Mutations in sticky lead to defective organization of the contractile ring during cytokinesis and are enhanced by Rho and suppressed by Rac

The contractile ring is a highly dynamic structure, but how this dynamism is accomplished remains unclear. Here, we report the identification and analysis of a novel Drosophila gene, sticky (sti), essential for cytokinesis in all fly proliferating tissues. sti encodes the Drosophila orthologue of the mammalian Citron kinase. RNA interference-mediated silencing of sti in cultured cells causes them to become multinucleate. Components of the contractile ring and central spindle are recruited normally in such STICKY-depleted cells that nevertheless display asymmetric furrowing and aberrant blebbing. Together with an unusual distribution of F-actin and Anillin, these phenotypes are consistent with defective organization of the contractile ring. sti shows opposite genetic interactions with Rho and Rac genes suggesting that these GTPases antagonistically regulate STICKY functions. Similar genetic evidence indicates that RacGAP50C inhibits Rac during cytokinesis. We discuss that antagonism between Rho and Rac pathways may control contractile ring dynamics during cytokinesis.     

Cytokinesis and the contractile ring in fission yeast

The fission yeast Schizosaccharomyces pombe provides a genetic model system for the study of cytokinesis. As in many eukaryotes, cell division in the fission yeast requires an actin-myosin-based contractile ring. Numerous components of the contractile ring that function in ring assembly, positioning and contraction have been characterized. Many of these proteins are evolutionarily conserved, suggesting that common molecular mechanisms may govern aspects of eukaryotic cell division. Recent advances in the assembly and placement of the contractile ring are discussed. In particular, major findings have been made in the characterization of myosins in cytokinesis, and in how the cell division site may be positioned by the nucleus.     

Fission yeast IQGAP arranges actin filaments into the cytokinetic contractile ring

The contractile ring (CR) consists of bundled actin filaments and myosin II; however, the actin‐bundling factor remains elusive. We show that the fission yeast Schizosaccharomyces pombe IQGAP Rng2 is involved in the generation of CR F‐actin and required for its arrangement into a ring. An N‐terminal fragment of Rng2 is necessary for the function of Rng2 and is localized to CR F‐actin. In vitro the fragment promotes actin polymerization and forms linear arrays of F‐actin, which are resistant to the depolymerization induced by the actin‐depolymerizing factor Adf1. Our findings indicate that Rng2 is involved in the generation of CR F‐actin and simultaneously bundles the filaments and regulates its dynamics by counteracting the effects of Adf1, thus enabling the reconstruction of CR F‐actin bundles, which provides an insight into the physical properties of the building blocks that comprise the CR.     

Septins: traffic control at the cytokinesis intersection

The physical division of one cell into two requires the highly orchestrated separation of genetic and cytoplasmic contents during M phase of the cell cycle. Mitosis, the physical segregation of the genetic material of a cell into two daughter cells, has traditionally received more attention than cytokinesis, the partitioning of the cytoplasmic contents, yet clearly the two processes must be intimately co-ordinated and tightly regulated. While plant cells divide by the formation of a membranous cell barrier called the phragmoplast, animal cell division is largely driven by contraction of an actomyosin ring. However, recent evidence has suggested that membranes derived from one or more intracellular compartments are also required to break the cytoplasmic bridge connecting two dividing cells during late telophase. In this review, we focus on studies of animal cell cytokinesis that support a requirement for specific endomembrane fusion during fission, define molecular components of the membrane fusion apparatus that may be involved and point to possible roles for an emerging family of cytoskeletal proteins, the septins, in this process.     

Plastin and spectrin cooperate to stabilize the actomyosin cortex during cytokinesis

