Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation - Wikidata - wikimedia - TriplyDB

Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation

Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation

http://www.wikidata.org/entity/Q31114481

about

Long range physical cell-to-cell signalling via mitochondria inside membrane nanotubes: a hypothesis.Large-area graphene-based nanofiltration membranes by shear alignment of discotic nematic liquid crystals of graphene oxide A Brief History of Research on Mitotic Mechanisms Possible existence of optical communication channels in the brain Structural basis of motility in the microtubular axostyle: implications for cytoplasmic microtubule structure and function.Micromanipulation studies of chromosome movement. II. Birefringent chromosomal fibers and the mechanical attachment of chromosomes to the spindle.Microtubule bundling and nested buckling drive stripe formation in polymerizing tubulin solutions Birefringence imaging directly reveals architectural dynamics of filamentous actin in living growth cones.Polarized Fluorescence Microscopy to Study Cytoskeleton Assembly and Organization in Live Cells.Visualization of the microtubules of glutaraldehyde-fixed cells by reflection-enhanced backscatter confocal microscopy.Analysis of microtubule dynamics by polarized light Image simulation for biological microscopy: microlith.Orientation-dependent visibility of long thin objects in polarization-based microscopy.Birefringence of macromolecules. Wiener's theory revisited, with applications to DNA and tobacco mosaic virus.Form birefringence of muscle.Birefringence of single and bundled microtubules Poleward force at the kinetochore in metaphase depends on the number of kinetochore microtubules.Force generation by microtubule assembly/disassembly in mitosis and related movements.Polarized light microscopy in reproductive and developmental biology.Living Cells and Dynamic Molecules Observed with the Polarized Light Microscope: the Legacy of Shinya Inoué.Quantitative studies on the polarization optical properties of striated muscle. I. Birefringence changes of rabbit psoas muscle in the transition from rigor to relaxed state.Experimental manipulation of the amount of tubulin available for assembly into the spindle of dividing sea urchin eggs.Mitosis in Barbulanympha. I. Spindle structure, formation, and kinetochore engagement.Role of spindle microtubules in the control of cell cycle timing Functional implications of cold-stable microtubules in kinetochore fibers of insect spermatocytes during anaphase.Calcium-labile mitotic spindles isolated from sea urchin eggs (Lytechinus variegatus).Video image processing greatly enhances contrast, quality, and speed in polarization-based microscopy Quantitative studies on the polarization optical properties of living cells II. The role of microtubules in birefringence of the spindle of the sea urchin egg Spindle microtubules and their mechanical associations after micromanipulation in anaphase.Studies on the in vivo sensitivity of spindle microtubules to calcium ions and evidence for a vesicular calcium-sequestering system.Rapid rate of tubulin dissociation from microtubules in the mitotic spindle in vivo measured by blocking polymerization with colchicine.The total length of spindle microtubules depends on the number of chromosomes present Spindle microtubule dynamics in sea urchin embryos: analysis using a fluorescein-labeled tubulin and measurements of fluorescence redistribution after laser photobleaching.Visualization and examination of the meiotic spindle in human oocytes with polscope Quantitative studies on the polarization optical properties of living cells. I. Microphotometric birefringence detection system Calcium-dependent regulator protein: localization in mitotic apparatus of eukaryotic cells.Calcium and cellular clocks orchestrate cell division.Microscopic imaging of cells.The susceptibility of pure tubulin to high magnetic fields: a magnetic birefringence and x-ray fiber diffraction study.Mitosis in Barbulanympha. II. Dynamics of a two-stage anaphase, nuclear morphogenesis, and cytokinesis.

