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Kang D, Lee J, Yook G, Jeong S, Shin J, Kim MS, Kim YJ, Jung H, Ahn J, Kim TW, Chang MJ, Chang CB, Kang SB, Yang WH, Lee YH, Cho JW, Yi EC, Kang C, Kim JH. Regulation of senescence-associated secretory phenotypes in osteoarthritis by cytosolic UDP-GlcNAc retention and O-GlcNAcylation. Nature communications 2025 16(1) 39904978

Abstract:
UDP-GlcNAc serves as a building block for glycosaminoglycan (GAG) chains in cartilage proteoglycans and simultaneously acts as a substrate for O-GlcNAcylation. Here, we show that transporters for UDP-GlcNAc to the endoplasmic reticulum (ER) and Golgi are significantly downregulated in osteoarthritic cartilage, leading to increased cytosolic UDP-GlcNAc and O-GlcNAcylation in chondrocytes. Mechanistically, upregulated O-GlcNAcylation governs the senescence-associated secretory phenotype (SASP) by stabilizing GATA4 via O-GlcNAcylation at S406, which compromises its degradation by p62-mediated selective autophagy. Elevated O-GlcNAcylation in the superficial layer of osteoarthritic cartilage coincides with increased GATA4 levels. The topical deletion of Gata4 in this cartilage layer ameliorates post-traumatic osteoarthritis (OA) in mice while inhibiting O-GlcNAc transferase mitigates OA by decreasing GATA4 levels. Excessive glucosamine-induced O-GlcNAcylation stabilizes GATA4 in chondrocytes and exacerbates post-traumatic OA in mice. Our findings elucidate the role of UDP-GlcNAc compartmentalization in regulating secretory pathways associated with chronic joint inflammation, providing a senostatic strategy for the treatment of OA.

O-GlcNAc proteins:
GATA4

Species: Homo sapiens

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Hou C, Wu C, Wu Z, Cheng Y, Li W, Sun H, Ma J. Systematic Evaluation of Affinity Enrichment Methods for O-GlcNAc Proteomics. Journal of proteome research 2024 39302247

Abstract:
O-Linked β-N-acetylglucosamine (O-GlcNAc) modification (i.e., O-GlcNAcylation) on proteins plays critical roles in the regulation of diverse biological processes. However, protein O-GlcNAcylation analysis, especially at a large scale, has been a challenge. So far, a number of enrichment materials and methods have been developed for site-specific O-GlcNAc proteomics in different biological settings. Despite the presence of multiple methods, their performance for the O-GlcNAc proteomics is largely unclear. In this work, by using the lysates of PANC-1 cells (a pancreatic cancer cell line), we provided a head-to-head comparison of three affinity enrichment methods and materials (i.e., antibody, lectin AANL6, and an OGA mutant) for site-specific O-GlcNAc proteomics. The enriched peptides were analyzed by HCD product-dependent EThcD (i.e., HCD-pd-EThcD) mass spectrometry. The resulting data files were processed by three different data analysis packages (i.e., Sequest HT, Byonic, and FragPipe). Our data suggest that each method captures a subpopulation of the O-GlcNAc proteins. Besides the enrichment methods, we also observe complementarity between the different data analysis tools. Thus, combining different approaches holds promise for enhanced coverage of O-GlcNAc proteomics.

