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Hao Y, Li Z, Du X, Xie Q, Li D, Lei S, Guo Y. Characterization and chemoproteomic profiling of protein O-GlcNAcylation in SOD1-G93A mouse model. Molecular medicine (Cambridge, Mass.) 2025 31(1) 40021952
Abstract:
Amyotrophic lateral sclerosis (ALS) is a devastating motor neuron disease. Protein O-linked β-N-acetylglucosamine (O-GlcNAc) modification has been found to affect the processing of several important proteins implicated in ALS. However, the overall level and cellular localization of O-GlcNAc during ALS progression are incompletely understood, and large-scale profiling of O-GlcNAcylation sites in this context remains unexplored.
O-GlcNAc proteins:
TANC2, ZEP3, MA7D2, AMRA1, AJM1, CNTRL, SKT, TITIN, ARI1A, S14L1, KI16B, TM245, RHG42, CTTB2, SAFB1, CCDC6, SHAN1, CE350, SYGP1, TPR, DPYL2, EMD, SYPL1, M3K5, PPE2, VIAAT, CTND2, LIMK2, ACK1, SYUA, ATX2, PDLI1, ZN106, DC1I1, PLIN4, ZFR, HCN2, BSN, SYN1, CO4B, MBP, ARAF, ALDOA, GCR, CATL1, NFL, NFM, RC3H2, NCAM1, HSPB1, MAP1B, G3P, NFH, VIME, MTAP2, MOV10, CRYAB, KCC2B, PABP1, AIMP1, KIF4, FOXK1, STAT3, EAA2, AINX, SOX2, LMNA, INPP, RORG, APC1, ATX1, PCBP3, KCNN2, GCP3, TB182, KCNH8, NPHP4, YTHD1, PI5PA, MRTFB, DOCK4, RUVB1, ABI2, RS3, KCNA2, ZHX1, TRAF5, SURF6, NCOA1, RGRF2, LYAG, IRS2, GBX1, TNIK, WNK1, CSRP1, G3BP2, RLA2, CTNB1, PLAK, S30BP, NFIA, ENAH, EMAL1, CNN2, CDK12, MA6D1, M3K13, PSD3, PLBL2, PRC2C, MILK2, YETS2, PBIP1, TPPC9, FUBP2, WNK2, LIMC1, TNR6C, ZEP2, AAK1, TNR6A, CAMKV, MINY4, GRM5, ARMX5, N42L1, PACS2, ABL2, OXR1, UN13A, HERC2, PHAR4, SRRM1, TR150, LIN54, TAB3, ZBTB4, UNKL, RBM27, TM1L2, MYO1G, ANR40, SYNRG, NACAD, A1CF, LAMA2, PMEL, NCOR1, LAMA5, BCAR1, HCFC1, MRE11, PACN1, MAFK, MCM7, PTN14, SPTB2, TAF6, SRBS1, DBNL, SH3G1, TLE4, IF4G2, MINT, ZYX, OMGP, HECAM, NR2E1, SF01, SYN2, GPDM, PLK4, SBNO1, SLAI1, PKP4, SYMC, SAM9L, SH3R1, HECD1, ABLM3, ARMX2, CE170, CDC5L, LAR4B, RHG20, F135A, SPKAP, SR140, KIF24, RPRD2, WWC2, REXO4, PTN23, IQCE, TRAK1, RN220, ERC2, NFRKB, MAGI1, TEX2, PF21A, CNOT1, NU188, TRPV1, SC6A5, PICAL, SMAP2, CPEB3, PLPR3, MYCB2, PRC2B, TPPP, ATX2L, CCNT2, MAP6, SI1L2, ERBIN, R3HD2, AUXI, RERE, SNPH, RIMB2, NU214, INT2, SDA1, EPN1, AGFG2, UBP2L, C2C2L, NRAP, DDHD1, BCAS1, ZN598, CTIP, SHAN2, MACA1, ANR26, MAST4, RHG32, LPP, MYPT2, IF4B, ZN750, WDR48, TB10B, CSTP1, SP130, ZC21A, ZNT6, SUN2, RCC2, ABLM2, HSP13, EMSY, CLAP2, CNOT4, SRRM2, IKZF5, TOX4, GEPH, DIP2A, LARP4, IFFO1, OSBL6, YTHD3, POGZ, ZHX2, TT21A, SI1L1, RBM14, UBP44, CNOT2, HYCC2, ANK2, DIDO1, PARP9, SYNPO, VCIP1, MB214, TAB1, RPB2, ASPP2, F193A, NAV1, SYNJ1, RPGF2, EP400, PHC3, VP37A, EPN2, PDLI5, CSR2B, FBP1L, SCAM1, ZBT20, HS12A, AGFG1, MATR3, FANCI, PO121, MRTFA, MTSS1, SPART, PPR42, NUP58, RFIP5, BRD8, PP6R2, CS047, LUZP1, RBM12, SC6A8, MAVS, MICA1, SIR2, AMOT, AGAP3, P66B, CCG8, TAF9, WDR13, UBAP2, NCOA5, PEX16, DCP1A, YTHD2, BMP2K, DYST, LRP1, SYUB, ALS2, BICD2, CLIP1, CIC, S12A6, NRBP, RP25L, TAB2, DDAH2, HGS, TM2D1, SNCAP, ASH1L, ANR17, RTN4, RRBP1, NUDC2, TPPP3, FLIP1, DDAH1, DLGP1, FIP1, TM263, CNN3, AL7A1, PLIN3, MYPT1, NDUBA, CRIP2, TSC1, NBEA, INP4A, RIMS2, SO1C1, RBP2, MKRN2, RTN3, NUDT3, LGI1, TULP4, ADRM1, FMN2, GIT2, BAG3, ZN207, ASAP1, SON, TBL1X, PLEC, MACF1, NPHP1, VAPB, ADDA, GOGA5, MAP1A, QKI, PCLO, GAB1, FBX6, FOXO1, ADA23, AKA12, NCOR2, C8AP2, TNIP1, DEMA, E41L3, SYUG, ITSN2, ZO2, ADNP, NEK4, APCL, MTMR1, MECP2, E41L1
Species: Mus musculus
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Burt RA, Dejanovic B, Peckham HJ, Lee KA, Li X, Ounadjela JR, Rao A, Malaker SA, Carr SA, Myers SA. Novel Antibodies for the Simple and Efficient Enrichment of Native O-GlcNAc Modified Peptides. Molecular & cellular proteomics : MCP 2021 20 34678516
Abstract:
Antibodies against posttranslational modifications (PTMs) such as lysine acetylation, ubiquitin remnants, or phosphotyrosine have resulted in significant advances in our understanding of the fundamental roles of these PTMs in biology. However, the roles of a number of PTMs remain largely unexplored due to the lack of robust enrichment reagents. The addition of N-acetylglucosamine to serine and threonine residues (O-GlcNAc) by the O-GlcNAc transferase (OGT) is a PTM implicated in numerous biological processes and disease states but with limited techniques for its study. Here, we evaluate a new mixture of anti-O-GlcNAc monoclonal antibodies for the immunoprecipitation of native O-GlcNAcylated peptides from cells and tissues. The anti-O-GlcNAc antibodies display good sensitivity and high specificity toward O-GlcNAc-modified peptides and do not recognize O-GalNAc or GlcNAc in extended glycans. Applying this antibody-based enrichment strategy to synaptosomes from mouse brain tissue samples, we identified over 1300 unique O-GlcNAc-modified peptides and over 1000 sites using just a fraction of sample preparation and instrument time required in other landmark investigations of O-GlcNAcylation. Our rapid and robust method greatly simplifies the analysis of O-GlcNAc signaling and will help to elucidate the role of this challenging PTM in health and disease.
