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The Acrasis kona genome and developmental transcriptomes reveal deep origins of eukaryotic multicellular pathways

Sanea Sheikh, Cheng-Jie Fu, Matthew W. Brown and Sandra L. Baldauf ()
Additional contact information
Sanea Sheikh: Uppsala University
Cheng-Jie Fu: Uppsala University
Matthew W. Brown: Mississippi State University
Sandra L. Baldauf: Uppsala University

Nature Communications, 2024, vol. 15, issue 1, 1-19

Abstract: Abstract Acrasids are amoebae with the capacity to form multicellular fruiting bodies in a process known as aggregative multicellularity (AGM). This makes acrasids the only known example of multicellularity among the earliest branches of eukaryotes (the former Excavata). Here, we report the Acrasis kona genome sequence plus transcriptomes from pre-, mid- and post-developmental stages. The genome is rich in novelty and genes with strong signatures of horizontal transfer, and multigene families encode nearly half of the amoeba’s predicted proteome. Development in A. kona appears molecularly simple relative to the AGM model, Dictyostelium discoideum. However, the acrasid also differs from the dictyostelid in that it does not appear to be starving during development. Instead, developing A. kona appears to be very metabolically active, does not induce autophagy and does not up-regulate its proteasomal genes. Together, these observations strongly suggest that starvation is not essential for AGM development. Nonetheless, development in the two amoebae appears to employ remarkably similar pathways for signaling, motility and, potentially, construction of an extracellular matrix surrounding the developing cell mass. Much of this similarity is also shared with animal development, suggesting that much of the basic tool kit for multicellular development arose early in eukaryote evolution.

Date: 2024
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DOI: 10.1038/s41467-024-54029-z

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