GNL3 is an evolutionarily conserved stem cell gene influencing cell proliferation,animal growth and regeneration in the hydrozoan Hydractinia

Nucleostemin (NS) is a vertebrate gene preferentially expressed in stem and cancer cells, which acts to regulate cell cycle progression, genome stability and ribosome biogenesis. NS and its paralogous gene, GNL3-like (GNL3L), arose in the vertebrate clade after a duplication event from their orthologous gene, G protein Nucleolar 3 (GNL3). Research on invertebrate GNL3, however, has been limited. To gain a greater understanding of the evolution and functions of the GNL3 gene, we have performed studies in the hydrozoan cnidarian Hydractinia symbiolongicarpus, a colonial hydroid that continuously generates pluripotent stem cells throughout its life cycle and presents impressive regenerative abilities. We show that Hydractinia GNL3 is expressed in stem and germline cells. The knockdown of GNL3 reduces the number of mitotic and S-phase cells in Hydractinia larvae of different ages. Genome editing of Hydractinia GNL3 via CRISPR/Cas9 resulted in colonies with reduced growth rates, polyps with impaired regeneration capabilities, gonadal morphological defects, and low sperm motility. Collectively, our study shows that GNL3 is an evolutionarily conserved stem cell and germline gene involved in cell proliferation, animal growth, regeneration and sexual reproduction in Hydractinia, and sheds new light into the evolution of GNL3 and of stem cell systems.     

A novel lysine-rich domain and GTP binding motifs regulate the nucleolar retention of human guanine nucleotide binding protein, GNL3L

A variety of G-proteins and GTPases are known to be involved in nucleolar function. We describe here a new evolutionarily conserved putative human GTPase, guanine nucleotide binding protein-like 3-like (GNL3L). Genes encoding proteins related to GNL3L are present in bacteria and yeast to metazoa and suggests its critical role in development. Conserved domain search analysis revealed that the GNL3L contains a circularly permuted G-motif described by a G5-G4-G1-G2-G3 pattern similar to the HSR1/MMR1 GTP-binding protein subfamily. Highly conserved and critical residues were identified from a three-dimensional structural model obtained for GNL3L using the crystal structure of an Ylqf GTPase from Bacillus subtilis. We demonstrate here that GNL3L is transported into the nucleolus by a novel lysine-rich nucleolar localization signal (NoLS) residing within 1-50 amino acid residues. NoLS identified here is necessary and sufficient to target the heterologous proteins to the nucleolus. We show for the first time that the lysine-rich targeting signal interacts with the nuclear transport receptor, importin-beta and transports GNL3L into the nucleolus. Interestingly, depletion of intracellular GTP blocks GNL3L accumulation into the nucleolar compartment. Furthermore, mutations within the G-domains alter the GTP binding ability of GNL3L and abrogate wild-type nucleolar retention even in the presence of functional NoLS, suggesting that the efficient nucleolar retention of GNL3L involves activities of both basic NoLS and GTP-binding domains. Collectively, these data suggest that GNL3L is composed of distinct modules, each of which plays a specific role in molecular interactions for its nucleolar retention and subsequent function(s) within the nucleolus.     

GNL3L stabilizes the TRF1 complex and promotes mitotic transition

Telomeric repeat binding factor 1 (TRF1) is a component of the multiprotein complex “shelterin,” which organizes the telomere into a high-order structure. TRF1 knockout embryos suffer from severe growth defects without apparent telomere dysfunction, suggesting an obligatory role for TRF1 in cell cycle control. To date, the mechanism regulating the mitotic increase in TRF1 protein expression and its function in mitosis remains unclear. Here, we identify guanine nucleotide-binding protein-like 3 (GNL3L), a GTP-binding protein most similar to nucleostemin, as a novel TRF1-interacting protein in vivo. GNL3L binds TRF1 in the nucleoplasm and is capable of promoting the homodimerization and telomeric association of TRF1, preventing promyelocytic leukemia body recruitment of telomere-bound TRF1, and stabilizing TRF1 protein by inhibiting its ubiquitylation and binding to FBX4, an E3 ubiquitin ligase for TRF1. Most importantly, the TRF1 protein-stabilizing activity of GNL3L mediates the mitotic increase of TRF1 protein and promotes the metaphase-to-anaphase transition. This work reveals novel aspects of TRF1 modulation by GNL3L.     

