Various cellular stresses activate autophagy, which is involved in lysosomal degradation of cytoplasmic materials for maintaining nutrient homeostasis and eliminating harmful components. Here, we show that RNA polymerase I (Pol I) transcription inhibition induces nucleolar disruption and autophagy. Treatment with autophagy inhibitors or siRNA specific for autophagy-related (ATG) proteins inhibited autophagy but not nucleolar disruption induced by Pol I transcription inhibition, which suggested that nucleolar disruption was upstream of autophagy. Furthermore, treatment with siRNA specific for nucleolar protein nucleophosmin (NPM) inhibited this type of autophagy. This showed that NPM was involved in autophagy when the nucleolus was disrupted by Pol I inhibition. In contrast, NPM was not required for canonical autophagy induced by nutrient starvation, as it was not accompanied by nucleolar disruption. Thus, our results revealed that, in addition to canonical autophagy, there may be NPM-dependent autophagy associated with nucleolar disruption.
Eukaryotic cells are continuously exposed to various types of stress; thus, activating an adaptive response to alleviate stress is necessary to maintain cellular homeostasis1. One of the key response pathways that removes stress is macroautophagy (hereafter referred to as autophagy)1,2,3,4. Autophagy is an intracellular system that degrades cytoplasmic material, such as proteins and organelles, by encircling it in double-membrane vesicles, designated autophagosomes, for delivery to lysosomes1,2,3,4. Lysosomes contain a variety of proteases and other acid hydrolases and ultimately degrade this material1,2,3,4. In addition, recent reports indicate that selective forms of autophagy, such as mitophagy, pexophagy and nucleophagy, mediate selective removal of mitochondria, peroxisomes and parts of the nucleus, respectively1,5,6,7. Autophagy is widely conserved among eukaryotes ranging from yeasts to humans and is strictly regulated by autophagy-related (ATG) proteins2,4.
Autophagy is induced by various types of stress1,5. Autophagy is primarily induced by nutrient stress due to depletion of various nutrients, such as amino acids, glucose and growth factors1,3,5. Nutrient stress-induced autophagy degrades cytoplasmic materials and recycles them to maintain nutrient and energy homeostasis, which allows cells to survive under nutrient starvation conditions. For example, yeasts with a deficient autophagy mechanism exhibit poor survival under starvation conditions8. Furthermore, mice with knockout of ATG3, ATG5 or ATG7, which are essential for autophagy, die within 1 day after birth, indicating that autophagy is important for mouse survival during the early neonatal starvation period3. The studies described below reveal that autophagy is also induced by other types of stress, such as hypoxia, UV irradiation, chemical compounds and heat shock1,3,5. Under these conditions, cells adapt to the stress by activating autophagy to eliminate damaged proteins and organelles1,3,5.
A recent study revealed that the nucleolus, the nuclear component considered to be the site of RNA polymerase I (Pol I)-dependent ribosomal RNA (rRNA) synthesis and a ‘ribosome factory,’ acts as a stress sensor9,10,11,12,13. A number of external and internal insults induce nucleolar stress by disrupting nucleolar structure, which leads to translocation of several nucleolar proteins from the nucleolus to the nucleoplasm, such as nucleophosmin (NPM; also called B23) and nucleostemin and ribosomal proteins, such as RPS7, RPL5, RPL11 and RPL2311,14,15. These translocated proteins cause accumulation and activation of tumour suppressor p53 by interacting with the p53 inhibitor HDM2 and inhibiting HDM2 activity directed towards p5311,14,15. We recently found that a nucleolar protein, Myb-binding protein 1a (MYBBP1A), is anchored to the nucleolus via nucleolar RNA16. A number of insults inhibited Pol I transcription and reduced nucleolar RNA levels, which caused MYBBP1A to translocate from the nucleolus to the nucleoplasm16. The translocated MYBBP1A activated p53 by enhancing the interaction between p53 and p300, which induced p53 acetylation16. Taken together, the nucleolus is regarded as a stress sensor that regulates the location of nucleolar proteins and activates p53 under various stress conditions.
Thus, the nucleolus acts as a stress sensor9,10,11,12,13 and autophagy is a response to various types of stress1,2,3,4. A number of stresses, such as hypoxia, UV irradiation, chemical compounds and heat shock, induce nucleolar disruption10,12 and autophagy17,18,19,20,21. Furthermore, nucleolar disruption and autophagy are enhanced in mouse medium spiny neurons by conditional knockout of the RNA Pol I-specific transcription initiation factor-IA (TIF-IA)22. A decrease in rRNA synthesis and nucleolar disruption have been reportedly observed in animal models for a variety of neurodegenerative diseases, including Huntington's disease and Parkinson's disease22,23,24,25, against which autophagy has protective roles3,26,27. In contrast, increased rRNA synthesis and an enlarged nucleolus are observed in tumour cells28,29,30 with high levels of autophagy31,32,33. Thus, it is speculated that altered nucleolar structure may be related to inducing autophagy.
Here we show that inhibiting Pol I transcription in cells using specific inhibitors and by siRNA treatment induces nucleolar disruption and autophagy. Furthermore, we found that the nucleolar protein NPM played a key role activating autophagy induced by nucleolar disruption. In contrast, NPM was not essential for canonical autophagy induced by nutrient starvation, which was not accompanied by nucleolar disruption.
