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Huynh VN, Wang S, Ouyang X, Wani WY, Johnson MS, Chacko BK, Jegga AG, Qian WJ, Chatham JC, Darley-Usmar VM, Zhang J. Defining the Dynamic Regulation of O-GlcNAc Proteome in the Mouse Cortex---the O-GlcNAcylation of Synaptic and Trafficking Proteins Related to Neurodegenerative Diseases. Frontiers in aging 2021 2 35822049
Abstract:
O-linked conjugation of ß-N-acetyl-glucosamine (O-GlcNAc) to serine and threonine residues is a post-translational modification process that senses nutrient availability and cellular stress and regulates diverse biological processes that are involved in neurodegenerative diseases and provide potential targets for therapeutics development. However, very little is known of the networks involved in the brain that are responsive to changes in the O-GlcNAc proteome. Pharmacological increase of protein O-GlcNAcylation by Thiamet G (TG) has been shown to decrease tau phosphorylation and neurotoxicity, and proposed as a therapy in Alzheimer's disease (AD). However, acute TG exposure impairs learning and memory, and protein O-GlcNAcylation is increased in the aging rat brain and in Parkinson's disease (PD) brains. To define the cortical O-GlcNAc proteome that responds to TG, we injected young adult mice with either saline or TG and performed mass spectrometry analysis for detection of O-GlcNAcylated peptides. This approach identified 506 unique peptides corresponding to 278 proteins that are O-GlcNAcylated. Of the 506 unique peptides, 85 peptides are elevated by > 1.5 fold in O-GlcNAcylation levels in response to TG. Using pathway analyses, we found TG-dependent enrichment of O-GlcNAcylated synaptic proteins, trafficking, Notch/Wnt signaling, HDAC signaling, and circadian clock proteins. Significant changes in the O-GlcNAcylation of DNAJC6/AUXI, and PICALM, proteins that are risk factors for PD and/or AD respectively, were detected. We compared our study with two key prior O-GlcNAc proteome studies using mouse cerebral tissue and human AD brains. Among those identified to be increased by TG, 15 are also identified to be increased in human AD brains compared to control, including those involved in cytoskeleton, autophagy, chromatin organization and mitochondrial dysfunction. These studies provide insights regarding neurodegenerative diseases therapeutic targets.
O-GlcNAc proteins:
TANC2, AMRA1, CAMP1, SKT, AGRIN, KANL3, TTLL3, NHSL2, CTTB2, CCDC6, SHAN1, SYGP1, DPYL2, STXB1, CLOCK, NOTC2, VIAAT, CTND2, TPD53, REPS1, NLK, ACK1, SYUA, ATX2, PDLI1, ZFR, HCN1, BSN, TOM1, SYN1, GCR, EGR1, NFL, NFM, ATX1L, DERPC, KCC2A, CNTN1, HSPB1, MAP1B, G3P, ATF2, MTAP2, RS2, FOXK1, STAT3, AINX, EPB41, RFX1, LMNA, INPP, VATA, DVL1, CNBP, ATX1, NCAN, GOGA3, PTPA, GCP3, TB182, GMEB2, YTHD1, PI5PA, MRTFB, LIPA3, NACAM, TNIK, WNK1, NPTN, NEO1, S30BP, ZEP1, APOC2, EMAL1, RELCH, PRC2C, YETS2, FUBP2, QRIC1, LIMC1, DAB2P, ZEP2, AAK1, TNR6A, FCHO2, DRC1, SRBS2, GRM5, PACS2, OXR1, PHAR4, LIN54, MLIP, UNKL, SMG7, RBM27, CYFP2, SYNRG, SRC8, SKIL, NCOR1, LAMA5, HCFC1, P3C2A, SAP, APC, TOB1, AP180, FXR1, HS71A, LASP1, MAFK, M3K7, TAF6, ASPP1, SRBS1, DBNL, SH3G1, TLE4, IF4G2, MINT, ZYX, NUP62, OMGP, TFE3, SYN2, TBR1, RBL2, SBNO1, SLAI1, PKP4, SH3R1, JHD2C, ABLM3, ARMX2, LAR4B, HELZ, S23IP, RBM26, BCR, AHDC1, PAPD7, MFF, KMT2D, ERC2, NFRKB, WDFY3, GGYF2, TEX2, CNOT1, IF2A, PICAL, PLPR3, PRC2B, C2CD5, TPPP, ATX2L, MAP6, NAV3, AUXI, RIMB2, AVL9, NU214, AP4E1, UBP2L, C2C2L, IF4G3, ZN598, SHAN2, LPP, MYPT2, PHIPL, TB10B, CCD40, ZC3HE, DLGP2, ZC21A, BAIP2, EMSY, CLAP2, LIPA2, SRRM2, PAMR1, GEPH, YTHD3, POGZ, EPC2, SI1L1, RBM14, F126B, ANK2, CDAN1, SYNPO, VCIP1, TAB1, MEF2C, F193A, OGT1, EP400, EPN2, P66A, PDLI5, GTPBA, ZBT20, RTN1, BRD3, AGFG1, ABLM1, MRTFA, DC1L1, SPART, RFIP5, NUP35, WASF1, SC6A8, SGIP1, AGAP3, P66B, TAF9, WDR13, LRP5, UBAP2, BASP1, DCP1A, SYUB, TRFE, TRIM7, CIC, S12A6, GORS2, TAB2, EPN4, RNF34, ANR17, NECP1, FLIP1, ROA0, RBM33, TPD54, ODO2, DLGP1, FIP1, TM263, PLIN3, LNEBL, KC1D, NBEA, INP4A, RIMS2, RBP2, RTN3, NUDT3, ATR, ADRM1, FMN2, NCOA6, SON, ULK2, ADDA, MAGD1, MAP1A, GRM3, PCLO, GAB1, FBX6, NPAS3, GUAD, NCOR2, ATRN, NFAT5, DEMA, E41L3, SLIT3, CARM1, DYR1B, MECP2, E41L1, HDAC6
Species: Mus musculus
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Liu W, Han G, Yin Y, Jiang S, Yu G, Yang Q, Yu W, Ye X, Su Y, Yang Y, Hart GW, Sun H. AANL (Agrocybe aegerita lectin 2) is a new facile tool to probe for O-GlcNAcylation. Glycobiology 2018 28(6) 29562282
Abstract:
O-linked N-acetylglucosamine (O-GlcNAcylation) is an important post-translational modification on serine or threonine of proteins, mainly observed in nucleus or cytoplasm. O-GlcNAcylation regulates many cell processes, including transcription, cell cycle, neural development and nascent polypeptide chains stabilization. However, the facile identification of O-GlcNAc is a major bottleneck in O-GlcNAcylation research. Herein, we report that a lectin, Agrocybe aegerita GlcNAc-specific lectin (AANL), also reported as AAL2, can be used as a powerful probe for O-GlcNAc identification. Glycan array analyses and surface plasmon resonance (SPR) assays show that AANL binds to GlcNAc with a dissociation constant (KD) of 94.6 μM, which is consistent with the result tested through isothiocyanate (ITC) assay reported before (Jiang S, Chen Y, Wang M, Yin Y, Pan Y, Gu B, Yu G, Li Y, Wong BH, Liang Y, et al. 2012. A novel lectin from Agrocybe aegerita shows high binding selectivity for terminal N-acetylglucosamine. Biochem J. 443:369-378.). Confocal imaging shows that AANL co-localizes extensively with NUP62, a heavily O-GlcNAcylated and abundant nuclear pore glycoprotein. Furthermore, O-GlcNAc-modified peptides could be effectively enriched in the late flow-through peak from simple samples by using affinity columns Sepharose 4B-AANL or POROS-AANL. Therefore, using AANL affinity column, we identified 28 high-confidence O-linked HexNAc-modified peptides mapped on 17 proteins involving diverse cellular progresses, including transcription, hydrolysis progress, urea cycle, alcohol metabolism and cell cycle. And most importantly, major proteins and sites were not annotated in the dbOGAP database. These results suggest that the AANL lectin is a new useful tool for enrichment and identification of O-GlcNAcylated proteins and peptides.
