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Fan J, Guo F, Mo R, Chen LY, Mo J, Lu CL, Ren J, Zhong Q, Kuang X, Wen Y, Gu TT, Liu J, Li S, Fang Y, Zhao C, Gao TM, Cao X. O-GlcNAc transferase in astrocytes modulates depression-related stress susceptibility through glutamatergic synaptic transmission. The Journal of clinical investigation 2023 36757814
Abstract:
Major depressive disorder is a common and devastating psychiatric disease, the prevalence and burden are substantially increasing worldwide. Multiple studies of depression patients have implicated glucose metabolic dysfunction in the pathophysiology of depression. However, the molecular mechanisms by which glucose and related metabolic pathways modulate depressive-like behaviors are largely uncharacterized. UDP-GlcNAc is a glucose metabolite with pivotal functions as a donor molecule for O-GlcNAcylation. O-GlcNAc transferase (OGT), a key enzyme in protein O-GlcNAcylation, catalyzes protein posttranslational modification by O-GlcNAc and acts as a stress sensor. Here, we show that Ogt mRNA was increased in depression patients and that astroglial OGT expression was specifically upregulated in the medial prefrontal cortex of susceptible mice after chronic social defeat stress. The selective deletion of astrocytic OGT resulted in antidepressant-like behaviors, moreover, astrocytic OGT in the mPFC bidirectionally regulated vulnerability to social stress. Furthermore, OGT modulated glutamatergic synaptic transmission through O-GlcNAcylation of glutamate transporter-1 (GLT-1) in astrocytes. OGT astrocyte-specific knockout preserved the neuronal morphology atrophy and Ca2+ activity deficits caused by chronic stress and resulted in antidepressant effects. Altogether, our study reveals that astrocytic OGT in the mPFC regulates depressive-like behaviors through the O-GlcNAcylation of GLT-1 and could be a potential target for antidepressants.
O-GlcNAc proteins:
ZFR, BSN, ABLM3, SHAN2, UNC80, HYCC2, 4ET, MACF1, PCLO, HDAC6
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 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, KANL3, 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, PICAL, 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, UBP2L, WNK3, ZN598, CTIP, SHAN2, NANOG, DDX42, RHG32, VGLU3, LPP, TET3, MYPT2, IF4B, CNO10, MISSL, TB10B, CARF, TGO1, ZN879, SP130, ZC3HE, ZNT6, SUN2, TNR6B, ARI5B, EMSY, BNC2, KAT6B, KMT2C, CLAP2, CNOT4, SRRM2, TOX4, GEPH, SYP2L, LARP4, KANK2, SALL4, YTHD3, TOIP2, KAT6A, ASXL2, POGZ, SREK1, 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, CIC, WAC, TRPS1, MED1, ACATN, NRBP, RP25L, NONO, TAB2, RBM10, 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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Zhu WZ, Palazzo T, Zhou M, Ledee D, Olson HM, Paša-Tolić L, Olson AK. First comprehensive identification of cardiac proteins with putative increased O-GlcNAc levels during pressure overload hypertrophy. PloS one 2022 17(10) 36288343
Abstract:
Protein posttranslational modifications (PTMs) by O-GlcNAc globally rise during pressure-overload hypertrophy (POH). However, a major knowledge gap exists on the specific proteins undergoing changes in O-GlcNAc levels during POH primarily because this PTM is low abundance and easily lost during standard mass spectrometry (MS) conditions used for protein identification. Methodologies have emerged to enrich samples for O-GlcNAcylated proteins prior to MS analysis. Accordingly, our goal was to identify the specific proteins undergoing changes in O-GlcNAc levels during POH. We used C57/Bl6 mice subjected to Sham or transverse aortic constriction (TAC) to create POH. From the hearts, we labelled the O-GlcNAc moiety with tetramethylrhodamine azide (TAMRA) before sample enrichment by TAMRA immunoprecipitation (IP). We used LC-MS/MS to identify and quantify the captured putative O-GlcNAcylated proteins. We identified a total of 700 putative O-GlcNAcylated proteins in Sham and POH. Two hundred thirty-three of these proteins had significantly increased enrichment in POH over Sham suggesting higher O-GlcNAc levels whereas no proteins were significantly decreased by POH. We examined two MS identified metabolic enzymes, CPT1B and the PDH complex, to validate by immunoprecipitation. We corroborated increased O-GlcNAc levels during POH for CPT1B and the PDH complex. Enzyme activity assays suggests higher O-GlcNAcylation increases CPT1 activity and decreases PDH activity during POH. In summary, we generated the first comprehensive list of proteins with putative changes in O-GlcNAc levels during POH. Our results demonstrate the large number of potential proteins and cellular processes affected by O-GlcNAc and serve as a guide for testing specific O-GlcNAc-regulated mechanisms during POH.