Inhibiting Pol I transcription induces nucleolar disruption and autophagy
To explore the relationship between nucleolar structure and autophagy, we treated cells with a Pol I transcription inhibitor to induce nucleolar disruption and assessed whether this treatment induced autophagy. To assay for autophagy, we generated MCF-7 cells that stably expressed the enhanced green fluorescent protein (EGFP)-tagged human microtubule-associated protein 1 light chain 3B (LC3B) protein (MCF-7/EGFP-LC3B cells). We treated these cells with 200 nM adriamycin (ADR), which inhibits Pol I transcription and induces autophagy (Fig. 1)19,34. After ADR treatment, the nucleolar marker protein nucleolin (NCL) was translocated from the nucleolus to the nucleoplasm, which indicated nucleolar disruption (Fig. 1a). Immunostaining of these cells with an anti-GFP antibody showed that ADR treatment enhanced formation of EGFP-LC3B punctate structures, an indicator of autophagy (Fig. 1a and Supplementary Fig. S1a). To further ascertain whether ADR treatment induced autophagy, we assayed for the conversion of LC3B-I to LC3B-II and p62 protein levels by immunoblotting. ADR treatment induced the conversion of LC3B-I to LC3B-II (Fig. 1b) and reduced p62 protein levels (Fig. 1b), both of which are indicators of autophagy. These results show that ADR treatment induced both nucleolar disruption and autophagy.
Furthermore, we tested whether another Pol I transcription inhibitor, actinomycin-D (ActD), could induce nucleolar disruption and autophagy. We treated MCF-7/EGFP-LC3B cells with low-dose ActD (5 nM), which specifically inhibits RNA polymerase I- but not RNA polymerase II- or RNA polymerase III-driven transcription35,36. As with ADR treatment, ActD induced nucleolar disruption and enhanced formation of EGFP-LC3B punctate structures (Fig. 1c and Supplementary Fig. S1b). In addition, it facilitated the conversion of LC3B-I to LC3B-II and reduced p62 protein levels (Fig. 1d). Taken together, these results indicate that the Pol I transcription inhibitors ADR and ActD induced both nucleolar disruption and autophagy.
ADR and ActD are DNA intercalators that induce DNA breaks by interacting between stacked base pairs19,34,35. Thus, these drugs induce nucleolar disruption and autophagy by inhibiting Pol I transcription or damaging DNA. To distinguish between these possibilities, Pol I transcription was specifically inhibited by treatment with siRNA specific for TIF-IA, a basal Pol I transcription factor13,37 or siRNA specific for the polymerase (RNA) I polypeptide A (POLR1A), a Pol I catalytic subunit38. This finding shows that, in agreement with previous reports, depleting TIF-IA caused nucleolar disruption13,16, as shown by translocation of the nucleolar marker protein NCL from the nucleolus to the nucleoplasm (Fig. 2a). This treatment inhibited rRNA transcription (Supplementary Fig. S2a) and enhanced p53 protein level (Supplementary Fig. S2b), reflecting the induction of nucleolar stress. The TIF-IA siRNA treatment induced formation of EGFP-LC3B punctate structures (Fig. 2a and Supplementary Fig. S2c). Furthermore, TIF-IA knockdown induced the conversion of LC3B-I to LC3B-II and reduced the p62 protein levels (Fig. 2b). Similar results were found when MCF-7/EGFP-LC3B cells were treated with siRNA specific for POLR1A (Fig. 2 and Supplementary Fig. S2). Taken together, inhibiting Pol I transcription induced both nucleolar disruption and autophagy, suggesting an association between nucleolar disruption and autophagy. However, it is unknown whether nucleolar disruption induces autophagy or vice versa.
Depleting ATG proteins and autophagy inhibitors repress autophagy, but not nucleolar disruption induced by TIF-IA knockdown
To dissect the autophagy induced by inhibiting Pol I and to investigate the relationship between nucleolar disruption and this type of autophagy in more detail, we depleted the ATG proteins or treated MCF-7/EGFP-LC3B cells with autophagy inhibitors. First, we depleted Beclin 1 (BECN1) and ATG5, both of which are ATG proteins involved in autophagy. BECN1, together with VPS15, VPS34 and Ambra 1, comprise the BECN1 complex, which is essential for allosteric activation of the class III phosphoinositide 3-kinases (PI3-kinase) to generate phosphatidylinositol-3-phoshate required for the initial stages of autophagosome formation1,2,39. ATG5 forms a protein complex with ATG12 and ATG16L1 and catalyses the conversion of LC3-I to LC3-II1,2,39. Knocking down BECN1 or ATG5 repressed the formation of EGFP-LC3B punctate structures induced by TIF-IA siRNA treatment without inhibiting NCL translocation from the nucleolus to the nucleoplasm (Fig. 3a and Supplementary Fig. S3a). BECN1 or ATG5 knockdown also inhibited the conversion of LC3B-I to LC3B-II caused by depleting TIF-IA (Fig. 3b). These results indicate that the ATG proteins BECN1 and ATG5 are involved in autophagy induced by TIF-IA knockdown, as well as other cases of reported autophagy, but that depleting BECN1 or ATG5 was independent of nucleolar disruption.