O-GlcNAc proteins:
FSIP2, OTU7B, CATB, CATD, GRN, ALDH2, TB182, MCM2, NUCB1, LAR4B, RPRD2, CPSM, TIM23, CATZ, CLIP2
Species: Mus musculus
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Qin K, Zhu Y, Qin W, Gao J, Shao X, Wang YL, Zhou W, Wang C, Chen X. Quantitative Profiling of Protein O-GlcNAcylation Sites by an Isotope-Tagged Cleavable Linker. ACS chemical biology 2018 13(8) 30059200
Abstract:
Large-scale quantification of protein O-linked β- N-acetylglucosamine (O-GlcNAc) modification in a site-specific manner remains a key challenge in studying O-GlcNAc biology. Herein, we developed an isotope-tagged cleavable linker (isoTCL) strategy, which enabled isotopic labeling of O-GlcNAc through bioorthogonal conjugation of affinity tags. We demonstrated the application of the isoTCL in mapping and quantification of O-GlcNAcylation sites in HeLa cells. Furthermore, we investigated the O-GlcNAcylation sensitivity to the sugar donor by quantifying the levels of modification under different concentrations of the O-GlcNAc labeling probe in a site-specific manner. In addition, we applied isoTCL to compare the O-GlcNAcylation stoichiometry levels of more than 100 modification sites between placenta samples from male and female mice and confirmed site-specifically that female placenta has a higher O-GlcNAcylation than its male counterpart. The isoTCL platform provides a powerful tool for quantitative profiling of O-GlcNAc modification.
O-GlcNAc proteins:
A0A0A6YVU8, A0A1B0GSG7, RBM47, ZN335, A2A8N0, TITIN, SBNO1, CNOT1, PHRF1, ZN462, TAGAP, D3YUK0, E9PUR0, E9PVW1, E9PWI7, PARP4, E9PZS2, E9Q2C0, E9Q3G8, E9Q616, BD1L1, E9Q732, ARHG5, E9Q7N9, E9Q842, E9Q9B4, E9Q9Q2, E9QA22, E9QAE1, F6Y6L6, F8VQ29, F8VQM5, J9JI28, PDLI1, SPT5H, TAF4, ARI1A, ABLM1, KMT2D, MYPT1, ZN609, SET1A, SYNEM, PUR4, TNC18, KDM6A, DPOD2, M3K7, TPD54, SYNJ1, ZN207, SRPK2, ACK1, SYUA, MYPT2, KIF1B, HBP1, OGA, VINEX, PLIN3, MAFK, BRD4, PDLI1, KDM6A, SRPK1, N4BP1, ANR17, NCOR1, CREG1, CRTAP, MYO1A, MTR1L, CREG1, TOX4, SUN1, M3K6, PSMG1, SC24B, CNOT4, ABL1, ABL1, EGFR, LAMC1, LMNA, GLCM, GCR, HSPB1, PPBT, RLA2, ITB1, K1C18, K2C8, SAP, CATL1, LAMB1, ENPL, BGLR, NFIC, VIME, SNRPA, ROA1, ATX1L, TGAP1, GLI2, HLAC, CATB, TAU, BIP, FINC, K2C8, TPR, MSH3, ENPL, PO2F1, ATF2, GNS, ZEP1, RS2, MUC1, JUNB, ATF7, CATD, SON, SERPH, NELFE, BIP, ROA2, CBL, IF4B, APC, ARNT, MAP4, TEAD1, RXRA, RXRB, RXRG, CLIP1, AIMP1, HXA11, ELF1, NU214, MP2K2, VATA, CUX1, PBX2, MLH1, STAT3, SSRB, KI67, STT3A, RFX5, LMNA, DPOD2, PAXI, CDK8, YLPM1, NU153, RBP2, TAF6, EMD, PPT1, FXR1, ICAL, HCFC1, AGFG1, NUP98, ATX1, ATN1, PTN5, AF17, DSRAD, AMRP, ACYP2, NU107, ACOT8, S26A1, TB182, YTHD1, ASXL1, PI5PA, RIN3, MRTFB, RL37, KCNA2, RALA, STIM1, PITX