Wnt/β-catenin signaling plays a central role in development and is also involved in a diverse array of diseases. Binding of Wnts to the coreceptors Frizzled and LRP6/5 leads to phosphorylation of PPPSPxS motifs in the LRP6/5 intracellular region and the inhibition of GSK3β bound to the scaffold protein Axin. However, it remains unknown how GSK3β is specifically inhibited upon Wnt stimulation. Here, we show that overexpression of the intracellular region of LRP6 containing a Ser/Thr rich cluster and a PPPSPxS motif impairs the activity of GSK3β in cells. Synthetic peptides containing the PPPSPxS motif strongly inhibit GSK3β in vitro only when they are phosphorylated. Microinjection of these peptides into Xenopus embryos confirms that the phosphorylated PPPSPxS motif potentiates Wnt-induced second body axis formation. In addition, we show that the Ser/Thr rich cluster of LRP6 plays an important role in LRP6 binding to GSK3β. These observations demonstrate that phosphorylated LRP6/5 both recruits and directly inhibits GSK3β using two distinct portions of its cytoplasmic sequence, and suggest a novel mechanism of activation in this signaling pathway.
Clip‐domain serine proteases (SPs) are the essential components of extracellular signaling cascades in various biological processes, especially in embryonic development and the innate immune responses of invertebrates. They consist of a chymotrypsin‐like SP domain and one or two clip domains at the N‐terminus. Prophenoloxidase‐activating factor (PPAF)‐II, which belongs to the noncatalytic clip‐domain SP family, is indispensable for the generation of the active phenoloxidase leading to melanization, a major defense mechanism of insects. Here, the crystal structure of PPAF‐II reveals that the clip domain adopts a novel fold containing a central cleft, which is distinct from the structures of defensins with a similar arrangement of cysteine residues. Ensuing studies demonstrated that PPAF‐II forms a homo‐oligomer upon cleavage by the upstream protease and that the clip domain of PPAF‐II functions as a module for binding phenoloxidase through the central cleft, while the clip domain of a catalytically active easter‐type SP plays an essential role in the rapid activation of its protease domain.
Macrolide-specific efflux pump MacAB-TolC has been identified in diverse Gram-negative bacteria including Escherichia coli. The inner membrane transporter MacB requires the outer membrane factor TolC and the periplasmic adaptor protein MacA to form a functional tripartite complex. In this study, we used a chimeric protein containing the tip region of the TolC ␣-barrel to investigate the role of the TolC ␣-barrel tip region with regard to its interaction with MacA. The chimeric protein formed a stable complex with MacA, and the complex formation was abolished by substitution at the functionally essential residues located at the MacA ␣-helical tip region. Electron microscopic study delineated that this complex was made by tip-to-tip interaction between the tip regions of the ␣-barrels of TolC and MacA, which correlated well with the TolC and MacA complex calculated by molecular dynamics. Taken together, our results demonstrate that the MacA hexamer interacts with TolC in a tip-to-tip manner, and implies the manner by which MacA induces opening of the TolC channel.Drug resistance of microbial pathogens presents an increasing threat to public health (1). In Gram-negative pathogens, high levels of intrinsic or acquired drug resistance are conferred by three-component multidrug efflux pumps, which are composed of the inner membrane transporter, the outer membrane factor (OMF), and the periplasmic membrane fusion protein (MFP) 4 (2-5). These tripartite complexes span the entire twomembrane envelope of Gram-negative bacteria and expel various molecules into the medium, utilizing a proton gradient or ATP hydrolysis. The inner membrane transporters belong to one of three structurally dissimilar superfamilies of proteins: resistance-nodulation-cell division (RND), ATP-binding cassette (ABC), or major facilitator. The inner membrane transporters expel the substrates through the central channel of the OMF, as exemplified by Escherichia coli TolC, which spans the outer membrane (6). The MFP, which connects the other two components in the periplasm, is also essential for the function of the efflux pump.In E. coli, AcrAB-TolC acts as a major multidrug efflux pump (7-9), where AcrB is the RND-type inner membrane transporter and AcrA belongs to MFP. The homotrimeric TolC is embedded in the outer membrane and continues ϳ100 Å into the periplasmic space as an ␣-barrel composed of six ␣-hairpins that form the wall of a 35-Å inner-diameter cylindrical channel (10). The TolC channel is closed at the aperture end and the channel opening is induced only in the presence of the other components, the mechanism of which remains to be determined at the molecular level.The MacAB-TolC pump has been identified in E. coli; the inner membrane transporter MacB belongs to non-canonic ABC-type transporters (8,9,11,12), and MFP MacA shares structural similarity with AcrA (sequence similarity 44%) (13). Overproduction of MacAB results in increased resistance to the macrolide antibiotics in macrolide-susceptible AcrAB-deficient E. coli (8, 9, 11).The s...
Nonsense-mediated mRNA decay (NMD) is an important mRNA surveillance system, and human PNRC2 protein mediates the link between mRNA surveillance and decapping. However, the mechanism by which PNRC2 interacts with the mRNA surveillance machinery and stimulates NMD is unknown. Here, we present the crystal structure of Dcp1a in complex with PNRC2. The proline-rich region of PNRC2 is bound to the EVH1 domain of Dcp1a, while its NR-box mediates the interaction with the hyperphosphorylated Upf1. The mode of PNRC2 interaction with Dcp1a is distinct from those observed in other EVH1/proline-rich ligands interactions. Disruption of the interaction of PNRC2 with Dcp1a abolishes its P-body localization and ability to promote mRNA degradation when tethered to mRNAs. PNRC2 acts in synergy with Dcp1a to stimulate the decapping activity of Dcp2 by bridging the interaction between Dcp1a and Dcp2, suggesting that PNRC2 is a decapping coactivator in addition to its adaptor role in NMD.
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