Issei Mabuchi

Three-dimensional arrangement of F-actin in the contractile ring of fission yeast

The contractile ring, which is required for cytokinesis in animal and yeast cells, consists mainly of actin filaments. Here, we investigate the directionality of the filaments in fission yeast using myosin S1 decoration and electron microscopy. The contractile ring is composed of around 1,000 to 2,000 filaments each around 0.6 μm in length. During the early stages of cytokinesis, the ring consists of two semicircular populations of parallel filaments of opposite directionality. At later stages, before contraction, the ring filaments show mixed directionality. We consider that the ring is initially assembled from a single site in the division plane and that filaments subsequently rearrange before contraction initiates.

Myosin-II reorganization during mitosis is controlled temporally by its dephosphorylation and spatially by Mid1 in fission yeast

Cytokinesis in many eukaryotes requires an actomyosin contractile ring. Here, we show that in fission yeast the myosin-II heavy chain Myo2 initially accumulates at the division site via its COOH-terminal 134 amino acids independently of F-actin. The COOH-terminal region can access to the division site at early G2, whereas intact Myo2 does so at early mitosis. Ser1444 in the Myo2 COOH-terminal region is a phosphorylation site that is dephosphorylated during early mitosis. Myo2 S1444A prematurely accumulates at the future division site and promotes formation of an F-actin ring even during interphase. The accumulation of Myo2 requires the anillin homologue Mid1 that functions in proper ring placement. Myo2 interacts with Mid1 in cell lysates, and this interaction is inhibited by an S1444D mutation in Myo2. Our results suggest that dephosphorylation of Myo2 liberates the COOH-terminal region from an intramolecular inhibition. Subsequently, dephosphorylated Myo2 is anchored by Mid1 at the medial cortex and promotes the ring assembly in cooperation with F-actin.

The small GTPase Rho3 and the diaphanous/formin For3 function in polarized cell growth in fission yeast

We identified a novel Rho gene rho3+ and studied its interaction with diaphanous/formin for3+ in the fission yeast Schizosaccharomyces pombe. Both rho3 null cells and for3 null cells showed defects in organization of not only actin cytoskeleton but also cytoplasmic microtubules (MTs). rho3 for3 double null cells had defects that were more severe than each single null cell: polarized growth was deficient in the double null cells. Function of For3 needed the highly conserved FH1 and FH2 domains, an N-terminal region containing a Rho-binding domain, and the C-terminal region. For3 bound to active forms of both Rho3 and Cdc42 but not to that of Rho1. For3 was localized as dots to the ends of interphase cells and to the mid-region in dividing cells. This localization was probably dependent on its interaction with Rho proteins. Overexpression of For3 produced huge swollen cells containing depolarized F-actin patches and thick cytoplasmic MT bundles. In addition, overexpression of a constitutively active Rho3Q71L induced a strong defect in cytokinesis. In conclusion, we propose that the Rho3-For3 signaling system functions in the polarized cell growth of fission yeast by controlling both actin cytoskeleton and MTs.

Identification of Myo3, a second type-II myosin heavy chain in the fission yeast Schizosaccharomyces pombe

We cloned the myo3 + gene of Schizosaccharomyces pombe which encodes a type‐II myosin heavy chain. myo3 null cells showed a defect in cytokinesis under certain conditions. Overproduction of Myo3 also showed a defect in cytokinesis. Double mutant analysis indicated that Myo3 genetically interacts with Cdc8 tropomyosin and actin. Myo3 may be implicated in cytokinesis and stabilization of F‐actin cables. Moreover, the function of Myo2 can be replaced by overexpressed Myo3. We observed a modest synthetic interaction between Myo2 and Myo3. Thus, Myo2 and Myo3 seem to cooperate in the formation of the F‐actin ring in S. pombe.

The small GTP-binding protein Rho1 is a multifunctional protein that regulates actin localization, cell polarity, and septum formation in the fission yeast Schizosaccharomyces pombe.

The small GTP‐binding protein Rho has been shown to regulate the formation of the actin cytoskeleton in animal cells. We have previously isolated two rho genes, rho1+ and rho2+ , from the fission yeast Schizosaccharomyces pombe in order to investigate the function of Rho using genetic techniques. In this paper, we report the cellular function of Rho1.

Subcellular localization and possible function of actin, tropomyosin and actin-related protein 3 (Arp3) in the fission yeast Schizosaccharomyces pombe

We investigated subcellular localizations and interactions of actin and two actin cytoskeleton-related proteins, Cdc8 tropomyosin and actin-related protein 3, Arp3, in the fission yeast Schizosaccharomyces pombe, using specific antibodies and by gene disruption. Actin was localized to the medial microfilamentous ring in the region of the septum during cytokinesis and to cortical patches by immunoelectron microscopy. F-actin cables were detected throughout the cell cycle by fluorescent staining with Bodipy-phallacidin. Cables were often linked to the patches and to the medial ring during its formation. Tropomyosin was localized to the medial ring and the cables. It was also distributed in the cell as patches, although co-localization with F-actin was not frequent. In cdc8ts mutant cells, F-actin cables were not observed although the F-actin patches were detected and cell polarity was maintained. These observations suggest that the F-actin cables may be involved in the formation of the medial ring, and that tropomyosin plays an important role in organizing both the ring and the cable, but is not involved in the F-actin patch formation or maintenance of cell polarity. Binding of Arp3 to actin was revealed by immunoprecipitation as well as by DNase I column chromatography. Arp3 seemed to form a complex with several proteins in the cell extracts, as previously reported for other organisms. Contrary to a previous report (McCollum et al., EMBO J. 15, 6438-6446, 1996), Arp3 was found to be concentrated in the medial region from early anaphase to late cytokinesis. Following arp3 gene disruption, F-actin patches were delocalized throughout the cell and cells did not undergo polarized growth, suggesting that Arp3 influences the proper localization of the actin patches in the cell and thereby controls the polarized growth of the cell.

