Fig 1: UBA2 expression levels in colorectal cancer cell lines. (A) UBA2 mRNA expression levels in colon cancer cell lines were detected by RT-qPCR. (B) UBA2 mRNA expression levels in RKO cells transfected with UBA2-siRNA or NC-siRNA. (C) UBA2 protein expression levels in RKO cells transfected with UBA2-siRNA or NC-siRNA were detected by western blotting. (D) UBA2 mRNA expression levels in HCT116 cells transfected with UBA2-siRNA or NC-siRNA were detected by RT-qPCR. (E) UBA2 protein expression levels in HCT116 cells transfected with UBA2-siRNA or NC-siRNA were detected by western blotting. All experiments were performed three times in triplicate. NC, negative control; RT-qPCR, reverse transcription-quantitative polymerase chain reaction; siRNA, small interfering; UBA2, ubiquitin like modifier activating enzyme 2.
Fig 2: Characterization of Epac1-EYFP and mRuby-UBA2 nuclear condensates.(A) Confocal images of HEK293 cells expressing WT Epac1-EYFP or Epac1-R279E-EYFP in response to 5 µM 007-AM (7 min). (B) Quantification of Epac1-EYFP or Epac1-R279E-EYFP nuclear condensates in DMSO- or 007-AM–treated HEK293 cells. Data are shown as means ± SEM. (C) Confocal live-cell images from a time-lapse movie of Epac1-EYFP–expressing HEK293 cells in response to 5 µM 007-AM. (D) Confocal images of HEK293 cells expressing Epac1-EYFP and mRuby-UBA2. (E) Line graphs show fluorescence intensities of Epac1-EYFP and mRuby-UBA2 across the white dashed lines. (F) Confocal images of HEK293 cells expressing Epac1-EYFP and mRuby-UBA2 in response to 5 µM 007-AM. (G) Graphs show fluorescence intensities of Epac1-EYFP and mRuby-UBA2 across the white dashed lines in 007-AM (5 µM)–treated HEK293 cells.
Fig 3: Restoration of UBA2 rescues the cancer inhibitory role of miR-133a in CRC cells. (A-C) The effect of miR-133a and UBA2 on CRC cell proliferative capability was analyzed according to cell viability and colony formation. (D, E) The effect of miR-133a and UBA2 on CRC cell invasion and migration capacity was assessed across transwell assay. (F, G) The effect of miR-133a and UBA2 on cycle arrest and apoptosis in CRC cell, respectively.
Fig 4: Effects of UBA2 on the cell cycle and apoptosis. (A and B) Cell cycle analysis by flow cytometry in RKO cells transfected with (A) NC-siRNA and (B) UBA2-siRNA. (C) Relative quantity of cells in G0/G1, S and G2/M phases in the RKO cells transfected with UBA2-siRNA or NC-siRNA. (D and E) Cell cycle analysis by flow cytometry in HCT116 cells transfected with (D) NC-siRNA and (E) UBA2-siRNA. (F) Relative quantity of cells in G1/G1, S and G2/M phases in the HCT116 cells transfected with UBA2-siRNA or NC-siRNA. (G-J) Apoptosis analysis by flow cytometry in (G) RKO cells transfected with NC-siRNA, (H) RKO cells transfected with UBA2-siRNA, (I) HCT116 cells transfected with NC-siRNA, and (J) HCT116 cells transfected with UBA2-siRNA. (K and L) Apoptotic rates calculated from data in RKO cells and HCT116 cells. *P<0.05, **P<0.01 vs. the NC-siRNA. All experiments were performed three times in triplicate.
Fig 5: FAT10 is unproductively activated by AOS1/UBA2. a No FAT10 conjugates are formed in HEK293-UBA6 knockout cells. FAT10 conjugate formation was investigated using crude cell lysates, prepared under denaturing conditions of FLAG-FAT10 expressing HEK293 wild-type (WT), or HEK293-UBA6 knockout (UBA6-ko) cells. FAT10 conjugates were visualized by western blotting using the antibodies indicated. Shown is one experiment out of three experiments with similar outcomes. b Reconstitution of UBA6-ko cells with overexpressed AOS1/UBA2 does not rescue FAT10 conjugate formation in these cells. HEK293-UBA6-ko cells were transiently transfected with expression plasmids for SUMO E1 subunits UBA2 and AOS1. Cells were treated with IFN-?/TNF-a to induce endogenous FAT10 expression. HEK293 wild-type (WT) cells were used as a control. Proteins were separated on 4–12% gradient gels (NuPage) and visualized by western blotting using the antibodies indicated. Shown is one experiment out of two experiments with similar outcomes. c No conjugation of FAT10 onto JunB under in vitro conditions in presence of the SUMOylation system instead of the FAT10ylation system after 60 min at 37 °C. In vitro JunB FAT10ylation assay was performed as shown in Fig. 2a. The exact recombinant protein amounts used are listed in the methods section. Shown is one experiment out of three experiments with similar outcomes. d Intra- and inter-protein crosslinks of AOS1/UBA2 and FAT10 in the absence of ATP. FAT10 (Sequence offset to UniProt sequence -1 aa due to tag) and the SUMO E1 subunits 6-His-AOS1 (Sequence offset to UniProt sequence: +23 aa) and UBA2 are depicted on the residue level. Lysine residues, as potential targets of the crosslinking agent used in this study, are indicated as black lines. Inter-protein crosslinks are shown in green and intra-protein crosslinks in purple. e Intra- and inter-protein crosslinks of AOS1/UBA2 and FAT10-AV in the absence of ATP, as described in d. f Schematic depiction of the mechanisms how FAT10 inhibits SUMO activation. (i) SUMO activation by AOS1/UBA2 in absence of FAT10. (ii) Inhibition of SUMO activation when FAT10 is non-covalently bound to the adenylation site of AOS1/UBA2, or when FAT10 is thioester bound to the active-site cysteine of the AOS1/UBA2. Source data are provided as a Source Data file
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