国产精品国产精品一区精品国产自在现偷99精品国产在热2019国产拍偷精品网国产精品视频全国免费观看,国产精品v欧美精品v日韩精品青青精品视频国产久久国产精品久久精品国产亚洲精品国产精品国产欧美精品一区二区三区,国产精品第一页国产亚洲精品国产福利国产精品自拍国产精品视频在线观看亚洲国产精品一区二区久久国产精品国产三级国产专不,国产精品视频大陆精大陆国产国语精品2019精品国产品对白在线285年香蕉精品国产高清自在自线隔壁老王国产在线精品在线观看精品国产福利片,国产三级精品三级在专区精品国产自在现偷国产精品一区二区三区国产日韩精品欧美一区喷水亚洲精品国产精品国自产国产在线精品一区二区不卡

熱門搜索:A549    293T 金黃色葡萄球菌 大腸桿菌 AKK菌
購(gòu)物車 1 種商品 - 共0元
當(dāng)前位置: 首頁(yè) > 行業(yè)資訊 > Landmark study signals shift in thinking about stem cell dif

Landmark study signals shift in thinking about stem cell dif

 Date:

June 20, 2019
Source:
Florida State University
Summary:

Researchers found that embryonic stem cells commit to a cell fate far more rapidly than anticipated.

A pioneering new study led by Florida State University biologists could fundamentally change our understanding of how embryonic stem cells differentiate into specific cell types.

The research, published today in the journal Stem Cell Reports, calls into question decades of scientific consensus about the behavior of embryonic stem cells as they transition to endoderm, a class of cell in animal embryos that gives rise to the digestive and respiratory systems.

David M. Gilbert, the J. Herbert Taylor Distinguished Professor of Molecular Biology in FSU's Department of Biological Science, said the study upends well-established notions of when embryonic stem cells chart their unalterable courses toward a fixed endoderm lineage -- in this case, their eventual fate as specific digestive or respiratory cells.

"This paper challenges the longstanding assumption that embryonic stem cells remain quite plastic and malleable during the earliest stages of cell commitment," Gilbert said. "We show that human embryonic stem cells can commit irreversibly to endoderm lineages -- liver and pancreas cells, for example -- very quickly."

The findings represent a new chapter in the study of embryonic stem cell differentiation, a field that could be key to helping scientists and clinicians unlock improved therapies for a range of diseases.

Using a sophisticated protocol developed by the San Diego-based regenerative medicine firm ViaCyte, Gilbert and his collaborators exposed a sample of embryonic stem cells to culture conditions engineered to nudge the cells into the definitive endoderm stage, a fast lane to specialized cell development. The team then quickly returned the cells to a bath of treatment factors designed to restore them to an embryonic state.

Based on previous studies, the researchers presumed it would take days in the endoderm culture, or at least a full cell division cycle, for the cells to commit to a developmental track.

"In fact, we found that after only a few hours exposure to the endoderm cocktail -- a fraction of a cell division cycle -- the cells could be returned to the stem cell cocktail and continue to go through the same series of gene expression changes as the control cells that remained in the endoderm cocktail."

In other words, after a remarkably short soak in the endoderm culture, the cells had committed full bore to a specific cellular program.

"Prior to the experiments reported here, there was no expectation that early stem cell lineage commitment would be so rapid and irreversible," Gilbert and his co-authors wrote in their paper.

This wasn't the only entrenched assumption challenged by the team's study. Scientists long believed the 3D organization of chromosomes in the nucleus to be both exceptionally rigid and closely linked to replication timing -- the order in which segments of DNA are copied before cell division. It was thought that the only way to reconfigure that architecture was to crack open a cell's nucleus when its chromosomes were being delivered to its daughter cells.

It turns out those assumptions may have been misguided as well.

"We show that chromosome architecture can be remodeled locally and rapidly without dismantling the entire cell nucleus -- akin to changing the scaffolding of a building without tearing it down -- which was quite unexpected," Gilbert said. "We also show that these changes in chromosome architecture occur dynamically and immediately upon stimulation of stem cells to become endoderm. This finding demonstrates that replication and architecture do not always go hand in hand, they can be what we call 'uncoupled.'"

The researchers' work delinking replication timing from chromosome architecture and showing the ability to surgically remodel that architecture could help refine scientists' understanding of embryonic stem cell behavior. Along with the discovery that stem cell lineage commitment occurs more rapidly and irreversibly than expected, Gilbert said the findings raise critical questions about the basic nature of stem cells and the barriers to turning one cell into another.

If researchers can harness these newly acquired insights, they could begin unraveling the mysteries of how and why stem cells commit to their developmental tracks and why certain cells are especially difficult to reprogram.

That information could inform the creation of new, powerful tools to combat disease and allay human suffering.

"The fact that large changes in genome organization and their temporal order of replication can be remodeled so easily, and that this is correlated with irreversible commitment so quickly in a cell culture system in the laboratory, means that we might be able to use this system to get at the mechanisms that represent irreversible commitment," Gilbert said. "We never anticipated that -- we expected irreversible commitment to take a lot more work, time and expense."

Scientists from ViaCyte, Emory University and the University of Georgia contributed to this study. The research was funded by the National Institutes of Health.

Story Source:

Materials provided by Florida State UniversityNote: Content may be edited for style and length.


Journal Reference:

  1. Vishnu Dileep, Korey A. Wilson, Claire Marchal, Xiaowen Lyu, Peiyao A. Zhao, Ben Li, Axel Poulet, Daniel A. Bartlett, Juan Carlos Rivera-Mulia, Zhaohui S. Qin, Allan J. Robins, Thomas C. Schulz, Michael J. Kulik, Rachel Patton McCord, Job Dekker, Stephen Dalton, Victor G. Corces, David M. Gilbert. Rapid Irreversible Transcriptional Reprogramming in Human Stem Cells Accompanied by Discordance between Replication Timing and Chromatin CompartmentStem Cell Reports, 2019; DOI: 10.1016/j.stemcr.2019.05.021
广汉市| 麦盖提县| 龙岩市| 广元市| 白朗县| 尼勒克县| 兰坪| 清丰县| 东明县| 昌平区| 丰台区| 彭泽县| 乌兰浩特市| 长丰县| 华蓥市| 西峡县| 尼勒克县| 电白县| 岳西县| 孝感市| 阳西县| 紫云| 旅游| 嘉鱼县| 黄平县| 咸宁市| 杭州市| 普格县| 阿拉善右旗| 金山区| 孟州市| 托克托县| 绥棱县| 沂南县| 宜城市| 万载县| 绥滨县| 沽源县| 仙桃市| 定日县| 全南县|