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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, 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, SMAP2, CPEB3, PLPR3, MYCB2, PRC2B, TPPP, ATX2L, CCNT2, MAP6, SI1L2, ERBIN, R3HD2, AUXI, RERE, SNPH, RIMB2, NU214, INT2, SDA1, EPN1, AGFG2, 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, 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, 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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Hou C, Zhang H, Deng J, Wang X, Byers S, Levi M, Pak DTS, Moremen KW, Pei H, Hart GW, Ma J. Comprehensive Evaluation of Cleavable Bioorthogonal Probes for Site-Specific O-GlcNAc Proteomics. Molecular & cellular proteomics : MCP 2025 24(10) 40885482
Abstract:
O-linked β-N-acetylglucosamine (O-GlcNAc) modification (i.e., O-GlcNAcylation) on proteins is an essential modification in physiology and pathology. Although O-GlcNAcylation is functionally critical, its analysis has been challenging. Despite the existence of a number of methods developed in the past years, which one(s) might have the best performance is largely unclear. To that end, we conducted a rigorous comparison of several cleavable bioorthogonal biotin-alkyne probes which showed promise for sensitive O-GlcNAc proteomics. In brief, we developed chemoenzymatic labeling/click chemistry-based analytical workflows for O-GlcNAc proteomics by utilizing four cleavable bioorthogonal probes, including photocleavabe-biotin-alkyne (PC-biotin-alkyne), dialkoxydiphenylsilane-biotin-alkyne (DADPS-biotin-alkyne); 1-(4,4-dimethyl-2,6-dioxocyclohex-1-ylidene)ethyl-biotin-alkyne (Dde-biotin-alkyne), and diazobenzene-biotin-alkyne (Diazo-biotin-alkyne). The analytical performance of these probes was evaluated with synthetic O-GlcNAc peptides and then benchmarked by using mouse brain lysates for O-GlcNAc proteomics. Besides providing valuable technical insights into O-GlcNAc proteomics methods, our work yielded an unprecedented O-GlcNAc proteome depth in the mouse brain. In total, 2906 O-GlcNAc sites were unambiguously assigned on 878 proteins. Among them, 1611 sites were newly identified, including 138 O-GlcNAcylated tyrosine residues. Our work will help guide the selection/development of O-GlcNAc proteomics methods for future studies, provide an invaluable resource for functional elucidation of protein O-GlcNAcylation in brain biology, and yield critical insights into tyrosine O-GlcNAcylation.
O-GlcNAc proteins:
QSER1, TANC2, ZEP3, MA7D2, CKAP5, AMRA1, CAMP1, LZTS3, AJM1, MA7D1, FRPD1, RPGP1, UBR4, SKT, BCORL, AGRIN, TITIN, SVEP1, ARI1A, SPAS1, PHRF1, PTPRS, SCN2A, DLGP4, EP300, RBM25, ILDR2, CTTB2, PTPRZ, NLRC5, CCDC6, SHAN1, SET1A, PARP4, PRR12, TENS1, I2BP2, AKP13, C2CD2, ARI1B, ZC3HD, ARID2, NUMA1, PDZD7, SC16A, SYGP1, TPR, BICRA, SI1L3, PLGT3, DPYL2, EMD, STXB1, AKAP1, CLOCK, DCTN1, NUMBL, DBIL5, SYPL1, M3K5, SCRB2, ATN1, NOTC2, VIAAT, HAP1, CTND2, PITM1, OX2G, REPS1, AKAP2, ACK1, CNTP1, CAC1B, SYUA, PI51C, ATX2, E41L2, PDLI1, ULK1, UBR1, HCN4, KDM6A, ZN106, PDE8A, PPT1, ZFR, HCN2, HCN1, CTBP1, BSN, TOM1, AKA10, HIPK1, SYN1, LGMN, TPP1, THY1, LAMC1, MBP, ALDOA, GCR, CATL1, EGR1, HCK, ENPL, KCC4, NFL, NFM, ITB1, RC3H2, MAMD1, ATX1L, CATB, TAU, LAMP1, DMD, KCC2A, ITPR1, CNTN1, NCAM1, AT1B2, HSPB1, MAP1B, G3P, ATF2, PPIA, CATD, BASI, COF1, NFH, BIP, HEXB, MTAP2, MAG, CYTC, EMB, GRIA1, GRIA2, RS2, RGRF1, KCC2B, PABP1, C5AR1, AIMP1, DPOA2, RAB23, NMDE1, NMDZ1, FMR1, FOXK1, STAT3, EAA2, EGR3, RAD52, ITAV, CBP, AINX, NEDD4, STT3A, RP3A, EPB41, RFX1, SOX2, LMNA, MPIP1, INPP, DHI1, ARSB, VATA, DVL1, ADCY7, DBX1, E41LA, ARNT, SOX1, ATX1, RD23B, 3BP1, AMRP, CX6B1, CTBP2, MAZ, WFS1, PCBP3, PTPA, KCNN2, FOXP1, TB10A, TB182, GMEB2, KCNH8, CAPAM, RHG39, YTHD1, RPC2, PI5PA, MRTFB, DOCK4, IRPL1, MYPR, ABI2, GBB1, RAB3A, VAMP2, KCNA2, KCNJ3, ZHX1, DCC, NFIX, NCOA1, RGRF2, USP9X, TP53B, NACAM, LYAG, IRS2, TNIK, WNK1, G3BP2, ARG28, MPRIP, CAC1A, NPAS2, GRM1, XRN1, SHPS1, NEO1, G3BP1, NFIB, RLA2, GABPA, CBPE, NMDE2, NMDE3, NOTC1, CTNB1, PLAK, S30BP, ZEP1, ENAH, KCNB1, RCN1, PGBM, EMAL1, LG3BP, TLE3, MITF, SSRP1, CHD8, TRIO, TANC1, RELCH, CDK12, MA6D1, F171B, SHRM4, PHAR1, GSK3A, PSD3, MLXIP, NELL1, ESP1, PLBL2, PDLI7, PRC2C, MILK2, YETS2, SRSF6, FUBP2, SRBP2, GSE1, F117B, WDR62, FOXK2, CARL3, DIP2B, WNK2, LIMC1, TNR6C, DAB2P, AGAP2, ZEP2, ZSWM8, AAK1, TEN4, TNR6A, CAMKV, MTCL1, PKHA7, COBL1, GRIN1, PRRC1, MINY4, FCHO2, SNX21, LIGO2, MRCKA, KSR2, GRM5, ARMX5, ELAP2, GARL3, 5NTC, PACS2, STOX2, UBN1, ABL2, OXR1, DSCL1, CDV3, PHAR4, ANR28, LRC47, SRRM1, EME2, LIN54, TAB3, STB5L, NEXMI, JCAD, NYNRI, NUFP2, UNKL, PRSR1, OSBP2, SMG7, LRRK2, RBM27, PHF12, CYFP2, TM1L2, ANR40, CCD42, SYNRG, RPGP2, NACAD, LHPL4, EPAB2, LMTK3, SIN3A, SRC8, ICAM5, LAMA2, ITF2, CAPR1, NCOR1, FOXG1, LAMA5, NCOA2, LAMC2, IL18R, NAB1, ASTN1, SPIN1, PAPOA, HCFC1, SAP, NELL2, APC, PGCB, ZN638, AP180, FXR1, GRID2, GRID1, PACN1, HIRA, RAI1, MAFK, NPM, NOTC3, CSPG2, M3K7, DAG1, RO52, SN, SPTB2, TAF6, SPEG, ASPP1, SRBS1, DBNL, SH3G1, TLE4, SP4, IF4G2, MINT, ZYX, OMGP, MEF2D, TFE3, PAN3, HECAM, SF01, SYN2, TBR1, DHSO, CGT, CH058, SBNO1, CRTC1, BEGIN, K1549, GIT1, SLAI1, PKP4, SYMC, CDK13, GBA2, SH3R1, PREX1, JHD2C, HECD1, MOR2A, ABLM3, TBC12, ARMX2, CE170, LAR4B, RHG21, HELZ, MEG10, SCAF8, LIGO3, ZZZ3, F135A, FBX41, SPKAP, RPRD2, WWC2, ZN532, DPP10, TAF9B, S23IP, IF4G1, RBM26, NSD3, SNX19, FHOD1, FKB15, MTSS2, BCR, AHDC1, AAKB2, PTN23, LPPRC, PAPD7, MFF, PIGS, TRAK1, PHLB1, KMT2D, RN220, DLGP3, RA54B, GMIP, WASC2, ERC2, KCC2D, NFRKB, ALEX, MAGI1, CENPE, DNMBP, GGYF2, TEX2, PF21A, KDM3B, FNBP4, CNOT1, LARP1, NU188, SYNE1, IF2A, UB2R2, CMYA5, SEM6D, SOX11, ASAP2, HUWE1, SMAP2, PLPR3, PRC2B, C2CD5, TPPP, MACOI, AMPH, ATX2L, PRC2A, TMM94, PP6R1, MAP6, MCAF1, DAAF9, SI1L2, LRRC7, ERBIN, PHF24, R3HD2, NAV3, AGRL1, DEND, AUXI, RERE, SNPH, MADD, RIMB2, PUM1, NU214, SEPT9, SESD1, CBPM, SRA1, EPN1, AKNA, HYDIN, UBN2, AGFG2, CHST2, T106B, C2C2L, REPS2, WNK3, DDHD1, CNKR2, BCAS1, ZN598, SHAN2, PKHL1, S2611, ZFYV1, NRCAM, DLG1, MAST4, RHG32, GPHB5, RN214, LPP, MYPT2, TB10B, CSTP1, SP130, ZC3HE, DLGP2, ZC21A, ZNT6, SUN2, EME1, TNR6B, BAIP2, ABLM2, NCEH1, LRFN3, SHC2, SEN34, FAT3, DMXL2, GORAB, CLAP2, K1671, FAKD3, LIPA2, CNOT4, RALYL, SRRM2, TOX4, PAMR1, F163B, GEPH, CREST, KCC1D, GRIN3, LARP4, Z385B, IFFO1, OSBL6, CC169, TENR, YTHD3, STON2, TM266, POGZ, DOC10, ZHX2, EPC2, SWAHC, ZHX3, SI1L1, SH3R3, FRS2, RBM14, CNOT2, MOR2B, HYCC2, ANK2, ELFN1, TM163, DIDO1, SMAG1, SYNPO, BCAS3, VCIP1, BAKOR, TAB1, SCYL2, NED4L, MEF2C, ASPP2, TENS2, F193A, OGT1, CHERP, NAV1, SYNJ1, RPGF2, EP400, PHC3, DPYD, VP37A, EPN2, P66A, PDLI5, ANM5, DOCK3, PLXB1, DNER, SPAT2, SCAM1, SAM14, ZBT20, PHYIP, RTN1, HS12A, C2D1A, UNC5A, PACS1, TRI68, BRD3, LS14A, AGFG1, MATR3, DEN1A, I2BPL, PO121, ABLM1, MRTFA, RPTOR, PLCE1, SPNS1, CACL1, KCNC4, DC1L1, MTSS1, SPART, LRC42, ZN445, RFIP5, IGSF8, BRD8, WIPI1, CDK8, PP6R2, SHLB2, CS047, NTNG2, PP14C, STAB2, LUZP1, RBM12, STAB1, OTU7A, SC6A8, ULA1, CLPT1, MAVS, GRAP1, SGIP1, PI3R4, PHIP, SIR2, GOLI, AMOT, AGAP3, WASF3, P66B, CCG8, TAF9, ZCH14, MCR, SFPQ, WDR13, UBAP2, SMAP1, NCOA5, CXXC5, FRS3, SPS2L, FUBP1, SH319, ZFN2B, VPS36, DLG2, DYH8, DCP1A, YTHD2, PTBP2, SRGP2, SRGP1, BMP2K, DYST, LRP1, SYUB, ALS2, TRFE, GPS2, CLIP1, WAC, SPRE1, MED1, NRBP, NPTXR, GGT7, GORS2, NONO, TAB2, DPP3, EPN4, RNF34, GAK, DDAH2, ZN281, HGS, RB6I2, RIMS1, ANR17, RTN4, RRBP1, ZN318, TRI33, MZT2, PCYOX, NECP1, FLIP1, NRX1A, SNX2, DDAH1, YIF1B, NOPC1, CYGB, GFOD2, TPD54, CEP97, CD37L, SSBP3, SARNP, SP2, UB2V2, DLGP1, NDUV2, SH24A, FIP1, ST1C2, F135B, TM263, CNPY3, RM12, BTBDH, AL7A1, PLIN3, MYPT1, LNEBL, DCAF6, KC1D, CRIP2, TSC1, NBEA, TCF20, CPSF1, DPYL5, RIMS2, ZN704, RBP2, RTN3, SPN90, SP6, GILT, CLD12, ELF2, TSSC4, LRP1B, NUDT3, CATR, PPR3F, NUP50, TULP4, ORC3, ATR, HYOU1, ADRM1, FMN2, NCOA6, BAG3, MINK1, ZN207, PHC2, SRCN1, ASAP1, SON, SALL2, LIMD1, TBL1X, APBB1, PLEC, MACF1, ULK2, ADDB, ADDA, PCX1, GOGA5, NDRG2, MAGD1, MAP1A, QKI, PCLO, GAB1, MAGL2, FBX6, NPAS3, HIPK2, SH2D3, CATJ, YLPM1, CELR2, RHG07, GUAD, FOXO1, TAGL3, ADA22, AKA12, TEN1, TEN3, NCOR2, ATRN, COR1B, SR5A3, GANP, NFAT5, ASAH1, GSK3B, DEMA, E41L3, CARM1, JIP1, KCNH3, MAGI2, FXR2, SYUG, CLIP2, PALM, ITSN1, ITSN2, ZO2, DYR1B, APCL, BAG6, DPP6, MTMR1, MECP2, SE1L1, E41L1, GRIA3, HOME1
Species: Mus musculus
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Liu X, Cai YD, Hou C, Liu X, Luo Y, Mendiola AJP, Xu X, Luo Y, Zheng H, Zhao C, Chen CH, Zhang Y, Xiang YK, Ma J, Chiu JC. O-GlcNAcylation of nuclear proteins in the mouse liver exhibit daily oscillations that are influenced by meal timing. PLoS biology 2025 23(9) 40997131
Abstract:
The liver circadian clock and hepatic transcriptome are highly responsive to metabolic signals generated from feeding-fasting rhythm. Previous studies have identified a number of nutrient-sensitive signaling pathways that could interpret metabolic input to regulate rhythmic hepatic biology. Here, we investigated the role of O-GlcNAcylation, a nutrient-sensitive post-translational modification (PTM) in mediating metabolic regulation of rhythmic biology in the liver. We observe daily oscillation of global nuclear protein O-GlcNAcylation in the liver of mice subjected to night-restricted feeding (NRF) using label-free global O-GlcNAc