Xiaojuan Du

hALP, a novel transcriptional U three protein (t-UTP), activates RNA polymerase I transcription by binding and acetylating the upstream binding factor (UBF)

Transcription of ribosome RNA precursor (pre-rRNA) and pre-rRNA processing are coordinated by a subset of U three proteins (UTPs) known as transcriptional UTPs (t-UTPs), which participate in pre-rRNA transcription in addition to participation in 18 S rRNA processing. However, the mechanism by which t-UTPs function in pre-rRNA transcription remains undetermined. In the present study, we identified hALP, a histone acetyl-transferase as a novel t-UTP. We first showed that hALP is nucleolar, and is associated with U3 snoRNA and required for 18 S rRNA processing. Moreover, depletion of hALP resulted in a decreased level of 47 S pre-rRNA. Ectopic expression of hALP activated the rDNA promoter luciferase reporter and knockdown of hALP inhibited the reporter. In addition, hALP bound rDNA. Taken together these data identify hALP as a novel t-UTP. Immunoprecipitation and GST pulldown experiments showed that hALP binds the upstream binding factor (UBF) in vivo and in vitro. It is of importance that hALP acetylated UBF depending on HAT in vivo, and hALP but not hALP (ΔHAT) facilitated the nuclear translocation of the RNA polymerase I (Pol I)-associated factor 53 (PAF53) from the cytoplasm and promoted the association of UBF with PAF53. Thus, we provide a mechanism in which a novel t-UTP activates Pol I transcription by binding and acetylating UBF.

A Small Ribosomal Subunit (SSU) Processome Component, the Human U3 Protein 14A (hUTP14A) Binds p53 and Promotes p53 Degradation

Ribosome biogenesis is required for normal cell function, and aberrant ribosome biogenesis can lead to p53 activation. However, how p53 is activated by defects of ribosome biogenesis remains to be determined. Here, we identified human UTP14a as an SSU processome component by showing that hUTP14a is nucleolar, associated with U3 snoRNA and involved in 18 S rRNA processing. Interestingly, ectopic expression of hUTP14a resulted in a decrease and knockdown of hUTP14a led to an increase of p53 protein levels. We showed that hUTP14a physically interacts with p53 and functionally promotes p53 turn-over, and that hUTP14a promotion of p53 destabilization is sensitive to a proteasome inhibitor but independent of ubiquitination. Significantly, knockdown of hUTP14a led to cell cycle arrest and apoptosis. Our data identified a novel pathway for p53 activation through a defect in rRNA processing and suggest that a ribosome biogenesis factor itself could act as a sensor for nucleolar stress to regulate p53.

NAT10 regulates p53 activation through acetylating p53 at K120 and ubiquitinating Mdm2

As a genome guardian, p53 maintains genome stability by arresting cells for damage repair or inducing cell apoptosis to eliminate the damaged cells in stress response. Several nucleolar proteins stabilize p53 by interfering Mdm2–p53 interaction upon cellular stress, while other mechanisms by which nucleolar proteins activate p53 remain to be determined. Here, we identify NAT10 as a novel regulator for p53 activation. NAT10 acetylates p53 at K120 and stabilizes p53 by counteracting Mdm2 action. In addition, NAT10 promotes Mdm2 degradation with its intrinsic E3 ligase activity. After DNA damage, NAT10 translocates to nucleoplasm and activates p53‐mediated cell cycle control and apoptosis. Finally, NAT10 inhibits cell proliferation and expression of NAT10 decreases in human colorectal carcinomas. Thus, our data demonstrate that NAT10 plays a critical role in p53 activation via acetylating p53 and counteracting Mdm2 action, providing a novel pathway by which nucleolar protein activates p53 as a cellular stress sensor.

Transcriptional Repressor NIR Functions in the Ribosome RNA Processing of Both 40S and 60S Subunits

Background NIR was identified as an inhibitor of histone acetyltransferase and it represses transcriptional activation of p53. NIR is predominantly localized in the nucleolus and known as Noc2p, which is involved in the maturation of the 60S ribosomal subunit. However, how NIR functions in the nucleolus remains undetermined. In the nucleolus, a 47S ribosomal RNA precursor (pre-rRNA) is transcribed and processed to produce 18S, 5.8S and 28S rRNAs. The 18S rRNA is incorporated into the 40S ribosomal subunit, whereas the 28S and 5.8S rRNAs are incorporated into the 60S subunit. U3 small nucleolar RNA (snoRNA) directs 18S rRNA processing and U8 snoRNA mediates processing of 28S and 5.8 S rRNAs. Functional disruption of nucleolus often causes p53 activation to inhibit cell proliferation. Methodology/Principal Findings Western blotting showed that NIR is ubiquitously expressed in different human cell lines. Knock-down of NIR by siRNA led to inhibition of the 18S, 28S and 5.8S rRNAs evaluated by pulse-chase experiment. Pre-rRNA particles (pre-rRNPs) were fractionated from the nucleus by sucrose gradient centrifugation and analysis of the pre-RNPs components showed that NIR existed in the pre-RNPs of both the 60S and 40S subunits and co-fractionated with 32S and 12S pre-rRNAs in the 60S pre-rRNP. Protein-RNA binding experiments demonstrated that NIR is associated with the 32S pre-rRNA and U8 snoRNA. In addition, NIR bound U3 snoRNA. It is a novel finding that depletion of NIR did not affect p53 protein level but de-repressed acetylation of p53 and activated p21. Conclusions We provide the first evidence for a transcriptional repressor to function in the rRNA biogenesis of both the 40S and 60S subunits. Our findings also suggested that a nucleolar protein may alternatively signal to p53 by affecting the p53 modification rather than affecting p53 protein level.