O-GlcNAc proteins:
IQIP1, A0A0A6YWG7, A0A0G2JF55, A0A0N4SW93, A0A0R4J060, A0A0U1RPL0, A0A140LIW3, A0A140T8K9, A0A1B0GS41, A0A1B0GS91, A0A1D5RMI8, A0A1L1M1J8, A0A1L1SR84, A0A1N9NPH8, A0A1Y7VNZ6, A0A286YDB3, A0JNY3, A2A482, A2A654, TANC2, LZTS3, AJM1, BCORL, A2AUD5, A2AWN8, B1ASA5, B1ATC3, B1AUX2, B2RQL0, CSPP1, B2RY58, B7ZNA5, CTTB2, D3YU22, D3YUV1, D3YWX2, D3YZ21, SHAN1, D3Z5K8, E0CXZ9, E9PUL3, PRRT2, E9PUR0, E9PV26, E9PVY8, SET1A, E9Q0N0, E9Q3E2, E9Q3G8, E9Q4K0, ARI1B, SETD2, E9Q6H8, E9Q6L9, E9Q828, E9Q9C0, E9Q9Y4, E9QAQ7, E9QAU4, E9QAU9, E9QKI2, E9QLZ9, E9QM77, F2Z3U3, F6RQA2, SYGP1, F7C376, BICRA, F8VQL9, F8WIS9, G3UZM1, G3X8R8, G3X928, RFIP2, H3BKF3, H3BKP8, H9KV00, J3QNT7, DPYL2, PRDX6, MNT, NUMBL, PEX5, BMPR2, CTND2, PITM1, ACK1, CAC1B, SYUA, DSG2, SPT5H, E41L2, SP3, KDM6A, CPNS1, ZFR, HCN1, CTBP1, BSN, STAM2, SYN1, MBP, EGR1, NFL, NFM, ITB1, RC3H2, ATX1L, RL7A, MAP1B, VIME, EIF3A, RGRF1, PABP1, FOXK1, EAA2, CBP, RFX1, SOX2, KPYM, CTBP2, GCP3, TB182, GMEB2, PI5PA, DOCK4, PCBP1, LIPA3, RS3, PAX6, KCNJ3, PP2BA, TBA4A, STAM1, NCOA1, CXB6, WNK1, PSME2, WBP2, SHPS1, NRSN1, CTNB1, PLAK, S30BP, NFIA, ZEP1, YES, CAPR2, MITF, GRD2I, Q0VF59, HDX, MA6D1, F171B, ZFHX2, MLXIP, PDLI7, PRC2C, CIART, YETS2, SRBP2, Q3U2K8, GSE1, RREB1, WNK2, DAB2P, ZEP2, AAK1, TNR6A, GRIN1, SRBS2, GRM5, Q3UZG4, RBM44, Q3ZB57, PHAR4, RESF1, Q5EBP8, UNKL, VP13A, COBL, KDM6B, PRSR1, Q5RIM6, SMG7, RBM27, TM1L2, Q5SVJ0, Q5SXC4, SIN3A, GAS7, CAPR1, KLF3, SIX4, AP180, GRID2, PACN1, LASP1, RAI1, NOTC3, SALL3, SPTB2, ARI3A, NUP62, PHC1, TFE3, PAN3, TIF1A, SF01, SYN2, SBNO1, CRTC1, RIPR1, GIT1, PKP4, ABLM3, ARMX2, CE170, Q6AXD2, NIPBL, FBX41, RPRD2, WWC2, Q6P1J1, Q6P5E3, UGGG1, SPRE3, Q6P9N8, AHDC1, PTN23, TRAK1, DLGP3, NYAP1, DHX29, NFRKB, MAGI1, Q6XZL8, CNOT1, SYNE2, IF2A, PICAL, PLPR4, PLPR3, CCNT2, PRC2A, MAP6, MCAF1, RERE, NU214, SESD1, UBP2L, C2C2L, CNKR2, SLIK5, RHG32, LPP, NELFA, C42S2, TB10B, TGO1, RFOX3, SP130, ANS1B, ZC3HE, ZC21A, BAIP2, EMSY, KAT6B, RELL2, LIPA2, CNOT4, TOX4, GASP2, CREST, KDM4A, GRIN3, KAT6A, ZN609, PAK5, A16L1, SI1L1, SH3R3, SKA3, RBM14, Q8C5J0, CNOT2, WDR26, UBA6, ANK2, DIDO1, SYNPO, VCIP1, FHI2A, NUP88, NED4L, SET1B, TENS2, OGT1, NAV1, STAU2, AFG32, S4A8, ZBT20, HS12A, GLT18, UNC5A, AGFG1, FRRS1, KCNQ3, PO121, T2FB, MTSS1, Q8R2E1, NUP35, MAVS, SGIP1, HNRL1, PP16B, CCG8, SFPQ, UBAP2, NCOA5, AJUBA, DCP1A, TWF1, ALS2, ETFD, CIC, GRIP1, GORS2, NONO, ZN281, CT2NL, RN111, ANR17, PPP6, RBM7, CYGB, SARNP, DLGP1, SUN1, TM263, GON4L, PLIN3, MYPT1, NBEA, ZN704, RBP2, ARHG7, RTN3, NUDT3, TULP4, Q9JIZ5, PAR6G, SCAM5, PRG4, ZN207, SRCN1, ASAP1, DREB, ULK2, ADDA, PCLO, UBQL2, FBX6, PCM1, SYT7, CRY2, FOXO1, MAST1, LYPA2, TEN3, GANP, DEMA, E41L3, ZO2, BAG6, E41L1, RM40, GRIA3, S4R294, V9GWU7, V9GX40
Species: Mus musculus
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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, HYCC2, 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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Lee BE, Kim HY, Kim HJ, Jeong H, Kim BG, Lee HE, Lee J, Kim HB, Lee SE, Yang YR, Yi EC, Hanover JA, Myung K, Suh PG, Kwon T, Kim JI. O-GlcNAcylation regulates dopamine neuron function, survival and degeneration in Parkinson disease. Brain : a journal of neurology 2020 143(12) 33300544
Abstract:
The dopamine system in the midbrain is essential for volitional movement, action selection, and reward-related learning. Despite its versatile roles, it contains only a small set of neurons in the brainstem. These dopamine neurons are especially susceptible to Parkinson's disease and prematurely degenerate in the course of disease progression, while the discovery of new therapeutic interventions has been disappointingly unsuccessful. Here, we show that O-GlcNAcylation, an essential post-translational modification in various types of cells, is critical for the physiological function and survival of dopamine neurons. Bidirectional modulation of O-GlcNAcylation importantly regulates dopamine neurons at the molecular, synaptic, cellular, and behavioural levels. Remarkably, genetic and pharmacological upregulation of O-GlcNAcylation mitigates neurodegeneration, synaptic impairments, and motor deficits in an animal model of Parkinson's disease. These findings provide insights into the functional importance of O-GlcNAcylation in the dopamine system, which may be utilized to protect dopamine neurons against Parkinson's disease pathology.
