Abstract
BackgroundNuclear size and shape are specific to a cell type, function, and location, and can serve as indicators of disease and development. We previously found that lamin A/C and associated nuclear envelope structural proteins were upregulated when murine embryonic stem (ES) cells differentiated to primitive endoderm cells. Here we further investigated the morphological changes of nuclei that accompany this differentiation.ResultsThe nuclei of undifferentiated wild type cells were found shaped as flattened, irregular ovals, whereas nuclei of Gata4-positive endoderm cells were more spherical, less flattened, and with a slightly reduced volume. The morphological change was confirmed in the trophectoderm and primitive endoderm lineages of E4.5 blastocysts, compared to larger and more irregularly shaped of the nuclei of the inner cell mass. We established ES cells genetically null for the nuclear lamina proteins lamin A/C or the inner nuclear envelope protein emerin, or compound mutant for both lamin A/C and emerin. ES cells deficient in lamin A/C differentiated to endoderm but less efficiently, and the nuclei remained flattened and failed to condense. The size and shape of emerin-deficient nuclei also remained uncondensed after treatment with RA. The emerin/lamin A/C double knockout ES cells failed to differentiate to endoderm cells, though the nuclei condensed but retained a generally flattened ellipsoid shape. Additionally, ES cells deficient for lamin A/C and/or emerin had compromised ability to undergo endoderm differentiation, where the differentiating cells often exhibited coexpression of pluripotent and differentiation markers, such as Oct3/4 and Gata4, respectively, indicating an infidelity of gene regulation.ConclusionsThe results suggest that changes in nuclear size and shape, which are mediated by nuclear envelope structural proteins lamin A/C and/or emerin, also impact gene regulation and lineage differentiation in early embryos. Nevertheless, mice lacking both lamin A/C and emerin were born at the expected frequency, indicating their embryonic development is completed despite the observed protein deficiency.
Highlights
Nuclear size and shape are specific to a cell type, function, and location, and can serve as indicators of disease and development
We found that the nuclear structure of embryonic stem (ES) cells undergoes morphological change concomitant with differentiation [27], in particular, the space between the inner nuclear membrane (INM) and outer nuclear membrane (ONM) diminishes upon differentiation, and an increased nesprin-1 expression was shown to be the cause of the nuclear envelope structural changes
Nuclear shape change during embryonic stem cell differentiation in culture Our initial motivation for the current study was prompted by observations of a striking nuclear size change observed during the differentiation of ES cells in culture
Summary
Nuclear size and shape are specific to a cell type, function, and location, and can serve as indicators of disease and development. We further investigated the morphological changes of nuclei that accompany this differentiation. The shape and size of a nucleus are particular to a cell type, function, and cell location [1,2,3]. Nuclear shape can change with age [4], and abnormalities in nuclear morphology serve as indicators of diseases, especially cancer [5,6,7,8,9]. Changes in the nuclear size and shape associate with cell differentiation and development [8, 10]
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