The nucleolar SUMO-specific protease SENP3 reverses SUMO modification of nucleophosmin and is required for rRNA processing

The ubiquitin-like SUMO system functions by a cyclic process of modification and demodification, and recent data suggest that the nucleolus is a site of sumoylation-desumoylation cycles. For example, the tumour suppressor ARF stimulates sumoylation of nucleolar proteins. Here, we show that the nucleolar SUMO-specific protease SENP3 is associated with nucleophosmin (NPM1), a crucial factor in ribosome biogenesis. SENP3 catalyses desumoylation of NPM1-SUMO2 conjugates in vitro and counteracts ARF-induced modification of NPM1 by SUMO2 in vivo. Intriguingly, depletion of SENP3 by short interfering RNA interferes with nucleolar ribosomal RNA processing and inhibits the conversion of the 32S rRNA species to the 28S form, thus phenocopying the processing defect observed on depletion of NPM1. Moreover, mimicking constitutive modification of NPM1 by SUMO2 interferes with 28S rRNA maturation. These results define SENP3 as an essential factor for ribosome biogenesis and suggest that deconjugation of SUMO2 from NPM1 by SENP3 is critically involved in 28S rRNA maturation.     

The SUMO system controls nucleolar partitioning of a novel mammalian ribosome biogenesis complex

Ribosome biogenesis is a tightly controlled pathway that requires an intricate spatial and temporal interplay of protein networks. Most structural rRNA components are generated in the nucleolus and assembled into pre-ribosomal particles, which are transferred for further maturation to the nucleoplasm and cytoplasm. In metazoa, few regulatory components for these processes have been characterized. Previous work revealed a critical role for the SUMO-specific protease SENP3 in the nucleolar steps of ribosome biogenesis. We biochemically purified a SENP3-associated complex comprising PELP1, TEX10 and WDR18, and demonstrate that this complex is involved in maturation and nucleolar release of the large ribosomal subunit. We identified PELP1 and the PELP1-associated factor LAS1L as SENP3-sensitive targets of SUMO, and provide evidence that balanced SUMO conjugation/deconjugation determines the nucleolar partitioning of this complex. This defines the PELP1-TEX10-WDR18 complex as a regulator of ribosome biogenesis and suggests that its SUMO-controlled distribution coordinates the rate of ribosome formation. These findings contribute to the basic understanding of mammalian ribosome biogenesis and shed new light on the role of SUMO in this process.     

Targeting a nucleolar SUMO protease for degradation: A mechanism by which ARF induces SUMO conjugation