Nucleolar trafficking of nucleostemin family proteins: common versus protein-specific mechanisms

The nucleolus has begun to emerge as a subnuclear organelle capable of modulating the activities of nuclear proteins in a dynamic and cell type-dependent manner. It remains unclear whether one can extrapolate a rule that predicts the nucleolar localization of multiple proteins based on protein sequence. Here, we address this issue by determining the shared and unique mechanisms that regulate the static and dynamic distributions of a family of nucleolar GTP-binding proteins, consisting of nucleostemin (NS), guanine nucleotide binding protein-like 3 (GNL3L), and Ngp1. The nucleolar residence of GNL3L is short and primarily controlled by its basic-coiled-coil domain, whereas the nucleolar residence of NS and Ngp1 is long and requires the basic and the GTP-binding domains, the latter of which functions as a retention signal. All three proteins contain a nucleoplasmic localization signal (NpLS) that prevents their nucleolar accumulation. Unlike that of the basic domain, the activity of NpLS is dynamically controlled by the GTP-binding domain. The nucleolar retention and the NpLS-regulating functions of the G domain involve specific residues that cannot be predicted by overall protein homology. This work reveals common and protein-specific mechanisms underlying the nucleolar movement of NS family proteins.     

Modeling and structural analysis of human Guanine nucleotide-binding protein-like 3,nucleostemin

Human GNL3 (nucleostemin) is a recently discovered nucleolar protein with pivotal functions in maintaining genomic integrity and determining cell fates of various normal and cancerous stem cells. Recent reports suggest that targeting this GTP-binding protein may have therapeutic value in cancer. Although, sequence analyzing revealed that nucleostemin (NS) comprises 5 permuted GTP-binding motifs, a crystal structure for this protein is missing at Protein Data Bank (PDB). Obviously, any attempt for predicting of NS structure can further our knowledge on its functional sites and subsequently designing molecular inhibitors. Herein, we used bioinformatics tools and could model 262 amino acids of NS (132-393 aa). Initial models were built by MODELLER, refined with Scwrl4 program, and validated with ProsA and Jcsc databases as well as PSVS software. Then, the best quality model was chosen for motif and domain analyzing by Pfam, PROSITE and PRINTS. The final model was visualized by vmd program. This predicted model may pave the way for next studies regarding ligand binding states and interaction sites as well as screening of databases for potential inhibitors.     

GNL3L Is a Nucleo-Cytoplasmic Shuttling Protein: Role in Cell Cycle Regulation

GNL3L is an evolutionarily conserved high molecular weight GTP binding nucleolar protein belonging to HSR1-MMR1 subfamily of GTPases. The present investigation reveals that GNL3L is a nucleo-cytoplasmic shuttling protein and its export from the nucleus is sensitive to Leptomycin B. Deletion mutagenesis reveals that the C-terminal domain (amino acids 501–582) is necessary and sufficient for the export of GNL3L from the nucleus and the exchange of hydrophobic residues (M567, L570 and 572) within the C-terminal domain impairs this process. Results from the protein-protein interaction analysis indicate that GNL3L interaction with CRM1 is critical for its export from the nucleus. Ectopic expression of GNL3L leads to lesser accumulation of cells in the ‘G2/M’ phase of cell cycle whereas depletion of endogenous GNL3L results in ‘G2/M’ arrest. Interestingly, cell cycle analysis followed by BrdU labeling assay indicates that significantly increased DNA synthesis occurs in cells expressing nuclear export defective mutant (GNL3L^∆NES) compared to the wild type or nuclear import defective GNL3L. Furthermore, increased hyperphosphorylation of Rb at Serine 780 and the upregulation of E2F1, cyclins A2 and E1 upon ectopic expression of GNL3L^∆NES results in faster ‘S’ phase progression. Collectively, the present study provides evidence that GNL3L is exported from the nucleus in CRM1 dependent manner and the nuclear localization of GNL3L is important to promote ‘S’ phase progression during cell proliferation.     

