Successful Stem Cell Differentiation Requires DNA Compaction
Friday, 11 May 2012
New research findings show that embryonic stem cells unable to fully compact the DNA inside them cannot complete their primary task: differentiation into specific cell types that give rise to the various types of tissues and structures in the body.
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This image shows hematoxylin and eosin
staining of sections of wild-type (top row)
and H1 triple-knockout (bottom row) embryoid
bodies. After 14 days in rotary suspension
culture, the wild-type embryoid bodies showed
more differentiated morphologies with cysts
forming (black arrows) and the knockout
embryoid bodies failed to form cavities (far
right). Credit: Yuhong Fan.
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A study published on May 10, 2012 in the journal PLoS Genetics found that embryonic stem cells lacking several histone H1 subtypes and exhibiting reduced chromatin compaction suffered from impaired differentiation under multiple scenarios and demonstrated inefficiency in silencing genes that must be suppressed to induce differentiation.
"While researchers have observed that embryonic stem cells exhibit a relaxed, open chromatin structure and differentiated cells exhibit a compact chromatin structure, our study is the first to show that this compaction is not a mere consequence of the differentiation process but is instead a necessity for differentiation to proceed normally," said Yuhong Fan, an assistant professor in the Georgia Tech School of Biology.
Fan and Todd McDevitt, an associate professor in the Wallace H. Coulter Department of Biomedical Engineering at Georgia Tech and Emory University, led the study with assistance from Georgia Tech graduate students Yunzhe Zhang and Kaixiang Cao, research technician Marissa Cooke, and postdoctoral fellow Shiraj Panjwani.
The work was supported by the National Institutes of Health's National Institute of General Medical Sciences (NIGMS), the National Science Foundation, a Georgia Cancer Coalition Distinguished Scholar Award, and a Johnson & Johnson/Georgia Tech Healthcare Innovation Award.
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These are phase contrast images showing
that
H1 triple-knockout (bottom) embryonic stem
cells were unable to adequately form neurites
and neural networks compared to wild-type
embryonic stem cells (top). Credit: Yuhong
Fan.
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"This study has uncovered a new, regulatory function for histone H1, a protein known mostly for its role as a structural component of chromosomes," said Anthony Carter, who oversees epigenetics grants at NIGMS.
"By showing that H1 plays a part in controlling genes that direct embryonic stem cell differentiation, the study expands our understanding of H1's function and offers valuable new insights into the cellular processes that induce stem cells to change into specific cell types."
During spontaneous differentiation, the majority of the H1 triple-knockout embryonic stem cells studied by the researchers retained a tightly packed colony structure typical of undifferentiated cells and expressed high levels of Oct4 for a prolonged time. Oct4 is a pluripotency gene that maintains an embryonic stem cell's ability to self-renew and must be suppressed to induce differentiation.
"H1 depletion impaired the suppression of the Oct4 and Nanog pluripotency genes, suggesting a novel mechanistic link by which H1 and chromatin compaction may mediate pluripotent stem cell differentiation by contributing to the epigenetic silencing of pluripotency genes," explained Fan.
"While a significant reduction in H1 levels does not interfere with embryonic stem cell self-renewal, it appears to impair differentiation."
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This image shows immunostaining of
wild-type
(top) and H1 triple-knockout (bottom) cultures
under a neural differentiation protocol. The H1
triple-knockout cells were defective in forming
neuronal and glial cells and a neural network,
which is essential for nervous system
development. Credit: Yuhong Fan.
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"H1 triple-knockout embryoid bodies displayed a reduced level of activation of many developmental genes and markers in rotary culture, suggesting that differentiation to all three germ layers was affected." noted McDevitt.
The embryoid bodies also lacked the epigenetic changes at the pluripotency genes necessary for differentiation, according to Fan.
"When we added one of the deleted H1 subtypes to the embryoid bodies, Oct4 was suppressed normally and embryoid body differentiation continued," explained Fan.
"The epigenetic regulation of Oct4 expression by H1 was also evident in mouse embryos."
In another experiment, the researchers provided an environment that would encourage embryonic stem cells to differentiate into neural cells. However, the H1 triple-knockout cells were defective in forming neuronal and glial cells and a neural network, which is essential for nervous system development. Only 10 percent of the H1 triple-knockout embryoid bodies formed neurites and they produced on average eight neurites each. In contrast, half of the normal embryoid bodies produced, on average, 18 neurites.
In future work, the researchers plan to investigate whether controlling H1 histone levels can be used to influence the reprogramming of adult cells to obtain induced pluripotent stem cells, which are capable of differentiating into tissues in a way similar to embryonic stem cells.
Contact: Abby Robinson
Reference:
Histone H1 Depletion Impairs Embryonic Stem Cell Differentiation
Yunzhe Zhang, Marissa Cooke, Shiraj Panjwani,Kaixiang Cao, Beth Krauth, Po-Yi Ho, Magdalena Medrzycki, Dawit T. Berhe, Chenyi Pan, Todd C. McDevitt, Yuhong Fan
PLoS Genet 8(5): e1002691. doi:10.1371/journal.pgen.1002691
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