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Local 3D matrix confinement determines division axis through cell shape.


ABSTRACT: How the division axis is determined in mammalian cells embedded in three-dimensional (3D) matrices remains elusive, despite that many types of cells divide in 3D environments. Cells on two-dimensional (2D) substrates typically round up completely to divide. Here, we show that in 3D collagen matrices, mammalian cells such as HT1080 human fibrosarcoma and MDA-MB-231 breast cancer cells exhibit division modes distinct from their Counterparts on 2D substrates, with a markedly higher fraction of cells remaining highly elongated through mitosis in 3D matrices. The long axis of elongated mitotic cells accurately predicts the division axis, independently of matrix density and cell-matrix interactions. This 3D-specific elongated division mode is determined by the local confinement produced by the matrix and the ability of cells to protrude and locally remodel the matrix via ?1 integrin. Elongated division is readily recapitulated using collagen-coated microfabricated channels. Cells depleted of ?1 integrin still divide in the elongated mode in microchannels, suggesting that 3D confinement is sufficient to induce the elongated cell-division phenotype.

SUBMITTER: He L 

PROVIDER: S-EPMC4872764 | biostudies-literature | 2016 Feb

REPOSITORIES: biostudies-literature

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Local 3D matrix confinement determines division axis through cell shape.

He Lijuan L   Chen Weitong W   Wu Pei-Hsun PH   Jimenez Angela A   Wong Bin Sheng BS   San Angela A   Konstantopoulos Konstantinos K   Wirtz Denis D  

Oncotarget 20160201 6


How the division axis is determined in mammalian cells embedded in three-dimensional (3D) matrices remains elusive, despite that many types of cells divide in 3D environments. Cells on two-dimensional (2D) substrates typically round up completely to divide. Here, we show that in 3D collagen matrices, mammalian cells such as HT1080 human fibrosarcoma and MDA-MB-231 breast cancer cells exhibit division modes distinct from their Counterparts on 2D substrates, with a markedly higher fraction of cell  ...[more]

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