Noriko Yasuhara

Synergistic anti-apoptotic activity between Bcl-2 and SMN implicated in spinal muscular atrophy

Spinal muscular atrophy (SMA) is a motor neuron disease characterized by degeneration of the anterior horn cells of the spinal cord. It is a common fatal autosomal recessive disorder and linkage studies have identified two candidate genes, SMN (ref. 1) and NAIP (ref. 2), both on chromosome 5q13. Although NAIP protein is known to have an anti-apoptotic function, the function of SMN has been unclear and it shows no significant sequence similarity to any other protein. The SMN gene is deleted or interrupted on both chromosomes in nearly all SMA patients. Here we show that SMN interacts with Bcl-2, another anti-apoptotic protein, and that co-expression of SMN with Bcl-2 confers a synergistic preventive effect against Bax-induced or Fas-mediated apoptosis, although SMN itself has only a weak anti-apoptotic activity. SMNY272C, which carries a missense mutation and was found in an SMA patient who exceptionally retained SMN on one allele, exerts no synergism with Bcl-2. Furthermore, the product of a truncated transcript lacking exon 7, which was derived from an SMN gene carrying an intragenic mutation or from the SMN copy gene c BCD541 (ref. 1) retained in all SMA patients, had no synergistic activity but instead had a dominant-negative effect on full-length SMN. Our results indicate that an absent or decreased anti-apoptotic activity of SMN in concert with Bcl-2 underlies the pathogenesis of SMA.

Triggering neural differentiation of ES cells by subtype switching of importin-α

Nuclear proteins are selectively imported into the nucleus by transport factors such as importin-α and importin-β. Here, we show that the expression of importin-α subtypes is strictly regulated during neural differentiation of mouse embryonic stem (ES) cells, and that the switching of importin-α subtype expression is critical for neural differentiation. Moreover, reproducing the switching of importin-α subtype expression in undifferentiated ES cells induced neural differentiation in the presence of leukaemia inhibitory factor (LIF) and serum, coordinated with the regulated expression of Oct3/4, Brn2 and SOX2, which are involved in ES–neural identity determination. These transcription factors were selectively imported into the nucleus by specific subtypes of importin-α. Thus, importin-α subtype switching has a major impact on cell differentiation through the regulated nuclear import of a specific set of transcription factors. This is the first study to propose that transport factors should be considered as major players in cell-fate determination.

Bis, a Bcl-2-binding protein that synergizes with Bcl-2 in preventing cell death

Bcl-2 is the best characterized inhibitor of apoptosis, although the molecular basis of this action is not fully understood. Using a protein interaction cloning procedure, we identified a human gene designated as bis (mapped to chromosome 10q25) that encoded a novel Bcl-2-interacting protein. Bis protein showed no significant homology with Bcl-2 family proteins and had no prominent functional motif. Co-immunoprecipitation analysis confirmed that Bis interacted with Bcl-2 in vivo. DNA transfection experiments indicated that Bis itself exerted only weak anti-apoptotic activity, but was synergistic with Bcl-2 in preventing Bax-induced and Fas-mediated apoptosis. These results suggest that Bis is a novel modulator of cellular anti-apoptotic activity that functions through its interaction with Bcl-2.

Essential role of active nuclear transport in apoptosis

Background : Apoptosis is defined by chromatin condensation, nuclear fragmentation and the formation of apoptotic bodies. Because apoptotic signals are transmitted through a common pathway that includes the target steps of death‐driving ICE‐family proteases and anti‐cell death protein Bcl‐2 in the cytoplasm, the signals must be transferred from the cytoplasm to the nucleus, at least to induce the apoptotic manifestation of the nucleus. Small signal molecules might diffuse across nuclear pores, but larger molecules are transported by active mechanisms requiring ATP and GTP hydrolysis. It is not known whether apoptotic signals are transmitted into the nucleus by the mechanisms of active nuclear transport.