GNOM-LIKE 2, Encoding an Adenosine Diphosphate-Ribosylation Factor-Guanine Nucleotide Exchange Factor Protein Homologous to GNOM and GNL1, is Essential for Pollen Germination in Arabidopsis

In flowering plants, male gametes are delivered to female gametophytes by pollen tubes. Although it is important for sexual plant reproduction, little is known about the genetic mechanism that controls pollen germination and pollen tube growth. Here we report the identification and characterization of two novel mutants, gnom-like 2-1 ( gnl2-1 ) and gnl2-2 in Arabidopsis thaliana , in which the pollen grains failed to germinate in vitro and in vivo . GNL2 encodes a protein homologous to the adenosine diphosphate-ribosylation factor-guanine nucleotide exchange factors, GNOM and GNL1 that are involved in endosomal recycling and endoplasmic reticulum-Golgi vesicular trafficking. It was prolifically expressed in pollen grains and pollen tubes. The results of the present study suggest that GNL2 plays an important role in pollen germination.     

Nucleostemin is indispensable for the maintenance and genetic stability of hematopoietic stem cells

Nucleostemin is a nucleolar protein known to play a variety of roles in cell-cycle progression, apoptosis inhibition, and DNA damage protection in embryonic stem cells and tissue stem cells. However, the role of nucleostemin in hematopoietic stem cells (HSCs) is yet to be determined. Here, we identified an indispensable role of nucleostemin in mouse HSCs. Depletion of nucleostemin using short hairpin RNA strikingly impaired the self-renewal activity of HSCs both in vitro and in vivo. Consistently, nucleostemin depletion triggered apoptosis rather than cell-cycle arrest in HSCs. Furthermore, DNA damage accumulated during cultivation upon depletion of nucleostemin. The impaired self-renewal activity of HSCs induced by nucleostemin depletion was partially rescued by p53 deficiency but not by p16^Ink4a or p19^Arf deficiency. Taken together, our study demonstrates that nucleostemin protects HSCs from DNA damage accumulation and is required for the maintenance of HSCs.     

Nucleostemin: Another nucleolar “Twister” of the p53-MDM2 loop

Several nucleolar proteins, such as ARF, ribosomal protein (RP) L5, L11, L23 and S7, have been shown to induce p53 activation by inhibiting MDM2 E3 ligase activity and consequently to trigger cell cycle arrest and/or apoptosis. Our recent study revealed another nucleolar protein called nucleostemin (NS), a nucleolar GTP binding protein, as a novel regulator of the p53-MDM2 feedback loop. However, unlike other known nucleolar regulators of this loop, NS surprisingly plays a dual role, as both up and downregulations of its levels could turn on p53 activity. Here, we try to offer some prospective views for this unusual phenomenon by reconciling previously and recently published studies in the field in hoping to better depict the role of NS in linking the p53 pathway with ribosomal biogenesis during cell growth and proliferation as well as to propose NS as another potential molecular target for anti-cancer drug development.Key words: ribosomal biogenesis, nucleolar stress, nucleostemin, p53, MDM2, cell cycle, cell growth     

