and to a form of ADAM8 with a function in cell adhesion.

The enzymatic activity of ADAM8 and ADAM9 is not regulated by TIMPs.

The ADAM family of proteases are type I transmembrane proteins with both metalloproteinase and disintegrin containing extracellular domains. ADAMs are implicated in the proteolytic processing of membrane-bound precursors and involved in modulating cell-cell and cell-matrix interactions. ADAM8 (MS2, CD156) has been identified in myeloid and B cells. In this report we demonstrate that soluble ADAM8 is an active metalloprotease in vitro and is able to hydrolyse myelin basic protein and a variety of peptide substrates based on the cleavage sites of membrane-bound cytokines, growth factors and receptors which are known to be processed by metalloproteinases. Interestingly, although ADAM8 was inhibited by a number of peptide analogue hydroxamate inhibitors, it was not inhibited by the tissue inhibitors of metalloproteinases (TIMPs). We also demonstrate that the activity of recombinant soluble ADAM9 (meltrin-gamma, MDC9) lacks inhibition by the TIMPs, but can be inhibited by hydroxamate inhibitors. The lack of TIMP inhibition of ADAM8 and 9 contrasts with other membrane-associated metalloproteinases characterised to date in this respect (ADAM10, 12, 17, and the membrane-type metalloproteinases) which have been implicated in protein processing at the cell surface.

Phosphorylation-dependent interactions between ADAM15 cytoplasmic domain and Src family protein-tyrosine kinases.

The adamalysins (ADAMs) are transmembrane glycoproteins involved in cell adhesion and proteolytic ectodomain processing of cytokines and adhesion molecules. Many ADAM cytoplasmic domains are proline-rich and have potential phosphorylation sites. We show here that the cytoplasmic domain of ADAM15, metargidin, can interact specifically with Src family protein-tyrosine kinases (PTKs) and the adaptor protein Grb2 in hematopoietic cells (Jurkat, THP-1, U937, and K562 cell lines). Src homology 3 domains from several Src family PTKs including Lck, Fyn, Abl, and Src associate with ADAM15 in vitro. Dephosphorylation of cell extracts resulted in decreased association of ADAM15 with Src family PTK SH3 domains, indicating that phosphorylation influences ADAM15 interactions with its binding partners. This was confirmed in vitro for Hck, Lck, and Grb2, which showed enhanced association with tyrosine-phosphorylated glutathione S-transferase-ADAM15 cytoplasmic domain compared with unphosphorylated protein. In contrast, binding of MAD2 to ADAM15 was slightly reduced by phosphorylation of the ADAM. Immunoprecipitation of ADAM15 from Jurkat cells confirmed the association with Lck in vivo, and upon PMA stimulation, the phosphorylation level of ADAM15 was increased. Cotransfection of ADAM15 and Hck showed Hck-dependent phosphorylation of ADAM15 in vivo. Hck, and to a lesser extent Lck, phosphorylated the ADAM15 cytoplasmic domain in vitro in immune complex kinase assays. Binding of ADAM15 cytoplasmic domain to Hck and Lck was also shown by Far Western analysis. In contrast to Hck, Lck activity was not required for binding to ADAM15, as shown by treatment of cells with PP1. Deletion and point mutation analysis of the ADAM15 cytoplasmic domain confirmed the importance of the proline-rich motifs for Grb2 and Lck binding and indicated the regulatory nature of Tyr(715) and Tyr(735). These data demonstrate selective, phosphorylation-dependent interactions of ADAM15 with Src family PTKs and Grb2, which highlight the potential for integration of ADAM functions and cellular signaling.