O-GlcNAc proteins:
NBAS, SBNO1, PRS37, CNOT1, MGT4D, P121C, P20L1, MCRI1, SPT5H, MANBA, AGRIN, BCL9, NOP56, ARI1A, ABLM1, KMT2D, SCAM3, MYPT1, HNRDL, XPO1, SYN3, SC16A, SYNJ2, SYNEM, TIF1A, LAMA5, MCES, DC1L2, CP110, IF4G3, E41L2, ZN207, BUB1, HTSF1, AKAP8, DHX16, MGRN1, TRAK2, KIF1B, PLIN3, MAFK, IF2P, DTNB, MITF, SRGP2, ATG13, ZC11A, PP6R2, ANR17, LRP5, NDUS2, NCOR1, U520, UTP20, WDHD1, FACE1, TOX4, SC24D, SUN1, SC31A, CE152, UBR5, AGFG2, APOL3, IPO7, SVIL, SC24A, SC24B, ZMYM6, GPR75, LATS1, LMNA, GCR, OAT, CPNS1, HSPB1, GNAI2, A4, K1C18, ATPB, SAP, PROF1, HS90A, HS90B, NFIC, VIME, SNRPA, ATX1L, DERPC, PTPRF, ESTD, ODPB, C1TC, SKIL, XRCC6, CCNB1, ATF2, NDKA, GNS, ZEP1, AT2A2, ATF7, ERCC2, EGR1, ATF1, GGT1, AT2B1, FLNA, 5NTD, PUR2, RFX1, SFPQ, RS3, STOM, ARNT, MAP4, KPYR, CLIP1, HXC9, ZEP2, QCR1, I5P2, ELF1, MRP1, TRY3, CAH8, T2FA, NU214, NUP62, STAT3, ECHA, HNF4A, LAP2A, LAP2B, CACP, GATA4, BAG6, MAP1B, STT3A, RFX5, PAXI, LMAN1, CDK8, CENPF, YLPM1, NU153, RBP2, GSK3A, TAF6, DNLI3, EMD, TCPD, PAPOA, HNRPM, AGFG1, STAT2, NUP98, ATX1, ATN1, RD23B, AF10, BRPF1, NP1L1, EIF3B, MAZ, HDAC4, IF6, H2B1D, ACTB, ABCE1, RRAS2, ERF1, RL32, ACTG, EF1A1, CSK21, F193A, SARNP, FOXK1, ZBED6, RHG04, CLH1, SPTB2, TIAR, SP2, DYST, ATP7A, NOTC2, TLE4, PTN12, FAK1, ZO1, ACK1, DHX9, EP300, AHNK, NEXN, CPSF1, WASC5, TROAP, BPTF, SF3A3, TP53B, PTN13, TRAP1, DLG1, ATM, PPIL2, TCOF, SMAD4, PICAL, MAMD1, ASPP2, RIN1, CDK13, VEZF1, UBP2L, SRC8, CAPR1, ITPR1, MDC1, RRP1B, UBP10, COG2, MEF2D, LASP1, IMB1, PLEC, NONO, SF3A1, JHD2C, ELF2, TAB1, NCOA1, ZYX, UAP1, DREB, PDS5A, QSER1, TXIP1, FHOD3, P3H1, EMAL3, ZN791, CHD9, TB10B, FND3B, CRTC2, BCORL, BRD10, CE170, ZN362, ZEP3, UBR4, UBAP2, AHDC1, RPRD2, ZN318, TUT7, RN213, TENS2, WAC2A, MAP1S, ARID2, TENS3, ANR40, BICRL, ATLA3, CPIN1, GRAM4, NIPBL, LIN54, RINT1, L2GL2, C2D1A, SCYL2, NFRKB, ZC3HE, LARP1, ZNT9, CRTC3, GLB1L, MCAF1, SRCAP, CFA65, UBN2, VP13C, RAPH1, H32, TMUB2, MARK2, DDX46, EIF3M, KDM3B, GRIN1, KANL1, POGZ, NUFP2, MAVS, DHX29, EMSY, RAI1, I2BP2, HUWE1, YTHD3, KAISO, MYPN, LYRIC, KTN1, PRSR1, DDX42, P66A, RHPN2, NUDC3, AHNK2, GID4, ARI3B, MA7D3, MGAP, LMTK2, ANKH1, SUGP1, MILK2, SRRM1, PHAR4, DCP1B, PELP1, TENS4, CCAR2, HROB, TXND5, RB15B, TNR6A, PHC3, NAV1, VP37A, SYNE1, FAD1, NUP35, TOIP2, KNL1, O52N2, TRY6, COP1, GOGA5, ALMS1, DLG5, MORC4, GEMI5, PIGO, PARD3, IPO4, TM263, PDC6I, LMO7, ATX2L, PHIP, P66B, BBX, SMG7, F168A, PRCC, RYR2, US6NL, SYMPK, RENT1, PF21A, EFHD2, KBP, F120B, RBM33, THOC1, P121A, PDLI5, VPS50, DNJC1, Z512B, ZFR, EP400, SENP8, PRRC1, DOCK7, RBM14, NEK1, PP1RA, PHF12, SPAG5, CIC, ERBIN, SIN3A, MINT, HTF4, VAT1, PLIN2, DNJC2, MNT, KIF2C, ATX2, ARI3A, GDF15, WAC, DIDO1, RFIP5, SRRT, SETD2, ABCA2, TRIM5, TANC1, ZN407, SP130, PUS7L, I2BPL, NELFA, CHM4B, WNK1, ZHX3, CDCP1, Z385D, BCAS3, PEAK1, ECT2, JUPI2, ZN408, PKHA1, ILRL2, RC3H2, TAF9B, NCOA5, TANC2, SYTL2, CHD8, UBN1, DCP1A, SEM4B, HPS4, PDLI7, 4ET, CHRC1, F1142, LTBP3, SYIM, IGSF5, RBM12, STAU2, TYDP1, SLTM, CARF, HXC10, TAB2, CDK12, ERAP1, MYOF, BICRA, CNOT2, SPN90, F135A, RBM27, KANL3, ZMYM2, LIMD1, TCF20, UBQL2, S30BP, PUF60, SIX4, TRM6, NOCT, TASOR, GMEB2, ACINU, CNO11, ASAP1, YETS2, ZMYD8, MYO6, SPAT2, PRP19, NSF1C, MACF1, TRAK1, SRRM2, SCML2, PDE10, AP3M1, ZN281, ZN711, TLN1, ARIP4, DCAF1, WAC2C, RPGF2, CRBG1, PRC2C, UTP18, SNX9, NCOR2, BIG1, NCOA3, PCLO, S23IP

