scholarly article | Q13442814 |
P2093 | author name string | Alexey Khodjakov | |
Bruce F McEwen | |||
Polla Hergert | |||
Greenfield Sluder | |||
Sabrina La Terra | |||
Christopher N English | |||
P2860 | cites work | Identification of a new mammalian centrin gene, more closely related to Saccharomyces cerevisiae CDC31 gene | Q24322832 |
Sfi1p has conserved centrin-binding sites and an essential function in budding yeast spindle pole body duplication | Q24671520 | ||
Centrioles in the cell cycle. I. Epithelial cells | Q24681444 | ||
Checkpoints: controls that ensure the order of cell cycle events | Q28131705 | ||
Most of centrin in animal cells is not centrosome-associated and centrosomal centrin is confined to the distal lumen of centrioles | Q28301913 | ||
Nucleation of microtubule assembly by a gamma-tubulin-containing ring complex | Q29615059 | ||
Centrosomes enhance the fidelity of cytokinesis in vertebrates and are required for cell cycle progression | Q30662520 | ||
De novo formation of centrosomes in vertebrate cells arrested during S phase | Q30858324 | ||
Centrosome-independent mitotic spindle formation in vertebrates | Q31494302 | ||
Centrosome-dependent exit of cytokinesis in animal cells | Q32062097 | ||
A synergy of technologies: combining laser microsurgery with green fluorescent protein tagging | Q32162613 | ||
Centrosomes and cancer | Q33750807 | ||
The centrosome in vertebrates: more than a microtubule-organizing center | Q33954846 | ||
Managing the centrosome numbers game: from chaos to stability in cancer cell division | Q34123299 | ||
Centrosome aberrations: cause or consequence of cancer progression? | Q34157650 | ||
Centrosome number is controlled by a centrosome-intrinsic block to reduplication | Q34199885 | ||
Absence of centrioles in the first and second meiotic spindles of mouse oocytes | Q34227802 | ||
The chromosome cycle and the centrosome cycle in the mitotic cycle | Q34690231 | ||
Loss of p53 and centrosome hyperamplification. | Q34818333 | ||
Centriole disassembly in vivo and its effect on centrosome structure and function in vertebrate cells | Q36255993 | ||
The disassembly and reassembly of functional centrosomes in vitro | Q36256655 | ||
Microtubule release from the centrosome in migrating cells | Q36324319 | ||
The respective contributions of the mother and daughter centrioles to centrosome activity and behavior in vertebrate cells | Q36328376 | ||
Requirement of a centrosomal activity for cell cycle progression through G1 into S phase | Q40823744 | ||
Papillomavirus infections--a major cause of human cancers | Q41159507 | ||
Drosophila parthenogenesis: a model for de novo centrosome assembly. | Q42446193 | ||
Transient concentration of a gamma-tubulin-related protein with a pericentrin-related protein in the formation of basal bodies and flagella during the differentiation of Naegleria gruberi | Q42523564 | ||
Centriole duplication in lysates of Spisula solidissima oocytes | Q45421513 | ||
Microtubule nucleation by gamma-tubulin-containing rings in the centrosome | Q46052298 | ||
Microsurgical removal of centrosomes blocks cell reproduction and centriole generation in BSC-1 cells | Q46145541 | ||
Three-dimensional transmission electron microscopy and its application to mitosis research | Q48925205 | ||
De novo formation of centrioles in parthenogenetically activated, diploidized rabbit embryos | Q50802692 | ||
Kinetics and regulation of de novo centriole assembly. Implications for the mechanism of centriole duplication. | Q52137805 | ||
Independence of centriole formation and initiation of DNA synthesis in Chinese hamster ovary cells | Q69886915 | ||
Origin and maturation of centrioles in association with the nuclear envelope in hypertonic-stressed sea urchin eggs | Q70478550 | ||
Centrosome defects and genetic instability in malignant tumors | Q77220481 | ||
Supernumerary centrosomes and cancer: Boveri's hypothesis resurrected | Q77701101 | ||
Correlative light and electron microscopy of mitotic cells in monolayer cultures | Q77801971 | ||
Planting the seeds of biotechnology | Q95806203 | ||
Science city | Q95806209 | ||
P433 | issue | 5 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | cell biology | Q7141 |
P304 | page(s) | 713-22 | |
P577 | publication date | 2005-02-28 | |
P1433 | published in | Journal of Cell Biology | Q1524550 |
P1476 | title | The de novo centriole assembly pathway in HeLa cells: cell cycle progression and centriole assembly/maturation | |
P478 | volume | 168 |
Q35479894 | A clinical overview of centrosome amplification in human cancers |
Q33288543 | A history of laser scissors (microbeams). |
