Research results in cells that may facilitate advances in organ regeneration

cells
Credit: CC0 Public Domain

In a world-first, scientists from BGI-Research, Chinese Academy of Sciences, and a group of partners published a study in Nature, announcing the discovery of a transgene-free, rapid, and controllable method to convert pluripotent stem-cells into bona fide 8-cell totipotent embryo-like cells, paving the way for advances in organ regeneration and synthetic biology.

BGI researchers, together with an international team from China, Bangladesh, and the UK, used BGI’s advanced single-cell sequencing technologies to help convert pluripotent stem cells, or an “adult” version of early embryonic cells, into a more “juvenile” version of cells that capture human zygotic genome activation and retain all lineage with developmental potential.

These cells could be used in regenerative medicine in the future to regenerate human organs that have become diseased and reduce the world’s reliance on organ donation. They can also be used to generate artificial blastocysts or blastoids. In addition, they will be useful for studying human embryonic development, helping to treat early developmental-related diseases and also prevent pregnancy loss.

While the technology to convert pluripotent stem cells into inner cell mass-like cells inside the blastocyst has existed for some time, this study is the first time researchers established methods to convert pluripotent stem cells to a bona fide earlier stage in the cycle of human development that matches the 8-cell embryo, which will help to expand understanding of early human embryonic development. Crucially, the researchers were able to then demonstrate that the converted cells could create placental cells in vivo—the first time this has been done.

“Totipotent 8-cell stage embryo-like cells recreate the embryonic state of a fertilized egg after only 3 divisions. Compared to the reported pluripotent stem cells, these cells can not only differentiate into placental tissue, but also potentially develop into more mature organs, bringing good news to the millions of patients in need of organ transplants around the world, ” said the corresponding authors of the paper, Professor Miguel A. Esteban, Dr. Md. Abdul Mazid and Dr. Li Wenjuan from the Chinese Academy of Sciences.

“This breakthrough is also a perfect example of the combination of regenerative medicine and single-cell sequencing technology,” said Dr. Liu Longqi of BGI-Research, another corresponding author of the paper. “Through large-scale single-cell multi-omics profiling, the efficient and precise identification of cells or tissues obtained in vitro or in vivo by stem cell technologies will greatly accelerate researches on regenerative medicine.”

Cells at this early stage of development can be described as “totipotent,” meaning they have the potential to create all type of early embryonic cells, which in turn create the tissues and organs necessary for development. The research builds on previous work with pluripotent stem cells at the blastocyst stage, a point at which cells have the potential to create a more limited range of different cells and tissues.

The study’s breakthrough was facilitated by advances in single-cell sequencing technology in which BGI Group is a world leader. Its single-cell library sequencing platform, combined with its sequencing technology, enable extensive and multi-dimensional single-cell analysis with high sensitivity and accuracy at a low cost. 

The international team behind the research took pluripotent stem cells and treated them with a chemical cocktail to create the 8-cell embryo-like cells. Among other experiments, these cells were sorted and injected into a mouse to undergo further development, and then analyzed using BGI’s single-cell genomic analysis. This innovative technology helped scientists to identify and isolate the target 8-cell embryo-like cells and demonstrate their “totipotent” ability to create the cells involved in generating the placenta in vivo.

The advances being made by the researchers could eventually make individualized organ regeneration a reality. Typically, the only avenue available for those in need of organ transplantation is finding a matching donor. The procedure is not fool proof. Transplants can fail if the donor’s serotype is too different from the recipient. A separate procedure designed to adapt animal organs for transplantation to humans through gene editing is also in its infancy.

This achievement also provides a new in vitro research system for basic research on early embryonic development, helps us understand the relationship between early embryonic development and disease occurrence, and a resource for the study and treatment of birth defects and various developmental diseases.


Stem cell model for early human embryo development


More information:
Miguel Esteban, Rolling back of human pluripotent stem cells to an 8-cell embryo-like stage, Nature (2022). DOI: 10.1038/s41586-022-04625-0

Provided by
BGI Group

Citation:
Research results in cells that may facilitate advances in organ regeneration (2022, March 21)
retrieved 22 March 2022
from https://phys.org/news/2022-03-results-cells-advances-regeneration.html

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.

For all the latest Science News Click Here 

 For the latest news and updates, follow us on Google News

Read original article here

Denial of responsibility! TheDailyCheck is an automatic aggregator around the global media. All the content are available free on Internet. We have just arranged it in one platform for educational purpose only. In each content, the hyperlink to the primary source is specified. All trademarks belong to their rightful owners, all materials to their authors. If you are the owner of the content and do not want us to publish your materials on our website, please contact us by email – [email protected] The content will be deleted within 24 hours.