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裂殖酵母Cnb1参与胞质分裂过程

丝/苏氨酸特异性钙调磷酸酶(Calcineurin, CN)是一种在真核生物中广泛存在的蛋白, 是参与转录调控的重要分子。裂殖酵母中的CN是由催化亚基Ppb1和调节亚基Cnb1组成的异源二聚体。文章报道了裂殖酵母中cnb1+的缺失引起细胞生长速度缓慢, 产生多隔膜现象, 胞质分裂受阻滞。胞质分裂过程中, Cnb1与Ppb1组成CN复合物, 与收缩环在分裂平面上共定位, 并与收缩环一起收缩。cnb1Δ菌株的隔膜成熟过程存在缺陷, 微管出现纵穿隔膜的现象。上述结果说明Cnb1可能参与隔膜的成熟过程。此外, 还检测了cnb1D菌株中胞裂蛋白的信号。胞裂蛋白包括Spn1、Spn2、Spn3和Spn4, 它们是引导隔膜降解的重要分子。结果显示, 在cnb1D菌株中, 80%左右的细胞在隔膜处缺失Spn2和Spn3的信号, 20%左右的细胞缺失Spn1和Spn4的信号。由于胞裂蛋白的蛋白表达量在cnb1D中没有降低, 因此胞裂蛋白信号的消失不是转录缺陷引起的, 这暗示Cnb1可能采用了不依赖转录的方式来调控胞裂蛋白环的稳定性。以上结果提示, Cnb1可能通过影响隔膜的成熟及胞裂蛋白环的稳定性参与调节裂殖酵母的胞质分裂过程。     

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.     

EFC/F-BAR proteins and the N-WASP-WIP complex induce membrane curvature-dependent actin polymerization

Extended Fer-CIP4 homology (EFC)/FCH-BAR (F-BAR) domains generate and bind to tubular membrane structures of defined diameters that are involved in the formation and fission of endocytotic vesicles. Formin-binding protein 17 (FBP17) and Toca-1 contain EFC/F-BAR domains and bind to neural Wiskott-Aldrich syndrome protein (N-WASP), which links phosphatidylinositol (4,5)-bisphosphate (PIP(2)) and the Rho family GTPase Cdc42 to the Arp2/3 complex. The N-WASP-WASP-interacting protein (WIP) complex, a predominant form of N-WASP in cells, is known to be activated by Toca-1 and Cdc42. Here, we show that N-WASP-WIP complex-mediated actin polymerization is activated by phosphatidylserine-containing membranes depending on membrane curvature in the presence of Toca-1 or FBP17 and in the absence of Cdc42 and PIP(2). Cdc42 further promoted the activation of actin polymerization by N-WASP-WIP. Toca-1 or FBP17 recruited N-WASP-WIP to the membrane. Conserved acidic residues near the SH3 domain of Toca-1 and FBP17 positioned the N-WASP-WIP to be spatially close to the membrane for activation of actin polymerization. Therefore, curvature-dependent actin polymerization is stimulated by spatially appropriate interactions of EFC/F-BAR proteins and the N-WASP-WIP complex with the membrane.     

Tellurite effect on ATPase activity of contractile membrane protein.

The effect of tellurite on ATPase activity of the contractile membrane protein in human erythrocytes was studied. Tellurite, even at a concentration of 0.01 mM, inhibited 25 per cent of the saponin-stimulated ATPase activity of the contractile membrane protein; the inhibition increased with increasing tellurite concentration, and was reversible. On the other hand, in erythrocytes preincubated with tellurite, the ATPase activity of the membrane contractile protein, non-stimulated by saponin, increased, and the increase was further enhanced by washing the erythrocytes. The behaviour is analogous to the tellurite effect on erythrocyte morphology: incubation of erythrocytes with tellurite caused morphological changes which were more pronounced after removing the tellurite by washing. The complex effect of tellurite is discussed.     

Mapping of the basic amino-acid residues responsible for tubulation and cellular protrusion by the EFC/F-BAR domain of pacsin2/Syndapin II

The extended Fes-CIP4 homology (EFC)/FCH-BAR (F-BAR) domain tubulates membranes. Overexpression of the pacsin2 EFC/F-BAR domain resulted in tubular localization inside cells and deformed liposomes into tubules in vitro. We found that overexpression of the pacsin2 EFC/F-BAR domain induced cellular microspikes, with the pacsin2 EFC/F-BAR domain concentrated at the neck. The hydrophobic loops and the basic amino-acid residues on the concave surface of the pacsin2 EFC/F-BAR domain are essential for both the microspike formation and tubulation. Since the curvature of the neck of the microspike and that of the tubulation share similar geometry, the pacsin2 EFC/F-BAR domain is considered to facilitate both microspike formation and tubulation.

