APC is essential for targeting phosphorylated beta-catenin to the SCFbeta-TrCP ubiquitin ligase.

Ubiquitin-dependent proteolysis is an important mechanism that suppresses the beta-catenin transcription factor in cells without Wnt stimulation. A critical step in this regulatory pathway is to create a SCF(beta-TrCP) E3 ubiquitin ligase binding site for beta-catenin. Here we show that the SCF(beta-TrCP) binding site created by phosphorylation of beta-catenin is highly vulnerable to protein phosphatase 2A (PP2A) and must be protected by the adenomatous polyposis coli (APC) tumor suppressor protein. Specifically, phosphorylated beta-catenin associated with the wild-type APC protein is recruited to the SCF(beta-TrCP) complex, ubiquitin conjugated, and degraded. A mutation in APC that deprives this protective function exposes the N-terminal phosphorylated serine/threonine residues of beta-catenin to PP2A. Dephosphorylation at these residues by PP2A eliminates the SCF(beta-TrCP) recognition site and blocks beta-catenin ubiquitin conjugation. Thus, by acting to protect the E3 ligase binding site, APC ensures the ubiquitin conjugation of phosphorylated beta-catenin.

Proteomic View of Basement Membranes from Human Retinal Blood Vessels, Inner Limiting Membranes, and Lens Capsules.

Basement membranes (BMs) are extracellular matrix sheets comprising the laminins, type-IV collagens, nidogens, and the heparan sulfate proteoglycans, perlecan, collagen XVIII, and agrin. In intact BMs, BM proteins are physiologically insoluble and partially resistant to proteolytic digestion, making BMs a challenge to study. Here three types of BMs from adult human eyes, the inner limiting membrane (ILM), the retinal vascular BMs, and the lens capsule, were isolated for analysis by 1D-SDS-PAGE and LC-MS/MS. Peptide and protein identifications were done using MaxQuant. 1129 proteins were identified with a 1% false discovery rate. Data showed that BMs are composed of multiple laminins, collagen IVs, nidogens, and proteoglycans. The dominant laminin family member in all BMs was laminin α5ß2γ1. The dominant collagen IV trimer in lens capsule (LC) and blood vessel (BV) BMs had a chain composition of α1(IV)2, α2 (IV), whereas the dominant collagen IV in the ILM had the α3(IV), α4(IV), α5(IV) chain composition. The data also showed that the ratio of laminin and collagen IVs varied among different BM types: the ratio of collagen IV to the other BM proteins is highest in LC, followed by BV and lowest for the ILM. The data have been deposited to the ProteomeXchange with identifier PXD001025.

Proteolysis of Rad17 by Cdh1/APC regulates checkpoint termination and recovery from genotoxic stress.

Recent studies have shown a critical function for the ubiquitin-proteasome system (UPS) in regulating the signalling network for DNA damage responses and DNA repair. To search for new UPS targets in the DNA damage signalling pathway, we have carried out a non-biased assay to identify fast-turnover proteins induced by various types of genotoxic stress. This endeavour led to the identification of Rad17 as a protein exhibiting a distinctive pattern of upregulation followed by subsequent degradation after exposure to UV radiation in human primary cells. Our characterization showed that UV-induced Rad17 oscillation is mediated by Cdh1/APC, a ubiquitin-protein ligase. Studies using a degradation-resistant Rad17 mutant demonstrated that Rad17 stabilization prevents the termination of checkpoint signalling, which in turn attenuates the cellular re-entry into cell-cycle progression. The findings provide an insight into how the proteolysis of Rad17 by Cdh1/APC regulates the termination of checkpoint signalling and the recovery from genotoxic stress.

Human liver microsomal metabolism of (+)-discodermolide.

The polyketide natural product (+)-discodermolide is a potent microtubule stabilizer that has generated considerable interest in its synthetic, medicinal, and biological chemistry. It progressed to early clinical oncology trials, where it showed some efficacy in terms of disease stabilization but also some indications of causing pneumotoxicity. Remarkably, there are no reports of its metabolism. Here, we examined its fate in mixed human liver microsomes. Due to limited availability of the agent, we chose a nanoflow liquid chromatography-electrospray ionization-mass spectrometry analytical approach employing quadrupolar ion trap and quadrupole-quadrupole-time-of-flight instruments for these studies. (+)-Discodermolide was rapidly converted to eight metabolites, with the left-side lactone (net oxidation) and the right-side diene (epoxidation followed by hydrolysis, along with an oxygen insertion product) being the most metabolically labile sites. Other sites of metabolism were the allylic and pendant methyl moieties in the C12-C14 region of the molecule. The results provide information on the metabolic soft spots of the molecule and can be used in further medicinal chemistry efforts to optimize discodermolide analogues.

Molecular interactions in the retinal basement membrane system: a proteomic approach.