P2860

Q26748642-DCD9FB5D-1552-40A7-91A9-750D38505072 Q27325486-33DAC325-A929-4393-AB50-AB5997516190 Q28074607-3EBE02EA-78B8-4044-9BD7-185360925A9A Q28822004-9AF84368-EC95-458D-A83B-376F44D52597 Q30442422-C9B804FC-4400-48C2-82FC-9F74812D38FF Q30442438-EB9EE392-FDF6-4E35-B9C0-87F71ABB400C Q30477583-87C3083E-0B80-48A1-9E16-9778501CBCE0 Q30483070-046405C2-E5F3-4582-8A01-2909016D8337 Q30488027-6AB7A622-2F41-4D91-BCBD-755C3E84985F Q33283762-31AB25BB-ED9D-4A52-812F-542EC96C8C7D Q33310702-E497E159-8260-466A-872D-F7451ECC68F8 Q33738354-34FCE490-88EB-4E88-8A62-347EC4B6398B Q34018033-5C50E610-B361-46C5-B97E-5F6A16B12D63 Q34124870-14E8C82D-5312-4201-98DD-E1894AC4BAA5 Q34124943-25D49C54-00F8-46D5-B0B2-A509BE2696FC Q34167266-FBCF716F-05E0-47F1-AE13-B7134D0895C5 Q34417496-AAF864D9-5EAB-45BD-B3A4-A15FB9E59BAC Q34453605-C505D17A-E0B1-425F-B32A-E321CF0AE3D3 Q34882113-40CCE8D1-8C5F-4F31-A0D9-33CA472F92C3 Q36136146-B937668B-292B-411C-A3A3-EC176D8B2F4F Q36197751-E3E3104A-2842-471D-B721-37BD8DF19777 Q36198374-833E72A8-9AEC-410F-B00E-C88B9911B868 Q36199656-23F49C64-79C1-4333-8862-6C506A57B9C4 Q36200472-4A8170BE-D597-47BD-8610-D8D1284CD606 Q36203548-6F29C2F7-F1A8-4BBA-9765-10CF8B37D855 Q36203663-8148B732-0EF5-4DCD-BB2C-0BE4E66FD95B Q36204354-B0382C2F-81EA-4D04-9995-D61492803CFE Q36204771-26AAB134-433D-4E34-9DAC-BFC72E7EFABC Q36207064-E3AE8339-734A-4D38-A5EE-9CD336437491 Q36208664-8977A1A9-2D2B-4E92-902A-3CBE4D50ECE4 Q36211372-DC91A925-0497-4A54-855F-F4FE74418EF0 Q36211692-B97A9671-0C29-44CE-A164-7C3224C79E32 Q36212099-9447B27F-6568-44F6-88CA-A184FDEE8CD6 Q36269646-D526B848-4D17-464B-904E-B701CFA5A561 Q36655910-5A5E816B-30A2-4814-8080-FE5AB1186766 Q37583879-54336E3D-9458-468F-A172-FA81EF186F4E Q37882553-11838D36-CF67-4C54-BA80-A429292AF5C5 Q39696100-939510D1-18DF-4338-88C6-B066AF41B73C Q40117488-75676495-A811-444D-B29A-1A8F1C9C2EBC Q41233756-F9175B6B-EC87-412F-A9E2-2CD219191D04

