Propagating left/right asymmetry in the zebrafish embryo: one-dimensional model

TL;DR

This paper introduces a simplified one-dimensional model of Nodal and Lefty signaling front propagation in zebrafish embryos, revealing conditions for asymmetry loss, pinned intervals, and oscillations, thus advancing understanding of L/R development mechanisms.

Contribution

It simplifies a complex two-dimensional model to a one-dimensional framework, analyzing front propagation, pinned intervals, and oscillatory behaviors in zebrafish embryonic asymmetry.

Findings

Identification of pinned intervals where production functions are threshold-bound

Parameter regimes allowing for spatially uniform oscillations

Prediction of asymmetry loss in oep mutants

Abstract

During embryonic development in vertebrates, left-right (L/R) asymmetry is reliably generated by a conserved mechanism: a L/R asymmetric signal is transmitted from the embryonic node to other parts of the embryo by the L/R asymmetric expression and diffusion of the TGF-$\beta$ related proteins Nodal and Lefty via propagating gene expression fronts in the lateral plate mesoderm (LPM) and midline. In zebrafish embryos, Nodal and Lefty expression can only occur along 3 narrow stripes that express the co-receptor \emph{one-eyed pinhead} (oep): Nodal along stripes in the left and right LPM, and Lefty along the midline. In wild-type embryos, Nodal is only expressed in the left LPM but not the right, because of inhibition by Lefty from the midline; however, bilateral Nodal expression occurs in loss-of-handedness mutants. A two-dimensional model of the zebrafish embryo predicts this loss of L/R asymmetry in oep mutants \cite{henley-xu-burdine}. In this paper, we simplify this two-dimensional picture to a one-dimensional model of Nodal and Lefty front propagation along the oep-expressing stripes. We represent Nodal and Lefty production by step functions that turn on when a linear function of Nodal and Lefty densities crosses a threshold. We do a parameter exploration of front propagation behavior, and find the existence of \emph{pinned} intervals, along which the linear function underlying production is pinned to the threshold. Finally, we find parameter regimes for which spatially uniform oscillating solutions are possible.