The p19^ARF p14^ARF in humans protein acts as a tumour suppressor through p53 dependent and independent mechanisms. A well-established role for ARF is to regulate the post-translational modification of substrate proteins with ubiquitin and ubiquitin-like molecules such as SUMO. It is now evident that induction of ARF causes a dramatic accumulation of SUMO conjugates and this has been related to the p53 independent functions of ARF. The majority of these conjugates appear to accumulate in the nucleolus where most of ARF is also found. An obvious function for ARF, which would result in increase of SUMOylation, is to act as an atypical SUMO E3-ligase. Indeed, initial studies suggested that ARF could directly interact with the SUMO E2-conjugating enzyme Ubc9 and therefore bringing the SUMO conjugation machinery in close proximity to its interacting substrates.¹ However, the highly basic charged nature of ARF makes biochemical analysis difficult and there is no clear demonstration that ARF can fulfill the criteria for an E3-ligase in vitro. Therefore, the mechanism(s) behind this phenomenon are not currently understood. As with ubiquitination, SUMO conjugation is a dynamic process controlled by E3-ligases and proteases that specifically remove SUMO from substrates. In this issue of Cell Cycle studies from the Sherr lab suggest that ARF can increase SUMO conjugation by controlling the stability of the nucleolar SUMO protease SENP3.² Recent studies have shown that SENP3 can deconjugate SUMO-2 and SUMO-3 from substrates including nucleophosmin (NPM). NPM is a nucleolar protein, which among other processes is involved in the processing of rRNA during ribosome biosynthesis. NPM interacts with ARF and this results in increased SUMOylation of NPM. SENP3 can counteract the effect of ARF by deconjugating SUMO from NPM and this appears to be critical for NPM function in rRNA processing.³ The new study now suggests that there is an opposing functional relationship between ARF and SENP3. ARF promotes phosphorylation dependent ubiquitination of SENP3, which results in SENP3 degradation and increase in NPM SUMO conjugation. In this process, NPM seems to act as a "platform" for ARF and SENP3, bringing in close proximity its two regulators. The new study suggests an interesting and complex mechanism by which ARF can control SUMOylation. It is now evident that post-translational modifications cooperate to control protein function. The new data suggest that ARF engages phosphorylation to promote ubiquitination and proteasomal degradation of a SUMO protease. This model would propose the existence of a kinase/phosphatase and an E3-ubiquitin ligase/de-ubiquitinating enzyme set which would cooperate their actions to control the stability of SENP3. Given that ARF has multiple binding partners, it would not be surprising that ARF would interact with components of the above enzymatic steps and control their activity. It would therefore be interesting to identify the role of ARF in this process. It is not clear whether degradation of SENP3 per se is sufficient to induce NPM SUMO conjugation and if this is the case which SUMO E3-ligases drive the forward reaction. Even if in this study an interaction of ARF with Ubc9 could not be demonstrated it may be the case that ARF mediates both the degradation of SENP3 and recruitment of the SUMO conjugation machinery, which will result in fast and efficient accumulation of SUMOylated NPM. Another possibility is the effect of ARF on NPM stability itself. Previous studies have shown that ARF can induce ubiquitin-mediated degradation of NPM.⁴ As NPM is important to prevent destabilisation of SENP3, ARF-mediated degradation of NPM could be part of SENP3 degradation. Another point that arises from this is the site of degradation for SENP3. Nucleoli have been suggested to be deficient for proteasomal activity, suggesting that ARF through the phosphorylation/ubiquitination events may alter the localisation/mobility of SENP3 making it susceptible to nucleoplasmic/cytoplasmic proteasomal degradation. The effect of ARF in controlling protein ubiquitination is now well established. Interaction of ARF with E3-ligases such as Mdm2 and ARF-BP1/Mule inhibits their function resulting in inhibition of p53 proteasomal degradation.^5,6 Therefore, the ability of ARF to induce ubiquitination and proteasomal degradation of SENP3 and NPM shows a complex and diverse role for ARF to control protein stability. Further experiments will show whether the ability of ARF to promote degradation of SENP3 or possibly other SUMO proteases is a general mechanism through which ARF induces SUMO conjugation of its binding partners or that the NPM/SENP3 system is a unique example.

References

1. Rizos H, Woodruff S, Kefford RF. p14ARF interacts with the SUMO-conjugating enzyme Ubc9 and promotes the sumoylation of its binding partners. Cell Cycle 2005; 4:597-603. 2. Kuo ML, den Besten W, Thomas MC, Sherr CJ. Arf-induced turnover of the nucleolar nucleophosmin-associated SUMO-2/3 protease Senp3. Cell Cycle 2008; 7:In this issue 3. Haindl M, Harasim T, Eick D, Muller S. The nucleolar SUMO-specific protease SENP3 reverses SUMO modification of nucleophosmin and is required for rRNA processing. EMBO Rep 2008; 9:273-9 4. Itahana K, Bhat KP, Jin A, Itahana Y, Hawke D, Kobayashi R, Zhang Y. Tumor suppressor ARF degrades B23, a nucleolar protein involved in ribosome biogenesis and cell proliferation. Mol Cell 2003; 12:1151-64. 5. Xirodimas D, Saville MK, Edling C, Lane DP, LaÃ?Â?Ã?Â?Ã?Â?Ã?­n S. Different effects of p14ARF on the levels of ubiquitinated p53 and Mdm2 in vivo. Oncogene 2001; 20:4972-83. 6. Chen D, Kon N, Li M, Zhang W, Qin J, Gu W. ARF-BP1/Mule is a critical mediator of the ARF tumor suppressor. Cell 2005; 121:1071-83.     