Species: Homo sapiens

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Hou C, Deng J, Wu C, Zhang J, Byers S, Moremen KW, Pei H, Ma J. Ultradeep O-GlcNAc proteomics reveals widespread O-GlcNAcylation on tyrosine residues of proteins. Proceedings of the National Academy of Sciences of the United States of America 2024 121(47) 39531497

Abstract:
As a unique type of glycosylation, O-linked β-N-acetylglucosamine (O-GlcNAc) modification (O-GlcNAcylation) on Ser/Thr residues of proteins was discovered 40 y ago. O-GlcNAcylation is catalyzed by two enzymes: O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA), which add and remove O-GlcNAc, respectively. O-GlcNAcylation is an essential glycosylation that regulates the functions of many proteins in virtually all cellular processes. However, deep and site-specific characterization of O-GlcNAcylated proteins remains a challenge. We developed an ultradeep O-GlcNAc proteomics workflow by integrating digestion with multiple proteases, two mass spectrometric approaches (i.e., electron-transfer/higher-energy collision dissociation [EThcD] and HCD product-dependent electron-transfer/higher-energy collision dissociation [HCD-pd-EThcD]), and two data analysis tools (i.e., MaxQuant and Proteome Discoverer). The performance of this strategy was benchmarked by the analysis of whole lysates from PANC-1 (a pancreatic cancer cell line). In total, 2,831 O-GlcNAc sites were unambiguously identified, representing the largest O-GlcNAc dataset of an individual study reported so far. Unexpectedly, in addition to confirming known sites and identifying many other sites of Ser/Thr modification, O-GlcNAcylation was found on 121 tyrosine (Tyr) residues of 93 proteins. In vitro enzymatic assays showed that OGT catalyzes the transfer of O-GlcNAc onto Tyr residues of peptides and OGA catalyzes its removal. Taken together, our work reveals widespread O-GlcNAcylation on Tyr residues of proteins and that Tyr O-GlcNAcylation is mediated by OGT and OGA. As another form of glycosylation, Tyr O-GlcNAcylation is likely to have important regulatory roles.