Furthermore, we tested the effects of autophagy inhibitors on nucleolar disruption and autophagy induced by TIF-IA knockdown. 3-Methyladenine (3-MA), a well-known autophagy inhibitor, inhibits PI3-kinase activity and blocks the initial stages of autophagosome formation39. To test whether 3-MA inhibits autophagy induced by TIF-IA knockdown, we treated MCF-7/EGFP-LC3B cells with 3-MA. The formation of EGFP-LC3B punctate structures induced by TIF-IA knockdown was inhibited by 3-MA treatment without inhibiting NCL translocation (Fig. 3c and Supplementary Fig. S3b). Moreover, 3-MA suppressed the conversion of LC3B-I to LC3B-II (Fig. 3d).
Furthermore, we tested the effects of the autophagy inhibitor bafilomycin A1, a specific vacuolar type H+-ATPase inhibitor. Bafilomycin A1 prevents the degradation of autophagosomes by inhibiting the fusion of autophagosomes with lysosomes, which results in an apparent accumulation of the autophagy apparatus4,39. Among TIF-IA siRNA-treated cells, bafilomycin A1 treatment increased the number of cells with the EGFP-LC3B punctate structures but did not affect localisation of NCL in MCF-7/EGFP-LC3B cells (Fig. 3e and Supplementary Fig. S3c). The immunoblotting results showed that bafilomycin A1 increased LC3B-II protein levels in TIF-IA siRNA-treated cells (Fig. 3f). Taken together, treatment with ATG protein siRNAs or autophagy inhibitors, all we tested, influenced autophagy, but did not markedly affect affected nucleolar disruption. Based on these results, nuclear disruption is upstream of autophagy in those cells in which Pol I transcription was inhibited. These results also suggest that inhibiting Pol I induces autophagy in a mechanism similar to that of general autophagy.
TIF-IA knockdown induces autophagy in the absence of active p53
Several groups, including ours, have reported that nucleolar disruption enhances p53 activity and the expression of multiple p53 target genes11,16. Furthermore, p53 activation is reportedly involved in activating autophagy in mouse medium spiny neurons22. Thus, autophagy was possibly induced by activating p53 when Pol I transcription was inhibited and the nucleolus was disrupted (Figs. 1 and 2).
To test whether p53 is essential for autophagy induced by inhibiting Pol I, we treated MCF-7/EGFP-LC3B cells with a combination of p53 siRNA and TIF-IA siRNA (Fig. 4a and b). p53 and TIFI-A double knockdown caused nucleolar disruption, formation of the EGFP-LC3B punctuate structures (Fig. 4a and Supplementary Fig. S4) and the LC3B-I to LC3B-II conversion, as well as reduced p62 levels (Fig. 4b). These results indicate that p53 was dispensable for autophagy induced by inhibiting Pol I in MCF-7/EGFP-LC3B cells.
We then treated HeLa cells, in which p53 is inactivated40,41, with TIF-IA siRNA and inhibited Pol I transcription (Supplementary Fig. S5a). As a result, nucleolar structures disappeared in these cells after TIF-IA siRNA treatment, as shown by translocation of NCL from the nucleolus to the nucleoplasm (Fig. 4c). Immunostaining of these cells with an anti-LC3 antibody showed that the TIF-IA siRNA treatment induced formation of endogenous LC3 punctate structures (Fig. 4c and Supplementary Fig. S5b). Immunoblotting results showed that the TIF-IA siRNA treatment increased LC3-II levels and reduced p62 protein levels (Fig. 4d and Supplementary Fig. S5c). Taken together with the results of MCF-7/EGFP-LC3B cells depleted of p53 and HeLa cells, autophagy was induced independently of activating p53 when TIF-IA was depleted.
NPM is required for autophagy induced by inhibiting Pol I
Because inhibiting Pol I transcription induced nucleolar disruption and autophagy, there was a possible relationship between nucleolar disruption and autophagy. One possibility is that some nucleolar proteins that were translocated from the nucleolus induced autophagy. To test this possibility, we screened for nucleolar proteins that were involved in activating autophagy in HeLa cells. We generated a siRNA library directed against mRNAs for nucleolar proteins42 and examined the effects of each siRNA on the conversion of LC3-I to LC3-II in cells, treated with TIF-IA siRNA. Based on these screening results, we focused on NPM, which is abundant in various cell types, is a multifunctional protein and is primarily localised to the nucleolus43,44,45,46. In addition, a role has not been previously shown for NPM during the induction of autophagy. Thus, we examined NPM function during the induction of autophagy.
We first ascertained that NPM was translocated from the nucleolus when Pol I was inhibited in MCF-7/EGFP-LC3B cells (Supplementary Fig. S6a and Supplementary Fig. S7a), as described in the previous reports13,16,22. To assess whether NPM was involved in the autophagy induced by inhibiting Pol I, we depleted TIF-IA and/or NPM in MCF-7/EGFP-LC3B cells and tested for the formation of EGFP-LC3B punctate structures (Fig. 5a and Supplementary Fig. S6b). The immunostaining results showed that NPM siRNA repressed formation of the EGFP-LC3B punctate structures induced by TIF-IA knockdown (compare panels 7 and 8, Fig. 5a), without affecting NCL translocation (compare panels 3 and 4, Fig. 5a). Furthermore, we conducted a transmission electron microscopy analysis to observe autophagic vacuoles. The electron microscopy analysis showed that TIF-IA knockdown increased the number of autophagic vacuoles, which were suppressed by NPM knockdown (Fig. 5b and Supplementary Fig. S8). Consistent with these immunostaining and electron microscopy results, depleting NPM counteracted the enhanced conversion of LC3B-I to LC3B-II induced by TIF-IA knockdown in MCF-7/EGFP-LC3B cells (Fig. 5c).
