about
Viscoelastic properties of differentiating blood cells are fate- and function-dependentCytoskeletal interactions at the nuclear envelope mediated by nesprinsThe nuclear lamina is mechano-responsive to ECM elasticity in mature tissueLINC complexes mediate the positioning of cone photoreceptor nuclei in mouse retinaMammalian sperm head formation involves different polarization of two novel LINC complexesRemodeling of nuclear landscapes during human myelopoietic cell differentiation maintains co-aligned active and inactive nuclear compartmentsThe nuclear envelope at a glanceMyosin II Activity Softens Cells in Suspension.Retrotransposon Alu is enriched in the epichromatin of HL-60 cells.An epichromatin epitope: persistence in the cell cycle and conservation in evolutionNucleosome repositioning during differentiation of a human myeloid leukemia cell line.The nuclear envelope environment and its cancer connections.Nuclear deformability constitutes a rate-limiting step during cell migration in 3-D environmentsNuclear mechanics during cell migration.A monolithic glass chip for active single-cell sorting based on mechanical phenotyping.Neural maintenance roles for the matrix receptor dystroglycan and the nuclear anchorage complex in Caenorhabditis elegans.Differentiation and characterization of myeloid cells.Nuclear mechanics in diseaseMechanics of the nucleus.Altering lamina assembly reveals lamina-dependent and -independent functions for A-type lamins.Gene-rich chromosomal regions are preferentially localized in the lamin B deficient nuclear blebs of atypical progeria cells.Fibroblasts Lead the Way: A Unified View of 3D Cell MotilityShaping the nucleus: factors and forces.The LINC complex component Sun4 plays a crucial role in sperm head formation and fertility.Nuclear aggregation of olfactory receptor genes governs their monogenic expression.Bringing KASH under the SUN: the many faces of nucleo-cytoskeletal connections.Nuclear mechanics and mechanotransduction in health and disease.Nesprin-3: a versatile connector between the nucleus and the cytoskeleton.Extracellular matrix determinants and the regulation of cancer cell invasion stratagems.Expression of individual mammalian Sun1 isoforms depends on the cell type.Recent advances in understanding nuclear size and shape.Pondering neutrophil extracellular traps with healthy skepticism.Differential nuclear shape dynamics of invasive andnon-invasive breast cancer cells are associated with actin cytoskeleton organization and stability.Cooperative Activity of GABP with PU.1 or C/EBPε Regulates Lamin B Receptor Gene Expression, Implicating Their Roles in Granulocyte Nuclear Maturation.An in vitro model for Pelger-Huët anomaly: stable knockdown of lamin B receptor in HL-60 cells.Transcriptomes reflect the phenotypes of undifferentiated, granulocyte and macrophage forms of HL-60/S4 cells.Nuclear positioning in migrating fibroblasts.Nesprin interchain associations control nuclear size.Breaking the scale: how disrupting the karyoplasmic ratio gives cancer cells an advantage for metastatic invasion.CEBPE-Mutant Specific Granule Deficiency Correlates With Aberrant Granule Organization and Substantial Proteome Alterations in Neutrophils.
P2860
Q21134049-E6B20BDA-0DFB-4588-B1B3-4E3999F539CCQ24315854-294BC8B9-C033-4E69-A0D7-A4C6EB365A92Q26859120-050EE3F7-3882-4313-9E26-94CD92804588Q27314986-5BBDFB20-9FE1-4251-A9C5-239191C755ACQ27321735-C92CE2C8-41FB-47D5-8AB9-9DDE407D5662Q27327205-DE0B12D9-E76E-47E4-B945-72F99D2A55A7Q28284110-F67AA2F6-A6E0-4485-871D-DADAC4165DA7Q30385390-6A9479B6-E5FB-4519-80CB-B94C800182DEQ30413241-939706FA-A3DA-40F6-9D5A-AB5044D40DAAQ30500749-9B0D5015-A414-43A1-8A8D-CED60DD5893AQ33597493-81BED06E-537B-43DB-96AA-622200DDB243Q34254678-1117D361-E2A2-4CC0-9D86-7CA9E77F8769Q34568577-E68B34DF-A94F-4793-8147-68BED8387A04Q34777149-C2461D39-A287-4B00-B926-3A94D3D3A64DQ35533551-B5922E1B-ED48-4A7F-88F8-88431F607414Q35863078-D26D12EB-0473-49D9-9F7C-E673733EA53AQ35962551-1D6335E9-28BF-44E3-806B-6313BBA0B5E6Q36144958-60AD3084-2656-43FF-BF5E-398506935E96Q36144966-A6252647-4EEF-4827-A233-2088F3FB5ACDQ36175286-9B15B1B2-186E-4251-B88E-37B85AC49F70Q36191582-B9F945ED-AA30-40DD-A19E-FB4DDC30BFA2Q36236775-CACEE4FA-17A1-4BC6-98AA-9CC7E5C7F3C9Q36317158-69573B47-257F-4A76-9E33-E0C45EBF9FD5Q36529257-41EFA805-5FCA-4D6B-903F-B521CA37E07BQ36859527-6137B810-B693-482E-AE3F-19247A824280Q37323130-DD98ECD9-84AC-43C3-92AB-8A4E62AA22AAQ37444772-404FB334-A219-45F9-9861-E2A13417C15FQ37958963-8612F331-A8FE-4E19-9093-643195B71E6BQ38127246-73291E16-7E81-4700-B268-29A9C70E15D6Q38577276-16336D13-ED4D-4249-8464-306760A94C2FQ38768262-3AFF5152-85A1-41F5-8BA4-DE046BD777A5Q38912110-E9F7A558-994C-41B0-96C2-DBB5E662A683Q38972545-EF334832-830E-4568-A7EF-EEEC51172796Q41087937-90953A48-6533-4D8A-B447-E8BF1B68D413Q42580389-FBDF2737-E239-426D-B175-0C624659918AQ42775574-622FD66C-4FE7-4E54-9807-10E3A693654FQ47292878-D40E7933-6318-4870-A8D9-633C1B382803Q47306531-745F7394-A8D0-41C2-AF76-409F6242B293Q47390159-51EAF1DA-CBAB-4E7E-9CB2-108B53F14F17Q52322888-648F3AF2-63C8-4404-AE9F-FAC42B373491
P2860
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh
2008年學術文章
@zh-hant
name
The LINC-less granulocyte nucleus.
@en
The LINC-less granulocyte nucleus.
@nl
type
label
The LINC-less granulocyte nucleus.
@en
The LINC-less granulocyte nucleus.
@nl
prefLabel
The LINC-less granulocyte nucleus.
@en
The LINC-less granulocyte nucleus.
@nl
P2093
P2860
P1476
The LINC-less granulocyte nucleus.
@en
P2093
Ada L Olins
Angelika A Noegel
Didier Hodzic
Donald E Olins
Hanswalter Zentgraf
Harald Herrmann
Iakowos Karakesisoglou
Monika Zwerger
Thanh V Hoang
P2860
P304
P356
10.1016/J.EJCB.2008.10.001
P577
2008-11-18T00:00:00Z