proteomics. Additional site-specific O-GlcNAc analysis by tandem mass tag mass spectrometry further supports temporal differences in O-GlcNAcylation by revealing day-night differences. Proteins involved in gene expression are enriched among rhythmically O-GlcNAcylated proteins, suggesting rhythmic O-GlcNAcylation may directly regulate the hepatic transcriptome. We show that rhythmic O-GlcNAcylation can also indirectly modulate nuclear proteins by interacting with phosphorylation. Several proteins harboring O-GlcNAcylation-phosphorylation interplay motif exhibit rhythmic O-GlcNAcylation and phosphorylation. Specifically, we show that O-GlcNAcylation occurs at a phospho-degron of a key circadian transcriptional activator, circadian locomotor output cycles kaput (CLOCK), thus regulating its stability and transcriptional output. Finally, we report that day-restricted feeding (DRF) in the nocturnal mouse significantly alters O-GlcNAcylation pattern. Whereas global O-GlcNAcylation analysis indicates dampening of global O-GlcNAcylation rhythm in mice fed under DRF, site-specific analysis reveals differential responses of O-GlcNAc sites when timing of food intake is altered. Notably, a substantial number of O-GlcNAcylation sites exhibit inverted day-night profiles when mice are subjected to DRF. This suggests the dysregulation of daily nuclear protein O-GlcNAcylation rhythm may contribute to the disruption in liver transcriptome previously observed in DRF condition. In summary, our results provide new mechanistic insights into metabolic regulation of hepatic transcriptional regulators via interplay between O-GlcNAcylation and phosphorylation and shed light on the deleterious effects of improper mealtimes.
O-GlcNAc proteins:
A0A075B680, A0A087WQ44, A0A087WSN6, A0A0A6YVV8, A0A0B6VMB2, A0A0F7QZE4, A0A0G2JGY6, A0A0R4J092, A0A0U1RNL9, A0A1I7Q4G8, A0A1N9PTV1, A0A1Y7VP67, A0A286YCY7, A2A654, ZMYM4, TM201, MED14, A2ADB1, A2AJ72, S35D1, BCORL, A2AQR4, A2ATN3, MGAP, KANL3, PHRF1, B1AR09, B1ASA5, B2RQG2, B2RR24, B2RT41, B2RUQ2, EP300, RBM25, B7ZNL9, D3YWX2, D3Z0K6, D3Z2U7, E9PUF4, E9PUH7, FIBA, E9PV38, SET1A, PARP4, PRR12, E9Q1A5, E9Q1M6, ICE1, E9Q3L4, ANR11, ARI1B, SETD2, YTDC1, ZC3HD, ARID2, E9Q7G1, E9Q9V3, E9Q9Y2, E9QAN9, E9QAP7, E9QKL0, E9QMD3, E9QNA7, F6R9G0, F6T8X6, BICRA, G3UVU2, G3X8Q1, G3X928, G3X961, G3X972, G3X9Q0, PCF11, G5E896, H9KV00, ERR1, GTPB1, HNF6, CLOCK, GLU2B, ATN1, IMA3, KLF12, CALU, AF10, ZN143, SP3, KDM6A, ZN106, ZFR, CCNK, PIAS1, LGMN, SP1, IGHG3, CFAH, EGR1, ITB1, ATX1L, CATB, ITPR1, B4GT1, HNF1A, PGH1, A1AT2, NFYA, PO2F1, 3BHS3, HNF1B, CEBPB, CELF1, RXRA, VTNC, NKTR, SUH, ANT3, G6PC1, FOXA1, FOXK1, STAT3, CBP, FKBP2, FOSL2, RFX1, LMNA, STS, MAT1, PON1, CEBPA, ATX1, RD23B, KMT2A, FUS, PAXB1, LMA2L, MRTFB, SUMO2, PP1B, RS11, SMD3, NFYB, SUMO1, ZHX1, TIAR, TBX3, NFYC, ATF1, ERG, NFIB, RBBP6, GABPA, CREB1, S30BP, NFIA, ZEP1, SPA3M, PPA5, CLUS, GATA4, CHD8, CDK12, Q3T9J2, KHDC4, Q3TGN5, PRC2C, CIART, K22E, YETS2, Q3U1M7, LMF1, FOXK2, PUF60, RREB1, ZEP2, UD3A1, ZCCHV, PRRC1, SFSWA, PRD10, ERMP1, Q3UXF4, TMED1, ZBT45, Q569X9, LIN54, TASO2, RESF1, ZN652, NUFP2, KDM6B, Q5PRE9, Q5RIM6, RBM27, UTP18, Q5SUT0, MED13, Q5SXC4, SFR19, UIMC1, A1CF, SIN3A, CSK21, CAPR1, MEF2A, RBBP7, KLF3, NCOA2, USF1, CTCF, GATA6, TS101, HCFC1, ZN148, HIRA, LASP1, RAI1, MAFK, PRG2, SPTB2, SSXT, TAF6, UD19, NUP62, UD11, MEF2D, TIF1A, USF2, CDK13, JHD2C, HECD1, Q6DI81, SCAF8, NOMO1, FND3B, Q6NXL1, ZMIZ1, NSD3, UGGG1, ALG8, AHDC1, PTN23, PIGS, NUP98, NFRKB, GNAS1, ONEC2, FNBP4, CNOT1, NU188, SPCS3, PICAL, HUWE1, CPEB4, PRR14, ATX2L, NACC1, MCAF1, KANL1, NU214, PR40B, UBN2, TNC18, UBP2L, ZN598, Q80ZX0, DDX42, LPP, TET3, E41L5, SP130, ZC3HE, SUN2, EST2E, NCEH1, ARI5B, EMSY, TM260, RFOX2, TM209, KMT2C, ASPH, SRRM2, NUP54, CPSF7, TOX4, IFIX, CREST, Z385B, PIGT, PGLT1, YTHD3, KAT6A, ASXL2, ZN609, POGZ, SREK1, ZHX2, ZHX3, P20D1, MBNL2, RBM14, PIAS2, CNOT2, ITCH, DIDO1, EPC1, SCYL2, G6PE, TCRG1, BCOR, CCAR1, Q8CHB3, ADNP2, BICRL, EP400, PHC3, P66A, FWCH1, PDLI5, NUP42, ZMIZ2, BTD, UD3A2, ESRP2, TAF10, ZBT20, Q8K154, GT251, ALG3, BRD3, I2BPL, PO121, SF3A1, EST2A, SF3B4, Q8R084, ZBT44, MTSS1, TMED4, ZC3HA, UBQL1, NUP58, BRD8, ATX7, STAB2, RBM12, RBPS2, MED25, MAVS, ALG12, HNRL1, CDIPT, SRSF4, P66B, TAF9, MCR, SFPQ, MBOA5, UBAP2, SMAP1, NCOA5, RBM47, CREL1, SC16B, BAZ2A, RBM5, RISC, ALS2, BCL7B, TMCO1, SYDC, CIC, MED15, WAC, MED1, GORS2, RBM10, ZN281, MLXPL, ANR17, ZN318, TRI33, PCYOX, NECP1, RBM33, SSRA, CREL2, PINX1, INT12, SP2, PHF14, SUN1, APMAP, FIP1, AP2B1, RPN2, LMAN2, AKAP8, MYPT1, RSRC1, EIF3F, Q9EQC8, ERAP1, SALL1, Q9ERL0, RBP2, RTN3, PALLD, TF2H2, ANM1, NUP50, HAKAI, HYOU1, ELOV1, ZN207, DOPP1, CCNT1, TBL1X, PO210, VKGC, QKI, UBQL2, HIPK2, COP1, PR40A, FOXO1, PIGN, MAN1, GANP, ENTP5, NFAT5, CARM1, FOXO3, FBLN5, IF2H, Q9Z1A1, DEAF1, HTAI2, HNRPF, ITPR2, S4R1W8, V9GX43
Species: Mus musculus
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Hao Y, Li X, Qin K, Shi Y, He Y, Zhang C, Cheng B, Zhang X, Hu G, Liang S, Tang Q, Chen X. Chemoproteomic and Transcriptomic Analysis Reveals that O-GlcNAc Regulates Mouse Embryonic Stem Cell Fate through the Pluripotency Network. Angewandte Chemie (International ed. in English) 2023 62(17) 36852467
Abstract:
Self-renewal and differentiation of embryonic stem cells (ESCs) are influenced by protein O-linked β-N-acetylglucosamine (O-GlcNAc) modification, but the underlying mechanism remains incompletely understood. Herein, we report the identification of 979 O-GlcNAcylated proteins and 1340 modification sites in mouse ESCs (mESCs) by using a chemoproteomics method. In addition to OCT4 and SOX2, the third core pluripotency transcription factor (PTF) NANOG was found to be modified and functionally regulated by O-GlcNAc. Upon differentiation along the neuronal lineage, the O-GlcNAc stoichiometry at 123 sites of 83 proteins-several of which were PTFs-was found to decline. Transcriptomic profiling reveals 2456 differentially expressed genes responsive to OGT inhibition during differentiation, of which 901 are target genes of core PTFs. By acting on the core PTF network, suppression of O-GlcNAcylation upregulates neuron-related genes, thus contributing to mESC fate determination.
