| scholarly article | Q13442814 |
| P2093 | author name string | Eisuke Nishida | |
| Fumiko Toyoshima | |||
| P2860 | cites work | Myosin-X is a molecular motor that functions in filopodia formation | Q24299253 |
| Microtubule-dependent changes in assembly of microtubule motor proteins and mitotic spindle checkpoint proteins at PtK1 kinetochores | Q24555706 | ||
| EB1 proteins regulate microtubule dynamics, cell polarity, and chromosome stability | Q24670199 | ||
| Dissecting temporal and spatial control of cytokinesis with a myosin II Inhibitor | Q28183531 | ||
| Transmembrane crosstalk between the extracellular matrix--cytoskeleton crosstalk | Q28206345 | ||
| Calcium sensitization of smooth muscle mediated by a Rho-associated protein kinase in hypertension | Q29614247 | ||
| Cell attachment activity of fibronectin can be duplicated by small synthetic fragments of the molecule | Q29616413 | ||
| Mammalian spindle orientation and position respond to changes in cell shape in a dynein-dependent fashion | Q30477500 | ||
| Rho overexpression leads to mitosis-associated detachment of cells from epithelial sheets: a link to the mechanism of cancer dissemination | Q30831570 | ||
| Beta1 integrins regulate mammary gland proliferation and maintain the integrity of mammary alveoli | Q33841885 | ||
| Myosin-X, a novel myosin with pleckstrin homology domains, associates with regions of dynamic actin. | Q33917620 | ||
| Microtubule "plus-end-tracking proteins": The end is just the beginning | Q33947998 | ||
| Beyond self-assembly: from microtubules to morphogenesis | Q34181655 | ||
| Myosin II-dependent cortical movement is required for centrosome separation and positioning during mitotic spindle assembly | Q34316446 | ||
| Myosin-X provides a motor-based link between integrins and the cytoskeleton. | Q34322246 | ||
| EB1 and APC bind to mDia to stabilize microtubules downstream of Rho and promote cell migration | Q34341177 | ||
| Proteasome inhibitors: from research tools to drug candidates | Q34341985 | ||
| Symmetric and asymmetric cell division in rat corneal epithelium | Q34664091 | ||
| Integrin signaling to the actin cytoskeleton. | Q35547365 | ||
| "Search-and-Capture" of Microtubules through Plus-End-Binding Proteins (+TIPs) | Q35560925 | ||
| Cortical control of microtubule stability and polarization | Q35705434 | ||
| Dynamic microtubules lead the way for spindle positioning. | Q35790338 | ||
| Mechanics and regulation of cytokinesis | Q35804823 | ||
| Drosophila EB1 is important for proper assembly, dynamics, and positioning of the mitotic spindle | Q36323890 | ||
| Chromosome instability in colorectal tumor cells is associated with defects in microtubule plus-end attachments caused by a dominant mutation in APC | Q36324684 | ||
| Dualistic nature of adhesive protein function: fibronectin and its biologically active peptide fragments can autoinhibit fibronectin function | Q36510361 | ||
| Orientation of spindle axis and distribution of plasma membrane proteins during cell division in polarized MDCKII cells | Q36534977 | ||
| Length control of the metaphase spindle | Q40348496 | ||
| Role of actin polymerization and adhesion to extracellular matrix in Rac- and Rho-induced cytoskeletal reorganization | Q42278235 | ||
| Adherens junctions inhibit asymmetric division in the Drosophila epithelium | Q42499987 | ||
| Endotoxin/lipopolysaccharide activates NF-kappa B and enhances tumor cell adhesion and invasion through a beta 1 integrin-dependent mechanism | Q44272097 | ||
| A microtubule-binding myosin required for nuclear anchoring and spindle assembly. | Q52560093 | ||
| Spindles cotton on to junctions, APC and EB1. | Q52586450 | ||
| The extracellular matrix guides the orientation of the cell division axis. | Q53656268 | ||
| Latrunculins: novel marine toxins that disrupt microfilament organization in cultured cells | Q57258304 | ||
| Cell biology. Microtubule asymmetry | Q73582102 | ||
| P433 | issue | 6 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 1487-1498 | |
| P577 | publication date | 2007-02-22 | |
| P1433 | published in | The EMBO Journal | Q1278554 |