Programmed cell death triggered by insect steroid hormone, 20-hydroxyecdysone, in the anterior silk gland of the silkworm, Bombyx mori

Abstract Silk gland is a larval specific tissue of lepidopteran insects and begins to degenerate shortly before pupation. Programmed cell death (PCD) of the anterior silk gland of Bombyx mori last instar larvae was studied in vivo and in vitro, focusing on the effects of 20- hydroxyecdysone (20E). The glands began to exhibit signs of PCD in vivo 2 days after gut purge and comp-leted PCD by 48 h. In vitro, 20E prematurely induced PCD, and its completion took 144 h (6 days). An oligo-nucleosomal ladder pattern was observed in DNA extracted at the end of PCD. Caspase 3 inhibitor inhibited attainment of full PCD, but it did not block chromatin condensation as revealed by acridine orange staining. α-Amanitin inhibited the PCD induced by 20E in vitro if added to the culture in the first 8 h. Similarly, cycloheximide and emetine completely blocked PCD when applied in the first 18 h of culture with 20E. These results indicate that 20E-stimulated transcription and protein synthesis for PCD are completed in 8 h and 18 h, respectively. Nevertheless, withdrawal of 20E from the medium at different times showed that 20E must be present in vitro for 42 h to elicit full PCD. Current results indicate that the effects of 20E on the progression of PCD are mediated by two distinct processes – one through nuclear hormone receptors, and the other independent from de novo gene expression.

A functional role for death proteases in s-Myc- and c-Myc-mediated apoptosis.

Upon activation, cell surface death receptors, Fas/APO-1/CD95 and tumor necrosis factor receptor-1 (TNFR-1), are attached to cytosolic adaptor proteins, which in turn recruit caspase-8 (MACH/FLICE/Mch5) to activate the interleukin-1 beta-converting enzyme (ICE)/CED-3 family protease (caspase) cascade. However, it remains unknown whether these apoptotic proteases are generally involved in apoptosis triggered by other stimuli such as Myc and p53. In this study, we provide lines of evidence that a death protease cascade consisting of caspases and serine proteases plays an essential role in Myc-mediated apoptosis. When Rat-1 fibroblasts stably expressing either s-Myc or c-Myc were induced to undergo apoptosis by serum deprivation, a caspase-3 (CPP32)-like protease activity that cleaves a specific peptide substrate, Ac-DEVD-MCA, appeared in the cell lysates. Induction of s-Myc- and c-Myc-mediated apoptotic cell death was effectively prevented by caspase inhibitors such as Z-Asp-CH2-DCB and Ac-DEVD-CHO. Furthermore, exposing the cells to a serine protease inhibitor, 4-(2-aminoethyl)benzenesulfonyl fluoride (AEBSF), also significantly inhibited s-Myc- and c-Myc-mediated apoptosis and the appearance of the caspase-3-like protease activity in vivo. However, AEBSF did not directly inhibit caspase-3-like protease activity in the apoptotic cell lysates in vitro. Together, these results indicate that caspase-3-like proteases play a critical role in both s-Myc- and c-Myc-mediated apoptosis and that caspase-3-like proteases function downstream of the AEBSF-sensitive step in the signaling pathway of Myc-mediated apoptosis.

The role of the nuclear transport system in cell differentiation

The eukaryotic cell nuclear transport system selectively mediates molecular trafficking to facilitate the regulation of cellular processes. The components of this system include diverse transport factors such as importins and nuclear pore components that are precisely organized to coordinate cellular events. A number of studies have demonstrated that the nuclear transport system is indispensible in many types of cellular responses. In particular, the nuclear transport machinery has been shown to be an important regulator of development, organogenesis, and tissue formation, wherein altered nuclear transport of key transcription factors can lead to disease. Importantly, precise switching between distinct forms of importin alpha is central to neural lineage specification, consistent with the hypothesis that importin expression can be a key mediator of cell differentiation.

