A protein-protein association regulated by phosphorylation of serine is examined by NMR studies. Degradation of the HIV receptor CD4 by the proteasome, mediated by the HIV-1 protein Vpu, is crucial for the release of fully infectious virions. Phosphorylation of Vpu at two sites, Ser52 and Ser56, on the motif DSGXXS is required for the interaction of Vpu with the ubiquitin ligase SCF-betaTrCP which triggers CD4 degradation by the proteasome. This motif is conserved in several signaling proteins known to be degraded by the proteasome. To elucidate the basis of beta-TrCP recognition, the bound conformation of the P-Vpu(41-62) peptide was determined by using NMR and MD. The TRNOE intensities provided distance constraints which were used in simulated annealing. The beta-TrCP-bound structure of P-Vpu was found to be similar to the structure of the free peptide in solution and to the structure recognized by its antibody. Residues 50-57 formed a bend while the phosphate groups are pointing away. The binding fragment was studied by STD-NMR spectroscopy. The phosphorylated motif DpS(52)GNEpS(56) was found to make intimate contact with beta-TrCP, and pSer52 displays the strongest binding effect. It is suggested that Ser phosphorylation allows protein-protein association by electrostatic stabilization: an obvious negative binding region of Vpu was recognizable by positive residues (Arg and Lys) of the WD domain of beta-TrCP. The Ile46 residue was also found essential for interaction with the beta-TrCP protein. Leu45 and Ile46 side chains lie in close proximity to a hydrophobic pocket of the WD domain.
-TrCP is the F-box protein component of an Skp1/ Cul1/F-box (SCF)-type ubiquitin ligase complex. Biochemical studies have suggested that -TrCP targets the oncogenic protein -catenin for ubiquitination and followed by proteasome degradation. To further elucidate the basis of this interaction, a complex between a 32-residue peptide from -catenin containing the phosphorylated motif DpSGXXpS (P--Cat 17-48 ) and -TrCP was studied using Saturation Transfer Difference (STD) Nuclear Magnetic Resonance (NMR) experiments. These experiments make it possible to identify the binding epitope of a ligand at atomic resolution. An analysis of STD spectra provided clear evidence that only a few of the 32 residues receive the largest saturation transfer. In particular, the amide protons of the residues in the phosphorylated motif appear to be in close contact to the amino acids of the -TrCP binding pocket. The amide and aromatic protons of the His 24 and Trp 25 residues also receive a significant saturation transfer. These findings are in keeping with a recently published x-ray structure of a shorter -catenin fragment with the -TrCP1-Skp1 complex and with the earlier findings from mutagenesis and activity assays. To better characterize the ligand-protein interaction, the bound conformation of the phosphorylated -catenin peptide was obtained using TRansfer Nuclear Overhauser Effect SpectroscopY (TRNOESY) experiments. Finally, we obtained the bound structure of the phosphorylated peptide showing the protons identified by STD NMR as exposed in close proximity to the molecule surface.The ubiquitin-proteasome pathway of protein degradation is essential for various important biological processes including cell cycle progression, gene transcription, and signal transduction (1, 2). This work is based on the study of the oncogenic protein -catenin (-Cat), 1 which plays an essential role in the Wingless/Wnt signaling pathway and is an important component of cadherin cell-adhesion complexes (Fig. 1A). The abundance of -catenin in the cytoplasm is regulated by ubiquitindependent proteolysis (3), and Wnt signaling is regulated by the presence or absence of the intracellular protein -catenin. When Wnt signal is absent, the signal transduction pathway is off because -catenin is rapidly destroyed. A large multiprotein machine normally facilitates the addition of phosphate groups to -catenin by glycogen synthase kinase-3 (GSK3). Phosphorylated -catenin binds to a protein called -TrCP and is then modified by the covalent addition of a small protein called ubiquitin. Proteins tagged with ubiquitin are degraded by the 26 S proteasome, the protein-recycling center of the cell. When cells are exposed to the Wnt signal, it binds to cell surface receptors. Receptor activation blocks -catenin phosphorylation, and its subsequent ubiquitination by an unknown mechanism that requires the intervention of the Disheveled protein (Dsh). -Catenin is thus diverted from the proteasome. It accumulates and enters the nucleus, where it finds a par...