Furthermore, we tested for the effect of inhibiting POLR1A (Supplementary Fig. S7). NPM knockdown repressed formation of the EGFP-LC3B punctate structures and the conversion of LC3B-I to LC3B-II induced by POLR1A siRNA treatment (Supplementary Fig. S7b–d). These results were similar to those when TIF-IA siRNA was depleted. Thus, our findings indicate that NPM is essential for the autophagy induced by inhibiting Pol I transcription.
Previous reports showed that NPM enhances p53 accumulation under nucleolar disruption conditions14,28,47. Thus, NPM may have enhanced autophagy by activating p53. However, our results indicate that depleting NPM compromised autophagy induced by depleting TIF-IA without reducing the p53 level (Supplementary Fig. S9). These results suggest that the autophagy induced by NPM was independent of p53 activation.
NPM knockdown does not affect starvation-induced autophagy
Finally, we tested whether NPM is required for the autophagy induced by cell starvation (Fig. 6 and Supplementary Fig. S10). Nucleolar structures were little affected by serum and amino acid starvation or by treatments with bafilomycin A1 or NPM siRNA (Fig. 6a: panels 1–8). Incubating control siRNA-treated cells in starvation media induced formation of the EGFP-LC3B punctate structures (Fig. 6a: panel 10), which was enhanced in the presence of bafilomycin A1 (Fig. 6a: panel 12). Similar results were obtained with NPM siRNA-treated cells; starvation induced formation of the EGFP-LC3B punctate structures (Fig. 6a: panel 14), which was enhanced by bafilomycin A1 (Fig. 6a: panel 16). To further evaluate the involvement of NPM in starvation-induced autophagy, we examined conversion of LC3B-I to LC3B-II by immunoblotting (Fig. 6b). NPM knockdown had little effect on conversion of LC3B-I to LC3B-II induced by starvation and/or in bafilomycin A1 treated-cells (Fig. 6b). These results indicate that NPM is not involved in the autophagy induced by starvation.
We summarise our findings in Figure 6c. Our experimental results have revealed that nucleolar disruption by inhibiting Pol I transcription induced autophagy. Furthermore, we found that the nucleolar protein NPM is essential for autophagy induced by inhibiting Pol I transcription. In contrast, NPM was not involved in canonical autophagy induced by nutrient starvation. This result suggests that in addition to canonical autophagy, NPM-dependent autophagy induced by Pol I transcription inhibition exists (Fig. 6c).
Recent reports have indicated that the nucleolus is involved in various cellular processes, such as cell cycle regulation, cell proliferation and stress response, in addition to a primary function as the site of ribosome biogenesis9,10,11,42. The relationship between the nucleolus and various human diseases has also been suggested22,23,28,29. In this study, we found that autophagy was induced when the nucleolus was experimentally disrupted by several methods (Figs. 1 and 2), reflecting the relationship between the nucleolus and autophagy. In addition, we revealed that nucleolar disruption was upstream of autophagy in cells in which Pol I transcription was inhibited using siRNAs for ATG proteins or autophagy inhibitors, because they influenced autophagy without affecting nucleolar disruption (Fig. 3). Recent reports indicate the presence of nucleophagy, which is a selective form of autophagy that removes and degrades damaged or non-essential parts of the nucleus7,48. We found no evidence of nucleophagy when the nucleolus was disrupted; however, it is intriguing to test for the presence of nucleophagy because Pol I inhibition may influence nuclear structures, including nucleolar dynamics.
There are two possible mechanisms by which nucleolar disruption could induce autophagy; one is that reduced protein synthesis via a reduced number of ribosomes causes autophagy9,13 and the other is that translocation of nucleolar proteins causes autophagy11,15. The former mechanism is unlikely because cycloheximide, an inhibitor of protein synthesis, does not enhance autophagy49,50. To test the latter possibility, we screened for nucleolar proteins, the knockdown of which compromised autophagy induced by Pol I inhibition. On the basis of these results, we focused on NPM, which is abundant in various cell types and is a multifunctional protein localised primarily to the nucleolus43,44,45,46.
NPM knockdown inhibited autophagy without affecting nucleolar disruption when Pol I transcription factors were depleted (Fig. 5 and Supplementary Fig. S7). Furthermore, NPM was not essential for canonical autophagy induced by nutrient starvation stress, which did not induce nucleolar disruption (Fig. 6a and b). On the basis of this result, NPM may have induced autophagy when nucleolar structure was disrupted by Pol I inhibition, a mechanism different from that involved in canonical autophagy (Fig. 6c). A previous study showed that p53 is implicated in autophagy induced by nucleolar stress22. Thus, NPM may enhance autophagy by activating p53, as NPM enhances the accumulation and activation of p5314,47. However, our screening results showed that NPM was also involved in autophagy of HeLa cells, which are cells that do not have active p53. Furthermore, NPM knockdown compromised autophagy without reducing the p53 level (Supplementary Fig. S9). On the basis of these results, it is likely that NPM-induced autophagy is independent of p53 activation under our conditions. Thus, NPM- and p53-dependent pathways may be present independently in the autophagy induced by nucleolar disruption (Fig. 6c).