O-GlcNAc proteins:
NPIA9, RBM47, E2F8, SBNO1, CNOT1, P121B, HMX3, RHG32, P121C, NACAM, PDLI1, TAF4, DNM1L, PLOD2, CAC1A, ARI1A, CDKA1, NCAN, ABLM1, KMT2D, HGS, MYPT1, ZN609, SC16A, SET1A, TRNK1, OGT1, TNC18, P4HA2, NUP42, KDM6A, ASAP2, SI1L1, RFOX2, PRPF3, SYNJ1, IF4G3, MTG8R, E41L2, PLRG1, ZN207, BUB1, MYPT2, KPRB, ZN292, SI1L3, GANP, TBC12, OGA, KLH41, PLIN3, MAFK, ABCC9, TBL1X, MITF, SRGP2, SLIT3, T22D2, PP6R2, ANR17, LIPA4, ZN217, NCOR1, U520, RASF9, DYSF, TOX4, SC24D, FCSD2, PCF11, NFAT5, SC31A, AGFG2, SCAF4, ELP1, MRP6, SVIL, SC24A, SC24B, CNOT4, ZMYM6, BAG3, LATS1, LMNA, CATA, GCR, CPNS1, HSPB1, RPN1, RLA2, ITB1, K1C18, K2C8, NPM, CATD, GP1BA, SAP, CATB, SP1, PTPRC, NFIC, VIME, K1C19, SNRPA, ATX1L, LAMC1, ARY2, SRF, PABP1, TPR, SKIL, ENPL, PO2F1, B4GT1, ATF2, FOSL1, FOSL2, GNS, ZEP1, RS2, TFE2, CREB1, HXB6, ATF7, EGR1, SON, ATF1, NUCL, ICAL, OSBP1, RFX1, CBL, NFYA, IF4B, GATA2, ARNT, MAP4, GRN, CDC27, CLIP1, HXC9, ZEP2, ELF1, NU214, NUP62, CUX1, STAT3, BUD31, HNF4A, LAP2A, MTOR, PCP, MATR3, GATA4, UTRN, STT3A, RFX5, SOX9, PRC2A, NEST, HSP13, NASP, CDK8, YLPM1, NU153, RBP2, TAF6, EMD, PPT1, PAPOA, FXR2, KCNQ1, MYOM1, AGFG1, HNRPF, NUP98, SMTN, SC24C, ATX1, RD23B, AF17, DSRAD, MAZ, CTBP2, CSK21, F193A, SERB, IF4G2, GTF2I, PHC1, NGAL, KGD4, SARNP, FOXK1, DAB2, PGBM, RHG04, SPTB2, FOXK2, OTUD4, EWS, SP2, NRG1, SP4, SP3, PAX2, KMT2A, IF4G1, NOTC2, PTN12, GABPA, GABP1, CKAP4, ZO1, ACK1, TLE5, EP300, AHNK, ASPH, TROAP, BPTF, NFIA, TP53B, FOXC1, TAF10, PICAL, MAMD1, SQSTM, RIPK1, STIM1, CUL4B, NFYC, CDK13, CKAP5, VEZF1, UBP2L, GIT2, SRC8, CAPR1, PUM1, MDC1, EPN4, TTLL4, RRP1B, NCOA6, GSE1, MEF2D, ZN638, NUMA1, HECAM, R3HD1, DAZP2, KIF14, PDK3, EBP, NONO, LRC41, RBMS2, SSXT, NCOA2, SF01, MED1, JHD2C, T22D1, ELF2, TAB1, NCOA1, TBCC, ZFHX3, ZYX, CCDC6, TAF9, DREB, NRF1, GEN, RFX7, QSER1, AAK1, PRSR3, RGPA2, QRIC1, TB10B, TPRN, FIL1L, CRTC2, IF44L, YIF1B, NOM1, BCORL, DDX6L, BRD10, SH319, TGO1, PRC2B, CE170, ZN362, DCST2, ZEP3, ZC3HD, CSCL2, LRIF1, RHG21, UBAP2, RBM26, CF163, AHDC1, RPRD2, ZN318, TASO2, ZMYM4, PAPD7, TENS2, KANK2, ICE2, ARID2, TENS3, USF3, ANR40, BICRL, SDE2, NIPBL, LIN54, TET2, ZNT6, EDC4, SCYL2, TTC27, NFRKB, RSBNL, TT23L, NCEH1, MDEAS, ZC3HE, FIP1, CRTC3, SAS6, ARSK, MCAF1, BCOR, GGYF2, AEBP2, BNC2, NFXL1, CO039, SRCAP, UBN2, TM1L2, RAPH1, HAKAI, ASXL2, SPT6H, BOP, KDM3B, ZCCHV, NUP54, RGPD4, POGZ, ZFY16, NUFP2, MAVS, EMSY, RAI1, I2BP2, SDK1, SRGP1, RBBP6, SH3R1, YTHD3, CENPV, KAISO, MYPN, LDB1, LYRIC, ABCAC, BCL9L, CASZ1, TSYL5, CARM1, PRSR1, DDX42, CACL1, P66A, HIPK1, RB6I2, AHNK2, NAV2, GID4, ARI3B, TEX2, MGAP, Z3H7A, ANKH1, SUGP1, CCAR1, MILK2, GAR4, TBC21, PHAR4, XRN1, MAML2, SPART, NUP93, DOCK4, SYNPO, FNBP4, AF1L2, TAB3, NOPC1, IGSF1, ARFG1, ENAH, TM102, WDR31, MISSL, TNR6A, PHC3, SP20H, NAV1, VP37A, KMT2C, ARI1B, NUP35, KNL1, O52H1, PLBL2, NEDD1, SMRC2, TBC15, ZN507, ALMS1, DLG5, FNIP1, ZN384, WIPF2, PYRD1, D42E1, PCNP, LMO7, ATX2L, P66B, BBX, ELYS, ZCH14, PIEZ1, GBF1, RTF1, PHF3, MAML1, ZN592, LAR4B, SORL, TFG, TAF4B, RREB1, CBP, DDX17, GPKOW, M4K1, FUBP2, LPP, WNT2B, P33MX, ACD, FKB10, TTC28, PF21A, ZN669, ZN501, REPS1, RBM33, CERS2, GWL, P121A, CC120, PDLI5, SENP5, VCIP1, ZN462, CHAP1, LCOR, Z512B, ZFR, EP400, BMF, PRRC1, NOL4L, RBM14, QKI, PHF12, CIC, MED15, ERBIN, SIN3A, MINT, HTF4, EYA3, DNJC2, ELF4, RGPD5, ATX2, TS101, ARI3A, TEP1, DPH2, GPTC1, WAC, DIDO1, HNRL1, CP250, NUP58, RBM4, UBP26, YTHD1, BCDO2, B2L14, AMRA1, CE295, TANC1, ZC12C, CEP44, SP130, BRD8, I2BPL, RBNS5, EPC1, ADNP, HIPK2, ZN106, PTN23, WNK1, ZHX3, ZN644, HAUS4, SLAP2, YTDC2, PEAK1, PKHG2, ECT2, GORS2, MLXIP, PKHA5, CLSPN, CDHR5, RC3H2, TAF9B, NCOA5, TANC2, ZN532, TNR6C, CHD8, APMAP, UBE2T, DMAP1, UBN1, DCP1A, RTN4, PRD10, PDLI7, EI2BG, MBNL1, RNC, RBM12, INT7, CARF, ABI2, HXC10, TAB2, CDK12, GRHL1, ITSN2, BICRA, CNOT2, FLRT1, KCMF1, DAPLE, CHD7, F135A, RBM27, KANL3, RERE, LIMD1, TCF20, SUN2, UBQL2, TRPS1, S30BP, PUF60, NRBP, BAZ2B, SIX4, HOOK1, GGA2, TASOR, AKA11, GMEB2, PARP4, MYO15, MYH13, NUP50, ZHX1, CDV3, MRTFB, ZBT21, PLXB3, PRR12, YETS2, HECD1, ZMYD8, SPAT2, PRP19, SOX13, SCAF8, TRI33, TNR6B, SET1B, SATB2, SHAN2, HPS5, SRRM2, SCML2, R3HD2, ZN281, KLK5, ARIP4, MTCL1, RPGF2, CRBG1, HYOU1, PRC2C, RBM7, YTHD2, HCFC2, NCOR2, GMEB1, NCOA3, S23IP