1, IF4G2, SRPK2, RENBP, COG7, WNK1, SERF2, RPTN, SPSY, DAB2, RBM10, HNRPU, SPTB2, FOXK2, EWS, MEF2A, SP2, CO7A1, S30BP, NUCB1, ENL, IF4G1, K1C17, TLE3, TLE4, TOP1, SUH, CBG, ACK1, DEMA, AHNK, FOXO1, TROAP, BPTF, NFIA, ROA0, G3BP1, PABP4, ATM, PICAL, MAMD1, RIPK1, STIM1, MTMR1, CUL4B, ASPP2, KLF5, NFYC, CDK13, VEZF1, DSG2, TRI29, UBP2L, SRC8, PUM1, EPN4, RRP1B, NCOA6, DIP2A, MEF2D, NUMA1, R3HD1, KIF14, EBP, RCN1, KS6A1, RBMS2, TAF1C, NCOA2, SF01, JHD2C, MARE1, ELF2, TAB1, ZFHX3, ZYX, ADRM1, CCDC6, TAF9, STX1A, RFX7, QSER1, QRIC1, PRC2C, PBIP1, GSE1, TNR6A, CEAM5, Q3UKP4, COBL1, ARH40, SC31A, PEG3, SRBS2, Q3UU43, Q3UUE0, F91A1, ARBK2, Q497W2, Q4KL65, PHAR4, EPC2, CRTC2, BCORL, K2026, TGO1, PRC2B, TOIP1, SPG17, SHRM1, ZN362, LRIF1, RHG21, UBAP2, RBM26, RPRD2, ZN318, NCOR1, LAMA5, HCFC1, P3C2A, SAP, AP180, MAFK, SPTB2, SH3G1, ZYX, TSH3, INADL, WAPL, KAZRN, SBNO1, ARID2, DYH17, SAM9L, CDK13, LAR4B, BICRL, RHG21, HELZ, TTLL5, PANX2, PKHG2, NIPBL, LIN54, F135A, RPRD2, IF4G1, SPIC, SCYL2, NFRKB, INT1, ZN182, UGGG1, MDEAS, ZC3HE, RICTR, FIP1, CRTC3, SAS6, MCAF1, BCOR, GGYF2, NU188, CO039, UBN2, HAKAI, ASXL2, SPT6H, DDX46, KDM3B, PICAL, PRC2B, OOG2, ZIC5, NRK, POGZ, MAVS, CLAP1, EMSY, I2BP2, SRGP1, SH3R1, HUWE1, YTHD3, NU214, UBP2L, TMC5B, ZN598, TOPRS, SHAN2, Q80ZX0, ZNF18, Q810G1, BCL9L, LUZP1, PRSR1, DDX42, PALB2, P66A, GNS, LPP, TB10B, TGO1, Q8BIB6, ZN771, ZNT6, AAPK2, CNOT4, SP110, IFFO1, YTHD3, NCBP3, DEFI6, RBM14, CNOT2, CABS1, Q8C6L9, TCAL5, TAB1, SCYL2, ASPP2, PHC3, EPN2, PDLI5, I2BP1, RN135, AHNK2, NAV2, MISP, MGAP, ANKH1, PHAR4, XRN1, PELP1, Q8JZK6, Q8K0U8, AGFG1, TXD11, IL23R, ARHG6, SPART, SPICE, NUP93, CLASR, ZN786, SYNPO, FNBP4, ARFG1, ENAH, TNR6A, PHC3, SP20H, NAV1, VP37A, KMT2C, BD1L1, NUP35, STXB6, KNL1, TCAL3, MTSS1, SPART, NUP35, PUM2, STT3B, ALMS1, GEMI5, WIPF2, MAVS, UTP6, PI3R4, AMOT, P66B, STAG1, PCNP, LMO7, ATX2L, CSKI2, P66B, BBX, TITIN, HNMT, UBAP2, DCP1A, NRIF1, SMG7, RTF1, MAML1, ZN592, LAR4B, TAF4B, SHIP1, DDX17, RENT1, GPKOW, FUBP2, LPP, TTC28, PF21A, INT12, RCN3, CERS2, PDLI5, FUBP3, MY15B, ANCHR, CLP1L, Z512B, ZFR, EP400, NOL4L, RBM14, CIC, MED15, PIGS, DCR1C, SIN3A, MINT, EYA3, TEAD3, ATX2, RFC4, DHX58, ANX13, GORS2, TAB2, EPN4, ANR17, DPH2, WAC, DIDO1, YTHD1, AMRA1, TANC1, TXD12, F133B, RBM33, GPI8, Q9D2U0, ZC21B, FUND2, F162A, APMAP, Q9D809, FIP1, CNPY3, Q9DAV5, Q9DB24, ALG2, PLIN3, MYPT1, WWTR1, Q9EQC8, SALL1, RBP2, GILT, MFF, SP130, APC1, I2BPL, RBNS5, EPC1, ADNP, ZN106, TM245, CPVL, PTN23, WNK1, E41L1, ZHX3, ZN335, PKHG2, CCSE2, CQ10B, MLXIP, PKHA5, RC3H2, TAF9B, ZBT20, NCOA5, ZN532, APMAP, HYOU1, ADRM1, GIT2, BAG3, UBN1, PDLI7, DIAP3, RBM12, CARF, ETAA1, HXC10, TAB2, UGGG1, CDK12, ITSN2, CNOT2, TMEM9, DAPLE, NYAP2, KANL3, SON, LIMD1, KI21B, KI21A, PPIE, PCM1, GALK1, MRP5, SE1L1, LIMD1, TCF20, SUN2, AFF4, UBQL2, S30BP, NRBP, SIX4, TASOR, GMEB2, PARP4, NUP50, ZHX1, YETS2, HECD1, SCAF8, SRRM2, SCML2, S22AL, NCOR2, DEMA, POLH, R3HD2, ZN281, FBX7, RPGF2, IRS2, HYOU1, PRC2C, NCOR2, GMEB1, S23IP, SRPK3, Q9Z0I7, VNN1, KLK4, SE1L1, RGS6, E41L1