Q41857706 | ASQ2 encodes a TBCC-like protein required for mother-daughter centriole linkage and mitotic spindle orientation |
Q24650428 | Ab ovo or de novo? Mechanisms of centriole duplication |
Q64123337 | Adolescent idiopathic scoliosis associated POC5 mutation impairs cell cycle, cilia length and centrosome protein interactions |
Q34785942 | Amphiastral mitotic spindle assembly in vertebrate cells lacking centrosomes |
Q27312428 | An intact centrosome is required for the maintenance of polarization during directional cell migration |
Q39580473 | Apparent diffusive motion of centrin foci in living cells: implications for diffusion-based motion in centriole duplication |
Q24307694 | Asymmetric CLASP-dependent nucleation of noncentrosomal microtubules at the trans-Golgi network |
Q26824247 | Atypical centrioles during sexual reproduction |
Q24318115 | Aurora A, centrosome structure, and the centrosome cycle |
Q33260165 | Brain-type creatine kinase BB-CK interacts with the Golgi Matrix Protein GM130 in early prophase |
Q34205722 | Building the Centriole |
Q37224316 | Building the cell: design principles of cellular architecture |
Q47248840 | Building the right centriole for each cell type |
Q34809067 | CDC25B overexpression stabilises centrin 2 and promotes the formation of excess centriolar foci |
Q28505755 | CDK5RAP2 regulates centriole engagement and cohesion in mice |
Q33269437 | Cell cycle progression and de novo centriole assembly after centrosomal removal in untransformed human cells |
Q42480923 | Centrin scaffold in Chlamydomonas reinhardtii revealed by immunoelectron microscopy |
Q36959273 | Centriole biogenesis: a tale of two pathways |
Q34149059 | Centriole duplication: analogue control in a digital age |
Q37080414 | Centriole inheritance |
Q34027191 | Centriole reduplication during prolonged interphase requires procentriole maturation governed by Plk1. |
Q33416534 | Centriole separation in DNA damage-induced centrosome amplification |
Q42648326 | Centriole triplet microtubules are required for stable centriole formation and inheritance in human cells. |
Q42451265 | Centrioles to basal bodies in the spermiogenesis of Mastotermes darwiniensis (Insecta, Isoptera). |
Q37077857 | Centrioles: some self-assembly required. |
Q36414032 | Centrosome aberrations in human mammary epithelial cells driven by cooperative interactions between p16INK4a deficiency and telomere-dependent genotoxic stress |
Q36823707 | Centrosome biogenesis and function: centrosomics brings new understanding |
Q34091715 | Centrosome biogenesis continues in the absence of microtubules during prolonged S-phase arrest |
Q37392998 | Centrosome duplication proceeds during mimosine-induced G1 cell cycle arrest |
Q21129300 | Centrosome dysfunction contributes to chromosome instability, chromoanagenesis, and genome reprograming in cancer |
Q38650721 | Centrosomes in the DNA damage response--the hub outside the centre |
Q36763236 | Clockwise or anticlockwise? Turning the centriole triplets in the right direction! |
Q27348481 | Computational support for a scaffolding mechanism of centriole assembly |
Q33320973 | Control of daughter centriole formation by the pericentriolar material |
Q35642595 | Cortical cytasters: a highly conserved developmental trait of Bilateria with similarities to Ctenophora |
Q24675495 | Cyclin G2 is a centrosome-associated nucleocytoplasmic shuttling protein that influences microtubule stability and induces a p53-dependent cell cycle arrest |
Q36452437 | De novo centriole formation in human cells is error-prone and does not require SAS-6 self-assembly. |
Q36321169 | De novo formation of basal bodies in Naegleria gruberi: regulation by phosphorylation |
Q28740894 | Defective nucleotide excision repair with normal centrosome structures and functions in the absence of all vertebrate centrins |
Q37987198 | Discovery of centrosomal RNA and centrosomal hypothesis of cellular ageing and differentiation |
Q24646328 | Drosophila asterless and vertebrate Cep152 Are orthologs essential for centriole duplication |
Q90045297 | Dynamics of centriole amplification in centrosome-depleted brain multiciliated progenitors |
Q59126926 | Emerging Picture of Deuterosome-Dependent Centriole Amplification in MCCs |
Q37164670 | Evolutionary problems in centrosome and centriole biology |
Q30482377 | Extra centrosomes and/or chromosomes prolong mitosis in human cells |
Q34098448 | Formation of extra centrosomal structures is dependent on β-catenin |
Q36144711 | Genomic instability in human cancer: Molecular insights and opportunities for therapeutic attack and prevention through diet and nutrition. |
Q34976788 | Identification of a polo-like kinase 4-dependent pathway for de novo centriole formation |