The Wnt Target Protein Peter Pan Defines a Novel p53-independent Nucleolar Stress-Response Pathway

Proper ribosome formation is a prerequisite for cell growth and proliferation. Failure of this process results in nucleolar stress and p53-mediated apoptosis. The Wnt target Peter Pan (PPAN) is required for 45 S rRNA maturation. So far, the role of PPAN in nucleolar stress response has remained elusive. We demonstrate that PPAN localizes to mitochondria in addition to its nucleolar localization and inhibits the mitochondrial apoptosis pathway in a p53-independent manner. Loss of PPAN induces BAX stabilization, depolarization of mitochondria, and release of cytochrome c, demonstrating its important role as an anti-apoptotic factor. Staurosporine-induced nucleolar stress and apoptosis disrupt nucleolar PPAN localization and induce its accumulation in the cytoplasm. This is accompanied by phosphorylation and subsequent cleavage of PPAN by caspases. Moreover, we show that PPAN is a novel interaction partner of the anti-apoptotic protein nucleophosmin (NPM). PPAN depletion induces NPM and upstream-binding factor (UBF) degradation, which is independent of caspases. In summary, we provide evidence for a novel nucleolar stress-response pathway involving PPAN, NPM, and BAX to guarantee cell survival in a p53-independent manner.     

Nucleophosmin serves as a rate-limiting nuclear export chaperone for the Mammalian ribosome

Nucleophosmin (NPM) (B23) is an essential protein in mouse development and cell growth; however, it has been assigned numerous roles in very diverse cellular processes. Here, we present a unified mechanism for NPM's role in cell growth; NPM directs the nuclear export of both 40S and 60S ribosomal subunits. NPM interacts with rRNA and large and small ribosomal subunit proteins and also colocalizes with large and small ribosomal subunit proteins in the nucleolus, nucleus, and cytoplasm. The transduction of NPM shuttling-defective mutants or the loss of Npm1 inhibited the nuclear export of both the 40S and 60S ribosomal subunits, reduced the available pool of cytoplasmic polysomes, and diminished overall protein synthesis without affecting rRNA processing or ribosome assembly. While the inhibition of NPM shuttling can block cellular proliferation, the dramatic effects on ribosome export occur prior to cell cycle inhibition. Modest increases in NPM expression amplified the export of newly synthesized rRNAs, resulting in increased rates of protein synthesis and indicating that NPM is rate limiting in this pathway. These results support the idea that NPM-regulated ribosome export is a fundamental process in cell growth.     

Physical and functional interaction between Pes1 and Bop1 in mammalian ribosome biogenesis

Molecular mechanisms of mammalian ribosome biogenesis remain largely unexplored. Here we develop a series of transposon-derived dominant mutants of Pes1, the mouse homolog of the zebrafish Pescadillo and yeast Nop7p implicated in ribosome biogenesis and cell proliferation control. Six Pes1 mutants selected by their ability to reversibly arrest the cell cycle also impair maturation of the 28S and 5.8S rRNAs in mouse cells. We show that Pes1 physically interacts with the nucleolar protein Bop1, and both proteins direct common pre-rRNA processing steps. Interaction with Bop1 is essential for the efficient incorporation of Pes1 into nucleolar preribosomal complexes. Pes1 mutants defective for the interaction with Bop1 lose the ability to affect rRNA maturation and the cell cycle. These data show that coordinated action of Pes1 and Bop1 is necessary for the biogenesis of 60S ribosomal subunits.     

Elucidation of Motifs in Ribosomal Protein S9 That Mediate Its Nucleolar Localization and Binding to NPM1/Nucleophosmin