O-GlcNAc proteins:
MA7D1, CAVN4, OTUD4, FIBA, TRDN, DPYL2, CLCA, MYH11, KNG1, PRDX6, AKAP1, DLDH, NDUBB, GSTO1, CASQ2, RL21, PHB2, ECH1, NDUA1, TIM44, CAVN1, AKAP2, SLK, NIPS2, AT2A2, PGAM2, EF1B, ATX2, NMT1, XIRP1, PDLI1, MYPC3, SNX3, DC1I2, PLIN4, ROA2, RAD, CLPP, TOM1, COX1, COX2, CAH2, CO3, IGJ, KV2A7, IGKC, GCAB, IGHG1, IGH1M, B2MG, HBA, HBB1, LAMC1, FABP4, CFAB, MYG, ALDOA, ANF, AATC, AATM, TBA1B, LDHA, G6PI, TRY2, TTHY, KCRM, ANXA2, ALBU, SPA3K, ENPL, APOE, MDHM, ITB1, PDIA1, NUCL, PGK1, FRIH, MYL3, SODM, NDUB1, ANXA1, EF1A1, CATB, TAU, THIO, GSTM1, H2B1F, H10, CO1A1, FABPH, HS90B, DMD, PFKAL, COX5A, RL7A, GELS, MYH3, AT1B1, GLUT4, RL7, MDHC, RSSA, CALR, HSPB1, ANXA6, GLNA, B4GT1, GSTM2, H12, LDHB, SPTN1, G3P, ENOA, HXK1, PPIA, TPIS, BASI, COF1, RL13A, SERPH, COX5B, COX41, BIP, PRDX3, VIME, CYTC, ENOB, TGM2, EIF3A, CBX3, CXA1, PIMT, CRYAB, CATA, CAPG, GSTA4, RS2, TLN1, MOES, RADI, CTNA1, DHE3, FKB1A, MAP4, RL3, H2AX, PDIA3, PABP1, FRIL1, FETUA, DESM, AIMP1, SCP2, LA, ANT3, RANG, MIF, PTN11, HSPB7, ODPA, CALX, PRDX1, RL12, RL18, FBLN2, HMGCL, GRP75, CAP1, TKT, RL28, ACSL1, ECI1, H14, H11, H15, H13, ALDR, COF2, ACADM, PRS7, ADX, ALDH2, CAPZB, RL6, RL29, CACP, RL13, ANXA5, TBCA, LMNA, CX7A2, TNNI3, ADT1, ROA1, PCY1A, CAV1, ODBA, DHB8, CSRP3, ACADV, PA2G4, TNNT2, ICAL, ACADL, CAV3, MLRV, ADT2, LUM, KPYM, NDUS6, CPT2, RL10A, ODB2, CCHL, MOT1, IDHP, STOM, ADK, ATPK, ACYP2, ATP68, ATP5E, AT5G2, CX6B1, CX7A1, COX7B, CYB5, UBP5, ATPB, WFS1, EF1D, ACTN4, EF2, OPA1, TPM1, B2L13, PCBP1, ACTB, RS20, PPLA, UB2D3, UBC12, UBE2N, RL26, RL27, SUMO2, HNRPK, 1433G, RS7, RS8, 1433E, RS14, RS18, RS11, RS13, DLRB1, EF1A2, RS4X, RL23A, RS6, H4, RAN, RS15, RS25, RS30, RL30, CYC, RL31, RS3, RL32, RL8, FBX40, YBOX1, RS27A, HSP7C, MPC1, CH60, GNAS2, 1433Z, HMGB1, IF5A1, ACTG, ACTH, RS12, RS10, RL22, ACTC, UB2L3, 1433T, TBA4A, TBB4B, H31, IMB1, PEBP1, HINT1, IDHG1, NACAM, TCPD, SGCD, SGCA, WNK1, RL19, SRSF3, H32, RS3A, G3BP2, ANXA4, COQ7, FUMH, G3BP1, LAMA4, QCR6, PRDX5, APOA1, CO1A2, NDKB, TERA, UBA1, MYH6, ATPA, KCRB, CO6A1, PGBM, EMAL1, ATP5I, CLUS, ANXA7, ACADS, CD36, NEBL, PERM1, TRI72, HSDL2, HP1B3, PRC2C, TM38A, Q3TV00, SRSF6, FUBP2, SDHF1, EI3JA, LIMC1, AAK1, NDUB6, MCCB, COBL1, SLMAP, SRBS2, K22O, CPZIP, NDUF2, MYPN, HSPB6, MLIP, IASPP, TM1L2, ODO1, LAMA2, STIP1, REEP5, VDAC2, VDAC1, COQ8A, LAP2B, PRDX2, HCFC1, LAMB2, HSP74, HCDH, FBN1, FXR1, KTN1, GDIB, DDX5, KINH, LASP1, PZP, NPM, NNTM, SNRPA, SPTB2, SPEG, SRBS1, DBNL, NDUA4, FKBP3, IF4G2, ZYX, CAVN2, SPRE, SF01, CD34, CH10, H2A2B, H2A2C, NQO1, VINC, EI3JB, CLH1, H2A2A, GPSM1, IF4G1, KCRS, LPPRC, AT1A2, CAND2, RS9, CMYA5, FHOD3, ATPMK, MIC27, MSRB2, NP1L4, MTCH1, MTCH2, PICAL, NDUAC, HNRPQ, HUWE1, LC7L2, MIC10, NEXN, SRCA, LNP, CLAP1, SRA1, UBP2L, NRAP, BDH, GLRX5, ATPF1, EFTU, H2A3, LPP, ROA3, MYPT2, IF4B, ECHM, RCN3, SYIM, EIF2A, ODPX, EEA1, ODP2, ECHA, COQ3, RL24, FLNA, TIDC1, PLIN5, SYP2L, SSDH, THIM, MIC60, PABP2, BOLA3, SYEP, LONM, H2A1F, H2A1H, H2A1K, SEPT8, PGP, AL4A1, SLAI2, PDLI5, PYGB, PAK2, AFG32, EIF3B, FIBB, COXM2, COQ9, SDHA, SIR5, ACD10, NDUS8, NNRE, HIBCH, THIL, MARE2, QCR9,