Nucleophosmin is a binding partner of nucleostemin in human osteosarcoma cells

Nucleostemin (NS) is expressed in the nucleoli of adult and embryonic stem cells and in many tumors and tumor-derived cell lines. In coimmunoprecipitation experiments, nucleostemin is recovered with the tumor suppressor p53, and more recently we have demonstrated that nucleostemin exerts its role in cell cycle progression via a p53-dependent pathway. Here, we report that in human osteosarcoma cells, nucleostemin interacts with nucleophosmin, a nucleolar protein believed to possess oncogenic potential. Nucleostemin (NS) and nucleophosmin (NPM) displayed an extremely high degree of colocalization in the granular component of the nucleolus during interphase, and both proteins associated with prenucleolar bodies in late mitosis before the reformation of nucleoli. Coimmunoprecipitation experiments revealed that NS and NPM co-reside in complexes, and yeast two-hybrid experiments confirmed that they are interactive proteins, revealing the NPM-interactive region to be the 46-amino acid N-terminal domain of NS. In bimolecular fluorescence complementation studies, bright nucleolar signals were observed, indicating that these two proteins directly interact in the nucleolus in vivo. These results support the notion that cell cycle regulatory proteins congress and interact in the nucleolus, adding to the emerging concept that this nuclear domain has functions beyond ribosome production.     

Critical Role of Nucleostemin in Pre-rRNA Processing

Nucleostemin is a nucleolar protein widely expressed in proliferating cells. Nucleostemin is involved in the regulation of cell proliferation, and both depletion and overexpression of nucleostemin induce cell cycle arrest through the p53 signaling pathway. Although the presence of p53-independent functions of nucleostemin has been previously suggested, the identities of these additional functions remained to be investigated. Here, we show that nucleostemin has a novel role as an integrated component of ribosome biogenesis, particularly pre-rRNA processing. Nucleostemin forms a large protein complex (>700 kDa) that co-fractionates with the pre-60 S ribosomal subunit in a sucrose gradient. This complex contains proteins related to pre-rRNA processing, such as Pes1, DDX21, and EBP2, in addition to several ribosomal proteins. We show that the nucleolar retention of DDX21 and EBP2 is dependent on the presence of nucleostemin in the nucleolus. Furthermore, the knockdown of nucleostemin delays the processing of 32 S pre-rRNA into 28 S rRNA. This is accompanied by a substantial decrease of protein synthesis as well as the levels of rRNAs and some mRNAs. In addition, overexpressed nucleostemin significantly promotes the processing of 32 S pre-rRNA. Collectively, these biochemical and functional studies demonstrate a novel role of nucleostemin in ribosome biogenesis. This is a key aspect of the role of nucleostemin in regulating cell proliferation.Nucleostemin (NS)² is a nucleolar protein preferentially expressed in actively proliferating cells. The structure of NS is characterized by two GTP-binding domains, which are involved in the regulation of its dynamic shuttling between the nucleolus and nucleoplasm (1). NS was originally identified as a nucleolar protein prominently expressed in rat neural stem cells and down-regulated during differentiation of these cells in vitro (2). The same authors also found that NS is widely expressed in neural precursor cells in early mouse embryos as well as in a variety of cancer cells and stem cells, including embryonic stem cells and a hematopoietic stem cell-enriched fraction. NS is generally down-regulated in the early stage of differentiation before exit from the cell cycle. In addition, knockdown of NS significantly inhibits proliferation of cortical stem cells and cancer cells. These initial observations led to suggestions that NS is involved in multipotency in stem cells as well as in the regulation of cancer and stem cell proliferation (2).Recent work, however, has demonstrated that NS is in fact widely expressed in many types of normal proliferating cells at levels similar to those in malignant cells. For instance, NS is expressed in normal kidney cells and renal carcinoma cells at comparable levels as detected in histological sections (3). The expression of NS is significantly up-regulated when normal T lymphocytes are activated by concanavalin A (3) and when bone marrow stem cells are stimulated by fibroblast growth factor 2 (4). Cells in NS-null mouse embryos fail to enter the S phase, resulting in embryonic death at the blastocyst stage (5, 6). In early Xenopus embryos NS is also expressed in the sites of active cell proliferation and local depletion of NS results in a decrease in proliferating neural progenitor cells (6). Based on these observations, it was proposed that expression of NS is more closely linked with cell proliferation than with the malignant state or differentiation status of a cell.Several studies have provided evidence that the p53 signaling pathway is involved in the G₁ arrest of the cell cycle induced by the down-regulation of NS. Physical interaction between NS and p53 was initially reported by Tsai and McKay (2). Later, it was shown that the G₁ arrest requires the presence of p53 (7). In the most recent study Dai et al. (8) showed that knockdown of NS enhances the interaction between the p53-binding protein MDM2 and the ribosomal protein L5 or L11, preventing MDM2 from inducing ubiquitylation-based p53 degradation. However, other studies have also suggested that NS may have a p53-independent role in the regulation of cell proliferation. For instance, the depletion of p53 from NS-null blastocysts did not rescue them from the embryonic lethality (6). In addition, NS partial loss-of-function in mouse fibroblasts did not result in any change in the p53 level (5). Furthermore, knockdown of L5 and L11 only partially rescued the G₁ arrest in NS knockdown cells (8). Finally, the fact that NS is primarily localized in the nucleolus, whereas the p53-mediated mechanism occurs in the nucleoplasm, suggests that NS might have an additional role more directly relevant to nucleolar functions.To identify novel functions of NS, we purified an endogenous NS complex from HeLa cell extract and investigated whether NS interacts with other proteins not described previously. Identification of the components of this complex and the alterations of the expression level of NS in HeLa cells led us to uncover a novel role of NS in the processing of rRNA. Our findings not only provide supporting evidence for the hypothesis that NS has a p53-independent function but also demonstrate that NS is critical for ribosome biogenesis, one of the most fundamental processes common for all cell types.     