Species: Homo sapiens

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Luo Y, Wang Y, Tian Y, Zhou H, Wen L. "Two Birds One Stone" Strategy for the Site-Specific Analysis of Core Fucosylation and O-GlcNAcylation. Journal of the American Chemical Society 2023 145(29) 37340703

Abstract:
Core fucosylation and O-GlcNAcylation are the two most famous protein glycosylation modifications that regulate diverse physiological and pathological processes in living organisms. Here, a "two birds one stone" strategy has been described for the site-specific analysis of core fucosylation and O-GlcNAcylation. Taking advantage of two mutant endoglycosidases (EndoF3-D165A and EndoCC-N180H), which efficiently and specifically recognize core fucose and O-GlcNAc, glycopeptides can be labeled using a biantennary N-glycan probe bearing azido and oxazoline groups. Then, a temperature-sensitive poly(N-isopropylacrylamide) polymer functionalized with dibenzocyclooctyne was introduced to facilitate the enrichment of the labeled glycopeptides from the complex mixture. The captured glycopeptides can be further released enzymatically by wild-type endoglycosidases (EndoF3 and EndoCC) in a traceless manner for mass spectrometry (MS) analysis. The described strategy allows simultaneous profiling of core-fucosylated glycoproteome and O-GlcNAcylated glycoproteome from one complex sample by MS technology and searching the database using different variable modifications.