Q39740553 | Inhibition of centrosome protein assembly leads to p53-dependent exit from the cell cycle. |
Q93364645 | It takes two (centrioles) to tango |
Q34968444 | JAK2 tyrosine kinase phosphorylates and is negatively regulated by centrosomal protein Ninein |
Q35797268 | Katanin p80 regulates human cortical development by limiting centriole and cilia number |
Q50267591 | Kinetic analysis of de novo centriole assembly in heat-shocked mammalian cells |
Q33288550 | Laser microsurgery in the GFP era: a cell biologist's perspective |
Q40165052 | Loss of centrosome integrity induces p38-p53-p21-dependent G1-S arrest |
Q28116536 | MDM1 is a microtubule-binding protein that negatively regulates centriole duplication |
Q33288547 | Mechanisms of laser cellular microsurgery |
Q37780832 | Microscopy methods for the study of centriole biogenesis and function in Drosophila |
Q40432009 | Microtubule dynamics of the centrosome-like polar organizers from the basal land plant Marchantia polymorpha. |
Q36118747 | Molecular characterization of centriole assembly in ciliated epithelial cells |
Q39896131 | Molecular dissection of the centrosome overduplication pathway in S-phase-arrested cells |
Q39874997 | Mps1 as a link between centrosomes and genomic instability |
Q34408480 | Mps1 phosphorylation sites regulate the function of centrin 2 in centriole assembly |
Q34475288 | Mutational analyses reveal a novel function of the nucleotide-binding domain of gamma-tubulin in the regulation of basal body biogenesis |
Q42333295 | Non-model model organisms. |
Q33959903 | One to only two: a short history of the centrosome and its duplication |
Q35830134 | Overexpressing centriole-replication proteins in vivo induces centriole overduplication and de novo formation. |
Q92126517 | Parental centrioles are dispensable for deuterosome formation and function during basal body amplification |
Q47675920 | Parthenogenesis in Insects: The Centriole Renaissance |
Q24336451 | Plk4-induced centriole biogenesis in human cells |
Q36638337 | Predictive-focus illumination for reducing photodamage in live-cell microscopy |
Q37080411 | Preformed cell structure and cell heredity |
Q36674345 | Promoter hijack reveals pericentrin functions in mitosis and the DNA damage response |
Q24306609 | RBM14 prevents assembly of centriolar protein complexes and maintains mitotic spindle integrity |
Q48647218 | RNA in centrosomes: structure and possible functions. |
Q42488982 | Rapid centriole assembly in Naegleria reveals conserved roles for both de novo and mentored assembly |
Q46007470 | Rebuilding MTOCs upon centriole loss during mouse oogenesis. |
Q24647101 | Regulated HsSAS-6 levels ensure formation of a single procentriole per centriole during the centrosome duplication cycle |
Q37387888 | Relative contributions of chromatin and kinetochores to mitotic spindle assembly |
Q35130181 | Repeated cleavage failure does not establish centrosome amplification in untransformed human cells |
Q24337615 | Rootletin forms centriole-associated filaments and functions in centrosome cohesion |
Q33976747 | SAS-6 assembly templated by the lumen of cartwheel-less centrioles precedes centriole duplication |
Q38034629 | Show me your license, please: deregulation of centriole duplication mechanisms that promote amplification |
Q35940219 | Stability and robustness of an organelle number control system: modeling and measuring homeostatic regulation of centriole abundance |
Q37998379 | Such small hands: the roles of centrins/caltractins in the centriole and in genome maintenance |
Q34573625 | The G1 phase Cdks regulate the centrosome cycle and mediate oncogene-dependent centrosome amplification |
Q24301726 | The Golgi protein GM130 regulates centrosome morphology and function |
Q24654805 | The centromere geometry essential for keeping mitosis error free is controlled by spindle forces |
Q35196084 | The conversion of centrioles to centrosomes: essential coupling of duplication with segregation |
Q36425575 | The interrelationship between APC/C and Plk1 activities in centriole disengagement |
Q30483859 | The spindle assembly checkpoint is satisfied in the absence of interkinetochore tension during mitosis with unreplicated genomes. |
Q24622331 | The transition from meiotic to mitotic spindle assembly is gradual during early mammalian development |
Q53653118 | Two-way traffic: centrosomes and the cell cycle. |
Q28079076 | Using sea urchin gametes and zygotes to investigate centrosome duplication |
Q46868732 | What mechanisms/processes underlie radiation-induced genomic instability? |
Q27310018 | p53 protects against genome instability following centriole duplication failure |
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