A multistep, GTP-driven mechanism controlling the dynamic cycling of nucleostemin

Nucleostemin (NS) was identified as a stem cell- and cancer cell-enriched nucleolar protein that controls the proliferation of these cells. Here, we report the mechanism that regulates its dynamic shuttling between the nucleolus and nucleoplasm. The nucleolar residence of nucleostemin involves a transient and a long-term binding by the basic and GTP-binding domains, and a dissociation mechanism mediated by the COOH-terminal region. This cycle is propelled by the GTP binding state of nucleostemin. We propose that a rapid nucleostemin cycle is designed to translate extra- and intra-cellular signals into the amount of nucleostemin in the nucleolus in a bidirectional and fast manner.     

骨髓间充质干细胞和部分肿瘤细胞中Nucleostemin基因的表达

以分离的人胚胎和大鼠骨髓间充质干细胞 (MSCs) ,6种肿瘤细胞株 ,裸鼠肿瘤和转移瘤组织为实验材料 ,以大鼠心肌组织和人胎盘组织为对照 ,探讨nucleostemin基因的表达情况 .RT PCR结果显示 ,nucleostemin基因在MSCs、肿瘤细胞和肿瘤组织中均有不同程度的表达 ,而大鼠心肌和人胎盘组织中无表达 .DNA测序结果证明 ,扩增的PCR产物与GenBank提供的DNA序列完全同源 .SCID裸鼠肿瘤动物模型定量PCR结果证实 ,nucleostemin的mRNA在裸鼠肿瘤组织和转移瘤组织中表达较高 .研究结果表明 ,在细胞中nucleostemin基因不同水平的表达可能与MSCs、肿瘤细胞的增殖和肿瘤的发生、发展与转移有关 .     

Nucleostemin

Several nucleolar proteins, such as ARF, ribosomal protein (RP) L5, L11, L23 and S7, have been shown to induce p53 activation by inhibiting MDM2 E3 ligase activity and consequently to trigger cell cycle arrest and/or apoptosis. Our recent study revealed another nucleolar protein called nucleostemin (NS), a nucleolar GTP binding protein, as a novel regulator of the p53-MDM2 feedback loop. However, unlike other known nucleolar regulators of this loop, NS surprisingly plays a dual role, as both up and down regulations of its levels could turn on p53 activity. Here, we try to offer some prospective views for this unusual phenomenon by reconciling previously and recently published studies in the field in hoping to better depict the role of NS in linking the p53 pathway with ribosomal biogenesis during cell growth and proliferation as well as to propose NS as another potential molecular target for anti-cancer drug development.