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Chuh KN, Batt AR, Zaro BW, Darabedian N, Marotta NP, Brennan CK, Amirhekmat A, Pratt MR. The New Chemical Reporter 6-Alkynyl-6-deoxy-GlcNAc Reveals O-GlcNAc Modification of the Apoptotic Caspases That Can Block the Cleavage/Activation of Caspase-8. Journal of the American Chemical Society 2017 139(23) 28528544
Abstract:
O-GlcNAc modification (O-GlcNAcylation) is required for survival in mammalian cells. Genetic and biochemical experiments have found that increased modification inhibits apoptosis in tissues and cell culture and that lowering O-GlcNAcylation induces cell death. However, the molecular mechanisms by which O-GlcNAcylation might inhibit apoptosis are still being elucidated. Here, we first synthesize a new metabolic chemical reporter, 6-Alkynyl-6-deoxy-GlcNAc (6AlkGlcNAc), for the identification of O-GlcNAc-modified proteins. Subsequent characterization of 6AlkGlcNAc shows that this probe is selectively incorporated into O-GlcNAcylated proteins over cell-surface glycoproteins. Using this probe, we discover that the apoptotic caspases are O-GlcNAcylated, which we confirmed using other techniques, raising the possibility that the modification affects their biochemistry. We then demonstrate that changes in the global levels of O-GlcNAcylation result in a converse change in the kinetics of caspase-8 activation during apoptosis. Finally, we show that caspase-8 is modified at residues that can block its cleavage/activation. Our results provide the first evidence that the caspases may be directly affected by O-GlcNAcylation as a potential antiapoptotic mechanism.
O-GlcNAc proteins:
A2A4A6, A2A5R8, GPTC8, SPD2B, A2ACG7, A2AFQ9, A2AFW6, A2AG46, CKAP5, A2AH75, A2AJ72, MA7D1, A2AL12, A2AMW0, A2AMY5, TPX2, PPIG, LAS1L, A5A4Y9, A6PWC3, A6PWK7, UBP36, B1AT03, B1AT82, B1AU75, B2RQG2, OTUD4, B7ZCP4, B7ZP47, D3YUW8, D3YWF6, D3YWK1, D3YX62, SAFB1, D3YXM7, D3YZ06, D3YZP6, D3Z069, D3Z158, D3Z3F8, D3Z6W2, E0CYM1, E9PUH7, E9PVM7, E9PWG6, E9PWV3, E9PWW9, E9PY48, E9PYT3, E9PZM7, E9Q066, E9Q2X6, E9Q3G8, E9Q450, E9Q4K7, E9Q4Q2, KIF23, BD1L1, NUMA1, E9Q7M2, E9Q986, E9Q9E1, E9Q9H2, E9QKG3, E9QKG6, E9QKZ2, E9QLA5, E9QP49, E9QP59, E9QPI5, F2Z3X7, F6S5I0, F7AA26, F7BQE4, FARP1, F8VQ93, F8VQC7, F8VQE9, F8VQK5, F8WI30, G3UZ44, G3UZX6, G3X8R0, G3X8Y3, G3X928, G3X963, G3X972, G3X9V0, G5E896, G5E8E1, H3BJU7, H3BK31, H3BKK2, H7BX26, I1E4X0, I7HIK9, J3QNW0, DPYL2, GTPB1, AKAP1, TCOF, AIP, HDAC1, RL21, GSH0, KIF1C, DHX15, SC6A6, IF6, ILK, ATX2, NMT1, E41L2, DHB12, SRPK1, ZN326, ZFR, PARG, SPD2A, SP1, CASP8, HPRT, LDHA, G6PI, TYSY, RIR1, GNAI2, ITB1, 