INDUCTION OF CHROMOSOME MOTION IN THE GLYCEROL‐ISOLATED MITOTIC APPARATUS: NUCLEOTIDE SPECIFICITY AND EFFECTS OF ANTIDYNEIN AND MYOSIN SERA ON THE MOTION*

Chromosome motion in glycerol‐isolated mitotic apparatus (MA) of sea urchin and starfish eggs was investigated with respect to nucleotide specificity and the effects of antisera against tryptic fragment (Fragment A) of flagellar dynein and starfish egg myosin. The motion was highly specific for ATP. GTP, ITP, CTP, UTP, and ADP caused no displacement of the chromosomes towards the poles. The anti‐Fragment A serum completely inhibited chromosome motion in the MA of the sea urchin egg, while antiserum against starfish egg myosin as well as its γ‐globulin fraction did not inhibit the motion in the isolated MA of the starfish egg, suggesting that chromosome motion depends upon dynein‐microtubule but not upon myosin‐actin interaction. In addition, colchicine completely suppressed the chromosome motion in vitro.

Determinants of Myosin II Cortical Localization during Cytokinesis

Myosin II is an essential component of the contractile ring that divides the cell during cytokinesis. Previous work showed that regulatory light chain (RLC) phosphorylation is required for localization of myosin at the cellular equator. However, the molecular mechanisms that concentrate myosin at the site of furrow formation remain unclear. By analyzing the spatiotemporal dynamics of mutant myosin subunits in Drosophila S2 cells, we show that myosin accumulates at the equator through stabilization of interactions between the cortex and myosin filaments and that the motor domain is dispensable for localization. Filament stabilization is tightly controlled by RLC phosphorylation. However, we show that regulatory mechanisms other than RLC phosphorylation contribute to myosin accumulation at three different stages: (1) turnover of thick filaments throughout the cell cycle, (2) myosin heavy chain-based control of myosin assembly at the metaphase-anaphase transition, and (3) redistribution and/or activation of myosin binding sites at the equator during anaphase. Surprisingly, the third event can occur to a degree in a Rho-independent fashion, gathering preassembled filaments to the equatorial zone via cortical flow. We conclude that multiple regulatory pathways cooperate to control myosin localization during mitosis and cytokinesis to ensure that this essential biological process is as robust as possible.

Effects of inhibitors of myosin light chain kinase and other protein kinases on the first cell division of sea urchin eggs

We investigated effects of protein kinase inhibitors on the first cell division in sea urchin eggs on the assumption that phosphorylation of myosin is requisite for the formation and/or the contraction of the contractile ring. ML‐7 or ML‐9, which inhibits myosin light chain kinase (MLCK), inhibited cytokinesis with a half maximal inhibition at 0.1–0.2 mM. The nuclear division was accomplished normally at 0.2–0.25 mM where the cytokinesis was completely blocked. Fluorescent staining of actin filaments with rhodamine‐labeled phalloidin revealed that the contractile ring was not formed in the cleavage‐inhibited eggs. H‐7 which inhibits cAMP‐dependent protein kinase, cGMP‐dependent protein kinase and protein kinase C arrested the process of the division at mid‐cleavage at 0.25–0.3 mM and at metaphase or anaphase at 0.5 mM. H‐8 and HA1004, which inhibit cAMP‐dependent and cGMP‐dependent protein kinases did not show significant effect at millimolar order. In the presence of micromolar concentrations of staurosporine which preferentially inhibits protein kinase C and MLCK small mitotic apparatuses were formed, in which chromosomes did not form the metaphase plate. The role of phosphorylation in the cell division is discussed.

LOCALIZATION OF DYNEIN IN SEA URCHIN EGGS DURING CLEAVAGE

Detection and localization of dynein in cleaving sea urchin eggs were attempted using antidynein serum (prepared against a tryptic fragment of dynein, Fragment A, of sea urchin sperm flagella) and fluorescein conjugated goat antiserum to rabbit γ‐globulin. In both unfertilized and newly fertilized eggs, fluorescence was distributed rather uniformly within the cells but was absent from the nuclei. At prophase, intense fluorescence was observed on both sides of nucleus, suggesting accumulation of dynein in developing asters. From metaphase to anaphase, the whole mitotic apparatus (MA) was stained with the exceptions of the chromosomes and pole areas. Fluorescence then again became dispersed within the eggs. Throughout the mitotic process and cytokinesis, the egg cortex including the cleavage furrow was stained intensely, presumably reflecting the presence of dynein in this region. Similar distributions of fluorescence were obtained with the isolated MAs. Neither non‐immune serum nor the antiserum to which Fragment A was absorbed stained the eggs. Little staining was obtained with the antiserum against starfish egg myosin. The results, together with the finding that the chromosome motion in the isolated MAs was completely inhibited by anti‐dynein serum, but not with the anti‐myosin serum, suggest an active role played by a tubulin‐dynein system in mitosis.