P2860

Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation

http://www.wikidata.org/entity/Q31114481

description

1975 nî lūn-bûn

@nan

1975 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած

@hyw

1975 թվականի դեկտեմբերին հրատարակված գիտական հոդված

@hy

1975年の論文

@ja

1975年論文

@yue

1975年論文

@zh-hant

1975年論文

@zh-hk

1975年論文

@zh-mo

1975年論文

@zh-tw

1975年论文

@wuu

name

Microtubular origin of mitotic ...... icability of Wiener's equation

@ast

Microtubular origin of mitotic ...... icability of Wiener's equation

@en

type

label

Microtubular origin of mitotic ...... icability of Wiener's equation

@ast

Microtubular origin of mitotic ...... icability of Wiener's equation

@en

prefLabel

Microtubular origin of mitotic ...... icability of Wiener's equation

@ast

Microtubular origin of mitotic ...... icability of Wiener's equation

@en

P1433

Q31114481-79BD43BD-B8C8-47E6-A1FC-B8B887471136

P1476

Q31114481-E62AC164-5D80-4436-B68C-3F7D8E690D0A

P2093

Q31114481-2E35A166-E78D-4D89-A19F-1F206694B724

Q31114481-3429865A-D2E3-4688-A55B-19DB2E8BDE62

Q31114481-5FCD0B7B-372E-4958-BF1E-B18F5A4A2F45

P2860

Q31114481-0F61C968-7A84-4416-9E05-DF6B6FD7537E

Q31114481-1A7DE649-70DB-4395-AD01-79F86D49154B

Q31114481-2390DFC8-17C6-4D11-B901-20FDA1CB66DA

Q31114481-2CACAE06-929D-4615-BE62-3FBE0F7E4D9F

Q31114481-3EE130BC-ED0C-4811-B2A1-847C68561319

Q31114481-4398EC0A-FD8E-4E35-BF76-5DB3D67AAADB

Q31114481-452914A1-9B3D-4D26-BD1F-184FD8FF4735

Q31114481-4A87B8A3-94A3-4BC6-B662-658E52A0191B

Q31114481-4B2C1372-D456-4F58-A1D9-B4E7CCBE5CD7

Q31114481-5A1E79F7-5FD0-47EC-BBA6-1FAB403DE169

P304

Q31114481-65600DF4-3756-42AE-BEC1-0E17B2128942

P31

Q31114481-5D279732-ED9F-4CBE-8BD7-6AC315AC2722

P356

Q31114481-6E4A54C6-BB16-402B-BA77-034834C92141

P407

Q31114481-63F7C869-5F97-4146-807A-1ED18DD09A36

P433

Q31114481-3EE1D18C-9751-404C-9D8A-2BED0FD25DF6

P478

Q31114481-9EC23A15-C4F5-45BF-B944-53EC2F96E42E

P577

Q31114481-FAB9D4E0-BE58-4641-AA21-C0B7E8FE3A96

P5875

Q31114481-70B2BC84-9E29-4042-8339-F78C44F6B785

P698

Q31114481-F52C25F8-91F3-4829-880D-CAB7BE36AAA3

P921

Q31114481-B8048C54-F260-4B15-BBB3-3752007B57BF

P932

Q31114481-8E2850CA-0147-4C56-BC5C-BEDC776A4F49

P356

P1433

Journal of Cell Biology

P1476

Microtubular origin of mitotic ...... icability of Wiener's equation

@en

P2093

Ellis GW

http://www.w3.org/2001/XMLSchema#string

Inoué S

http://www.w3.org/2001/XMLSchema#string

Sato H

http://www.w3.org/2001/XMLSchema#string

P2860

Studies on depolarization of light at microscope lens surfaces. II. The simultaneous realization of high resolution and high sensitivity with the polarizing microscope.

FILAMENT LENGTHS IN STRIATED MUSCLE.

Functional organization of mitotic microtubules. Physical chemistry of the in vivo equilibrium system.

Birefringence of protein solutions and biological systems. I

Microtubules: evidence for 13 protofilaments.

The mitotic apparatus: isolation by controlled pH.

The mitotic apparatus. Structural changes after isolation.

Ultrastructure and birefringence of the isolated mitotic apparatus of marine eggs.

Intrinsic birefringence of glycerinated myofibrils.

Birefringence of spermatozoa. II. Form birefringence of bull sperm.

P304

501-517

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1083/JCB.67.3.501

http://www.w3.org/2001/XMLSchema#string

P407

P433

3

http://www.w3.org/2001/XMLSchema#string

P478

67

http://www.w3.org/2001/XMLSchema#string

P577

1975-12-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

277517103

http://www.w3.org/2001/XMLSchema#string

P698

1238403

http://www.w3.org/2001/XMLSchema#string

P921

P932

2111675

http://www.w3.org/2001/XMLSchema#string