Proteomics

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Proteome changes to primary human MSCs subjected to high-intensity cyclic tensile strain (CTS) aligned to SUN2 overexpressing samples


ABSTRACT: Our current understanding of cellular mechano-signalling is based on static models, which do not replicate the dynamics of living tissues. Here, we examined the time-dependent response of primary human mesenchymal stem cells (hMSCs) to cyclic tensile strain (CTS). At low-intensity strain (1 hour, 4% CTS at 1 Hz) morphological changes mimicked responses to increased substrate stiffness. As the strain regime was intensified (frequency increased to 5 Hz), we characterised rapid establishment of a broad, structured and reversible protein-level response, even as transcription was apparently downregulated. Protein abundance was regulated coincident with changes to protein conformation and post transcriptional modification. Furthermore, we characterised changes within the linker of nucleo- and cytoskeleton (LINC) complex of proteins that bridges the nuclear envelope, and specifically to levels of SUN domain-containing protein 2 (SUN2). The result of this regulation was to decouple mechano-transmission between the cytoskeleton and the nucleus, thus conferring protection to chromatin.

INSTRUMENT(S): Q Exactive

ORGANISM(S): Homo Sapiens (human)

TISSUE(S): Multipotent Stem Cell, Bone Marrow

SUBMITTER: Venkatesh Mallikarjun  

LAB HEAD: Joe Swift

PROVIDER: PXD012873 | Pride | 2019-04-24

REPOSITORIES: Pride

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20190215_SwiftJ_GilbertH_01.raw Raw
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Publications

Nuclear decoupling is part of a rapid protein-level cellular response to high-intensity mechanical loading.

Gilbert Hamish T J HTJ   Mallikarjun Venkatesh V   Dobre Oana O   Jackson Mark R MR   Pedley Robert R   Gilmore Andrew P AP   Richardson Stephen M SM   Swift Joe J  

Nature communications 20190912 1


Studies of cellular mechano-signaling have often utilized static models that do not fully replicate the dynamics of living tissues. Here, we examine the time-dependent response of primary human mesenchymal stem cells (hMSCs) to cyclic tensile strain (CTS). At low-intensity strain (1 h, 4% CTS at 1 Hz), cell characteristics mimic responses to increased substrate stiffness. As the strain regime is intensified (frequency increased to 5 Hz), we characterize rapid establishment of a broad, structured  ...[more]

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