| P1476 | title | Integrin-mediated adhesion orients the spindle parallel to the substratum in an EB1- and myosin X-dependent manner | |
| P478 | volume | 26 |
| Q37725776 | 27 T ultra-high static magnetic field changes orientation and morphology of mitotic spindles in human cells. |
| Q58173395 | A Cancer-Associated Mutation in Atypical Protein Kinase C Occurs in a Substrate-Specific Recruitment Motif |
| Q27310178 | A Role for the Chaperone Complex BAG3-HSPB8 in Actin Dynamics, Spindle Orientation and Proper Chromosome Segregation during Mitosis |
| Q27310167 | A ZO-1/α5β1-integrin complex regulates cytokinesis downstream of PKCε in NCI-H460 cells plated on fibronectin |
| Q38917298 | A ligand-independent integrin β1 mechanosensory complex guides spindle orientation. |
| Q43244945 | A novel harvesting method for cultured cells using iron-cross-linked alginate films as culture substrates |
| Q42175728 | A proteomic study of mitotic phase-specific interactors of EB1 reveals a role for SXIP-mediated protein interactions in anaphase onset. |
| Q30512982 | ABL1 regulates spindle orientation in adherent cells and mammalian skin. |
| Q30524706 | AMPK regulates mitotic spindle orientation through phosphorylation of myosin regulatory light chain |
| Q37308181 | ASK1 controls spindle orientation and positioning by phosphorylating EB1 and stabilizing astral microtubules |
| Q54110225 | Actin Dysfunction Induces Cell Cycle Delay at G2/M with Sustained ERK and RSK Activation in IMR-90 Normal Human Fibroblasts. |
| Q27306218 | Actin structure-dependent stepping of myosin 5a and 10 during processive movement |
| Q30562515 | Adducin-1 is essential for mitotic spindle assembly through its interaction with myosin-X. |
| Q33830288 | Adhesion molecules in the stem cell niche--more than just staying in shape? |
| Q26801738 | Adult Stem Cell Responses to Nanostimuli |
| Q36185377 | An evolutionary shift in the regulation of the Hippo pathway between mice and flies |
| Q36021806 | Analyzing Spindle Positioning Dynamics in Cultured Cells |
| Q27022900 | And the dead shall rise: actin and myosin return to the spindle |
| Q34310944 | Aurora A kinase modulates actin cytoskeleton through phosphorylation of Cofilin: Implication in the mitotic process |
| Q47298497 | Aurora A kinase regulates proper spindle positioning in C. elegans and in human cells. |
| Q30540082 | Aurora B spatially regulates EB3 phosphorylation to coordinate daughter cell adhesion with cytokinesis |
| Q30841843 | Automated mitotic spindle tracking suggests a link between spindle dynamics, spindle orientation, and anaphase onset in epithelial cells |
| Q30559683 | Automated tracking of mitotic spindle pole positions shows that LGN is required for spindle rotation but not orientation maintenance |
| Q39915665 | Biomimetic poly(amidoamine) hydrogels as synthetic materials for cell culture. |
| Q30437856 | Cadherin adhesion receptors orient the mitotic spindle during symmetric cell division in mammalian epithelia |
| Q42442333 | Calmodulin-like protein upregulates myosin-10 in human keratinocytes and is regulated during epidermal wound healing in vivo |
| Q27666969 | Cargo recognition mechanism of myosin X revealed by the structure of its tail MyTH4-FERM tandem in complex with the DCC P3 domain |
| Q28255939 | Cdk1-dependent mitotic enrichment of cortical myosin II promotes cell rounding against confinement |
| Q36525471 | Cell Fate Decision Making through Oriented Cell Division |
| Q38677606 | Cell adhesion molecule control of planar spindle orientation. |
| Q29977782 | Cell cycle-regulated membrane binding of NuMA contributes to efficient anaphase chromosome separation |
| Q35624653 | Cell polarity: The missing link in skeletal morphogenesis? |
| Q35679252 | Cell shape impacts on the positioning of the mitotic spindle with respect to the substratum. |
| Q38661407 | Centrosomes in spindle organization and chromosome segregation: a mechanistic view |
| Q39278356 | Characterization of a myosin VII MyTH/FERM domain. |
| Q27318727 | Characterization of ring-like F-actin structure as a mechanical partner for spindle positioning in mitosis |
