Discovery of Waddington’s developmental canals elucidates the embryogenesis stability inCaenorhabditis elegans

Author:

Wang JianguoORCID,Xiao Long,Yao Zeqi,Deng Shanjun,Yang JianrongORCID,Wu Chung-I,Du ZhuoORCID,He Xionglei

Abstract

AbstractDuring embryogenesis, the cells in an embryo need to make numerous spatiotemporal decisions. However, there is inherent noise in each decision due to genetic or environmental fluctuations. How to suppress the noise accumulation to achieve stable embryonic end-products, a process known as Waddington’s developmental canalization, has been a major puzzle in biology since the 1940s. Previous studies have focused on the molecular noise within a cell instead of the cell noise within an embryo, thus providing indirect understandings (e,g., the well-known genetic capacitor Hsp90). In this study, we applied time-lapse microscopic imaging to capturing the spatiotemporal features of single cells, including cell position and cell cycle length, during the embryogenesis of approximately 2,100Caenorhabditis elegansembryos exposed to various genetic or environmental perturbations. By treating the deviation of a cell’s spatiotemporal feature from the expected value as noise, we modeled the transmission of noise from each mother cell to their daughters. We discovered pervasive mother-daughter negative feedbacks, which collectively constitute continuous and comprehensive ‘canals’ for suppressing noise accumulation along the developmental cell lineages, with the steepness (measuring noise suppression efficacy) and depth (measuring noise tolerance level) of the canals quantitatively defined. The learned quantitative rules enabled us to develop a cell-noise-based model that accurately predicts the nematode hatching phenotype, revealing how embryonic stochasticity could cause phenotypic disparity. With a high-dimensional mathematical tool we then proved the system stability of embryogenesis against the cell spatiotemporal noise. We also revealed several dozen canal-maintaining genes and proposed a novel association study framework that links embryonic cells rather than genetic variants with organismal traits. In sum, this study discovered and quantitatively characterized the developmental canals that directly stabilize embryogenesis in a metazoan, illuminating an 80-year-old puzzle and paving a way for studying the phenotypic plasticity and robustness of multicellular organisms from the perspective of embryogenesis.

Publisher

Cold Spring Harbor Laboratory

Reference52 articles.

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