Biogenesis of eukaryotic ribosomes occurs mainly in a specific subnuclear compartment, the nucleolus, and involves the coordinated assembly of ribosomal RNA and ribosomal proteins. Identification of amino acid sequences mediating nucleolar localization of ribosomal proteins may provide important clues to understand the early steps in ribosome biogenesis. Human ribosomal protein S9 (RPS9), known in prokaryotes as RPS4, plays a critical role in ribosome biogenesis and directly binds to ribosomal RNA. RPS9 is targeted to the nucleolus but the regions in the protein that determine its localization remains unknown. Cellular expression of RPS9 deletion mutants revealed that it has three regions capable of driving nuclear localization of a fused enhanced green fluorescent protein (EGFP). The first region was mapped to the RPS9 N-terminus while the second one was located in the proteins C-terminus. The central and third region in RPS9 also behaved as a strong nucleolar localization signal and was hence sufficient to cause accumulation of EGFP in the nucleolus. RPS9 was previously shown to interact with the abundant nucleolar chaperone NPM1 (nucleophosmin). Evaluating different RPS9 fragments for their ability to bind NPM1 indicated that there are two binding sites for NPM1 on RPS9. Enforced expression of NPM1 resulted in nucleolar accumulation of a predominantly nucleoplasmic RPS9 mutant. Moreover, it was found that expression of a subset of RPS9 deletion mutants resulted in altered nucleolar morphology as evidenced by changes in the localization patterns of NPM1, fibrillarin and the silver stained nucleolar organizer regions. In conclusion, RPS9 has three regions that each are competent for nuclear localization, but only the central region acted as a potent nucleolar localization signal. Interestingly, the RPS9 nucleolar localization signal is residing in a highly conserved domain corresponding to a ribosomal RNA binding site.     

GLTSCR2 is an upstream negative regulator of nucleophosmin in cervical cancer

Nucleophosmin (NPM)/B23, a multifunctional nucleolar phosphoprotein, plays an important role in ribosome biogenesis, cell cycle regulation, apoptosis and cancer pathogenesis. The role of NPM in cells is determined by several factors, including total expression level, oligomerization or phosphorylation status, and subcellular localization. In the nucleolus, NPM participates in rRNA maturation to enhance ribosomal biogenesis. Consistent with this finding, NPM expression is increased in rapidly proliferating cells and many types of human cancers. In response to ribosomal stress, NPM is redistributed to the nucleoplasm, where it inactivates mouse double minute 2 homologue to stabilize p53 and inhibit cell cycle progression. These observations indicate that nucleolus‐nucleoplasmic mobilization of NPM is one of the key molecular mechanisms that determine the role of NPM within the cell. However, the regulatory molecule(s) that control(s) NPM stability and subcellular localization, crucial to the pluripotency of intercellular NPM, remain(s) unidentified. In this study, we showed that nucleolar protein GLTSCR2/Pict‐1 induced nucleoplasmic translocation and enhanced the degradation of NPM via the proteasomal polyubiquitination pathway. In addition, we showed that GLTSCR2 expression decreased the transforming activity of cells mediated by NPM and that the expression of NPM is reciprocally related to that of GLTSCR2 in cervical cancer tissue. In this study, we demonstrated that GLTSCR2 is an upstream negative regulator of NPM.     

Removal of a ribosome small subunit-dependent GTPase confers salt resistance on Escherichia coli cells

RsgA is a unique GTP hydrolytic protein in which GTPase activity is significantly enhanced by the small ribosomal subunit. Deletion of RsgA causes slow cell growth as well as defects in subunit assembly of the ribosome and 16S rRNA processing, suggesting its involvement in maturation of the small subunit. In this study, we found that removal of RsgA or inactivation of its ribosome small subunit-dependent GTPase activity provides Escherichia coli cells with resistance to high salt stress. Salt stress suppressed the defects in subunit assembly of the ribosome and processing of 16S rRNA as well as truncation of the 3′ end of 16S rRNA in RsgA-deletion cells. In contrast, salt stress transiently impaired subunit assembly of the ribosome and processing of 16S rRNA and induced 3′ truncation of 16S rRNA in wild-type cells. These results suggest that the action of RsgA on the ribosome, which usually facilitates maturation of the small subunit, disturbs it under a salt stress condition. Consistently, there was a drastic but transient decrease in the intracellular amount of RsgA after salt shock. Salt shock would make the pathway of maturation of the ribosome small subunit RsgA independent.     

The sequence of the 5' end of the U8 small nucleolar RNA is critical for 5.8S and 28S rRNA maturation.