O-GlcNAc proteins:
AMRA1, SETX, SKT, BCORL, AGRIN, MGAP, ARI1A, CHD6, PHRF1, ZCH24, EP300, KIF7, KI67, CE350, ANR11, NUMA1, TPR, MORC3, TAF4B, KMT2B, EMD, AKAP1, TCOF, DCTN1, MNT, NCOA3, ATN1, ECP3, DPOD2, CTND2, PIAS3, AF10, ACK1, GET3, DSG2, ESS2, ATX2, PDLI1, ULK1, BARD1, KDM6A, ZN106, NSD1, ZFR, HIPK1, SETB1, LAMC1, MYCN, GCR, EGR1, RC3H2, ATX1L, DERPC, K2C8, HSPB1, JUND, FGFR1, G3P, ATF2, COF1, HEXB, VIME, PO5F1, CBL, CCNB1, PO2F1, RS2, NFKB1, MAX, PABP1, NEDD1, PTN12, FMR1, ELK1, FOXK1, STAT3, SOX15, PLIN2, CBP, NEDD4, YAP1, RFX1, SOX2, LMNA, ROA1, S1PR2, ARNT, RD23A, PLTP, KMT2A, KLF16, FOXP1, TB182, GMEB2, SENP1, YTHD1, MRTFB, DOCK4, STIM1, TBX3, NCOA1, ERF, SIAE, NACAM, ATF1, WNK1, G3BP2, DNLI3, G3BP1, RLA2, GABPA, S30BP, ZEP1, ENAH, SOX13, CAPR2, APLP2, CLUS, TLE3, GATA4, MITF, CHD8, ZCH18, TANC1, CDK12, SAP25, LIN41, MLXIP, HROB, VRTN, CO039, PDLI7, SMCA4, PRC2C, MILK2, MIDN, YETS2, PBIP1, FUBP2, TFPT, SRBP2, GSE1, F117B, ZN865, WDR62, QRIC1, FOXK2, RREB1, TNR6C, DAB2P, TNR6A, RHG17, PKHA7, COBL1, FCHO2, TET1, ARMX5, GARL3, TET2, CDV3, PHAR4, C2CD3, LIN54, NPA1P, TAB3, TASO2, RESF1, NUFP2, UNKL, COBL, KDM6B, PRSR1, SMG7, RBM27, PHF12, ZDBF2, PUR4, SYNRG, UIMC1, SIN3A, NFAC2, SRC8, SKIL, ELF1, KLF4, NCOR1, KLF3, NCOA2, FOXD3, PAPOA, HCFC1, P3C2A, SIX4, ZFHX3, TOB1, AP180, GLI3, ATRX, MAFK, NPM, M3K7, DAG1, SPTB2, TAF6, TIF1B, SPT6H, SH3G1, ARI3A, TLE1, TLE4, IF4G2, MINT, ZIC3, ZYX, NUP62, PHC1, TFE3, TIF1A, SF01, DAZL, RBL1, KNL1, BCL9L, SBNO1, SLAI1, PKP4, CDK13, SH3R1, JHD2C, HECD1, ARMX2, LAR4B, RHG21, HELZ, SCAF8, UTF1, PKHG2, NIPBL, CCD66, F135A, RPRD2, WWC2, ZN532, KRBA1, TAF9B, RBM26, INT1, BCR, AHDC1, PTN23, PAPD7, KDM3A, KMT2D, CHD4, RN220, NUP98, NFRKB, GGYF2, LCOR, TEX2, PF21A, KDM3B, FNBP4, CNOT1, LARP1, RHG26, NU188, CNDD3, SPAG5, HUWE1, SMAP2, CPEB3, MYCB2, PRC2B, PRR14, MACOI, ATX2L, CKP2L, PRC2A, MCAF1, SI1L2, KANL1, ERBIN, R3HD2, RERE, PUM2, PUM1, NU214, WNK4, TCAM1, SAS6, CAMP3, UBN2, TNC18, AGFG2, WNK3, ZN598, CTIP, SHAN2, NANOG, DDX42, RHG32, VGLU3, LPP, TET3, MYPT2, IF4B, CNO10, MISSL, TB10B, CARF, TGO1, ZN879, SP130, ZC3HE, ZNT6, SUN2, TNR6B, ARI5B, BNC2, KAT6B, KMT2C, CLAP2, CNOT4, SRRM2, TOX4, GEPH, SYP2L, LARP4, KANK2, SALL4, YTHD3, TOIP2, KAT6A, ASXL2, POGZ, TAF5, ZHX2, EPC2, SI1L1, CND2, RBM14, SUCO, CNOT2, DIDO1, SMAG1, LENG8, CDAN1, DPPA4, LRIF1, VCIP1, MB214, TAB1, SCYL2, ASPP2, LS14B, SYEP, F193A, BCOR, OGT1, SUGP1, NAV1, SYNJ1, ADNP2, RPGF2, BICRL, EP400, PHC3, VP37A, EPN2, P66A, PDLI5, ELYS, ZBT20, ANLN, AGFG1, MATR3, CASC3, I2BPL, PO121