NAT10 is upregulated in hepatocellular carcinoma and enhances mutant p53 activity

BackgroundN-acetyltransferase 10 (NAT10) is a histone acetyltransferase which is involved in a wide range of cellular processes. Recent evidences indicate that NAT10 is involved in the development of human cancers. Previous study showed that NAT10 acetylates the tumor suppressor p53 and regulates p53 activation. As Tp53 gene is frequently mutated in hepatocellular carcinoma (HCC) and associates with the occurrence and development of HCC, the relationship between NAT10 and HCC was investigated in this study.MethodsImmunohistochemistry (IHC) and western blot analysis were performed to evaluate the NAT10 expression in HCC. Immunoprecipitation experiments were performed to verify the interaction of NAT10 with mutant p53 and Mdm2. RNA interference and Western blot were applied to determine the effect of NAT10 on mutant p53. Cell growth curve was used to examine the effect of NAT10 on HCC cell proliferation.ResultsNAT10 was upregulated in HCC and increased NAT10 expression was correlated with poor overall survival of the patients. NAT10 protein levels were significantly correlated with p53 levels in human HCC tissues. Furthermore, NAT10 increased mutant p53 levels by counteracting Mdm2 action in HCC cells and promoted proliferation in cells carrying p53 mutation.ConclusionIncreased NAT10 expression levels are associated with shortened patient survival and correlated with mutant p53 levels. NAT10 upregulates mutant p53 level and might enhance its tumorigenic activity. Hence, we propose that NAT10 is a potential prognostic and therapeutic candidate for p53-mutated HCC.

A Novel Retinoblastoma Protein (RB) E3 Ubiquitin Ligase (NRBE3) Promotes RB Degradation and Is Transcriptionally Regulated by E2F1 Transcription Factor

Background: Retinoblastoma protein (RB) is frequently targeted for proteasomal degradation by oncoproteins. Results: NRBE3 promotes RB degradation as an E3 and is transcriptionally activated by E2F1. Conclusion: NRBE3 is an E3 ubiquitin ligase for RB and regulates the cell cycle. Significance: This study identified a novel E3 ubiquitin ligase for RB that might be a potential oncoprotein in human cancers. Retinoblastoma protein (RB) plays critical roles in tumor suppression and is degraded through the proteasomal pathway. However, E3 ubiquitin ligases responsible for proteasome-mediated degradation of RB are largely unknown. Here we characterize a novel RB E3 ubiquitin ligase (NRBE3) that binds RB and promotes RB degradation. NRBE3 contains an LXCXE motif and bound RB in vitro. NRBE3 interacted with RB in cells when proteasome activity was inhibited. NRBE3 promoted RB ubiquitination and degradation via the ubiquitin-proteasome pathway. Importantly, purified NRBE3 ubiquitinated recombinant RB in vitro, and a U-box was identified as essential for its E3 activity. Surprisingly, NRBE3 was transcriptionally activated by E2F1/DP1. Consequently, NRBE3 affected the cell cycle by promoting G1/S transition. Moreover, NRBE3 was up-regulated in breast cancer tissues. Taken together, we identified NRBE3 as a novel ubiquitin E3 ligase for RB that might play a role as a potential oncoprotein in human cancers.

Does not hUTP14a promoter form a regulation feedback loop with P53

OBJECTIVE We previously found that hUTP14a binds P53 and promotes P53 degradation. However, if hUTP14a is a downstream gene of P53 remains to be determined. This study aimed to identify the promoter of hUTP14a and investigate if hUTP14a is regulated by P53. METHODS The hUTP14a promoter region was cloned into pGL3-Basic-luciferase reporter plasmid to get pGL3-hUTP14a-luc. The reporter plasmid was transfected into 293T cells and luciferase activity was evaluated by the Dual-Luciferase Reporter Assay System. Putative transcription factors were identified through searching MatInspector Professional and Algorismica i Genetica databases. Either pGL3-hUTP14a-luc or p21 promoter reporter plasmid was co-transfected with increasing dose of p53 plasmid, and luciferase activity was evaluated. A series of deletion constructs of pGL3-hUTP14a-luc were constructed and minimal promoter region of hUTP14a was determined. Differences of the luciferase activities between different groups were assessed by statistical analysis. RESULTS The hUTP14a gene promoter reporter construct was correctly cloned and was demonstrated to possess promoter activity. The transcription of hUTP14a was not regulated by P53. The minimal promoter region of hUTP14a gene is located between -203 to -100 of the transcription initiation site. CONCLUSION Unlike other P53-interacting proteins such as MDM2, Pirh2 and Cop I which promote P53 degradation and whose transcriptions are regulated by P53, does not hUTP14a transcription form a regulation feedback loop with P53.