O-GlcNAc proteins:
LCE6A, RBM47, HFM1, SMCO3, SBNO1, ODAD3, CNOT1, RCCD1, GLTD2, AGAP5, CX049, PDLI1, TAF4, ABLM1, DVL1, HGS, SC16A, NPC1, LAMA5, TET3, IF4G3, E41L2, AKAP8, PLIN3, MAFK, OPHN1, MITF, OBSL1, ANR17, ENTP6, NCOR1, ERLN1, JERKY, MYCB2, WDHD1, CBPD, TOX4, AGFG2, SC24B, PCNT, BAG3, DDAH2, CLPT1, AACT, LMNA, FINC, FETUA, GCR, KITH, HSPB1, RPN1, RLA2, ITB1, K1C18, ENOA, CATD, TBB5, TACD2, LYAG, BIP, LAMC1, HSP7C, DMD, MPRI, SKI, GILT, GLU2B, ENPL, RSMB, PO2F1, PVR, ZEP1, DPEP1, CBPE, ATF7, SON, ATF1, ITIH2, FST, ICAL, FGF7, CD9, CBL, ITA6, PTPRB, COF1, GATA3, PSA4, PEBP1, CLIP1, ZEP2, GLPK, ELF1, CD68, GPC1, HRH1, IRS1, NU214, SRP14, NUP62, ETFB, LICH, TXLNA, STAT3, MATR3, SSRA, GATA4, MMP13, 5HT3A, NOTC1, YAP1, RFX5, FAS, CDK8, CENPF, NU153, SEPP1, EMD, BCAM, SPHM, ARSD, AGFG1, NUP98, PTTG, RAD, AF17, DSRAD, ITA1, IF6, STAR6, ACTB, HNRPK, H4, RL40, CXAR, GPC5, FOXK1, PGBM, SPTB2, FOXK2, IF4G1, NOTC2, PTN12, MTG8, ZO1, LRP1, RGS1, CD47, EP300, AHNK, TROAP, BPTF, NFIA, HYAL2, LMAN2, FOXC1, MB211, OS9, TUSC3, ROCK1, ASAH1, RIPK1, ASPP2, CDK13, SCRB2, VEZF1, DSG2, UBP2L, GIT2, PUM1, RRP1B, NCOA6, MEF2D, CHD4, NUMA1, R3HD1, RCN1, RBMS2, TAF1C, SF01, JHD2C, ELF2, TAB1, HERC1, ZFHX3, ZYX, ADRM1, CCDC6, SNPC1, MA2A1, YC018, QSER1, AAK1, P3H1, GNPTA, RABL6, TB10B, LUZP6, PRC2B, WIPI1, DCA10, HP1B3, ZN362, ZEP3, ZC3HD, UBR4, RHG21, UBAP2, RPRD2, DNAI4, TASO2, RN123, PCX4, ARID2, FTM, BICRL, SCAR3, GRHL2, NIPBL, LIN54, NFRKB, ZC3HE, LCN15, CREL2, IGS10, GGYF2, NBEL2, SRCAP, K0408, UBN2, BACHL, KDM3B, PARPT, RGPD4, POGZ, MAVS, EMSY, RAI1, I2BP2, ABCAC, ZFHX4, LUZP1, FRAS1, RB6I2, AHNK2, S22A9, TEX2, MGAP, SULF2, ANKH1, SUGP1, HYCC2, MILK2, CC116, PHAR4, K319L, ASPM, RPTOR, SYNPO, GALT4, MFSD9, SLAI1, LRTM3, TNR6A, PHC3, VP37A, SYNE1, PLBL2, TIP, CC110, TEX47, TBC15, STT3B, SPP2B, MAGC3, DYH5, PO210, GEMI5, PIGO, F222B, F151A, LMO7, P66B, MYO3B, GBF1, NICA, TM131, ZN592, LAR4B, GSLG1, GPKOW, LPP, TTC28, PF21A, RBM33, GWL, TONSL, PDLI5, VCIP1, ZFR, EP400, CH048, CI072, NOL4L, RBM14, GBP4, CDK15, PHF12, CIC, MED15, G3ST4, FNBP1, MINT, HTF4, EYA3, ARI3A, H2A1J, GDF15, DPH2, BCL7B, TM2D3, PELO, DIDO1, TRAIP, RBM4, CLC7A, UBE2O, PEG3, SP130, BRD8, I2BPL, EPC1, ADNP, RM46, NELFA, WNK1, ZHX3, SDS3, MLXIP, RC3H2, MUC5B, TANC2, CHD8, CELR2, APMAP, PDLI7, RBM12, STAU2, GPTC2, TAB2, CDK12, PTTG3, FLRT1, CRIM1, DAPLE, IBTK, RBM27, KANL3, RERE, SE1L1, LIMD1, TCF20, DPP2, BAP29, S30BP, LCAP, SIX4, POMT2, INT6, MRTFB, NOTC3, ATS5, BSN, SCAF8, ANR26, SHAN2, SRRM2, CTND2, SCML2, ZN652, ZN281, STRAP, VPP2, PRC2C, NCOR2, DC1L1, STON1, S23IP