, ALMS1, SF3A1, GRHL2, ATF7, CACL1, DC1L1, MTSS1, SPART, TDIF2, HBP1, NUP58, RFIP5, BRD8, WIPI1, CDK8, CS047, ATX7, NUP35, LUZP1, RPAP2, NDC1, MAVS, AMOT, CSKI2, P66B, TAF9, IPO4, ZCH14, UBAP2, NCOA5, FUBP1, RBM47, AJUBA, VPS36, DCP1A, EGLN2, YTHD2, SRGP2, GRHL1, BCL7B, P4R3B, PLRG1, WAC, TRPS1, MED1, ACATN, NRBP, RP25L, NONO, TAB2, EPN4, DDAH2, NOG2, ZN281, HGS, NASP, ARIP4, ANR17, ZN318, TRI33, MZT2, ZWINT, ECD, YIF1B, ROA0, DHRS7, TPD54, SSBP3, PSRC1, SARNP, BCL9, SP2, NOP56, SH24A, FIP1, PLIN3, MYPT1, KC1D, TCF20, TOR3A, SALL1, ZN704, RBP2, UBE4B, TBX20, AFF4, RBCC1, 4ET, PALLD, ELF2, TSSC4, NUDT3, HAKAI, ADRM1, NCOA6, FANCA, GIT2, BAG3, TOB2, ZN207, SON, TBL1X, PLEC, MACF1, GOGA5, QKI, GAB1, DMRT1, YLPM1, PCM1, RHG07, TAF7, FOXO1, ADA23, AKA12, UXT, MAN1, NCOR2, AKT3, COR1B, TNIP1, GANP, DEMA, CARM1, RGAP1, ITSN2, ZO2, KLF5, ADNP, ARI3B, BCL3, SE1L1, E41L1, ZN292
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, 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, PLPR3, PRC2B, C2CD5, TPPP, ATX2L, MAP6, NAV3, AUXI, RIMB2, AVL9, NU214, AP4E1, C2C2L, IF4G3, ZN598, SHAN2, LPP, MYPT2, PHIPL, TB10B, CCD40, ZC3HE, DLGP2, ZC21A, BAIP2, 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, 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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Wu JL, Chiang MF, Hsu PH, Tsai DY, Hung KH, Wang YH, Angata T, Lin KI. O-GlcNAcylation is required for B cell homeostasis and antibody responses. Nature communications 2017 8(1) 29187734
Abstract:
O-linked N-acetylglucosamine (O-GlcNAc) transferase (Ogt) catalyzes O-GlcNAc modification. O-GlcNAcylation is increased after cross-linking of the B-cell receptor (BCR), but the physiological function of this reaction is unknown. Here we show that lack of Ogt in B-cell development not only causes severe defects in the activation of BCR signaling, but also perturbs B-cell homeostasis by enhancing apoptosis of mature B cells, partly as a result of impaired response to B-cell activating factor. O-GlcNAcylation of Lyn at serine 19 is crucial for efficient Lyn activation and Syk interaction in BCR-mediated B-cell activation and expansion. Ogt deficiency in germinal center (GC) B cells also results in enhanced apoptosis of GC B cells and memory B cells in an immune response, consequently causing a reduction of antibody levels. Together, these results demonstrate that B cells rely on O-GlcNAcylation to maintain homeostasis, transduce BCR-mediated activation signals and activate humoral immunity.