4F2, H2B1F, MAP1B, HMOX1, LEG1, G3P, KS6A3, COF1, GNAO, IFRD1, VIME, TPM3, UBL4A, CBX3, CXA1, CATA, IMDH2, IL1RA, MCM3, CDK4, NKTR, FKBP4, CBX2, HMGB2, AIMP1, KAP3, MP2K1, SYWC, KIF4, NEDD1, DPOLA, RANG, UBP4, PTN11, RAB18, PTN1, PTN12, LDLR, DNLI1, CAP1, STAT3, STA5B, PURA, ALD2, RAGP1, NEDD4, STT3A, ALDH2, GSHR, GFPT1, PCY1A, MCM4, ICAL, PLCB3, CDN2A, HDGF, UBP10, KPYM, CCHL, IDHP, DDX6, GOGA3, COX17, ACTN4, GCP3, TB182, EIF3E, ABCE1, PFD3, HNRPK, 1433E, RAP1A, RS25, TCTP, DNJA1, HMGB1, IF5A1, RS17, RS12, UB2L3, HXD13, HDAC2, ELAV1, TP53B, CASP3, PYRG1, TCPB, STIM2, SRSF3, CSRP2, SPTC2, BOP1, SMAD4, M4K4, HNRL2, MARK3, LARP7, CNN2, PP4R2, PEPD, CDCA2, Q3TFP0, GUAA, PDE12, Q3TL72, PRC2C, NOL9, FUBP2, TRADD, CTU2, ZN865, Q3U4W8, Q3UG37, NAT9, NOL8, Q3UJQ9, SC31A, NCBP1, LRRF1, DDX17, LRC47, JIP4, EHMT1, CA050, AAPK1, NSRP1, Q5RL57, Q5SQB0, TENS3, PUR4, Q5UE59, SRC8, SAMH1, KHDR1, GRB10, HELLS, SPB6, RIPK1, CAPR1, ASNS, LAP2A, CDC37, TS101, SNTB2, FNTA, BAP31, PLPP1, FSCN1, FXR1, DDX5, ATRX, HS105, DDX3Y, DDX3X, TGFI1, DBNL, SH3G1, CYTB, SMAD2, NDRG1, ZYX, SQSTM, TPP2, ZN512, LAR4B, F120A, CNDG2, NOP58, LTV1, Q6NV52, Q6NXL1, Q6NZD2, ANKL2, Q6P5B5, XPO1, KIF15, FHOD1, TXLNA, PTN23, JUPI2, NUDC1, TACC1, UBE2O, LARP1, ACAP2, 2AAA, MTCH2, ZN503, CYFP1, HNRPQ, SPAG7, DEK, ACTN1, ATX2L, CKP2L, ZN516, ERBIN, SEPT9, PGRC2, Q80VB6, UBP2L, PI42B, ZN598, SAFB2, Q80ZX0, DLG1, LPP, PEF1, IF4B, Q8BGJ5, FTO, TIPRL, Q8BH80, MISSL, ERC6L, CARF, PRUN1, NUP93, FBX30, HBAP1, AHSA1, RCC2, IPO5, SYLC, CKAP4, MAP11, PALM2, CPNE3, SENP7, CSN7B, NSD2, DPP9, Q8BWW3, KANK2, PXK, PIGT, ITPK1, NHLC2, MAP1S, GWL, PKHH2, CND2, THOP1, SEP11, SKA3, CA198, SEP10, AROS, UBA6, LIPB1, SMAG1, Q8CCM0, ZN276, NAA30, SNX8, SYEP, OGT1, GNL3, PDLI5, FERM2, AGO2, HMCS1, AMERL, SCNM1, DNM1L, NEK9, ANLN, EDC3, MATR3, CHAP1, MEPCE, ERF3A, CC137, TDIF2, VPS18, RFC3, MCMBP, HEXI1, LUZP1, SNP47, TMX1, MAVS, UBXN4, Q8VCQ8, ACSF2, PARN, VIGLN, PSMD2, NAA40, F1142, CBWD1, PAXI, SFPQ, CPIN1, RAB14, IPYR2, PUS7, CSDE1, PIP30, RABE2, CISD1, Q91X76, DUS3L, KCC1A, TTC1, SRGP2, SNX18, RISC, HNRLL, Q921K2, PP6R3, LRC59, UBXN1, DBR1, KCC2G, Q924B0, WAC, SMC6, PAWR, SIAS, STML2, PSIP1, NXF1, PDXD1, NONO, PLST, RRAGC, VMA5A, MAOM, DCTN2, ZN281, CT2NL, GRPE1, ABD12, RTN4, NU155, OGFR, NPM3, NOP16, GLOD4, Q9CQ43, MTAP, IFM3, CYB5B, PAF15, PSMD9, WIPI3, SKA2, VATG1, CHSP1, LRC40, RANB3, SMC1A, MFR1L, ARHGP, DDX47, TBC15, PPIL4, MPPB, CYBP, TECR, PAIRB, ZCHC8, SPCS2, Q9CZP3, CD37L, SSBP3, MMS19, MGRN1, ARPIN, HNRPM, SYRC, MCES, Q9D4G5, ATAD1, F162A, TRIR, IPYR, PHF10, ARFG3, ORN, BOLA1, CNN3, KAP0, PLIN3, AKAP8, XRN2, GNAI3, PUR6, RAI14, SENP3, ARFG1, SIL1, VPS35, DGCR8, SYCC, ELP4, LIMA1, XPO2, RBP2, RTN3, PALLD, TMOD3, STK3, COPB, NUP50, DDX21, SH3L1, DDX20, MBNL1, BAG3, GKAP1, ZN207, TRXR1, PPCE, CAF1A, LIMD1, NDRG3, DNJC7, NFU1, COPG1, NUBP1, SMAP, DEST, ACOT9, PR40A, FOXO1, FIZ1, NFKB2, KAD2, AKA12, PRKRA, PDC6I, CHIP, COR1C, VAPA, NDKM, E41L3, TAGL2, CARM1, MTNB, BCL10, IF2G, P5CS, COG1, MD2L1, EIF3G, SAE2, ILF3, TRIP6, USO1, BAZ1B, HNRPF, KEAP1
Species: Mus musculus
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Alfaro JF, Gong CX, Monroe ME, Aldrich JT, Clauss TR, Purvine SO, Wang Z, Camp DG 2nd, Shabanowitz J, Stanley P, Hart GW, Hunt DF, Yang F, Smith RD. Tandem mass spectrometry identifies many mouse brain O-GlcNAcylated proteins including EGF domain-specific O-GlcNAc transferase targets. Proceedings of the National Academy of Sciences of the United States of America 2012 109(19) 22517741
Abstract:
O-linked N-acetylglucosamine (O-GlcNAc) is a reversible posttranslational modification of Ser and Thr residues on cytosolic and nuclear proteins of higher eukaryotes catalyzed by O-GlcNAc transferase (OGT). O-GlcNAc has recently been found on Notch1 extracellular domain catalyzed by EGF domain-specific OGT. Aberrant O-GlcNAc modification of brain proteins has been linked to Alzheimer's disease (AD). However, understanding specific functions of O-GlcNAcylation in AD has been impeded by the difficulty in characterization of O-GlcNAc sites on proteins. In this study, we modified a chemical/enzymatic photochemical cleavage approach for enriching O-GlcNAcylated peptides in samples containing ∼100 μg of tryptic peptides from mouse cerebrocortical brain tissue. A total of 274 O-GlcNAcylated proteins were identified. Of these, 168 were not previously known to be modified by O-GlcNAc. Overall, 458 O-GlcNAc sites in 195 proteins were identified. Many of the modified residues are either known phosphorylation sites or located proximal to known phosphorylation sites. These findings support the proposed regulatory cross-talk between O-GlcNAcylation and phosphorylation. This study produced the most comprehensive O-GlcNAc proteome of mammalian brain tissue with both protein identification and O-GlcNAc site assignment. Interestingly, we observed O-β-GlcNAc on EGF-like repeats in the extracellular domains of five membrane proteins, expanding the evidence for extracellular O-GlcNAcylation by the EGF domain-specific OGT. We also report a GlcNAc-β-1,3-Fuc-α-1-O-Thr modification on the EGF-like repeat of the versican core protein, a proposed substrate of Fringe β-1,3-N-acetylglucosaminyltransferases.