| Q61800321 | Chromosome alignment maintenance requires the MAP RECQL4, mutated in the Rothmund-Thomson syndrome |
| Q29871463 | Chromosome- and spindle-pole-derived signals generate an intrinsic code for spindle position and orientation |
| Q37801734 | Common themes in centriole and centrosome movements |
| Q42078751 | Convergent extension movements in growth plate chondrocytes require gpi-anchored cell surface proteins |
| Q24300064 | Cortical dynein is critical for proper spindle positioning in human cells |
| Q38879997 | Coupling changes in cell shape to chromosome segregation. |
| Q26829338 | Cytoskeletal dynamics: a view from the membrane |
| Q34403336 | Depletion of nuclear actin is a key mediator of quiescence in epithelial cells |
| Q28066088 | Diacylglycerol Kinases: Shaping Diacylglycerol and Phosphatidic Acid Gradients to Control Cell Polarity |
| Q27314555 | Direct Microtubule-Binding by Myosin-10 Orients Centrosomes toward Retraction Fibers and Subcortical Actin Clouds |
| Q24299033 | Dishevelled, a Wnt signalling component, is involved in mitotic progression in cooperation with Plk1 |
| Q46111698 | Diverse mitotic functions of the cytoskeletal cross-linking protein Shortstop suggest a role in Dynein/Dynactin activity |
| Q30487617 | Dual role of Cdc42 in spindle orientation control of adherent cells |
| Q30525035 | Dynein light chain 1 and a spindle-associated adaptor promote dynein asymmetry and spindle orientation |
| Q58768354 | E-cadherin bridges cell polarity and spindle orientation to ensure prostate epithelial integrity and prevent carcinogenesis in vivo |
| Q47944282 | EB1 and EB3 regulate microtubule minus end organization and Golgi morphology. |
| Q27311190 | EB1 is required for spindle symmetry in mammalian mitosis |
| Q27313451 | Effect of Cell Shape and Dimensionality on Spindle Orientation and Mitotic Timing |
| Q30495669 | Epicardial spindle orientation controls cell entry into the myocardium |
| Q33543778 | Epimorphin regulates bile duct formation via effects on mitosis orientation in rat liver epithelial stem-like cells |
| Q30538070 | Evidence for dynein and astral microtubule-mediated cortical release and transport of Gαi/LGN/NuMA complex in mitotic cells |
| Q24336902 | Evidence for the involvement of FAM110C protein in cell spreading and migration |
| Q60228249 | External forces control mitotic spindle positioning |
| Q50627126 | FAK transduces extracellular forces that orient the mitotic spindle and control tissue morphogenesis. |
| Q36780764 | FMNL1, a key regulator for asymmetric cell division |
| Q27325820 | Focal adhesions control cleavage furrow shape and spindle tilt during mitosis |
| Q37201503 | Formin-mediated actin polymerization cooperates with Mushroom body defect (Mud)-Dynein during Frizzled-Dishevelled spindle orientation |
| Q64065268 | GAS2-like 1 coordinates cell division through its association with end-binding proteins |
| Q39429868 | HAS3-induced accumulation of hyaluronan in 3D MDCK cultures results in mitotic spindle misorientation and disturbed organization of epithelium. |
| Q36127036 | Headless Myo10 is a negative regulator of full-length Myo10 and inhibits axon outgrowth in cortical neurons |
| Q30490728 | Helicobacter pylori CagA causes mitotic impairment and induces chromosomal instability |
| Q64052738 | Hexameric NuMA:LGN structures promote multivalent interactions required for planar epithelial divisions |
| Q38910981 | Integrin-linked kinase links dynactin-1/dynactin-2 with cortical integrin receptors to orient the mitotic spindle relative to the substratum |
| Q37360848 | Integrins and cell-fate determination |
| Q36158444 | Integrins as regulators of the mitotic machinery |
| Q27313566 | Interphase adhesion geometry is transmitted to an internal regulator for spindle orientation via caveolin-1. |
| Q36030193 | JAM-A regulates cortical dynein localization through Cdc42 to control planar spindle orientation during mitosis. |
| Q39134536 | Kindlin-1 regulates mitotic spindle formation by interacting with integrins and Plk-1. |
