Scale invariance in early embryonic development

Article

Nikolic, Milos; Antonetti, Victoria; Liu, Feng; Muhaxheri, Gentian; Petkova, Mariela D.; Scheeler, Martin; Smith, Eric M.; Bialek, William; Gregor, Thomas

Princeton University; Princeton University; City University of New York (CUNY) System; Lehman College (CUNY); Hebei University of Technology; Harvard University; Pasteur Network; Universite Paris Cite; Institut Pasteur Paris

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA

0027-14367

10.1073/pnas.2403265121

2024-11-12

The expression of a few key genes determines the body plan of the fruit fly. We show that the spatial expression patterns for several of these genes scale precisely with embryo size. Discrete positional markers such as the peaks in striped patterns or the boundaries of expression domains have positions along the embryo's major axis proportional to embryo length, accurate to within 1%. Further, the information (in bits) that graded patterns of expression provide about a cell's position can be decomposed into information about fractional or scaled position and information about absolute position or embryo length; all information available is about scaled position, with < 2% error. These findings imply that the underlying genetic network's behavior exhibits scale invariance in a more precise mathematical sense. We argue that models that can explain this scale invariance also have a zero mode in the dynamics of gene expression, and this connects to observations on the spatial correlation of fluctuations in expression levels.