O-GlcNAc proteins:
BIG2, F1712, VIR, AJM1, RPGP1, UBR4, SCN1A, AGRIN, KALRN, STPG3, FXL16, TT23L, PTPRS, GRIK3, SCN2A, DLGP4, OSBL8, PTPRZ, PGBD5, GLSK, GCN1, CE350, PI4KA, RYR2, AGRF2, UBE4A, NRX2A, FRY, SYGP1, OTOGL, AT2B1, ANK3, CA2D1, DPYL2, STXB1, DCTN1, U5S1, GFRA2, GALT1, SEM4D, KIF3C, PLCA, PHB2, NCAM2, GRAK, PURB, IMA3, IMA7, PLD3, FOLH1, FKBP8, STX1A, PSDE, VIAAT, AP1B1, C1QBP, SYT3, HNRH1, SATT, CTND2, SDC4, AP3D1, RGS9, RGS7, CSK22, OX2G, AAKG1, CRYM, PROM1, CNTP1, ENTP2, BCKD, SNG1, NIPS1, NIPS2, SEPT7, AT2A2, PI51C, PI42A, ITB5, GPX4, NPTX2, GNAZ, WDR1, S4A4, MTX2, CNTFR, ZFR, CSN3, HCN2, HCN1, CTBP1, BSN, MPP3, NOE1, CBPD, LGMN, COR1A, CYB, COX1, COX2, COX3, HPRT, ATP6, THY1, H3C, LAMC1, NU1M, NU2M, NU4M, NU5M, ATP8, GFAP, MBP, PRIO, ALDOA, KAPCA, AATM, TBA1B, TBA3, KIT, LDHA, G6PI, MDR1B, ENPP1, HS90A, ENPL, KCC4, NFL, NFM, RASN, PGK2, ITB1, PPBT, NUCL, PGK1, ACE, LRC4B, UBB, UBC, EF1A1, IF4A2, GSTM1, 4F2, H10, LAMP1, HS90B, L1CAM, ITA5, KCC2A, ITB2, ITPR1, TCPA, PFKAL, CNTN1, NCAM1, AT1B1, C1QB, RS16, RL7, AT1B2, PSMD3, MAP1B, GLNA, CADH2, INSR, NTRK2, KCNC1, SPTB1, H12, KPCE, LDHB, CN37, DDX3L, KCNA1, KCNA3, AMPE, ASSY, SPTN1, G3P, LAMP2, ENOA, AP2A1, AP2A2, HXK1, GTR1, PTPRA, COF1, GNAO, FAS, LAMA1, NFH, COX41, BIP, HEXB, VIME, MTAP2, MAG, GNA11, GNAQ, MDR1A, ACES, GBRG2, AP1G1, GBRD, EIF3A, CXA1, GRIA1, GRIA2, TY3H, RS2, GBRA2, RL3, BRAF, KCC2B, NP1L1, NCKP1, SNAB, KIF3A, PABP1, GBB4, KCRU, GNA14, KAP3, SC6A1, S6A11, MP2K1, GTR3, LA, RASK, SYWC, KIF1A, HYES, RAB3D, RAB5C, RAB6A, RAB21, NMDZ1, ODPA, RET, FBRL, KCNJ2, CD81, GPM6A, GPM6B, GNL1, DYN1, DYN2, GRIK2, CAP1, ABCA2, PURA, HD, EAA2, H14, H15, H13, ITAV, SYT1, NSF, RB11B, AINX, MYO1B, NEDD4, ALDH2, GRM8, CAZA2, CAPZB, MP2K4, PFKAM, RL6, RL29, RL5, GLRB, DCE1, DCE2, CBR1, GSTM5, ADT1, INPP, CDK5, SAHH, GDIA, VATA, VATE1, GBRB1, RAB7A, ACADL, VA0D1, ADT2, EAA3, KCNJ4, KPYM, RAB2A, PRS6B, PTN5, NCAN, ABCD3, RAB8A, ATPK, ATP5E, UBP5, ATPB, CTBP2, EAA1, WFS1, FUS, NICA, ACTN4, ASM3B, EF2, OPA1, DOCK4, IRPL1, ARPC4, MYPR, PLPP, ACTB, MDGA2, NEUG, RAC3, IF4A1, MEGF8, RAB5B, RAB10, RAB8B, ARP2, ACTZ, CSN2, ARF3, ARL1, CAH10, RAP2B, STX1B, RAB6B, RL27, ARF4, GABT, 1433G, RS7, PP1A, RS8, SMD1, KCAB2, ABI2, RB11A, EF1A2, RS4X, PP2AB, RL18A, ACTA, AP2S1, RL23A, VISL1, H4, GBRA1, VATB2, RAB1A, RAB3C, RAN, RAP1A, RS24, GBB1, GBB2, RS3, RL8, RS27A, RL40, RAC1, RAB3A, HSP7C, CH60, VAMP2, NOE3, GBRB3, VATL, PP1G, 1433Z, GBRB2, KCNA2, KCAB1, CRNL1, DYL1, ACTG, ACTH, KPCG, PP2BA, PP2AA, PHB1, CSK2B, ACTC, RACK1, ACTS, KAPCB, TBA4A, TBA1A, TBB4B, KPCB, H31, IMB1, PLXA1, PLXA2, PLXA3, DCC, ITPR3, NCHL1, HNRH2, ELAV1, USP9X, IDHG1, LYAG, AT8A1, TCPH, TCPB, TCPD, TCPE, TCPZ, TCPG, TNIK, WNK1, RL36A, ARF1, ARF5, AP2M1, H32, H33, ADCY5, NPTN, RS3A, AT1B3, DPYL1, ZNT3, GRM1, SHPS1, NEO1, M4K4, C1QA, TBB5, PDE4D, PDE1B, NMDE2, SC23A, TERA, C1QC, CTNB1, PLAK, EPHA4, MARK3, ATPA, CHLE, KCND1, KCRB, NF1, CDK18, RAC2, MARK2, PGBM, PTPRG, PYC, KCMA1, PADI2, INF2, TRIO, MDGA1, CTP5A, ITB8, PSA, GRM2, PTCD3, PHAR1, LRFN1, SPP2B, HP1B3, NLRX1, PRC2C, TM38A, VGLU1, BIG3, PLXD1, AGAP2, AAK1, TEN4, CAMKV, DOP2, RMD3, SMU1, MCCB, GPD1L, LIGO2, SRBS2, CDKL5, K22O, VPS51, GRM5, CBAR2, SHAN3, UN13A, SE6L2, KCTD8, KCD16, LRC8B, VP13A, C2C4C, S2551, MRS2, DIRA2, CYFP2, TM1L2, RHG44, MYO1D, RABL6, DJC11, UIMC1, ICAM5, FLOT2, HNRPD, PTPRN, CSK21, KHDR1, IGF1R, CLD11, SPB6, ARHG2, VDAC2, VDAC3, VDAC1, ABCB7, ASTN1, P3C2A, CAC1E, LAMB2, CTNA2, SC6A3, CNTN2, PGCB, NEP, KCNA4, CD166, 5NTD, GSLG1, EWS, AP180, FSCN1, GDIB, GRIK5, GRID1, DDX5, ITIH3, IL1AP, CD47, KINH, KIF3B, LASP1, MYH10, MOG, NPM, PCBP2, CSPG2, DDX3Y, DLG4, RHOC, DAG1, DDX3X, SYPH, TICN1, NDUA4, NPTX1, NUP62, OMGP, HECAM, AOFA, ARP3B, SURF4, SYN2, CP3AD, H2B1H, GLPK, SDC3, GPDM, H2A2C, H2B2B, GRM7, GRM4, CLH1, K1549, GIT1, PKP4, PPR29, CNTN4, NLGN2, SV2C, THS7A, CE170, UBP7, BRNP2, SCMC3, LIGO3, DGKB, RPRD2, DPP10, S23IP, PPRC1, 2ABA, TNPO3, SIK3, U520, S39AA, TTYH3, XPO1, SPCS, KCRS, CSKI1, NRX3A, BCR, SARM1, PRRT3, TEFF1, RAB35, CA2D2, KCC2D, AT1A3, AT1A2, GNAS1, SDK2, WDFY3, NTRK3, RAD9B, DGLA, KCD12, MTMR5, UBE2O, CAND1, UBP34, RS9, 