Structured summary

MINT-7710892: EFCS pacsin2 (uniprotkb:Q9UNF0) and EFCS pacsin2 (uniprotkb:Q9UNF0) bind (MI:0407) by X-ray crystallography (MI:0114)     

Plasmodium induced by SU6656, an Src family kinase inhibitor,is accompanied by a contractile ring defect

We have shown that SU6656, a potent Src family kinase inhibitor, has the ability to induce multinucleation at a high frequency in diverse cells: rat skin fibroblasts, bone marrow adherent cells, 5F9A mesenchymal stem cell‐like clones, 2C5 tracheal epithelial cells and MDCK epithelial cells from dog kidney. To gain insight into the mechanism of multinucleation, we observed the process by time‐lapse and confocal microscopy. These multinuclei generally seem to exist independently in one cell without any connections with each other. By time‐lapse microscopy, multinucleated cells were found to be formed through the mechanism of plasmodium: karyokinesis without cytokinesis. The observation of EGFP‐actin transfected cells by time‐lapse confocal laser scanning microscopy suggested that plasmodium occurred with deficient contractile ring formation. Although we examined the differentiation of these cells, the multinucleated cells could not be categorized into any type of cell in vivo known to exhibit multinuclei. Copyright © 2011 John Wiley & Sons, Ltd.     

Mid2p stabilizes septin rings during cytokinesis in fission yeast

Septins are filament-forming proteins with a conserved role in cytokinesis. In the fission yeast Schizosaccharomyces pombe, septin rings appear to be involved primarily in cell-cell separation, a late stage in cytokinesis. Here, we identified a protein Mid2p on the basis of its sequence similarity to S. pombe Mid1p, Saccharomyces cerevisiae Bud4p, and Candida albicans Int1p. Like septin mutants, mid2delta mutants had delays in cell-cell separation. mid2delta mutants were defective in septin organization but not contractile ring closure or septum formation. In wild-type cells, septins assembled first during mitosis in a single ring and during septation developed into double rings that did not contract. In mid2delta cells, septins initially assembled in a single ring but during septation appeared in the cleavage furrow, forming a washer or disc structure. FRAP studies showed that septins are stable in wild-type cells but exchange 30-fold more rapidly in mid2delta cells. Mid2p colocalized with septins and required septins for its localization. A COOH-terminal pleckstrin homology domain of Mid2p was required for its localization and function. No genetic interactions were found between mid2 and the related gene mid1. Thus, these studies identify a new factor responsible for the proper stability and function of septins during cytokinesis.     

Cell polarization and cytokinesis in budding yeast

Asymmetric cell division, which includes cell polarization and cytokinesis, is essential for generating cell diversity during development. The budding yeast Saccharomyces cerevisiae reproduces by asymmetric cell division, and has thus served as an attractive model for unraveling the general principles of eukaryotic cell polarization and cytokinesis. Polarity development requires G-protein signaling, cytoskeletal polarization, and exocytosis, whereas cytokinesis requires concerted actions of a contractile actomyosin ring and targeted membrane deposition. In this chapter, we discuss the mechanics and spatial control of polarity development and cytokinesis, emphasizing the key concepts, mechanisms, and emerging questions in the field.     

The IQGAP Iqg1 is a regulatory target of CDK for cytokinesis in Candida albicans

Cyclin-dependent kinases (CDKs) drive and coordinate multiple cell-cycle events, including construction and contraction of the actomyosin ring during cytokinesis. However, it remains unclear whether CDKs regulate cytokinesis by directly targeting components of the ring. In a search for proteins containing consensus CDK phosphorylation sites in Candida albicans, we found that the IQGAP Iqg1 contains two dense clusters of 19 such sites flanking the actin-interacting CH domain. Here, we show that Iqg1 is indeed a phosphoprotein that undergoes cell-cycle-dependent phosphorylation and can be phosphorylated by purified Clb-Cdc28 kinases in vitro. Mass spectrometry identified several phosphoserine and phosphothreonine residues among these CDK sites. Mutating 15 of the CDK phosphorylation sites with alanine markedly reduced Iqg1 phosphorylation in vivo. The 15A mutation greatly stabilized Iqg1, caused both premature assembly and delayed disassembly of the actomyosin ring, blocked Iqg1 interaction with the actin-nucleating proteins Bni1 and Bnr1, and resulted in defects in cytokinesis. Our data therefore strongly support the idea that the Cdc28 CDK regulates cytokinesis partly by directly phosphorylating the actomyosin ring component Iqg1.     