Autophagy is reportedly related to various diseases, such as neurodegenerative diseases and tumours3,26,27,31,32,33. In addition, abnormalities in nucleolar structure are observed in such diseases22,23,24,25,28,29,30. A decrease in rRNA transcription and reduced nucleolar volume are found in animal models of various neurodegenerative diseases22,23,24,25. Furthermore, targeted disruption of the nucleolus by conditional TIF-IA ablation results in a mouse model with neurodegenerative disease-like phenotypes22,24. Thus, nucleolar stress and its resultant shrinking nucleolus is one of the causes of neurodegenerative diseases. Several lines of evidence indicate that autophagy has neuroprotective functions3,26,27. For example, disruption of the nucleolus in response to nucleolar stress activates p53, which enhances autophagy and prolongs neural survival, along with PTEN22; although, the effect of p53 on neural survival is biphasic; p53 causes cell death by inducing apoptosis23. Moreover, neural cell-specific Atg5 or Atg7 conditional knockout mice develop neurodegenerative diseases51,52, indicating the importance of autophagy to prevent such diseases. In addition, NPM translocates from the nucleolus to the nucleoplasm in response to nucleolar stress12,13. Overexpression of NPM is neuroprotective in cellular models53. Taken together with our results showing that NPM has a critical role in the induction of autophagy by nucleolar disruption (Fig. 5 and Supplementary Fig. S7), NPM may have a role in alleviating neuronal diseases by inducing autophagy. Thus, NPM could be a molecular drug target or be used in a strategy to cure neuronal disease.
Next, we discuss tumours. An increase in rRNA synthesis and an enlarged nucleolus are tumour hallmarks28,29,30, in contrast to neurodegenerative diseases. Autophagy is enhanced in tumour cells31,32,33; however, the link between autophagy and the nucleolus has not been established. We propose that NPM could be a key molecule. NPM is overexpressed in various tumour types, including gastric, colon, ovarian and prostate43,54,55. NPM promotes tumour progression by enhancing cell proliferation and inhibiting cell differentiation and apoptosis43,54,55. Translocation of NPM to the cytoplasm, which is caused by a mutation in the NPM nucleolar localisation domain, is detected in >30% of primary acute myelogenous leukaemia cells56,57. Thus, translocation of NPM may enhance cancer progression by facilitating autophagy, which is related to tumorigenesis; autophagy suppresses tumour growth during the initiation stage, although it also plays a critical role in tumour progression and maintenance58,59,60. If this is the case, then inhibiting autophagy would enhance the effect of anti-cancer drugs in tumours with translocated NPM, as inhibiting autophagy enhances the cytotoxic effects of some anti-cancer agents31,32,33,60. Alternatively, inhibition or downregulation of NPM could lead to a new cancer therapy strategy.
MCF-7 human breast cancer cells and HeLa human cervical cancer cells were maintained in DMEM (Sigma, St. Louis, MO, USA) as previously described16.
Full-length cDNA encoding human LC3B was amplified by polymerase chain reaction (PCR) using total DNA isolated from MCF-7 cells. PCR amplification was conducted using the following primers: human LC3B forward, 5′-GGCGAATTCGATGCCGTCGGAGAAGACCTTC-3′ and reverse, 5′-GGCGTCGACTTACACTGACAATTTCATCCC-3′. cDNA was cloned into the pEGFP-C1 vector (Invitrogen, Carlsbad, CA, USA) to generate the pEGFP-C1-LC3B plasmid.
Generation of stable cell lines
MCF-7 cells were transfected with the pEGFP-C1-LC3B plasmid using Lipofectamine LTX & Plus Reagent (Invitrogen) according to the manufacturer's guidelines. Selective pressure was applied 48 h after transfection using DMEM containing 0.5 mg/ml G418. At least five stable transgenic clones were isolated after 14 days.
siRNA transfection was performed as previously described16. In brief, Cells at 30–50% confluence were transfected with 20 nM siRNA (see below) using Lipofectamine RNAiMAX (Invitrogen) for 48–72 h according to the manufacturer's protocol.
The anti-GFP, anti-p62/SQSTM1, anti-BECN1, anti-ATG5 and anti-LC3 antibodies were purchased from MBL International (Woburn, MA, USA) (598, PM045, PM017, M153-3 and PM036, respectively). Anti-β-actin and anti-p53 antibodies were purchased from Santa Cruz Biotechnology (Santa Cruz, CA, USA) (sc-47778 and sc-126, respectively). The anti-NCL antibody was purchased from Abcam (Cambridge, MA, USA) (ab-13541) and anti-NPM antibody was purchased from Invitrogen (32-5200).