2ABB, H2B1C, TLN2, CSPG5, 2AAA, NP1L4, MTCH2, OPALI, CYFP1, TBB2A, HUWE1, IGS21, ROBO2, ACTN1, IGSF1, TR143, TPPP, OTUB1, KPBB, PP6R1, MAP6, ELP1, RRAGD, MRCKB, GABR2, CSMD3, EPT1, VAT1L, LRRC7, CAPS1, CYLD, AGRL1, AGRL3, CLAP1, AUXI, DAAM2, MADD, MFN2, NU214, UBE3C, PLXA4, FBX2, KCMF1, CBPM, GSTM7, AGFG2, LRC8A, HPLN4, VAC14, UBP2L, C2C2L, LRRT4, BDH, MK15, CNKR2, TENA, ASTN2, NEGR1, RAP2A, THEM6, SLIK5, SLIK4, SLIK3, SLIK2, NFASC, NRCAM, RHG32, SRGP3, EFTU, VGLU3, ERLN2, SV2B, MIRO1, EFR3A, LRRT2, U2AF4, ENPP6, SYAC, FLRT3, CBLN2, LRTM2, HPCL4, COR2B, S2512, ATLA1, NU107, RB39B, RB39A, ZN526, ANS1B, DLGP2, AHSA1, IPO5, NCEH1, LSAMP, CADM2, NOE2, ODP2, RBGPR, ECHA, SPA2L, SYNC, RL24, DAAM1, DMXL2, RLGPB, CLAP2, VMAT2, ARF2, NDRG4, ENPP4, HSDL1, RAP2C, GEPH, VATH, PMGT2, TTC12, AOFB, LRFN5, PIGT, CTL2, TENR, NLGN3, LRRT3, DYN3, LRC4C, ARHGA, SYFA, SI1L1, LCAP, EXOG, CERS6, SEP11, IKZF4, GP158, CWC22, VPS52, SCAI, ANK2, PDE10, PGM2L, SHFL, MIC60, WDR37, ABI1, SYNPO, T132C, GLT13, NED4L, RPB2, TCRG1, GNAL, H2B1K, H2B1P, H2A1F, H2A1H, H2A1K, OGT1, SYNJ1, SEPT8, MBOA7, PGP, NGEF, PYGB, COPA, MARK4, DOCK3, PLXB1, TXTP, AGRL2, TRHDE, R4RL1, RTN1, HS12A, K319L, DNM1L, AGRG1, PACS1, ABCF3, SDHA, HACD3, AGFG1, PAF1, IPO11, CCM2, MATR3, ATAT, LRRT1, LGI3, RPTOR, COL12, NAC2, THIL, EIF3L, MARE2, HNRPL, K0513, IQEC1, CACB4, SCPDL, BPHL, SNG3, EIF3C, H2AJ, DC1L1, S35A3, AP3M2, MUC18, UBQL1, PSPC1, NUP58, IGSF8, EXOC1, CACB1, CADM4, NUP85, SNP47, ACTY, WASF1, AMPB, MICU1, PSMD2, AT1A1, CDIPT, GD1L1, CC50A, HNRPU, REM2, S25A3, MARK1, CSPG4, SORC3, IPO4, SFPQ, BACH, S12A5, RAB14, SFXN3, ACLY, NDUS1, ITM2C, RMXL1, MIC25, ATPG, DDX1, MLP3A, UBAP2, ACSL6, NDUS2, ERLN1, DLG2, PI42C, IPO9, NDUV1, GRHPR, SRGP2, SRGP1, RAB4B, LRP1, WDR7, BRNP1, SYDC, TBB6, PDK3, TSN2, PDE2A, RPAB3, CSMD1, KCC2G, 2ABD, ATAD3, SFXN5, MYO5A, G37L1, RAP1B, SFXN1, NLGN1, NONO, RRAGC, TIP, MLF2, GAK, CDS2, NDUAA, ETFA, TNPO2, PTPRT, DNJA3, T121B, SF3B1, RIMS1, CNTP4, NTRI, PRP8, COX6C, MGST3, CNTP2, 6PGL, QCR8, NDUB4, RAB5A, GLRX3, AT5F1, S2546, MLP3B, 1433B, RL14, M2OM, UCRI, MIC19, PRPS2, NRX1A, MICU3, ARPC2, TBB2B, ROA0, CENPV, RL11, ILF2, TECR, RN181, BIEA, QCR1, OLA1, RL15, AL1B1, TOM70, MPC2, ODPB, MMS19, MGRN1, HNRPM, SCOT1, DYL2, RM28, RAB1B, LIGO1, RUFY3, MEII1, ATAD1, CUL5, GBRA4, TBB4A, GHC1, IDH3A, PRPS1, U2AF1, RL4, PSD12, SNAA, ATPO, BTBDH, QCR2, ALG2, AP2B1, RPN2, SUSD2, NDUA9, NDUS7, 6PGD, EIF3F, NDUS3, RAB13, XPO7, IPO7, NBEA, SORC2, VPS35, RPGF4, TBB3, XPO2, RTN3, LRBA, SPN90, TRIM2, DYHC1, LRP1B, LGI1, PRAF2, SV2A, SCAM5, NECT1, HYOU1, EXTL1, SORC1, DCLK1, MTOR, MINK1, ZN207, AP3B2, RHOA, HPLN1, FAK2, NAGAB, COPG2, KI21A, SHRM3, PLEC, DREB, S2513, EHD3, PLXB3, ADDA, DNJA2, GRM3, PCLO, SIA7A, ARP10, DCTN5, PLXC1, COPG1, GPC1, UBQL2, FBX6, SRR, AT2B2, CELR2, DEST, ARC1A, KAD1, GBRG1, GUAD, CBLN1, DGKE, VAS1, ADA22, ADA23, PEPL, CAD13, TEN1, TEN2, CUL1, ATRN, GLPK2, PDC6I, PFKAP, PYGM, SUCA, RBMX, GABR1, GSK3B, FPRP, E41L3, BUB3, CARM1, PSD13, CP46A, APC7, NCDN, ITB6, KCND2, NU160, HNRDL, SAE2, VATC1, VPP1, ARI1, CA2D3, SEPT3, AP3B1, STK39, DPP6, E41L1, SUCB1, SEPT5, GRIA4, GRIA3, HOME1
Species: Mus musculus
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Tramutola A, Sharma N, Barone E, Lanzillotta C, Castellani A, Iavarone F, Vincenzoni F, Castagnola M, Butterfield DA, Gaetani S, Cassano T, Perluigi M, Di Domenico F. Proteomic identification of altered protein O-GlcNAcylation in a triple transgenic mouse model of Alzheimer's disease. Biochimica et biophysica acta. Molecular basis of disease 2018 1864(10) 30031227
Abstract:
PET scan analysis demonstrated the early reduction of cerebral glucose metabolism in Alzheimer disease (AD) patients that can make neurons vulnerable to damage via the alteration of the hexosamine biosynthetic pathway (HBP). Defective HBP leads to flawed protein O-GlcNAcylation coupled, by a mutual inverse relationship, with increased protein phosphorylation on Ser/Thr residues. Altered O-GlcNAcylation of Tau and APP have been reported in AD and is closely related with pathology onset and progression. In addition, type 2 diabetes patients show an altered O-GlcNAcylation/phosphorylation that might represent a link between metabolic defects and AD progression. Our study aimed to decipher the specific protein targets of altered O-GlcNAcylation in brain of 12-month-old 3×Tg-AD mice compared with age-matched non-Tg mice. Hence, we analysed the global O-GlcNAc levels, the levels and activity of OGT and OGA, the enzymes controlling its cycling and protein specific O-GlcNAc levels using a bi-dimensional electrophoresis (2DE) approach. Our data demonstrate the alteration of OGT and OGA activation coupled with the decrease of total O-GlcNAcylation levels. Data from proteomics analysis led to the identification of several proteins with reduced O-GlcNAcylation levels, which belong to key pathways involved in the progression of AD such as neuronal structure, protein degradation and glucose metabolism. In parallel, we analysed the O-GlcNAcylation/phosphorylation ratio of IRS1 and AKT, whose alterations may contribute to insulin resistance and reduced glucose uptake. Our findings may contribute to better understand the role of altered protein O-GlcNAcylation profile in AD, by possibly identifying novel mechanisms of disease progression related to glucose hypometabolism.
O-GlcNAc proteins:
DPYL2, ULK1, MDHM, NFL, G3P, ENOA, AKT1, IRS1, 1433E, RAN, TBA1C, ELOC, MPRIP, TDRD9, CCD63, CNTP2
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.
O-GlcNAc proteins:
ZEP3, CAMP1, FRPD1, SKT, DLGP4, DPYL2, STXB1, MAP2, NUMBL, M3K5, NOTC2, CTND2, CSK22, ACK1, SYUA, ATX2, ZFR, BSN, GCR, EGR1, NFL, NFM, RC3H2, MAMD1, ATX1L, DERPC, NCAM1, MAP1B, G3P, ATF2, MAP4, KCC2B, AIMP1, FOXK1, STAT3, AINX, NEDD4, RP3A, DVL1, GOGA3, FOXP1, TB182, GMEB2, PI5PA, MRTFB, DOCK4, ABI2, KCNJ3, NCOA1, RGRF2, TNIK, WNK1, G3BP2, MPRIP, XRN1, RLA2, S30BP, NFIA, MARK3, ENAH, PGBM, CDK12, MA6D1, PHAR1, PSD3, NELL1, PRC2C, YETS2, FOXK2, WNK2, LIMC1, TNR6C, AGAP2, ZEP2, AAK1, TNR6A, CAMKV, PKHA7, GRIN1, FCHO2, GARL3, STOX2, UBN1, ABL2, CDV3, PHAR4, TAB3, NUFP2, UNKL, OSBP2, RBM27, CYFP2, TM1L2, ANR40, NACAD, SIN3A, NCOR1, LAMA5, NCOA2, AP180, RAI1, M3K7, TAF6, SRBS1, SH3G1, TLE4, MINT, ZYX, SF01, SYN2, TBR1, SBNO1, CRTC1, GIT1, SLAI1, PKP4, CDK13, RHG23, SH3R1, JHD2C, HECD1, ABLM3, ARMX2, LAR4B, RHG21, FBX41, RPRD2, WWC2, ZN532, BCR, DLGP3, NYAP1, GMIP, NFRKB, MAGI1, CNOT1, NU188, PICAL, SMAP2, SPAG7, PRC2B, ATX2L, MAP6, MCAF1, PHF24, NAV3, AUXI, RERE, RIMB2, PUM1, NU214, KCMF1, EPN1, AGFG2, UBP2L, C2C2L, CNKR2, ZN598, SHAN2, MAST4, RHG32, MYPT2, TB10B, FRM4A, SP130, DLGP2, ZNT6, ABLM2, EMSY, CLAP2, CNOT4, PAMR1, CREST, IFFO1, OSBL6, YTHD3, TM266, SI1L1, SH3R3, RBM14, CNOT2, ANK2, DIDO1, SYNPO, VCIP1, TAB1, SCYL2, ASPP2, F193A, OGT1, NAV1, SYNJ1, RPGF2, EP400, P66A, PDLI5, SCAM1, HS12A, AGFG1, I2BPL, PO121, ABLM1, SPART, RFIP5, CS047, SIR2, AMOT, CCG8, ZCH14, WDR13, UBAP2, NCOA5, FRS3, ZFN2B, BASP1, DCP1A, SRGP2, SRGP1, SYUB, CLIP1, UBXN1, GORS2, EPN4, RB6I2, ANR17, TXD12, NECP1, DLGP1, FIP1, F135B, TM263, PLIN3, MYPT1, CRIP2, TSC1, NBEA, RIMS2, ZN704, RBP2, RTN3, 4ET, ELF2, NUDT3, FMN2, NCOA6, SRCN1, ASAP1, RAD1, SON, PLEC, ULK2, ADDA, PCLO, HIPK2, SH2D3, YLPM1, RHG07, TEN1, NCOR2, COR1B, TNIP1, DEMA, E41L3, SYUG, APCL, MECP2, E41L1
Species: Mus musculus
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Trinidad JC, Barkan DT, Gulledge BF, Thalhammer A, Sali A, Schoepfer R, Burlingame AL. Global identification and characterization of both O-GlcNAcylation and phosphorylation at the murine synapse. Molecular & cellular proteomics : MCP 2012 11(8) 22645316
Abstract:
O-linked N-acetylglucosamine (O-GlcNAc) is a dynamic, reversible monosaccharide modifier of serine and threonine residues on intracellular protein domains. Crosstalk between O-GlcNAcylation and phosphorylation has been hypothesized. Here, we identified over 1750 and 16,500 sites of O-GlcNAcylation and phosphorylation from murine synaptosomes, respectively. In total, 135 (7%) of all O-GlcNAcylation sites were also found to be sites of phosphorylation. Although many proteins were extensively phosphorylated and minimally O-GlcNAcylated, proteins found to be extensively O-GlcNAcylated were almost always phosphorylated to a similar or greater extent, indicating the O-GlcNAcylation system is specifically targeting a subset of the proteome that is also phosphorylated. Both PTMs usually occur on disordered regions of protein structure, within which, the location of O-GlcNAcylation and phosphorylation is virtually random with respect to each other, suggesting that negative crosstalk at the structural level is not a common phenomenon. As a class, protein kinases are found to be more extensively O-GlcNAcylated than proteins in general, indicating the potential for crosstalk of phosphorylation with O-GlcNAcylation via regulation of enzymatic activity.
O-GlcNAc proteins:
A0JNY3, A2A653, A2A654, TANC2, ZEP3, MA7D2, CKAP5, CAMP1, LZTS3, A2AJ19, AJM1, MA7D1, A2ALK6, RPGP1, UBR4, A2AP92, SKT, ANR63, A2ATK9, A2AUD5, A2BI30, A6H6J9, A6MDD2, A8DUV1, B1AQX6, B1AR09, GRIK3, B1ATI9, B1AWT3, NHSL2, FRS1L, UBP24, DLGP4, B2RQ57, B2RQ80, PYR1, B2RQL0, B2RQQ5, GNAI1, B2RUE8, OTU7B, B2RWX1, B6ZHC4, B6ZHC5, B7ZCA7, B7ZMP8, B7ZNA4, B7ZNF6, B7ZWM6, B9EHE8, CTTB2, B9EKL9, PTPRZ, D1FNM8, D3YU59, D3YWX2, DGKH, D3YXR8, PGBD5, SHAN1, D3Z0V7, D3Z2J5, D9HP81, E0CYT1, E9PUA3, E9PUC4, DGKD, E9PUR0, E9PV14, E9PV26, KI67, E9PWL1, E9PWM3, E9PY55, E9PZP8, E9Q1M1, E9Q2B2, E9Q3D6, E9Q3G8, E9Q3M9, E9Q4N6, E9Q616, E9Q6T8, E9Q6Y8, NUMA1, E9Q828, E9Q9I2, E9Q9J6, E9QA16, E9QAP7, E9QAR5, SC16A, E9QJU8, E9QMJ1, SYGP1, RFIP2, HXK2, CAN2, SC22B, DPYL2, STXB1, TCOF, DCTN1, GLU2B, EF2K, PRDX4, AIP, NUMBL, GSTO1, GSH0, M3K5, PSMD4, DHX15, NPC1, BMPR2, VIAAT, BCAT2, CTND2, PITM1, CSK22, REPS1, ACK1, SLK, CAC1B, PGRC1, IMPA1, SYUA, AKA7A, STRN, RL35A, AT2A2, PGAM2, ATX2, NMT1, E41L2, GPX4, EMC8, DHB12, HCN4, KDM6A, ZN326, SORL, GRPE2, KLC1, ZFR, O88568, HCN2, HCN1, BSN, TOM1, RPP30, DNJB5, COX1, HA1D, HBA, K2C1, MBP, ALDOA, PGFRB, LDHA, G6PI, ENPP1, NEUM, ANXA2, RIR1, HS90A, EGR1, MDHM, KCC4, NFL, NFM, GNAI2, PDIA1, NUCL, CADH1, RC3H2, LRC4B, IGS11, DERPC, UBB, IFI5B, IFI4, ANXA1, EF1A1, H2B1F, PARP1, HS90B, DMD, KCC2A, TCPA, A4, COX5A, GELS, UMPS, NCAM1, GPDA, MDHC, SRP54, RLA0, GLNA, H12, LEG1, DDX3L, SPTN1, AP2A2, TPIS, KS6A3, COF1, GNAO, NFH, SERPH, VIME, MTAP2, EIF3A, CBX3, IMDH2, MCM3, CTNA1, MAP4, GNA12, GNA13, PDIA3, PSB8, NCKP1, PABP1, FKBP4, HMGB2, AIMP1, LA, ACM4, SYWC, RANG, RAB5C, RAB18, CALX, PRDX1, RL12, PPM1B, DNLI1, CAP1, STAT3, PURA, OPRM, TCPQ, CX6A1, MSH2, H14, H11, ALDR, ALD2, CBP, AINX, NEDD4, RP3A, CAPZB, SRPRB, RL36, SOX2, HS74L, ADT1, ROA1, INPP, PCY1A, MCM4, CSRP3, RAB7A, CDN2A, HDGF, ADT2, IMA1, UBP10, KPYM, RIDA, HMGA2, RL10A, CCHL, SOX1, RAB2A, ATX1, CACB3, HMCS2, GOGA3, ATPK, ATPB, ACTN4, IDI1, ACOT8, PTPA, KCNN2, KCNN3, TB10A, TB182, SF3B6, MRTFB, DOCK4, MYPR, EIF3E, PCBP1, LIPA3, ACTB, IF4A1, SNP25, RAB10, CSN2, RRAS2, PRS8, RS15A, 1433E, RS18, RS11, SMD1, ABI2, EF1A2, ACTA, VATB2, RL23, RS24, GBB1, HSP7C, TCTP, GNAS2, 1433Z, HMGB1, IF5A1, ACTG, RS17, RS12, UB2L3, RACK1, ACTS, TBA4A, TBA1A, TBB4B, PLXA2, DCC, EBP, NFIX, EM55, HNRH2, NCOA1, ELAV1, RGRF2, USP9X, TCPB, TCPE, TCPZ, NUCB2, IRS2, WNK1, RL36A, CSRP1, SEPR, RS3A, DPYL1, MPRIP, CAC1A, ATP5J, BOP1, RS5, WBP2, CXAR, PLPL9, G3BP1, RBBP6, CDS1, TBB5, IL6RB, NMDE2, NMDE3, TOP2A, NOTC1, NDKB, AQP1, UBA1, CTNB1, S30BP, NFIA, NUCB1, MARK3, APLP1, ENAH, ATPA, TF65, YES, MARK2, PGBM, PYC, CAPR2, EMAL1, LARP7, BAX, CNN2, LYAR, CHD8, CNNM1, INF2, TT21B, Q0IJ77, TRIO, VGF, TANC1, CDK12, Q14B66, MA6D1, NSUN2, MCM9, PHAR1, PSD3, Q2Q7P0, FILA2, Q3TAD4, NB5R4, GUAA, METK2, PRC2C, Q3TRG3, PLPL6, K22E, YETS2, Q3TY93, FUBP2, F117B, Q3U882, LBR, TM109, FOXK2, Q3UFK1, Q3UGZ4, TNR6C, DAB2P, ZEP2, AAK1, Q3UHT7, DTX3L, EDC4, PARP3, WASC4, GRIN1, Q3UQ23, SRBS2, THSD4, MRCKA, SPRY3, KSR2, GRM5, TBCD9, LRRF1, ARMX5, STOX2, SHAN3, UBN1, OXR1, DDX17, PHAR4, ANR28, ZN608, Q571B7, PRAG1, TAB3, Q58DZ3, IQEC2, Q5DU62, AAPK1, NUFP2, UNKL, SMG7, RBM27, CYFP2, TM1L2, PSME4, ANR40, Q5SUH6, GGNB2, SYNRG, Q5SVJ0, RPGP2, TBC9B, ACACA, Q5SXC4, Q5XJV5, LMTK3, RN123, ZDHC8, SRC8, MYL6, SKI, SAMH1, IRGM1, CLD11, NPT2A, SPB6, VDAC2, VDAC3, VDAC1, STYX, RBBP4, ASNS, NCOA2, LAP2A, PPM1G, ASTN1, PRDX2, HCFC1, APC, KCNA4, AP180, FXR1, GDIB, GRID2, GRID1, CBX5, SERA, LASP1, NPM, PCBP2, M3K7, SRBS1, DBNL, SH3G1, CYTB, IF4G2, MINT, ZYX, RALY, TFE3, Q640L6, AR13B, HECAM, NPDC1, SYN2, TBR1, ISG15, ABCG1, ATP4A, MRC2, G3PT, PTN13, TPP2, CTNA3, SBNO1, BEGIN, K1549, GIT1, SLAI1, PKP4, PEAK1, CDK13, SH3R1, MYOF, ABLM3, ARMX2, CE170, LAR4B, NOP58, Q6GR78, TPM4, NIPBL, RRP5, FBX41, Q6NVA3, RPRD2, WWC2, ZN532, Q6NXW0, S23IP, SMHD1, NEST, CSKI1, Q6P9N8, MTSS2, AHDC1, PTN23, TRAK1, SRSF1, CHD4, DLGP3, NUP98, NYAP1, KCC2D, AT1A3, AT1A2, NFRKB, RIGI, MAGI1, WDFY3, TACC1, GGYF2, PF21A, KDM3B, CNOT1, LARP1, Q6ZQB7, NU188, Q6ZQJ9, Q6ZQK4, RS9, RL10, IF2A, SC6A5, SEM6D, 2AAA, EEIG1, MTCH2, PICAL, MRO2B, SCN4B, PLPR4, HNRPQ, TBB2A, SMAP2, Q7TNS5, PLPR3, MBB1A, LNP, TPPP, ATX2L, OTUB1, EXOS3, MAP6, ELP1, SI1L2, LRRC7, ERBIN, PHF24, R3HD2, NAV3, AGRL3, Q80TS6, AUXI, MADD, AVL9, PUM1, UBP8, NU214, SEPT9, NAA15, CAMP3, FA98B, TDRKH, EPN1, TMCC2, AGFG2, UBP2L, Q80X68, C2C2L, FLNB, LRRT4, WNK3, PRIC2, CNKR2, ZN598, SHAN2, AGRB3, Q80ZX0, ZFYV1, MAST4, RHG32, ENTP3, LPP, PEF1, ACTBL, TET3, MYPT2, IF4B, SYAC, F168A, TBL1R, TB10B, CSTP1, CARF, TGO1, FRM4A, SYIM, ANS1B, DLGP2, ZNT6, RCC2, ABLM2, LSS, UNC80, NOE2, CF015, EMSY, ODP2, GGA3, SYLC, DMXL2, IMP2L, CLAP2, LIPA2, ASPH, CNOT4, FLNA, F163B, GEPH, CREST, KCC1D, PGES2, KANK2, GEMI5, IFFO1, OSBL6, YTHD3, TM266, POGZ, LACC1, MAP1S, A16L1, SI1L1, PP4R4, MYO9A, THOP1, RBM14, Q8C2R1, CNOT2, Q8C6E9, CC134, ANK2, ELFN1, DIDO1, NHSL1, WDR37, DCTN4, SYNPO, BCAS3, VCIP1, Q8CE98, TAB1, SCYL2, NED4L, SYEP, F193A, GNAL, OGT1, NAV1, SYNJ1, RPGF2, EP400, PHC3, P66A, TBCE, VWF, STAU2, LIN7A, TBC23, ZBT20, RTN1, HS12A, DNM1L, UNC5B, UNC5A, ANLN, AGFG1, MATR3, Q8K314, AHI1, NDUS8, I2BPL, PREP, ABLM1, EIF3L, ERF3A, HNRPL, IQEC1, DOCK7, DC1L1, SPART, BST2, RFIP5, AT2A1, NUP35, LUZP1, MAVS, MYH9, PARN, AT1A1, SIR2, SNRK, ZDHC5, CC50A, AMOT, AGAP3, MARK1, Q8VHM5, FLNC, SFPQ, CPIN1, WDR13, BACH, S12A5, RAB14, ACLY, MIC25, ATPG, DDX1, SH3L3, UBAP2, NCOA5, CSDE1, FRS3, ZFN2B, DLG2, PTBP2, SRGP1, TMLH, DYST, SYUB, ELOV6, ALS2, TADBP, TBB6, CLIP1, LRC59, K2C5, UBXN1, SIR1, SPRE1, PAWR, MED1, MEP50, STML2, UBP11, NONO, RRAGC, VMA5A, MAOM, DCTN2, NEUA, DDAH2, DNJA3, TRXR3, RB6I2, SRRT, DSRAD, Q99NC2, RIMS1, ANR17, NU155, NTRI, RRBP1, ZN318, TRI33, ATP5L, RL17, GLOD4, DUT, SDHB, GLRX3, IFM3, NECP1, OCAD1, RRP44, TBB2B, DDAH1, YIF1B, ROA0, NIP7, MPPB, CYBP, RL11, TECR, CHTOP, SERB1, QCR1, NNRD, GARS, TOM70, RS19, SYRC, CNDP2, TMEDA, ODO2, DLGP1, TBB4A, IDH3A, IPYR, RL37, FIP1, TIM50, EF1G, RM17, GSDMD, DDA1, F135B, TM263, CNN3, PLIN3, PGAM1, XRN2, MYPT1, DJC10, KC1D, GNAI3, PUR6, S38A3, NDUBA, CRIP2, TSC1, RAI14, NBEA, TCF20, SORC2, DPYL5, TBB3, RBP2, ARHG7, RTN3, SPN90, RBCC1, PSMG2, DDX24, CLD12, PALLD, ELF2, TMOD3, NUDT3, COPB, NUP50, DDX21, TULP4, FLII, RPF2, CCG3, TBA8, IQGA1, NECT1, ADRM1, FMN2, PALS1, DCLK1, BAG3, CUL3, MINK1, REEP6, TRXR1, SYGP1, SON, APBB1, DREB, SPY2, MACF1, ULK2, ZBP1, TOM40, ADDA, GOGA5, DNJB1, MAP1A, PCLO, GAB1, RIPK3, NPAS3, SH2D3, NUBP2, ZEB2, SYT7, DEST, TEBP, SRS10, RPGR, PR40A, KHDR3, TPSN, CDYL, KAD2, TEN1, PDC6I, CHIP, IF4H, COR1B, COR1C, TNIP1, GANP, ARC, MPP2, SHAN1, VAPA, GSK3B, DEMA, E41L3, JIP1, GBP2, CAD20, P5CS, LAT1, DYR1B, MD2L1, SAE2, APCL, SYVC, MTMR1, MECP2, E41L1, SUCB1, HDAC6, GRIA4, HOME1, OSB10
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Chalkley RJ, Thalhammer A, Schoepfer R, Burlingame AL. Identification of protein O-GlcNAcylation sites using electron transfer dissociation mass spectrometry on native peptides. Proceedings of the National Academy of Sciences of the United States of America 2009 106(22) 19458039
Abstract:
Protein O-GlcNAcylation occurs in all animals and plants and is implicated in modulation of a wide range of cytosolic and nuclear protein functions, including gene silencing, nutrient and stress sensing, phosphorylation signaling, and diseases such as diabetes and Alzheimer's. The limiting factor impeding rapid progress in deciphering the biological functions of protein O-GlcNAcylation has been the inability to easily identify exact residues of modification. We describe a robust, high-sensitivity strategy able to assign O-GlcNAcylation sites of native modified peptides using electron transfer dissociation mass spectrometry. We have studied the murine postsynaptic density pseudoorganelle and report the assignment of 58 modification sites from a single experiment--significantly increasing the number of sites known in the literature. Components of several repressor complexes, such as NCoR1, polyhomeotic-like protein3, and EMSY, are modified. In addition, 28 O-GlcNAc sites were found on the protein Bassoon, effectively matching the number of phosphorylation sites reported previously on this protein. This finding suggests that on certain proteins, O-GlcNAcylation may be as extensive and important as phosphorylation in regulating protein function. Three of the newly discovered O-GlcNAc sites on Bassoon have previously been reported as phosphorylation sites, highlighting the interplay of the modifications. Surprisingly, several peptides with GlcNAc modifications on asparagines within the N-X-S/T consensus sequence were also observed from membrane protein extracellular domains. This powerful strategy fulfills a long-standing need in the biological community by facilitating modification site identifications that will accelerate understanding of the biological significance of this elusive regulatory posttranslational modification.
O-GlcNAc proteins:
ANK3, CTND2, BSN, NFL, NFM, ZEP2, NCOR1, ABLM3, EMSY, PHC3, ABLM1, DLGP1, RIMS2, PCLO, DEMA
Species: Mus musculus
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Vosseller K, Trinidad JC, Chalkley RJ, Specht CG, Thalhammer A, Lynn AJ, Snedecor JO, Guan S, Medzihradszky KF, Maltby DA, Schoepfer R, Burlingame AL. O-linked N-acetylglucosamine proteomics of postsynaptic density preparations using lectin weak affinity chromatography and mass spectrometry. Molecular & cellular proteomics : MCP 2006 5(5) 16452088
Abstract:
O-GlcNAc is a widespread dynamic carbohydrate modification of cytosolic and nuclear proteins with features analogous to phosphorylation. O-GlcNAc acts critically in many cellular processes, including signal transduction, protein degradation, and regulation of gene expression. However, the study of its specific regulatory functions has been limited by difficulties in mapping sites of O-GlcNAc modification. We report methods for direct enrichment and identification of in vivo O-GlcNAc-modified peptides through lectin weak affinity chromatography (LWAC) and mass spectrometry. The effectiveness of this strategy on complex peptide mixtures was demonstrated through enrichment of 145 unique O-GlcNAc-modified peptides from a postsynaptic density preparation. 65 of these O-GlcNAc-modified peptides were sequenced and belonged to proteins with diverse functions in synaptic transmission. Beta-elimination/Michael addition, MS(3) on O-GlcNAc neutral loss ions, and electron capture dissociation were shown to facilitate analysis of O-GlcNAc-modified peptides/sites from lectin weak affinity chromatography enriched postsynaptic density samples. Bassoon and Piccolo, proteins critical to synapse assembly and vesicle docking, were extensively modified by O-GlcNAc. In some cases, O-GlcNAc was mapped to peptides previously identified as phosphorylated, indicating potential interplay between these modifications. Shared substrate amino acid context was apparent in subsets of O-GlcNAc-modified peptides, including "PVST" and a novel "TTA" motif (two hydroxyl-containing amino acids adjacent to an alanine). The results suggest specific roles for O-GlcNAc modification in synaptic transmission, establish a basis for site-specific regulatory studies, and provide methods that will facilitate O-GlcNAc proteome analysis across a wide variety of cells and tissues.
O-GlcNAc proteins:
SKT, SYGP1, ANK3, CTND2, BSN, SYN1, NFL, NFM, AINX, MRTFB, SRBS1, TPPP, SHAN2, EMSY, SYNPO, PCLO
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