Physical Influence on the Trajectory of Nascent Multicellular Evolution

Shane Jacobeen; Thomas Day; Elyes Graba; Colin Brandys; Jennifer Pentz; David Yanni; William Ratcliff; Peter Yunker

Physical Influence on the Trajectory of Nascent Multicellular Evolution

ORAL

Abstract

The evolution of multicellularity transformed life on earth by setting the stage for all higher orders of organismal complexity; yet many critical aspects of this transition remain poorly understood. Using experimental evolution of snowflake yeast^1,2, we study the role of physics in this fundamental evolutionary process. Under selection for large size, nascent multicellular snowflake yeast clusters evolve increased fitness along trajectories that are highly physically efficient. Further, we find that a physically challenging environment impedes the evolution of increased cluster fitness. Thus we demonstrate the significant role played by physical constraints in the evolution of nascent multicellularity.

¹W. Ratcliff et al. 2012. PNAS. 109:1959–1600.

²W. Ratcliff et al. 2015. Nature Communications. 6:6102.

^*NASA Exobiology grant no. NNX15AR33G to William C. Ratcliff;
NSF grant no. IOS-1656549 to William C. Ratcliff and Peter J.Yunker;
Packard Foundation Fellowship for William C. Ratcliff

March 8, 2018, 5:18 PM – March 8, 2018, 5:30 PM

Presenters

Shane Jacobeen
- Physics, Georgia Inst of Tech

Authors

Shane Jacobeen
- Physics, Georgia Inst of Tech
Thomas Day
- Physics, Georgia Inst of Tech
Elyes Graba
- Physics, Georgia Inst of Tech
Colin Brandys
- Physics, Georgia Inst of Tech
Jennifer Pentz
- School of Biological Sciences, Georgia Institute of Technology
David Yanni
- Physics, Georgia Inst of Tech
- Physics, Georgia Institute of Technology
William Ratcliff
- School of Biological Sciences, Georgia Institute of Technology
Peter Yunker
- Physics, Georgia Inst of Tech
- Physics, Georgia Institute of Technology
- Georgia Inst of Tech