Cells grown on chamber slides were washed with phosphate-buffered saline (PBS; 140 mM NaCl, 2.7 mM KCl, 1.5 mM KH2PO4 and 8.1 mM Na2HPO4) and fixed in 4% paraformaldehyde phosphate buffer solution (Wako Pure Chemical, Osaka, Japan) for 10 min. After washing twice with PBS, the cells were permeabilised in 0.1% Triton X-100 in PBS and blocked with 0.1% Triton X-100 in PBS containing 1% bovine serum albumin and 10% foetal bovine serum for 1 h at room temperature. Then the MCF-7/EGFP-LC3B cells were incubated with anti-GFP, anti-NCL or anti-NPM antibodies and HeLa cells were incubated with anti-LC3, anti-NCL or anti-NPM antibodies for 6 h at 4°C. After washing with 0.1% Triton X-100 in PBS, the cells were incubated with Alexa Fluor 488- and 594-conjugated secondary antibodies (Invitrogen) for 1 h and mounted with Vectashield (Vector Laboratories, Burlingame, CA, USA). Immunofluorescence signals were detected by Biorevo BZ-9000 immunofluorescence microscopy (Keyence, Osaka, Japan). More than 150 cells were determined in triplicate experiments to quantify the number of EGFP-LC3B and LC3 puncta. More than 100 cells were determined in triplicate experiments to quantify the number of cells with translocated NCL.
All siRNAs were purchased from Invitrogen. The following sequences were used: human TIF-IA#1-siRNA sense: 5′-CGACACCGUGGUUUCUCAUGCCAAU-3′ and antisense: 5′-AUUGGCAUGAGAAACCACGGUGUCG-3′; human TIF-IA#2-siRNA sense: 5′-AGGAUGUCUGCUAUGUAGAUGGUAA-3′ and antisense, 5′-UUACCAUCUACAUAGCAGACAUCCU-3′; human POLR1A#1-siRNA sense: 5′-CCUAGGAGACCAGAUGUUUACUAAU-3′ and antisense: 5′-AUUAGUAAACAUCUGGUCUCCUAGG-3′; human POLR1A#2-siRNA sense: 5′-CAACAGCAAGUUGACUAUCACGUUU-3′ and antisense: 5′-AAACGUGAUAGUCAACUUGCUGUUG-3′; human BECN1-siRNA sense: 5′-CCACUCUGUGAGGAAUGCACAGAUA-3′ and antisense: 5′-UAUCUGUGCAUUCCUCACAGAGUGG-3′; human ATG5-siRNA sense: 5′-CAAAGAAGUUUGUCCUUCUGCUAUU-3′ and antisense: 5′-AAUAGCAGAAGGACAAACUUCUUUG-3′; human p53#1-siRNA sense: 5′- UUCCGUCCCAGUAGAUUACCACUGG-3′ and antisense: 5′- CCAGUGGUAAUCUACUGGGACGGAA-3′; human p53#2-siRNA sense: 5′- GCUUCGAGAUGUUCCGAGAGCUGAA-3′ and antisense: 5′- UUCAGCUCUCGGAACAUCUCGAAGC-3′; human NPM1#1-siRNA sense: 5′-GAUGACUGACCAAGAGGCUAUUCAA-3′ and antisense: 5′-UUGAAUAGCCUCUUGGUCAGUCAUC-3′ and human NPM1#2-siRNA sense: 5′-UGUAUGGAAUGUUAUGAUAGGACAU-3′ and antisense: 5′-AUGUCCUAUCAUAACAUUCCAUACA-3′. The Stealth™ RNAi Luciferase Reporter Control Duplex was used as a control.
Immunoblotting was performed as previously described16 with minor modifications. The membranes were blocked with 3% skim milk in TBS-T buffer (20 mM Tris-HCl, pH 7.5; 150 mM NaCl and 0.05% Tween20) for 30 min.
MCF-7 cells were prefixed in 2% glutaraldehyde in 0.1 M phosphate buffer at 4°C. The following experiments were performed by the Hanaichi Ultra Structure Institute. In brief, the cells were washed overnight in 0.1 M phosphate buffer at 4°C and were postfixed in 2% osmium tetraoxide for 3 h. The cells were further dehydrated in a graded ethanol series and embedded in epoxy resin. Ultrathin sections were stained with 2% uranyl acetate and lead staining solution and observed with a JEM-1200EX electron microscope. At least 100 μm2 of the cytoplasmic area was determined to quantify the ratio of the area of autophagic vacuoles to the cytoplasmic area.
Kroemer, G., Marino, G. & Levine, B. Autophagy and the integrated stress response. Mol. Cell 40, 280–293 (2010).
Hurley, J. H. & Schulman, B. A. Atomistic autophagy: the structures of cellular self-digestion. Cell 157, 300–311 (2014).
Mizushima, N. & Komatsu, M. Autophagy: renovation of cells and tissues. Cell 147, 728–741 (2011).
Mehrpour, M., Esclatine, A., Beau, I. & Codogno, P. Overview of macroautophagy regulation in mammalian cells. Cell Res. 20, 748–762 (2010).
He, C. & Klionsky, D. J. Regulation mechanisms and signaling pathways of autophagy. Annu. Rev. Genet. 43, 67–93 (2009).
Manjithaya, R., Nazarko, T. Y., Farre, J. C. & Subramani, S. Molecular mechanism and physiological role of pexophagy. FEBS Lett. 584, 1367–1373 (2010).
Hughson, L. R., Poon, V. I., Spowart, J. E. & Lum, J. J. Implications of therapy-induced selective autophagy on tumor metabolism and survival. Int. J. C. Biol. 2012, 872091 (2012).
Tsukada, M. & Ohsumi, Y. Isofation and charactzation of autophagy-defective mutants of Sacharomyces cerevisiae. FEBS Lett. 333, 169–174 (1993).