Ribosome biogenesis in eucaryotes involves many small nucleolar ribonucleoprotein particles (snoRNP), a few of which are essential for processing pre-rRNA. Previously, U8 snoRNA was shown to play a critical role in pre-rRNA processing, being essential for accumulation of mature 28S and 5.8S rRNAs. Here, evidence which identifies a functional site of interaction on the U8 RNA is presented. RNAs with mutations, insertions, or deletions within the 5'-most 15 nucleotides of U8 do not function in pre-rRNA processing. In vivo competitions in Xenopus oocytes with 2'O-methyl oligoribonucleotides have confirmed this region as a functional site of a base-pairing interaction. Cross-species hybrid molecules of U8 RNA show that this region of the U8 snoRNP is necessary for processing of pre-rRNA but not sufficient to direct efficient cleavage of the pre-rRNA substrate; the structure or proteins comprising, or recruited by, the U8 snoRNP modulate the efficiency of cleavage. Intriguingly, these 15 nucleotides have the potential to base pair with the 5' end of 28S rRNA in a region where, in the mature ribosome, the 5' end of 28S interacts with the 3' end of 5.8S. The 28S-5.8S interaction is evolutionarily conserved and critical for pre-rRNA processing in Xenopus laevis. Taken together these data strongly suggest that the 5' end of U8 RNA has the potential to bind pre-rRNA and in so doing, may regulate or alter the pre-rRNA folding pathway. The rest of the U8 particle may then facilitate cleavage or recruitment of other factors which are essential for pre-rRNA processing.     

Xenopus U3 snoRNA docks on pre-rRNA through a novel base-pairing interaction

U3 small nucleolar RNA (snoRNA) is essential for rRNA processing to form 18S ribosomal RNA (rRNA). Previously, it has been shown that nucleolin is needed to load U3 snoRNA on pre-rRNA. However, as documented here, this is not sufficient. We present data that base-pairing between the U3 hinges and the external transcribed spacer (ETS) is critical for functional alignment of U3 on its pre-rRNA substrate. Additionally, the interaction between the U3 hinges and the ETS is proposed to serve as an anchor to hold U3 on the pre-rRNA substrate, while box A at the 5' end of U3 snoRNA swivels from ETS contacts to 18S rRNA contacts. Compensatory base changes revealed base-pairing between the 3' hinge of U3 snoRNA and region E1 of the ETS in Xenopus pre-rRNA; this novel interaction is required for 18S rRNA production. In contrast, base-pairing between the 5' hinge of U3 snoRNA and region E2 of the ETS is auxiliary, unlike the case in yeast where it is required. Thus, higher and lower eukaryotes use different interactions for functional association of U3 with pre-rRNA. The U3 hinge sequence varies between species, but covariation in the ETS retains complementarity. This species-specific U3-pre-rRNA interaction offers a potential target for a new class of antibiotics to prevent ribosome biogenesis in eukaryotic pathogens.     

Evidence of p53-dependent cross-talk between ribosome biogenesis and the cell cycle: effects of nucleolar protein Bop1 on G(1)/S transition

Bop1 is a novel nucleolar protein involved in rRNA processing and ribosome assembly. We have previously shown that expression of Bop1Delta, an amino-terminally truncated Bop1 that acts as a dominant negative mutant in mouse cells, results in inhibition of 28S and 5.8S rRNA formation and deficiency of newly synthesized 60S ribosomal subunits (Z. Strezoska, D. G. Pestov, and L. F. Lau, Mol. Cell. Biol. 20:5516-5528, 2000). Perturbation of Bop1 activities by Bop1Delta also induces a powerful yet reversible cell cycle arrest in 3T3 fibroblasts. In the present study, we show that asynchronously growing cells are arrested by Bop1Delta in a highly concerted fashion in the G(1) phase. Kinase activities of the G(1)-specific Cdk2 and Cdk4 complexes were downregulated in cells expressing Bop1Delta, whereas levels of the Cdk inhibitors p21 and p27 were concomitantly increased. The cells also displayed lack of hyperphosphorylation of retinoblastoma protein (pRb) and decreased expression of cyclin A, indicating their inability to progress through the restriction point. Inactivation of functional p53 abrogated this Bop1Delta-induced cell cycle arrest but did not restore normal rRNA processing. These findings show that deficiencies in ribosome synthesis can be uncoupled from cell cycle arrest and reveal a new role for the p53 pathway as a mediator of the signaling link between ribosome biogenesis and the cell cycle. We propose that aberrant rRNA processing and/or ribosome biogenesis may cause "nucleolar stress," leading to cell cycle arrest in a p53-dependent manner.