Artificial embryo grown in a dish from two types of stem cells – New Scientist

By raymumme

By Andy Coghlan

Sarah Harrison and Gaelle Recher, Zernicka-Goetz Lab, University of Cambridge

Artificial mouse embryos grown from stem cells in a dish could help unlock secrets of early development and infertility that have until now evaded us.

Magdalena Zernicka-Goetz at the University of Cambridge and her team made the embryos using embryonic stem cells, the type of cells found in embryos that can mature into any type of tissue in the body.

The trick was to grow these alongside trophoblast stem cells, which normally produce the placenta. By growing these two types of cell separately and then combining them in a special gel matrix, the two mixed and started to develop together.

After around four-and-a-half days, the embryos resembled normal mouse embryos that were about to start differentiating into different body tissues and organs.

They are very similar to natural mouse embryos, says Zernicka-Goetz. We put the two types of stem cells together which has never been done before to allow them to speak to each other. We saw that the cells could self-organise themselves without our help.

This is the first time something resembling an embryo has been made from stem cells, without using an egg in some way. Techniques such as cloning, as done for Dolly the sheep and other animals, bypass the need for sperm, but still require an egg cell.

The artificial embryos are providing new insights into how embryos organise themselves and grow, says Zernicka-Goetz. The team engineered the artificial embryos so the cell types fluoresced in different colours, to reveal their movements and behaviour as the embryos go through crucial changes.

Mammal embryos were already known to start as a symmetrical ball, then elongate, form a central cavity and start developing a type of cell layer called mesoderm, which ultimately goes on to form bone and muscle.

We didnt know before how embryos form this cavity, but weve now found the mechanism for it and the sequential steps by which it forms, says Zernicka-Goetz. Its building up the foundations for the whole body plan.

The work is a great addition to the stem cell field and could be extended to human stem cell populations, says Leonard Zon at Boston Childrens Hospital, Massachusetts. Using the system, the factors that participate in embryo development could be better studied and this could help us understand early events of embryogenesis.

But Robin Lovell-Badge at the Francis Crick Institute in London says that the embryos lack two other types of cell layer required to develop the bodies organs: ectoderm, which forms skin and the central nervous system, and endoderm, which makes our internal organs.

Zernicka-Goetz hopes to see these types of cell layers develop in future experiments by adding stem cells that normally form the yolk sac, a third structure involved in embryonic development, to the mix.

If a similar feat can be achieved using human stem cells, this could tell us much about the earliest stages of our development. Current research is limited by the number of excess embryos that are donated from IVF procedures. But the new technique could produce a limitless supply, making it easier to conduct in-depth research. These artificial embryos may also be easier to tinker with, to see what effect different factors have in early embryogenesis.

Disrupting development in this way may provide new insights into the causes of abnormal embryo development and miscarriage. You would be able to understand the principles that govern each stage of development. These are not normally accessible, because they happen inside the mother, says Zernicka-Goetz.

But it is doubtful that this work could ever lead to fully grown babies in the lab. Lovell-Badge says the artificial embryos are unlikely to develop in vitro much further than shown in the study, as they would soon need the supply of nutrients and oxygen that a placenta normally channels from the mother.

Were not planning to make a mouse in the lab using stem cells, says Zernicka-Goetz. But she is hopeful that adding yolk sac stem cells will allow these artificial embryos to survive long enough to study the beginnings of organs like the heart.

Journal reference: Science, DOI: 10.1126/science.aal1810

Read more: Its time to relax the rules on growing human embryos in the lab

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