Nucleostemin deletion reveals an essential mechanism that maintains the genomic stability of stem and progenitor cells

Meng, Lingjun; Lin, Tao; Peng, Guang; Hsu, Joseph K.; Lee, Sun; Lin, Shiaw Yih; Tsai, Robert Y.L.

doi:10.1073/pnas.1301672110

Cited by 50 publications

(79 citation statements)

References 19 publications

(24 reference statements)

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“…Regardless, until such evidence is presented, it is scientifically inaccurate to refer to mammalian nucleostemin as a nucleolar GTPase or assume it functions as a GTPase enzyme. The biological importance of nucleostemin has never been in doubt, as it is well established that nucleostemin makes key contributions to blastocyst formation (Beekman et al, 2006;Zhu et al, 2006), embryogenesis (Meng et al, 2013), postnatal tissue regeneration Shugo et al, 2012), cancer development (Lin et al, 2010;Sijin et al, 2004;Tamase et al, 2009) and reprograming to pluripotency (Qu and Bishop, 2012).…”

Section: History and Mysteriesmentioning

confidence: 99%

“…One study has shown that nucleostemin is able to reduce telomere damage through modification of telomeric repeat Science (2014Science ( ) 127, 3885-3891 doi:10.1242 binding factor 1 (TRF1, also known as TERF1) and recruitment of promyelocytic leukemia protein isoform IV (PML-IV) in telomerase-negative human cancer cells (Hsu et al, 2012). Two reports have identified that it protects the genome integrity of stem or progenitor cells by promoting the recruitment of RAD51, the core component of the homologous recombination machinery, to stalled replication-induced DNA damage foci Meng et al, 2013) (Fig. 1).…”

Section: History and Mysteriesmentioning

confidence: 99%

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Turning a new page on nucleostemin and self-renewal

Tsai

2014

Journal of Cell Science

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A quintessential trait of stem cells is embedded in their ability to selfrenew without incurring DNA damage as a result of genome replication. One key self-renewal factor is the nucleolar GTPbinding protein nucleostemin (also known as guanine-nucleotidebinding protein-like 3, GNL3, in invertebrate species). Several studies have recently pointed to an unexpected role of nucleostemin in safeguarding the genome integrity of stem and cancer cells. Since its discovery, the predominant presence of nucleostemin in the nucleolus has led to the notion that it might function in the cardcarrying event of the nucleolus -the biogenesis of ribosomes. As tantalizing as this might be, a ribosomal role of nucleostemin is refuted by evidence from recent studies, which argues that nucleostemin depletion triggers a primary event of DNA damage in S phase cells that then leads to ribosomal perturbation. Furthermore, there have been conflicting reports regarding the p53 dependency of nucleostemin activity and the cell cycle arrest profile of nucleostemindepleted cells. In this Commentary, I propose a model that explains how the many contradictory observations surrounding nucleostemin can be reconciled and suggest that this protein might not be as multitasking as has been previously perceived. The story of nucleostemin highlights the complexity of the underlying molecular events associated with the appearance of any cell biological phenotype and also signifies a new understanding of the genome maintenance program in stem cells.

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Section: History and Mysteriesmentioning

confidence: 99%

Section: History and Mysteriesmentioning

confidence: 99%

Turning a new page on nucleostemin and self-renewal

Tsai

2014

Journal of Cell Science

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“…uS3) has been reported to act as an apurinic/apyrimidinic endonuclease in both nuclear and mitochondrial base excision repair (Kim et al 2013), while nucleostemin/GNL3 has been implicated in the recruitment of RAD51 to stalled replication forks Meng et al 2013), and Nol12 has D r a f t 5 been identified as an important protective factor against oxidative DNA damage (Scott et al 2016). Most strikingly, two proteins -nucleophosmin (NPM1) and nucleolin (NCL) -are required for optimal activity of multiple independent DNA repair pathways, and their dysregulation has been reported in numerous cancers, in particular leukemias and other myeloproliferative disorders (Berger et al 2015;Colombo et al 2011;Federici et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Nucleolin and nucleophosmin: nucleolar proteins with multiple functions in DNA repair

Scott

Oeffinger

2016

Biochem. Cell Biol.