ATF4 plays a crucial role in the cellular response to stress. The E3 ubiquitin ligase, SCF beta-TrCP protein responsible for ATF4 degradation by the proteasome, binds to ATF4 through a DpSGXXXpS phosphorylation motif, which is similar but not identical to the DpSGXXpS motif found in most other substrates of beta-TrCP. NMR studies were performed on the free and bound forms of a peptide derived from this ATF4 motif that enabled the elucidation of the conformation of the ligand complexed to the beta-TrCP protein and its binding mode. Saturation transfer difference (STD) NMR allowed the study of competition for binding to beta-TrCP, between the phosphorylation motifs of ATF4 and beta-catenin, to characterize the ATF4 binding epitope. Docking protocols were performed using the crystal structure of the beta-catenin-beta-TrCP complex as a template and NMR results of the ATF4-beta-TrCP complex. In agreement with the STD results, in order to bind to beta-TrCP, the ATF4 DpSGIXXpSXE motif required the association of two negatively charged areas, in addition to the hydrophobic interaction in the beta-TrCP central channel. Docking studies showed that the ATF4 DpSGIXXpSXE motif fits the binding pocket of beta-TrCP through an S-turning conformation. The distance between the two phosphate groups is 17.8 A, which matched the corresponding distance 17.1 A for the other extended DpSGXXpS motif in the beta-TrCP receptor model. This study identifies the residues of the beta-TrCP receptor involved in ligand recognition. Using a new concept of STD competition experiment, we show that ATF4 competes and inhibits binding of beta-catenin to beta-TrCP.
A new structurally distinct class of 14-membered-ring macrolides is characterized by a keto-function instead of the cladinose sugar, well-known for its fragility even in weakly acidic media. This new class called ketolides is endowed with remarkable antibacterial activity against macrolide-resistant strains. A complete assignment of the 1H and 13C NMR spectra of RU 004 in deuteriochloroform, methanol-d4 and D2O has been made using different two-dimensional (2D) chemical-shift correlation methods. The study of ketolide-ribosome interaction has been investigated using 2D transferred nuclear Overhauser effect spectroscopy (TRNOESY). A comparison of the conformations in solution and bound to ribosomes was made with those of previous macrolides. This study can highlight some of the significant differences between RU 004 and other antibiotics.
The drugs roxithromycin 1 and erythromycin 2 differ in their ability to produce a hepatotoxic effect or drug interactions involving macrolide antibiotics. The major metabolite of 1, RU39001 (3) does not induce hepatic cytochrome P-450 while the metabolite of 2, erythralosamine (4) has greater interaction properties either in vitro or in vivo with the cytochrome P-450 system. A combination of NMR spectroscopy and molecular dynamics (MD) has shown that the conformations of 1 and 2, in CDCI,
The IkappaB-alpha protein, inhibitor of the transcription factor nuclear factor-kappaB (NF-kappaB), is a cellular substrate of beta-transducin repeat containing protein (beta-TrCP). beta-TrCP is the F-box protein component of an Skp1/Cul1/F-box (SCF)-type ubiquitin ligase complex. beta-TrCP targets the protein IkappaB-alpha for ubiquitination, followed by proteasome degradation. The SCF-beta-TrCP complex specifically recognizes an IkappaB-alpha peptide containing the DpSGXXpS motif in a phosphorylation-dependent manner. A fragment comprising 24 amino acids residues for the phosphorylated peptide at the two sites Ser32 and Ser36 and thus termed 24P-IkappaBalpha (P-IkappaBalpha21-44) was characterized conformationally by NMR spectroscopy and molecular dynamics simulation. In the free states, 24P-IkappaBalpha exhibits mainly a random coil conformation, although the presence of a nascent bend was detected between residues 30 and 36, flanked by two N- and C-terminal disordered regions. The bound conformation of the phosphorylated IkappaB-alpha peptide was obtained using transfer nuclear Overhauser effect spectroscopy (TRNOESY) experiments. To further elucidate the basis of the beta-TrCP interaction, a complex between 24P-IkappaBalpha peptide and beta-TrCP protein was studied using saturation transfer difference (STD) NMR experiments. The conformation of 24P-IkappaBalpha bound to beta-TrCP presents a bend corresponding to the 31DpSGLDpS36 motif and on both sides N- and C-terminal turn regions (Lys22-Asp31 and Met37-Glu43). The bound structure of the phosphorylated peptide suggests that these domains are crucial for the interaction of the peptide with its receptor showing the protons identified by STD NMR as exposed in close proximity to the beta-TrCP surface.
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