Species: Homo sapiens

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Li J, Li Z, Duan X, Qin K, Dang L, Sun S, Cai L, Hsieh-Wilson LC, Wu L, Yi W. An Isotope-Coded Photocleavable Probe for Quantitative Profiling of Protein O-GlcNAcylation. ACS chemical biology 2019 14(1) 30620550

Abstract:
O-linked N-acetylglucosamine ( O-GlcNAc) is a ubiquitous post-translational modification of proteins and is essential for cell function. Quantifying the dynamics of O-GlcNAcylation in a proteome-wide level is critical for uncovering cellular mechanisms and functional roles of O-GlcNAcylation in cells. Here, we develop an isotope-coded photocleavable probe for profiling protein O-GlcNAcylation dynamics using quantitative mass spectrometry-based proteomics. This probe enables selective tagging and isotopic labeling of O-GlcNAcylated proteins in one step from complex cellular mixtures. We demonstrate the application of the probe to quantitatively profile O-GlcNAcylation sites in 293T cells upon chemical induction of O-GlcNAc levels. We further applied the probe to quantitatively analyze the stoichiometry of O-GlcNAcylation between sorafenib-sensitive and sorafenib-resistant liver cancer cells, which lays the foundation for mechanistic investigation of O-GlcNAcylation in regulating cancer chemoresistance. Thus, this probe provides a powerful tool to profile O-GlcNAcylation dynamics in cells.