Human UTP14a promotes colorectal cancer progression by forming a positive regulation loop with c-Myc

Nucleolar protein hUTP14a is required for 18S rRNA processing and promotes p53 degradation. Here, we report that hUTP14a stabilizes c-Myc in colorectal cancer (CRC) progression. Firstly, nucleolar hUTP14a is upregulated in human CRC tissues. Mass spectrometry analysis identified c-Myc and its deubiquitinase ubiquitin-specific protease 36 (USP36) in the hUTP14a-specific complex. Importantly, hUTP14a interacts with c-Myc and protects c-Myc from ubiquitination and degradation in a USP36-dependent way. We further demonstrate that hUTP14a forms a complex with USP36/Fbw7γ to inhibit Fbw7γ-mediated c-Myc degradation. Ectopic expression of Flag-hUTP14a enriches c-Myc in the nucleolus, indicating hUTP14a stabilizes c-Myc in the nucleolus. Interestingly, c-Myc activates transcription of hUTP14a. Knockdown of hUTP14a by short hairpin RNA inhibits tumor growth and decreases c-Myc levels in mouse xenografts. Significantly, nucleolar hUTP14a and c-Myc are co-upregulated in human CRC tissues, and this co-upregulation indicates poor prognosis of CRC patients. Thus, disruption of hUTP14a-c-Myc regulation may provide a potential therapeutic strategy for a subset of CRC patients.

Deacetylation of NAT10 by Sirt1 promotes the transition from rRNA biogenesis to autophagy upon energy stress

Abstract Anabolism and catabolism are tightly regulated according to the cellular energy supply. Upon energy stress, ribosomal RNA (rRNA) biogenesis is inhibited, and autophagy is induced. However, the mechanism linking rRNA biogenesis and autophagy is unclear. Here, we demonstrate that the nucleolar protein NAT10 plays a role in the transition between rRNA biogenesis and autophagy. Under normal conditions, NAT10 is acetylated to activate rRNA biogenesis and inhibit autophagy induction. Mechanistic studies demonstrate that NAT10 binds to and acetylates the autophagy regulator Che-1 at K228 to suppress the Che-1-mediated transcriptional activation of downstream genes Redd1 and Deptor under adequate energy supply conditions. Upon energy stress, NAT10 is deacetylated by Sirt1, leading to suppression of NAT10-activated rRNA biogenesis. In addition, deacetylation of NAT10 abolishes the NAT10-mediated transcriptional repression of Che-1, leading to the release of autophagy inhibition. Collectively, we demonstrate that the acetylation status of NAT10 is important for the anabolism-catabolism transition in response to energy stress, providing a novel mechanism by which nucleolar proteins control rRNA synthesis and autophagy in response to the cellular energy supply.

Human U3 protein14a is a novel type ubiquitin ligase that binds RB and promotes RB degradation depending on a leucine-rich region

The nucleolar protein hUTP14a promotes p53 degradation and possesses an oncogene potential. Here, we report that hUTP14a promotes degradation of tumor suppressor retinoblastoma (RB) protein. Sequences alignment showed that hUTP14a contains the RB-binding PENF motif in its C-terminus. We showed that hUTP14a interacted with RB in vivo and in vitro. Further, hUTP14a promoted polyubiquitination and proteasome-dependent turnover of RB. Importantly, purified Flag-hUTP14a facilitated RB ubiquitination in vitro, demonstrating that hUTP14a is an ubiquitin E3 ligase for RB. A BLAST alignment with hUTP14a does not reveal a RING or HECT domain. To define the conserved domain for E3 ligase activity in hUTP14a, the minimum domain for promoting RB degradation was mapped to residues 61-120 of hUTP14a, in which a leucine-rich region (LRR) LxLxxLL was suggested to be conserved. Flag-hUTP14a (ΔLRR), Flag-hUTP14a-MT1(LxLxxLL to LxLxxAA) and Flag-hUTP14a-MT2(LxLxxLL to AxAxxAA) lost the capability of ubiquitinating RB in vitro, demonstrating that LRR is required for the E3 ligase activity of hUTP14a. Consequently, expression of hUTP14a caused upregulation of E2F1 downstream genes, thus promoting cancer cell proliferation. Taken together, we demonstrate that hUTP14a promotes RB degradation through its E3 ligase activity and suggest that the LRR could be a potential conserved E3 ligase domain.