Expression of GFP-actin leads to failure of nuclear elongation and cytokinesis in Tetrahymena thermophila

Green fluorescent protein (GFP)-tagged actin was used to investigate the distribution and function of actin in Tetrahymena. A strain that expresses both GFP-actin and endogenous actin was developed by transformation of Tetrahymena thermophila with a ribosomal DNA-based replicative vector. Confocal microscopy of living cells and immunogold electron microscopy confirmed localization of GFP-actin to basal bodies and the contractile ring. Incorporation of the fusion protein into these and other actin-related structures correlated with severe impairment of macronuclear elongation and cytokinesis. At 30 degrees C macronuclear elongation failed to occur in 25% of the transformants despite completion of micronuclear division. At 20 degrees C macronuclear elongation failed to occur in 2% of the population. Arrest of cytokinesis coincided with failure of macronuclear elongation. Arrested cells developed into homopolar doublets with two sets of oral structures. This study indicates a requirement for actin in nuclear elongation and cytokinesis. Although GFP-actin can interfere with the functioning of actin-containing structures, the GFP-actin transformant strain can be used to monitor actin distribution and dynamics and is therefore an important new tool for further studies of Tetrahymena actin.     

Development of periodic tension in the contractile vacuole complex membrane of paramecium governs its membrane dynamics

The contractile vacuole complex is a membrane-bound osmoregulatory organelle of fresh water protozoa such as Paramecium. In Paramecium it consists of a central vacuole (the contractile vacuole) and 5-10 arms that radially extend from the vacuole into the cytosol (the radial arms). Excess cytosolic water, acquired osmotically, is segregated by the radial arms and enters the vacuole, so that the vacuole swells (the fluid-filling phase). The vacuole then rounds (the rounding phase) and the radial arms sever from the vacuole. The vacuole membrane then fuses with the plasma membrane at the pore region and the pore opens. The vacuole shrinks as its fluid is discharged through the pore (the fluid-discharging phase). The pore closes when the fluid has been discharged. The radial arms then reattach to the vacuole, so that the vacuole swells again as the fluid enters from the arms (the next fluid-filling phase). We found that the vacuole continued to show rounding and slackening even after it together with a small amount of cytosol had been isolated from the cell. Using a microcantilever placed on the surface of the vacuole the tension of the in vitro vacuole increased to 5 x 10(-3)N m(-1) as the vacuole rounds, and its lowest value was 1 x 10(-4)N m(-1) during slackening. We propose a hypothesis that an increase in the spontaneous curvature of the organelle's membrane leads to an increase in membrane tension and thus to the vacuole's rounding, severing of the radial arms from the vacuole, and opening of the pore. Conversely, a decrease in the spontaneous curvature accompanied by a decrease in membrane tension could lead to the closing of the pore and reattachment of the radial arm at the start of the fluid-filling phase.     

Ethanol induced alterations in plasma membrane protein phosphorylation of neurons and astrocytes

The endogenous protein phosphorylation patterns in plasma membranes of bulk isolated neurons and astroglia from control and chronic ethanol treated rats have been investigated. Chronic ethanol treatment resulted in increased phosphorylation of specific proteins with molecular weights 116, 63 and 60 kDa in both neurons and astrocytes. These proteins were further resolved by 2-DE and the analysis suggested an increased phosphorylation of 10–15 proteins, of which 116 kDa protein is phosphorylated to a higher extent by ethanol. Further, decreased phosphorylation was noticed in D-95 and D-63 proteins in neurons and D-78 and D-54 proteins in astrocytes. Alkali stability experiments for identifying the phosphoamino acid involved in phosphorylation of 116, 63 and 60 kDa proteins suggested that tyrosine and threonine are not involved and probably serine is the likely site for phosphorylation during chronic ethanol treatment. The phosphorylation of specific membrane proteins during chronic ethanol treatment might contribute to ethanol evoked cellular dysfunction.