Boisvert, F. M., van Koningsbruggen, S., Navascues, J. & Lamond, A. I. The multifunctional nucleolus. Nat. Rev. Mol. Cell Biol. 8, 574–585 (2007).
Boulon, S., Westman, B. J., Hutten, S., Boisvert, F. M. & Lamond, A. I. The nucleolus under stress. Mol. Cell 40, 216–227 (2010).
Manfredi, J. J. The Mdm2-p53 relationship evolves: Mdm2 swings both ways as an oncogene and a tumor suppressor. Genes Dev. 24, 1580–1589 (2010).
Rubbi, C. P. & Milner, J. Disruption of the nucleolus mediates stabilization of p53 in response to DNA damage and other stresses. EMBO J. 22, 6068–6077 (2003).
Yuan, X. et al. Genetic inactivation of the transcription factor TIF-IA leads to nucleolar disruption, cell cycle arrest and p53-mediated apoptosis. Mol. Cell 19, 77–87 (2005).
Kurki, S. et al. Nucleolar protein NPM interacts with HDM2 and protects tumor suppressor protein p53 from HDM2-mediated degradation. Cancer Cell 5, 465–475 (2004).
Zhou, X., Liao, J. M., Liao, W. J. & Lu, H. Scission of the p53-MDM2 Loop by Ribosomal Proteins. Genes Cancer 3, 298–310 (2012).
Kuroda, T. et al. RNA content in the nucleolus alters p53 acetylation via MYBBP1A. EMBO J. 30, 1054–1066 (2011).
Rouschop, K. M. et al. The unfolded protein response protects human tumor cells during hypoxia through regulation of the autophagy genes MAP1LC3B and ATG5. J. Clin. Invest. 120, 127–141 (2010).
Chen, L. H. et al. Targeting Protective Autophagy Exacerbates UV-Triggered Apoptotic Cell Death. Int. J. Mol. Sci. 13, 1209–1224 (2012).
Kobayashi, S. et al. Transcription factor GATA4 inhibits doxorubicin-induced autophagy and cardiomyocyte death. J. Biol. Chem. 285, 793–804 (2010).
Zhao, J. et al. Interferon-alpha suppresses invasion and enhances cisplatin-mediated apoptosis and autophagy in human osteosarcoma cells. Oncol. Lett. 7, 827–833 (2014).
Yang, Y., Xing, D., Zhou, F. & Chen, Q. Mitochondrial autophagy protects against heat shock-induced apoptosis through reducing cytosolic cytochrome c release and downstream caspase-3 activation. Biochem. Biophys. Res. Commu. 395, 190–195 (2010).
Kreiner, G. et al. A neuroprotective phase precedes striatal degeneration upon nucleolar stress. Cell Death Differ. 20, 1455–1464 (2013).
Parlato, R. & Liss, B. How Parkinson's disease meets nucleolar stress. Biochim. Biophys. Acta 1842, 791–797 (2014).
Rieker, C. et al. Nucleolar disruption in dopaminergic neurons leads to oxidative damage and parkinsonism through repression of mammalian target of rapamycin signaling. J. Neurosci. 31, 453–460 (2011).
Healy-Stoffel, M., Ahmad, S. O., Stanford, J. A. & Levant, B. Altered nucleolar morphology in substantia nigra dopamine neurons following 6-hydroxydopamine lesion in rats. Neurosci. Lett. 546, 26–30 (2013).
Schneider, J. L. & Cuervo, A. M. Autophagy and human disease: emerging themes. Curr. Opin. Genet. Dev. 26C, 16–23 (2014).
Levine, B. & Kroemer, G. Autophagy in the pathogenesis of disease. Cell 132, 27–42 (2008).
Quin, J. E. et al. Targeting the nucleolus for cancer intervention. Biochim. Biophys. Acta 1842, 802–816 (2014).
Derenzini, M., Montanaro, L. & Trere, D. What the nucleolus says to a tumour pathologist. Histopathology 54, 753–762 (2009).
Uemura, M. et al. Overexpression of ribosomal RNA in prostate cancer is common but not linked to rDNA promoter hypomethylation. Oncogene 31, 1254–1263 (2012).
Choi, K. S. Autophagy and cancer. Exp. Mol. Med. 44, 109–120 (2012).
Yang, Z. J., Chee, C. E., Huang, S. & Sinicrope, F. A. The role of autophagy in cancer: therapeutic implications. Mol. Cancer Ther. 10, 1533–1541 (2011).
Cheong, H., Lu, C., Lindsten, T. & Thompson, C. B. Therapeutic targets in cancer cell metabolism and autophagy. Nat. Biotechnol. 30, 671–678 (2012).
Dimitrakis, P., Romay-Ogando, M. I., Timolati, F., Suter, T. M. & Zuppinger, C. Effects of doxorubicin cancer therapy on autophagy and the ubiquitin-proteasome system in long-term cultured adult rat cardiomyocytes. Cell Tissue Res. 350, 361–372 (2012).
Drygin, D., Rice, W. G. & Grummt, I. The RNA polymerase I transcription machinery: an emerging target for the treatment of cancer. Annu. Rev. Pharmacol. Toxicol. 50, 131–156 (2010).
Jordan, P., Mannervik, M., Tora, L. & Carmo-Fonseca, M. In vivo evidence that TATA-binding protein/SL1 colocalizes with UBF and RNA polymerase I when rRNA synthesis is either active or inactive. J. Cell Biol. 133, 225–234 (1996).
