Two distinct repeat sequences of Nup98 nucleoporins characterize dual nuclei in the binucleated ciliate tetrahymena.

Ciliated protozoa have two functionally distinct nuclei, a micronucleus (MIC) and a macronucleus (MAC) [1]. These two nuclei are distinct in size, transcriptional activity, and division cycle control, proceeding with cycles of DNA replication and nuclear division at different times within the same cell [2, 3]. The structural basis generating functionally distinct nuclei remains unknown. Here, we show that, in Tetrahymena thermophila, the nuclear pore complexes (NPCs) of MIC and MAC are composed of different sets of nucleoporins. Among the 13 nucleoporins identified, Nup98 homologs were of interest because two out of the four homologs were localized exclusively in the MAC and the other two were localized exclusively in the MIC. The two MAC-localizing Nup98s contain repeats of GLFG [4]. In contrast, the two MIC-localizing Nup98s lack the GLFG repeats and instead contain a novel repeat signature of NIFN. Ectopic expression of a chimeric MIC-localizing Nup98 homolog bearing GLFG repeats obstructed the nuclear accumulation of MIC-specific nuclear proteins, and expression of a chimeric MAC-localizing Nup98 homolog bearing NIFN repeats obstructed the nuclear accumulation of MAC-specific nuclear proteins. These results suggest that Nup98s act as a barrier to misdirected localization of nucleus-specific proteins. Our findings provide the first evidence that the NPC contributes to nucleus-selective transport in ciliates.

Roles of three domains of Tetrahymena eEF1A in bundling F-actin.

The conventional role of eukaryotic elongation factor 1A (eEF1A) is to transport aminoacyl tRNA to the A site of ribosomes during the peptide elongation phase of protein synthesis. eEF1A also is involved in regulating the dynamics of microtubules and actin filaments in cytoplasm. In Tetrahymena, eEF1A forms homodimers and bundles F-actin. Ca(2+)/calmodulin (CaM) causes reversion of the eEF1A dimer to the monomer, which loosens F-actin bundling, and then Ca(2+)/CaM/eEF1A monomer complexes dissociate from F-actin. eEF1A consists of three domains in all eukaryotic species, but the individual roles of the Tetrahymena eEF1A domains in bundling F-actin are unknown. In this study, we investigated the interaction of each domain with F-actin, recombinant Tetrahymena CaM, and eEF1A itself in vitro, using three glutathione-S-transferase-domain fusion proteins (GST-dm1, -2, and -3). We found that only GST-dm3 bound to F-actin and influences dimer formation, but that all three domains bound to Tetrahymena CaM in a Ca(2+)-dependent manner. The critical Ca(2+) concentration for binding among three domains of eEF1A and CaM were < or =100 nM for domain 1, 100 nM to 1 microM for domain 3, and >1 microM for domain 2, whereas stimulation of and subsequent Ca(2+) influx through Ca(2+) channels raise the cellular Ca(2+) concentration from the basal level of approximately 100 nM to approximately 10 microM, suggesting that domain 3 has a pivotal role in Ca(2+)/CaM regulation of eEF1A.

Tetrahymena eukaryotic translation elongation factor 1A (eEF1A) bundles filamentous actin through dimer formation.

Eukaryotic translation elongation factor 1A (eEF1A) is known to be a multifunctional protein. In Tetrahymena, eEF1A is localized to the division furrow and has the character to bundle filamentous actin (F-actin). eEF1A binds F-actin and the ratio of eEF1A and actin is approximately 1:1 (Kurasawa et al., 1996). In this study, we revealed that eEF1A itself exists as monomer and dimer, using gel filtration column chromatography. Next, eEF1A monomer and eEF1A dimer were separated using gel filtration column, and their interaction with F-actin was examined with cosedimentation assay and electron microscopy. In the absence of Ca2+/calmodulin (CaM), eEF1A dimer bundled F-actin and coprecipitated with F-actin at low-speed centrifugation, but eEF1A monomer did not. In the presence of Ca2+/CaM, eEF1A monomer increased, while dimer decreased. To examine that Ca2+/CaM alters eEF1A dimer into monomer and inhibits bundle formation of F-actin, Ca2+/CaM was added to F-actin bundles formed by eEF1A dimer. Ca2+/CaM separated eEF1A dimer to monomer, loosened F-actin bundles and then dispersed actin filaments. Simultaneously, Ca2+/CaM/ eEF1A monomer complexes were dissociated from actin filaments. Therefore, Ca2+/CaM reversibly regulates the F-actin bundling activity of eEF1A.

Stg 1 is a novel SM22/transgelin-like actin-modulating protein in fission yeast.

We identified a novel actin-modulating protein Stg 1 in the fission yeast Schizosaccharomyces pombe. Stg 1 is similar to mammalian SM22/transgelin, and biochemical experiments showed that Stg 1 crosslinked F-actin. Microscopic observation suggested that Stg 1 was a component of actin patch. Overexpression of Stg 1 caused a defect in cytokinesis by suppressing the formation of a contractile ring and formation of abnormal aggregates of F-actin in the ends and mid-region of cells. Although distribution of the actin cytoskeleton was not affected by disrupting Stg 1(+), genetic interaction suggested that Stg 1 was likely involved in controlling the organization of the actin cytoskeleton in cell morphogenesis and cytokinesis in fission yeast.