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The nucleolus represents a highly multifunctional intranuclear organelle in which, in addition to the canonical ribosome assembly, numerous processes such as transcription, DNA repair and replication, the cell cycle and apoptosis are coordinated. The nucleolus is further a key hub in the sensing of cellular stress and undergoes major structural and compositional changes in response to cellular perturbations.Numerous nucleolar proteins have been identified that, upon nucleolar stress sensing, deploy additional, non-ribosomal roles in the regulation of varied cell processes including cell cycle arrest, arrest of DNA replication, induction of DNA repair, and apoptosis, among others. The highly abundant proteins nucleophosmin (NPM1) and nucleolin (NCL) are two such factors that transit to the nucleoplasm in response to stress, and participate directly in the repair of numerous different DNA damages. This review discusses the contributions made by NCL and/or NPM1 to the different DNA repair pathways employed by mammalian cells to repair DNA insults, and examines the implications of such activities for the regulation, pathogenesis and therapeutic targeting of NPM1 and NCL.

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“…Thus, we believe that the conclusion reached by Romanova et al might be confounded by unsuspected issues surrounding the immediate versus longterm effects of nucleostemin depletion, as well as the interconnecting relationship between nucleolar function and cell cycle. Furthermore, while the present investigation was under way, a parallel study suggested that there is a direct molecular recruitment of nucleostemin to DNA damage sites, where it interacts with the DNA repair protein RAD51 (Meng et al, 2013). This also alerted us to the possibility that nucleostemin is involved in genome protection and not rRNA synthesis.…”

Section: Discussion the Hypothesismentioning

confidence: 99%

“…In this respect, it is noteworthy that effects on ribosome synthesis have been observed following two rounds of RNAi-mediated nucleostemin knockdown over a period of 5 days (Romanova et al, 2009a;Romanova et al, 2009b). Motivated by the recent discovery of a role for nucleostemin in protecting telomeres and the genome integrity of stem and progenitor cells (Hsu et al, 2012;Lin et al, 2013;Meng et al, 2013;Yamashita et al, 2013), we began to consider whether the accumulation of DNA damage, rather than impaired ribosome production, is actually the initial event following nucleostemin depletion. Using human breast cancer MDA-MB-231 cells, we found that DNA damage arises as early as 12 hours after the initiation of nucleostemin depletion, without incurring a significant effect on rRNA synthesis or nucleolar structure for up to 48 hours.…”

Section: Introductionmentioning

confidence: 99%

Distinct genome protective vs. ribosome synthetic functions of the paralogous nucleolar proteins nucleostemin and GNL3L

Lin

Meng

Lin

et al. 2014

Journal of Cell Science

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The mammalian nucleolar proteins nucleostemin and GNL3-like (GNL3L) are encoded by paralogous genes that arose from an ancestral invertebrate gene, GNL3. Invertebrate GNL3 has been implicated in ribosome biosynthesis, as has its mammalian descendent, GNL3L. The paralogous mammalian nucleostemin protein has, instead, been implicated in cell renewal. Here, we found that depletion of nucleostemin in a human breast carcinoma cell line triggers prompt and significant DNA damage in S-phase cells without perturbing the initial step of ribosomal (r)RNA synthesis and only mildly affects the total ribosome production. By contrast, GNL3L depletion markedly impairs ribosome production without inducing appreciable DNA damage. These results indicate that, during vertebrate evolution, GNL3L retained the role of the ancestral gene in ribosome biosynthesis, whereas the paralogous nucleostemin acquired a novel genome-protective function. Our results provide a coherent explanation for what had seemed to be contradictory findings about the functions of the invertebrate versus vertebrate genes and are suggestive of how the nucleolus was fine-tuned for a role in genome protection and cell-cycle control as the vertebrates evolved.

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Nucleostemin deletion reveals an essential mechanism that maintains the genomic stability of stem and progenitor cells

Cited by 50 publications

References 19 publications

Turning a new page on nucleostemin and self-renewal

Turning a new page on nucleostemin and self-renewal

Nucleolin and nucleophosmin: nucleolar proteins with multiple functions in DNA repair

Distinct genome protective vs. ribosome synthetic functions of the paralogous nucleolar proteins nucleostemin and GNL3L

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