Basement membranes (BMs) are physiologically insoluble extracellular matrix sheets present in all multicellular organisms. They play an important role in providing mechanical strength to tissues and regulating cell behavior. Proteomic analysis of BM proteins is challenged by their high molecular weights and extensive post-translational modifications. Here, we describe the direct analysis of an in vivo BM system using a mass spectrometry (MS) based proteomics approach. Retinal BMs were isolated from embryonic chick eyes. The BM macromolecules were deglycosylated and separated by low percentage gradient SDS PAGE, in-gel digested and analyzed by LC-MS/MS. This identified over 27 extracellular matrix proteins in the retinal BM. A semi-quantitative measure of protein abundance distinguished, nidogens-1 and -2, laminin subunits α1, α5, ß2, and γ1, agrin, collagen XVIII, perlecan, FRAS1 and FREM2 as the most abundant BM protein components. Laminin subunits α3, ß1, γ2, γ3 and collagen IV subunits α5 and α6 were minor constituents. To examine binding interactions that contribute to the stability of the retinal BM, we applied the LC-MS/MS based approach to detect potential BM complexes from the vitreous. Affinity-captured nidogen- and heparin-binding proteins from the vitreous contained >10 and >200 proteins respectively. Comparison of these protein lists with the retinal BM proteome reveals that glycosaminoglycan and nidogen binding interactions play a central role in the internal structure and formation of the retinal BM. In addition, we studied the biomechanical qualities of the retinal BM before and after deglycosylation using atomic force microscopy. These results show that the glycosaminoglycan side chains of the proteoglycans play a dominant role in regulating the thickness and elasticity of the BMs by binding water to the extracellular matrix. To our knowledge, this is the first large-scale investigation of an in vivo BM system using MS-based proteomics.

Myeloperoxidase-catalyzed metabolism of etoposide to its quinone and glutathione adduct forms in HL60 cells.

Etoposide is a widely used antineoplastic agent that has provided great success in the treatment of childhood leukemias and other malignancies. Unfortunately, its use is associated with the increased risk of development of secondary acute myelogenous leukemias involving translocations at the MLL gene in chromosome band 11q23. Previous studies showed that the phenoxyl radical of etoposide can be generated by myeloperoxidase (MPO), an enzyme prevalent in myeloid progenitor cells that can derive myelogenous leukemias. Disproportionation of this radical leads to formation of the redox active etoposide ortho-quinone metabolite. We hypothesized that etoposide ortho-quinone could therefore form in myeloid progenitor cells and might be a contributor to the development of treatment-related secondary leukemias. Etoposide ortho-quinone is an inherently unstable compound and readily reacts with glutathione in aqueous media without any requirement for catalytic assistance from glutathione S-transferase. We looked for the presence of its glutathione adduct as an indicator of etoposide ortho-quinone in cells. MPO-expressing human myeloid leukemia HL60 cells were treated with etoposide for 0.5 h in the presence and absence of the cosubstrate of MPO, hydrogen peroxide. Cell lysates and medium were analyzed by LC-ESI-ion trap-MS and MS/MS, which yielded clear evidence of the intracellular formation of the etoposide ortho-quinone-glutathione adduct. A stable isotope-labeled form of the GSH adduct was synthesized and employed as an isotope dilution internal standard in LC-ESI-quadrupole-MS analyses. The glutathione adduct level was dependent on the concentration of etoposide added to the cells. More importantly, the formation of the glutathione adduct was significantly suppressed by the pretreatment of HL60 cells with the heme synthesis inhibitor succinylacetone (p < 0.001), which resulted in a decreased level and activity of MPO. These results are consistent with the idea that MPO is responsible for the conversion of etoposide to its ortho-quinone in these cells.

Redox regulation of Cdc25B by cell-active quinolinediones.

Intracellular reduction and oxidation pathways regulate protein functionality through both reversible and irreversible mechanisms. The Cdc25 phosphatases, which control cell cycle progression, are potential subjects of oxidative regulation. Many of the more potent Cdc25 phosphatase inhibitors reported to date are quinones, which are capable of redox cycling. Therefore, we used the previously characterized quinolinedione Cdc25 inhibitor DA3003-1 [NSC 663284 or 6-chloro-7-(2-morpholin-4-yl-ethylamino)-quinoline-5,8-dione] and a newly synthesized congener JUN1111 [7-(2-morpholin-4-yl-ethylamino)-quinoline-5,8-dione] to test the hypothesis that quinone inhibitors of Cdc25 regulate phosphatase activity through redox mechanisms. Like DA3003-1, JUN1111 selectively inhibited Cdc25 phosphatases in vitro in an irreversible, time-dependent manner and arrested cells in the G1 and G2/M phases of the cell cycle. It is noteworthy that both DA3003-1 and JUN1111 directly inhibited Cdc25B activity in cells. Depletion of glutathione increased cellular sensitivity to DA3003-1 and JUN1111, and in vitro Cdc25B inhibition by these compounds was sensitive to pH, catalase, and reductants (dithiothreitol and glutathione), consistent with oxidative inactivation. In addition, both DA3003-1 and JUN1111 rapidly generated intracellular reactive oxygen species. Analysis of Cdc25B by mass spectrometry revealed sulfonic acid formation on the catalytic cysteine of Cdc25B after in vitro treatment with DA3003-1. These results indicate that irreversible oxidation of the catalytic cysteine of Cdc25B is indeed a mechanism by which these quinolinediones inactivate this protein phosphatase.