MOLECULAR BASIS FOR THE RECOGNITION OF PHOSPHORYLATED STAT1 BY IMPORTIN α5

Interferon-gamma stimulation triggers tyrosine phosphorylation of the transcription factor STAT1 at position 701, which is associated with switching from carrier-independent nucleocytoplasmic shuttling to carrier-mediated nuclear import. Unlike most substrates that carry a classical nuclear localization signal (NLS) and bind to importin alpha1, STAT1 possesses a nonclassical NLS recognized by the isoform importin alpha5. In the present study, we have analyzed the mechanisms by which importin alpha5 binds phosphorylated STAT1 (pSTAT1). We found that a homodimer of pSTAT1 is recognized by one equivalent of importin alpha5 with K(d)=191+/-20 nM. Whereas tyrosine phosphorylation at position 701 is essential to assemble a pSTAT1-importin alpha5 complex, the phosphate moiety is not a direct binding determinant for importin alpha5. In contrast to classical NLS substrates, pSTAT1 binding to importin alpha5 is not displaced by the N-terminal importin beta binding domain and requires the importin alpha5 C-terminal acidic tail (505-EEDD-508). A local unfolding of importin alpha5 Armadillo (ARM) repeat 10 accompanies high-affinity binding to pSTAT1. This unfolding is mediated by a single conserved tyrosine at position 476 of importin alpha5, which is inserted between ARM repeat 10 helices H1-H2-H3, thereby preventing intramolecular helical stacking essential to stabilize the folding conformation of ARM 10. Introducing a glycine at this position, as in importin alpha1, disrupts high-affinity binding to pSTAT1, suggesting that pSTAT1 recognition is dependent on the intrinsic flexibility of ARM 10. Using the quantitative stoichiometry and binding data presented in this article, together with mutational information available in the literature, we propose that importin alpha5 binds between two STAT1 monomers, with two major binding determinants in the SH2 and DNA binding domains. In vitro, this model is supported by the observation that a 38-mer DNA oligonucleotide containing two tandem cfosM67 promoters can displace importin alpha5 from pSTAT1, suggesting a possible role for DNA in releasing activated STAT1 in the cell nucleus.

Importin Alpha Subtypes Determine Differential Transcription Factor Localization in Embryonic Stem Cells Maintenance

We recently demonstrated that the expression of the importin α subtype is switched from α2 to α1 during neural differentiation in mouse embryonic stem cells (ESCs) and that this switching has a major impact on cell differentiation. In this study, we report a cell-fate determination mechanism in which importin α2 negatively regulates the nuclear import of certain transcription factors to maintain ESC properties. The nuclear import of Oct6 and Brn2 was inhibited via the formation of a transport-incompetent complex of the cargo bound to a nuclear localization signal binding site in importin α2. Unless this dominant-negative effect was downregulated upon ESC differentiation, inappropriate cell death was induced. We propose that although certain transcription factors are necessary for differentiation in ESCs, these factors are retained in the cytoplasm by importin α2, thereby preventing transcription factor activity in the nucleus until the cells undergo differentiation.

Transcriptional program of Kpna2/Importin-α2 regulates cellular differentiation-coupled circadian clock development in mammalian cells

Significance The emergence of the cell-autonomous circadian oscillator is coupled with cellular differentiation. Cellular differentiation, as well as reprogramming, results in global alterations of the transcriptional program via epigenetic modification such as DNA methylation. We here demonstrate that c-Myc constitutive expression and Dnmt1 ablation disrupt the differentiation-coupled emergence of the clock from mouse ES cells (ESCs). Using these model ESCs, 484 genes were identified by global gene expression analysis as factors correlated with circadian clock development. Among them, we find that misregulation of Kpna2 (Importin-α2) during the differentiation culture of ESCs significantly impairs clock development, and KPNA2 facilitates cytoplasmic localization of PER1/2. These results suggest that the programmed gene expression network regulates the differentiation-coupled circadian clock development in mammalian cells. The circadian clock in mammalian cells is cell-autonomously generated during the cellular differentiation process, but the underlying mechanisms are not understood. Here we show that perturbation of the transcriptional program by constitutive expression of transcription factor c-Myc and DNA methyltransferase 1 (Dnmt1) ablation disrupts the differentiation-coupled emergence of the clock from mouse ESCs. Using these model ESCs, 484 genes are identified by global gene expression analysis as factors correlated with differentiation-coupled circadian clock development. Among them, we find the misregulation of Kpna2 (Importin-α2) during the differentiation of the c-Myc-overexpressed and Dnmt1−/− ESCs, in which sustained cytoplasmic accumulation of PER proteins is observed. Moreover, constitutive expression of Kpna2 during the differentiation culture of ESCs significantly impairs clock development, and KPNA2 facilitates cytoplasmic localization of PER1/2. These results suggest that the programmed gene expression network regulates the differentiation-coupled circadian clock development in mammalian cells, at least in part via posttranscriptional regulation of clock proteins.