Long suffering readers of this blog will recall our occasional sallies into the remote past. Like some latter day Doug McClure we occasionally take you into a world stuffed with dinosaurs, ape men and pterodactyls, to the detriment of more relevant stuff on antibiotics or the US Ten Year Bond. And so, although we were privately raving about this piece below called How did life get multicellular? from Nature Briefing, we thought we ‘d spare you from our private obsessions about things that took place between 800 -600 million years ago.
Until a chance encounter with one of more intelligent friends in the car park at our Spanish Conversation group produced the most inspiring thought. “All those Choanoflagellates. protometazoans. Filasterea. whatever, have to do several things if they are to succeed in living together. To glue up to each other. To signal little messages. To co-ordinate the cycles of cell division. Just like cancer cells have to, in fact. And then it hit us. These funny little organisms are the perfect way to model the behaviour of cancer cells. Not just the molecular and genetic mechanisms, but also the Information and Complexity models we must build to understand them: a cancer cell is a typical metazoan cell gone wrong.
Which confirmed a very old principle of this blog. All research however abstruse it may seem, will have a pay off somewhere one day. If it doesn’t benefit the economy, it will make us live longer; sometimes it may do both. These researchers are not just having fun on the edge of time: they may be contributing directly to the study of a disease which will kill half of us. There’s a thought for anyone who wants to cut university budgets or meddle with the findings of scientists.
To play out we shall first post the Nature Briefing paragraph. If you can get past that we’ve some supporting evidence for our basic proposition. We hope both will inform
Across all forms of life, the move from being single-celled to multicellular seems to have happened dozens of times — for animals, though, the jump was one-and-done. The unique cocktail of environmental and genetic factors that helped animal ancestors make that jump still eludes our understanding. To investigate, researchers are focussing on unicellular organisms that ‘dabble’ in multicellularity, occasionally forming colonies of many cells. By studying these organisms as they flit between the two states, scientists are hoping to illuminate how multicellularity stuck in animals — and what sparked the single successful event that gave rise to the animal kingdom.Nature | 11 min read
ASTRACT BECOMES APPLIED
This work discusses how cancer disrupts the gene regulatory networks (GRNs) that evolved to coordinate multicellular life. These networks balance genes inherited from unicellular ancestors (handling basics like metabolism and division) with newer multicellular genes (handling coordination, differentiation, and tissue integrity). https://genomebiology.biomedcentral.com/articles/10.1186/s13059-024-03247-1
and this how somatic mutations in early metazoan genes specifically disrupt the regulatory links between unicellular and multicellular gene networks. The result? Tumours behave like rogue unicellular entities, ignoring the cooperative rules of multicellularity. Some of these disrupted genes even correlate with drug response, hinting at therapeutic relevance
thanks to R Muggridge
https://elifesciences.org/articles/40947
#cancer #evolution #multicellularity #medicine #health #choanoflagellates
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