Grummt, I. Life on a planet of its own: regulation of RNA polymerase I transcription in the nucleolus. Genes Dev. 17, 1691–1702 (2003).
Donati, G. et al. Selective inhibition of rRNA transcription downregulates E2F-1: a new p53-independent mechanism linking cell growth to cell proliferation. J. Cell Sci. 124, 3017–3028 (2011).
Mizushima, N., Yoshimori, T. & Levine, B. Methods in mammalian autophagy research. Cell 140, 313–326 (2010).
DeFilippis, R. A., Goodwin, E. C., Wu, L. & DiMaio, D. Endogenous Human Papillomavirus E6 and E7 Proteins Differentially Regulate Proliferation, Senescence and Apoptosis in HeLa Cervical Carcinoma Cells. J. Virol. 77, 1551–1563 (2003).
Hoppe-Seyler, F. & Butz, K. Repression of endogenous p53 transactivation function in HeLa cervical carcinoma cells by human papillomavirus type 16 E6, human mdm-2 and mutant p53. J. Virol. 67, 3111–3117 (1993).
Andersen, J. S. et al. Nucleolar proteome dynamics. Nature 433, 77–83 (2005).
Grisendi, S., Mecucci, C., Falini, B. & Pandolfi, P. P. Nucleophosmin and cancer. Nat. Rev. Cancer 6, 493–505 (2006).
Okuwaki, M. The structure and functions of NPM1/Nucleophsmin/B23, a multifunctional nucleolar acidic protein. J. Biochem. 143, 441–448 (2008).
Murano, K., Okuwaki, M., Hisaoka, M. & Nagata, K. Transcription regulation of the rRNA gene by a multifunctional nucleolar protein, B23/nucleophosmin, through its histone chaperone activity. Mol. Cell. Biol. 28, 3114–3126 (2008).
Amin, M. A., Matsunaga, S., Uchiyama, S. & Fukui, K. Nucleophosmin is required for chromosome congression, proper mitotic spindle formation and kinetochore-microtubule attachment in HeLa cells. FEBS Lett. 582, 3839–3844 (2008).
Colombo, E., Marine, J. C., Danovi, D., Falini, B. & Pelicci, P. G. Nucleophosmin regulates the stability and transcriptional activity of p53. Nat. Cell Biol. 4, 529–533 (2002).
Mijaljica, D. & Devenish, R. J. Nucleophagy at a glance. J. Cell Sci. 126, 4325–4330 (2013).
Ding, W. X. et al. Differential effects of endoplasmic reticulum stress-induced autophagy on cell survival. J. Biol. Chem. 282, 4702–4710 (2007).
Watanabe-Asano, T., Kuma, A. & Mizushima, N. Cycloheximide inhibits starvation-induced autophagy through mTORC1 activation. Biochem. Bbiophys. Res. Commun. 445, 334–339 (2014).
Hara, T. et al. Suppression of basal autophagy in neural cells causes neurodegenerative disease in mice. Nature 441, 885–889 (2006).
Komatsu, M. et al. Loss of autophagy in the central nervous system causes neurodegeneration in mice. Nature 441, 880–884 (2006).
Marquez-Lona, E. M., Tan, Z. & Schreiber, S. S. Nucleolar stress characterized by downregulation of nucleophosmin: a novel cause of neuronal degeneration. Biochem. Biophys. Res. Commun. 417, 514–520 (2012).
Colombo, E., Alcalay, M. & Pelicci, P. G. Nucleophosmin and its complex network: a possible therapeutic target in hematological diseases. Oncogene 30, 2595–2609 (2011).
Lim, M. J. & Wang, X. W. Nucleophosmin and human cancer. Cancer Detect. Prev. 30, 481–490 (2006).
Falini, B., Gionfriddo, I., Cecchetti, F., Ballanti, S., Pettirossi, V. & Martelli, M. P. Acute myeloid leukemia with mutated nucleophosmin (NPM1): any hope for a targeted therapy? Blood Rev. 25, 247–254 (2011).
Federici, L. & Falini, B. Nucleophosmin mutations in acute myeloid leukemia: a tale of protein unfolding and mislocalization. Protein Sci. 22, 545–556 (2013).
Guo, J. Y., Xia, B. & White, E. Autophagy-mediated tumor promotion. Cell 155, 1216–1219 (2013).
Hoare, M., Young, A. R. & Narita, M. Autophagy in cancer: having your cake and eating it. Semin. Cancer Biol. 21, 397–404 (2011).
White, E. & DiPaola, R. S. The double-edged sword of autophagy modulation in cancer. Clin. Cancer Res. 15, 5308–5316 (2009).
We thank Enago for the English language review. This study was supported by grants from the Ministry of Education, Culture, Sports, Science and Technology of Japan. N.K. is a Japan Society for the Promotion of Science (JSPS) Research Fellow. The electron microscopy was performed by the Hanaichi Ultra Structure Institute (Okazaki, Japan).
The authors declare no competing financial interests.
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Katagiri, N., Kuroda, T., Kishimoto, H. et al. The nucleolar protein nucleophosmin is essential for autophagy induced by inhibiting Pol I transcription. Sci Rep 5, 8903 (2015). https://doi.org/10.1038/srep08903
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