O-GlcNAc proteins:
FAIM3, BLTP1, BCORL, M3K15, EXC6B, PLHD1, CTTB2, MYO1E, SCLT1, TAF4B, TCOF, FLOT1, OXLA, HDAC1, SYPL1, SEM4D, MA2B1, PPE2, PLD3, DPOD2, NOCT, HNRH1, API5, DFFA, MMP8, DPM1, EIF3D, ESS2, CTNL1, VTI1B, S28A2, FA5, CO4B, IGKC, LAC1, IGHA, IGHDM, HA11, LAMC1, TBA1B, LDHA, HVM51, SPTA1, ZFP1, EGR1, ENPL, RPB1, ITB1, ENV1, 4F2, HS90B, HA2B, HB2A, CD44, BLK, CN37, LAMP2, ZFP37, PTBP1, HB2I, BASI, FAS, EVI2A, MDR1A, BGAL, ITAL, LYN, TLN1, MOES, U2AF2, MAP4, GNA13, RL3, CATG, DPP4, PTN6, HEXA, NKTR, HMGB2, SUH, CEAM1, GTR3, DRG1, RAB5C, CD22, FMR1, VGFR1, HSPA9, CAP1, ECI1, FOXK1, STAT1, NKX25, TCPQ, H11, H13, IL12B, CAPZB, RL5, VDR, RET3, ADCY7, VA0D1, AAAT, IMA1, STOM, FUS, NICA, RU2A, EF2, AAAS, RUVB1, ABCE1, DCAF7, 1433G, ACTA, RS6, VATB2, RL23, RL8, PP2BA, RACK1, TBB4B, M4K1, ITPR3, SURF6, ELAV1, EVL, H2B1A, AT8A1, TCPH, TCPB, NXN, TBB5, HNRL2, CREB1, PLAK, 3MG, CO6A1, LG3BP, COE1, CNN2, NSUN2, HMHA1, SNUT2, SMCA4, TPC10, TGRM2, I20L2, ZSWM8, PRRC1, SC31A, CPZIP, ITAD, ULK4, ITA1, DYHC2, LIN54, JKIP3, GRHL3, MYO1G, SIN3A, IRAG2, SAMH1, KHDR1, LY75, RASA3, NPT2A, CAPR1, ARHG2, PML, IMA5, LAP2B, PRP4B, M4K2, TS101, PLSL, CTNA2, VSX2, CD37, SERA, PCBP2, TIF1B, COCH, NUP62, RALY, UT14A, ARG39, CLH1, ATS16, F120A, NOP58, TEDC2, U520, RRP12, SMHD1, ANO6, TTBK1, CHD4, SARM1, NUP98, RASL2, TNKS1, AT1A2, NFRKB, DDX55, DNA2, H2B1C, CMYA5, GIMA8, CYFP1, SPAG5, HNRPQ, RPF1, MBB1A, PRC2A, ADCY2, MOGS, SDA1, FA98B, WIPI2, TRRAP, XYLT1, WDR82, GNS, ERLN2, S38A9, WASF2, S2512, NIM1, TBL1R, ZN526, CARF, HES7, UNC80, RBGPR, ECHA, ELMO1, ATOSB, KMT2C, FLNA, TPC2, RBBP5, POGZ, DOC10, SYFA, SMKZ, COR2A, RBM14, DOCK2, CASP9, RAE1L, NUP88, RPB2, UACA, SYEP, P66A, VPS50, COPA, VWF, TXTP, ZN536, LMBD1, R4RL1, C2D1A, URP2, STX5, GT251, SDHA, PO121, ABLM1, COL12, ALAT1, RORB, PDLI2, ERO1B, CD177, PSPC1, NUP58, STAB2, LRC8C, COX18, MAVS, PLBL1, UN93B, EVI2B, MYH9, ESIP1, VIGLN, PSMD2, HNRL1, CCAR2, SP7, RECQ5, SFXN3, IF4A3, RINI, DDX1, UBAP2, S15A4, DNJC9, MASP2, UXS1, CSCL1, BMP2K, CYRIB, SYDC, C1TC, GLYR1, PDIA6, S12A6, ATAD3, MYO5A, MCLN1, ABEC3, STML2, SFXN1, PRP19, TARA, MCRS1, RTCB, NDUS5, S12A9, SF3B1, ANR17, NU155, TR34A, BAP1, PRP8, NUDC2, TSN31, RN138, RTRAF, RU2B, YETS4, M2OM, MIC19, SNX2, DDX28, CXXC1, RUSD4, ILF2, CHTOP, LUC7L, DIM1, MCES, SEC13, SP2, NOP56, U2AF1, EF1G, MCEM1, EVPL, PRP4, CMTR1, WWP2, DHB11, PESC, TLR9, IRX6, KRT81, RBP2, AFF4, KAT2B, STK3, NUP50, DDX21, ACINU, SIGIR, ZN207, SLAF1, SON, H2AY, MTA2, SAE1, MYO1C, RUVB2, TRPV2, PFKAP, ARC1B, ASAH1, VAPA, EHD1, IF2G, CLIC1, HNRPF
Species: Mus musculus
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