Abstract
During development, many mutations cause increased variation in phenotypic outcomes, a phenomenon termed decanalization. Phenotypic discordance is often observed in the absence of genetic and environmental variations, but the mechanisms underlying such inter-individual phenotypic discordance remain elusive. Here, using the anterior-posterior (AP) patterning of the Drosophila embryo, we identified embryonic geometry as a key factor predetermining patterning outcomes under decanalizing mutations. With the wild-type AP patterning network, we found that AP patterning is robust to variations in embryonic geometry; segmentation gene expression remains reproducible even when the embryo aspect ratio is artificially reduced by more than twofold. In contrast, embryonic geometry is highly predictive of individual patterning defects under decanalized conditions of either increased bicoid (bcd) dosage or bcd knockout. We showed that the phenotypic discordance can be traced back to variations in the gap gene expression, which is rendered sensitive to the geometry of the embryo under mutations.
Highlights
The phenomenon of canalization describes the constancy in developmental outcomes between different individuals within a wild-type species growing in their native environments [1,2,3]
Phenotypic variation was observed among embryos derived from females carrying the same mutant allele [16,18]
The patterning outcomes ranging from abdominal segments 1 (A1) to A5 are highly variable among different individuals, manifesting in either fusion or depletion of various number of denticle belts
Summary
The phenomenon of canalization describes the constancy in developmental outcomes between different individuals within a wild-type species growing in their native environments [1,2,3]. To better understand how canalized a developmental process is, we need to quantitatively measure the molecular profiles of the developmental regulatory genes in multi-cellular organisms. The inter-individual variation of the positional information conferred by gene expression is below the width of a single cell [4,7]. This means that these developmental processes are highly canalized. Given the ubiquity of canalization in nature, such highly reproducible developmental processes are likely not exclusive to insect development
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