Despite its apparent simplicity, a tube-like body topped with tentacles, the sea anemone is actually a highly complex creature. Scientists from the Institut Pasteur, in collaboration with the CNRS, have just discovered over 100 cell types in this small marine invertebrate as well as incredible neuronal diversity. This surprising complexity was revealed when the researchers built a real cell atlas of the animal. Their findings, which will add to discussions on how cells have diversified and developed into organs during evolution, have been published in the journal Cell.
The sea anemone Nematostella vectensis provides a perfect model for researchers—apart from its stinging tentacles, perhaps. It is a small marine invertebrate that is easy to keep in the laboratory, its genome is simple enough to study and close enough to that of humans for researchers to draw conclusions. "When the sea anemone genome was sequenced in 2007, scientists discovered that it was very similar to the human genome, both in terms of the number of genes (roughly 20,000) and its organization, explains Heather Marlow, a specialist in developmental biology in the (Epi)genomics of Animal Development Unit at the Institut Pasteur and the main author of this study.
Marlow says, "These similarities make the sea anemone an ideal model for studying the animal genome and understanding interactions existing between genes. It also has another advantage—its strategic position in the tree of life. The cnidaria branch that anemones belong to separated from the bilateria branch, in other words from most other animals, including humans, over 600 million years ago. "The anemone can therefore also help us to understand the origin and evolution of the multiple cell types making up the bodies and organs of animals, and particularly their nervous systems."
To try and understand a little more about sea anemones, and consequently about the whole animal kingdom, Marlow's team decided to examine this cnidarian at the cellular level. The researchers isolated the animal's tiny cells, which measure no more than 1 micron in diameter, and analyzed their RNA. Although chromosomal DNA contains all genes, RNA shows those that are active. "The development of genome approaches at single-cell level can be used to accurately list the different cell types and also identify the genes responsible for the function of each of these cells," explains Marlow. In total, over 100 cell types were identified, grouped into eight main cell families (muscle, digestive, neuronal, epidermal, etc.). And one of the greatest surprises of this research concerns the nervous system. Close to 30 types of neurons—peptidergic, glutamatergic or even insulinergic—were identified, revealing a relatively complex nervous and sensory system.
This research should therefore help evolution specialists to establish the common ancestor of cnidaria (anemones) on the one hand, and bilateria (humans) on the other. Undoubtedly, this ancestor already had some level of cell complexity. In addition, even though the sea anemone appears to be very different from us, it reveals the fundamental rules that today enable its cells, and our own, to perform so many different functions. "The cell is the basic element making up living beings." By defining how the information coded by the genome determines the identity of each cell, we hope to uncover the mechanisms conserved by all animals that are essential for their development and homeostasis," concludes Heather Marlow.
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Arnau Sebé-Pedrós et al, Cnidarian Cell Type Diversity and Regulation Revealed by Whole-Organism Single-Cell RNA-Seq, Cell (2018). DOI: 10.1016/j.cell.2018.05.019