| Q41815390 | Kinetic Analysis Reveals Differences in the Binding Mechanism of Calmodulin and Calmodulin-like Protein to the IQ Motifs of Myosin-10 |
| Q30434467 | LGN regulates mitotic spindle orientation during epithelial morphogenesis |
| Q53510991 | LIM kinase-mediated cofilin phosphorylation during mitosis is required for precise spindle positioning. |
| Q30560241 | LIS1 controls mitosis and mitotic spindle organization via the LIS1-NDEL1-dynein complex. |
| Q88938502 | Laminin β2 Chain Regulates Retinal Progenitor Cell Mitotic Spindle Orientation via Dystroglycan |
| Q36009204 | Laminin/β1 integrin signal triggers axon formation by promoting microtubule assembly and stabilization. |
| Q28743071 | Lever-arm mechanics of processive myosins |
| Q30608477 | Lis1 regulates asymmetric division in hematopoietic stem cells and in leukemia |
| Q66679494 | Live imaging screen reveals that TYRO3 and GAK ensure accurate spindle positioning in human cells |
| Q88875551 | Living Xenopus oocytes, eggs, and embryos as models for cell division |
| Q36916403 | Local 3D matrix confinement determines division axis through cell shape |
| Q30537786 | MISP is a novel Plk1 substrate required for proper spindle orientation and mitotic progression |
| Q30514185 | Mechanical impulses can control metaphase progression in a mammalian cell |
| Q64103888 | Mechanisms of Spindle Positioning: Lessons from Worms and Mammalian Cells |
| Q36843504 | Mechanisms to suppress multipolar divisions in cancer cells with extra centrosomes |
| Q53236082 | Might makes right: Using force to align the mitotic spindle. |
| Q35826056 | Mio depletion links mTOR regulation to Aurora A and Plk1 activation at mitotic centrosomes |
| Q24314268 | Mitotic control of kinetochore-associated dynein and spindle orientation by human Spindly |
| Q35063606 | Mitotic spindle asymmetry in rodents and primates: 2D vs. 3D measurement methodologies |
| Q27025216 | Molecular pathways regulating mitotic spindle orientation in animal cells |
| Q24318195 | Msd1/SSX2IP-dependent microtubule anchorage ensures spindle orientation and primary cilia formation |
| Q37359223 | Multiple centrosomes: together they stand, divided they fall |
| Q89545561 | Myosin X is required for efficient melanoblast migration and melanoma initiation and metastasis |
| Q30493830 | Myosin X regulates sealing zone patterning in osteoclasts through linkage of podosomes and microtubules |
| Q30482632 | Myosin-10 and actin filaments are essential for mitotic spindle function |
| Q37245779 | Myosin-10 independently influences mitotic spindle structure and mitotic progression |
| Q26825835 | Myosin-X and disease |
| Q30513859 | Myosin-X functions in polarized epithelial cells |
| Q47139973 | Myosin-X knockout is semi-lethal and demonstrates that myosin-X functions in neural tube closure, pigmentation, hyaloid vasculature regression, and filopodia formation. |
| Q35576442 | Myosin-X: a MyTH-FERM myosin at the tips of filopodia |
| Q60949857 | Myosins in Osteoclast Formation and Function |
| Q27004163 | Myosins in cell junctions |
| Q42109218 | Noncanonical frizzled signaling regulates cell polarity of growth plate chondrocytes |
| Q27346737 | Novel functions for the endocytic regulatory proteins MICAL-L1 and EHD1 in mitosis |
| Q29871430 | NuMA interacts with phosphoinositides and links the mitotic spindle with the plasma membrane |
| Q29871442 | NuMA phosphorylation by CDK1 couples mitotic progression with cortical dynein function |
| Q30480911 | Oncogenic H-Ras V12 promotes anchorage-independent cytokinesis in human fibroblasts |
| Q41991085 | PCTK1 regulates integrin-dependent spindle orientation via protein kinase A regulatory subunit KAP0 and myosin X. |
| Q41569146 | PLK1-dependent activation of LRRK1 regulates spindle orientation by phosphorylating CDK5RAP2. |
| Q36395967 | PTEN is required to maintain luminal epithelial homeostasis and integrity in the adult mammary gland |
| Q41717807 | Palladin is a novel microtubule-associated protein responsible for spindle orientation |
| Q33615110 | Pericentrin in cellular function and disease |