O-GlcNAc proteins:
A0A0B4J203, A0A0C4DFX4, SBNO1, P121B, CX028, RGPD3, AN36A, P121C, GG6L6, S31C2, E9PCH4, H0YAE9, H0YHG0, GG6LV, H3BMH7, PDLI1, TAF4, BCL9, ABLM1, CHD2, KMT2D, RGPD8, OPLA, HGS, MYPT1, ZN609, SC16A, SET1A, TIF1A, EIF3H, TET3, M3K7, PRPF3, TPD54, IF4G3, E41L2, AKAP8, TM11D, MYPT2, GANP, PLIN3, MAFK, BRD4, MITF, N4BP1, ATG13, PP6R2, ANR17, NCOR1, SPAG7, SRS10, SF3B1, CSDE1, TOX4, PCF11, AGFG2, SMC2, M3K6, SC24B, ZBT11, CNOT4, EYA4, OXSR1, ZMYM6, CCNE2, ANGT, LMNA, ALDOA, GCR, HSPB1, F13B, RLA2, K1C18, K2C8, ZFY, SRPRA, RU17, VIME, RU2A, ATX1L, RGPD1, S31C1, GLI3, LYAG, PABP1, COBA1, CO6A3, MYH7, ENPL, ZEP1, RS2, ZFX, ZNF30, ANPRC, ATF7, EGR1, SON, RCC1, ATF1, ATF6A, HXA5, ROA2, CBL, IF4B, GATA2, RIR1, RAE1, APC, ATPA, ARNT, MAP4, HXD9, HLAF, CLIP1, ZEP2, MYH10, TIE1, NU214, DEK, PDE6B, SRP14, CUX1, LPPRC, GATA4, KI67, YAP1, RFX5, SOX2, PRC2A, NASP, CDK8, NU153, RBP2, TAF6, EMD, PAPOA, NEK4, AGFG1, NUP98, INHBC, CADH6, F193A, KGD4, RT34, SARNP, LACTB, COG7, FOXK1, DAB2, PLIN5, SPTB2, SP2, NRG1, IF4G1, K1C17, TLE1, TLE4, UBE3A, ACK1, AHNK, FCHO2, FOXO1, TROAP, BPTF, IRAG2, BFSP1, FOXC1, PRDM2, DDX10, G3BP1, PABP4, GRB10, PPIG, MADCA, PICAL, MAMD1, CUL4B, ASPP2, SPTN1, CDK13, CYLC2, DSG2, UBP2L, SRC8, ITPR3, PUM1, MDC1, EPN4, RRP1B, NCOA6, RRP5, RFTN1, R3HD1, WDR43, EEA1, MTFR1, SF3B3, RYR3, SF01, JHD2C, ELF2, MYLK, TAB1, ZYX, ADRM1, QSER1, CL16A, RHG31, AAK1, TMM44, AMOT, IF44L, YIF1B, AG10A, CD048, FSIP2, ESCO1, S2553, BCORL, AN36C, MTUS2, PRC2B, CEP78, SAMD9, TSBP1, LRIF1, CXG2, SKT, ZN648, UBAP2, RBM26, RC3H1, EFCB6, CE350, RPRD2, S31A6, TASO2, ECM29, RN123, PLCX3, ARID2, DEN2C, K0930, LIN54, M18BP, SCYL2, NFRKB, KLH35, ZC3HE, ANR11, FIP1, SBSN, S49A3, FAT4, MCAF1, BCOR, DUSTY, GGYF2, BNC2, CO039, SRCAP, UBN2, FOXNB, UBP54, HAKAI, ASXL2, KNDC1, SPT6H, TAOK1, KDM3B, RGPD4, POGZ, NUFP2, EMSY, I2BP2, SH3R1, HUWE1, YTHD3, FLIP1, KAISO, MYPN, TTC6, LDB1, TM135, TBC26, ZFHX4, ANGL5, SPAS2, DZIP1, P66A, AHNK2, FMNL3, NAV2, ARI3B, MGAP, RP1L1, CC28A, Z3H7A, CDAN1, ANKH1, SUGP1, PHAR4, KMT2E, XRN1, SPART, NUP93, ZN687, CMTR1, THMS1, AN36B, TMTC2, SYNPO, FNBP4, GG6L1, ENAH, GG6L2, SLAI1, PHC3, BD1L1, NUP35, DDX55, NEIL3, GSDMB, ALMS1, STK35, GEMI5, RPGF6, SMCR8, WIPF2, TM171, RN133, TEKT4, LMO7, CKAP2, ATX2L, ACO11, P66B, DAAF4, BBX, FIG4, ZN516, RREB1, FUBP2, LPP, E2F7, TTC28, TOM6, ASTRA, OTUB2, PGBD4, LEG12, ELP4, RBM33, MYEOV, SMRD1, DDX27, P121A, TONSL, PDLI5, THOC3, VCIP1, LRIQ1, ZFR, EP400, CBPC4, RBM14, IPP2L, QKI, PLIN4, JMJD8, RBM15, MINT, SEC62, AGAP2, RGPD5, ATX2, MYD88, ARI3A, SPI2A, SPI2B, DPH2, MCMBP, TMPSD, YTHD1, WNK3, PP12C, TB182, TANC1, CEP44, SENP6, BRD8, RGAP1, ALX4, KI13A, KCNH6, ZN106, FOXP1, PABP3, SMOC2, WNK1, ZHX3, CP095, REEP4, DOCK5, ZN703, GORS2, MLXIP, PKHA5, FOH1B, RC3H2, TANC2, TRPM3, SYTL2, CP4FC, GAK5, JPH1, APMAP, DMAP1, GP108, KMT5A, GPR84, DUOX2, DUOX1, PCDBG, MDN1, NALP2, CARF, HXC10, TAB2, CDK12, ADA2, ITSN2, F135A, SI1L2, RBM27, KANL3, ZN219, DYH17, AFF4, NB5R1, S30BP, NRBP, BAZ2A, SIX4, HOOK1, TASOR, GMEB2, ZHX1, TAOK2, CFA92, MRTFB, ZBT21, PRR12, YETS2, HECD1, MYO6, ICAM5, MAGD2, SCAF8, TRAK1, SHAN2, SRRM2, EXO1, SCML2, POK19, POLH, NCKP1, AT11B, NOP58, ZN281, UB2J1, GRIP1, SALL2, ARIP4, RPGF2, HYOU1, TTLL3, PRC2C, PCDB4, NCOR2, CP46A, 5MP1, CABIN, NCOA3, S23IP, U3KPZ7

Species: Homo sapiens

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