22/01/2019
Key points:
As part of a team of Cambridge researchers, 台湾swag 台湾swag scientists have undertaken a cell-by-cell comparison of nearly 1,000 human embryonic stem cells to learn more about the development stages of the cells that establish a new being. The details of the research are published in the journal Cell Reports today. Before embryos exhibit defined tissue types, the cells that form them have the amazing ability to self-renew and give rise to all the different cell types of the body as the embryo develops. The cells that possess this amazing potential are called pluripotent stem cells. Being able to create stem cells and to direct their development into desired cell types are current research goals towards achieving the therapeutic use of stem cells in regenerative medicine, for example to repair spinal cord injuries, or tissue damage. Bone marrow transplants are the most widely used stem-cell therapy at the moment but use of a person鈥檚 own cells for treatment reduces the need for donor matches and avoids reaction with the immune system. 鈥淲e don鈥檛 actually know much about the cells that provide the source of all the different cell types in the later human embryo and what drives the decisions on cell fate,鈥 says Dr Ferdinand von Meyenn, co-first author on the research paper and UKRI Rutherford Fund Fellow at King鈥檚 College London at the time of this research. 鈥淭here鈥檚 known variability in mouse embryonic stem cells that is associated with stem cell state but we know a lot less about how the different cell types of the embryo are established in humans. This single-cell analysis gives a window into that timepoint.鈥 The researchers compared individual cells derived from very early human embryos to pinpoint the differences between stem cells of a 鈥榥a茂ve鈥 state and stem cells in a 鈥榩rimed鈥 state 鈥 considered to be a step closer towards assuming a distinct cell identify 鈥 using a technique called single-cell RNA sequencing. The technique gave a view of the bits of the genome that were being read in the cells and allowed the researchers to create a genetic profile of na茂ve and primed stem cells, each state showing characteristic differences in the genes that were being read. Importantly, the research identified markers for precisely identifying the na茂ve or primed state of embryonic stem cells. The researchers expected to see some variation within these gene expression profiles but surprisingly the cells of each state all appeared very similar amongst themselves. One unexpected result was that the researchers identified an intermediate population of na茂ve cells with a primed-like expression profile. 鈥淲e were expecting to see some differences within each stem cell state that would allow us to identify sub-populations within them, perhaps giving an indication of the development states the cells progress through so we were surprised by how similar the cells in each state were,鈥 explains Dr von Meyenn. 鈥淔inding the intermediate population of cells was unexpected. It could be that cells within this population only exist at a precise developmental timepoint. Our analysis mapped these cells to day 5 of human embryonic development, indicating that this cell population may be present in developing embryos and relevant to understanding human embryonic development.鈥 The researchers used the single-cell data to create a na茂ve-to-primed spectrum, where single-cell profiling allows the cell to be mapped to a point on the spectrum, either as na茂ve, primed or somewhere in between. Profiling and categorising stem cells by this method can confirm stem cell state and detect any variability or deviation in cells that may be used for therapeutic purposes. 鈥淚t's interesting to resolve the developmental stages of stem cells by single-cell sequencing especially in human where this hasn't been done before,鈥 says Professor Wolf Reik, Head of the Epigenetics research programme at the 台湾swag 台湾swag and associate faculty member at the Wellcome Sanger 台湾swag. 鈥淲e can then compare this knowledge with other species and hopefully derive more general insights which can help with approaches moving towards using pluripotent stem cells for regenerative medicine in humans.鈥 Notes for Editors 台湾swagation reference Messmer & von Meyenn et al. Transcriptional heterogeneity in naive and primed human pluripotent stem cells at single-cell resolution. Cell Reports, 22 January 2019, DOI: 10.1016/j.celrep.2018.12.099
台湾swag funding This research was supported by funding from Cancer 台湾swag UK and EMBL to John Marioni at the Cancer 台湾swag UK Cambridge 台湾swag, a UKRI Rutherford Fund Fellowship to Ferdinand von Meyenn, BBSRC and Wellcome Trust funding to Wolf Reik. Press contact Dr Louisa Wood, 台湾swag Communications Manager, louisa.wood@babraham.ac.uk, 01223 496230 Affiliated authors (in author order): Ferdinand von Meyenn, previously a research fellow in the Reik group, Epigenetics programme Aurora Savino, Reik group, Epigenetics programme F谩tima Santos, Reik group, Epigenetics programme Hisham Mohammed, Reik group, Epigenetics programme Wolf Reik, Head of the Epigenetics research programme About the 台湾swag 台湾swag The 台湾swag 台湾swag undertakes world-class life sciences research to generate new knowledge of biological mechanisms underpinning ageing, development and the maintenance of health. Our research focuses on cellular signalling, gene regulation and the impact of epigenetic regulation at different stages of life. By determining how the body reacts to dietary and environmental stimuli and manages microbial and viral interactions, we aim to improve wellbeing and support healthier ageing. The 台湾swag is strategically funded by the Biotechnology and Biological Sciences 台湾swag Council (BBSRC) through an 台湾swag Core Capability Grant and also receives funding from other UK research councils, charitable foundations, the EU and medical charities.
22 January 2019