| Q27321639 | Phosphorylation of EB2 by Aurora B and CDK1 ensures mitotic progression and genome stability |
| Q38768808 | Phosphorylation-dependent Akt-Inversin interaction at the basal body of primary cilia. |
| Q58688346 | Poly(amidoamine) Hydrogels as Scaffolds for Cell Culturing and Conduits for Peripheral Nerve Regeneration |
| Q27311381 | Properties of cells through life and death - an acoustic microscopy investigation |
| Q24295713 | RanGTP and CLASP1 cooperate to position the mitotic spindle |
| Q33834308 | Reduced Notch signaling leads to renal cysts and papillary microadenomas |
| Q38901748 | Regulation of mitotic spindle orientation: an integrated view. |
| Q58057603 | Reticular adhesions are a distinct class of cell-matrix adhesions that mediate attachment during mitosis |
| Q39640040 | Revolving movement of a dynamic cluster of actin filaments during mitosis |
| Q30495284 | Ric-8A and Gi alpha recruit LGN, NuMA, and dynein to the cell cortex to help orient the mitotic spindle |
| Q33797006 | SLK-dependent activation of ERMs controls LGN-NuMA localization and spindle orientation |
| Q52647903 | Sema4C/PlexinB2 signaling controls breast cancer cell growth, hormonal dependence and tumorigenic potential. |
| Q30494681 | Single-molecule stepping and structural dynamics of myosin X. |
| Q30592489 | Spatial pattern of cell geometry and cell-division orientation in zebrafish lens epithelium |
| Q26829174 | Spindle orientation in mammalian cerebral cortical development |
| Q35903531 | Spindle position in symmetric cell divisions during epiboly is controlled by opposing and dynamic apicobasal forces |
| Q89239881 | Spindle rotation in human cells is reliant on a MARK2-mediated equatorial spindle-centering mechanism |
| Q92038703 | Spindle-F-actin interactions in mitotic spindles in an intact vertebrate epithelium |
| Q24305586 | Structural basis of cargo recognition by the myosin-X MyTH4-FERM domain |
| Q39242330 | Symmetry Does not Come for Free: Cellular Mechanisms to Achieve a Symmetric Cell Division. |
| Q30850728 | The Light Intermediate Chain 2 Subpopulation of Dynein Regulates Mitotic Spindle Orientation |
| Q39242277 | The Midbody and its Remnant in Cell Polarization and Asymmetric Cell Division |
| Q91044884 | The Signaling Pathways Project, an integrated 'omics knowledgebase for mammalian cellular signaling pathways |
| Q30539764 | The UBXN-2/p37/p47 adaptors of CDC-48/p97 regulate mitosis by limiting the centrosomal recruitment of Aurora A. |
| Q30499405 | The cilia protein IFT88 is required for spindle orientation in mitosis |
| Q28119161 | The conserved Wdr8-hMsd1/SSX2IP complex localises to the centrosome and ensures proper spindle length and orientation |
| Q90315239 | The focal adhesion protein kindlin-2 controls mitotic spindle assembly by inhibiting histone deacetylase 6 and maintaining α-tubulin acetylation |
| Q30540338 | The novel actin/focal adhesion-associated protein MISP is involved in mitotic spindle positioning in human cells |
| Q92890916 | The role of polarisation of circulating tumour cells in cancer metastasis |
| Q27026481 | The role of the cilium in normal and abnormal cell cycles: emphasis on renal cystic pathologies |
| Q41275553 | Tipping the spindle into the right position |
| Q48057176 | Two populations of cytoplasmic dynein contribute to spindle positioning in C. elegans embryos |
| Q36929781 | Unconventional myosins acting unconventionally. |
| Q29030919 | Using biomaterials to study stem cell mechanotransduction, growth and differentiation |
| Q39822734 | VHL loss causes spindle misorientation and chromosome instability. |
| Q30528767 | Wtip and Vangl2 are required for mitotic spindle orientation and cloaca morphogenesis |
| Q28585697 | Zika virus causes supernumerary foci with centriolar proteins and impaired spindle positioning |
| Q47340348 | p37/UBXN2B regulates spindle orientation by limiting cortical NuMA recruitment via PP1/Repo-Man. |
| Q28586922 | γ-Tubulin Ring Complexes and EB1 play antagonistic roles in microtubule dynamics and spindle positioning |
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