Rohit Krishnan Harish scite author profile

Spatio‐temporal regulation of signalling pathways plays a key role in generating diverse responses during the development of multicellular organisms. The role of signal dynamics in transferring signalling information in vivo is incompletely understood. Here, we employ genome engineering in Drosophila melanogaster to generate a functional optogenetic allele of the Notch ligand Delta (opto‐Delta), which replaces both copies of the endogenous wild‐type locus. Using clonal analysis, we show that optogenetic activation blocks Notch activation through cis‐inhibition in signal‐receiving cells. Signal perturbation in combination with quantitative analysis of a live transcriptional reporter of Notch pathway activity reveals differential tissue‐ and cell‐scale regulatory modes. While at the tissue‐level the duration of Notch signalling determines the probability with which a cellular response will occur, in individual cells Notch activation acts through a switch‐like mechanism. Thus, time confers regulatory properties to Notch signalling that exhibit integrative digital behaviours during tissue differentiation.

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Real-time monitoring of endogenous Fgf8a gradient attests to its role as a morphogen during zebrafish gastrulation

Harish

Gupta

Zöller

et al. 2022

Preprint

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Morphogen gradients impart positional information to cells in a homogenous tissue field. Fgf8a, a highly conserved growth factor, has been proposed to act as a morphogen during zebrafish gastrulation. However, technical limitations have so far prevented direct visualization of the endogenous Fgf8a gradient and confirmation of its morphogenic activity. Here, we monitored Fgf8a propagation in the developing neural plate using a CRISPR/Cas9-mediated EGFP knock-in at the endogenous fgf8a locus. By combining sensitive imaging platforms with single-molecule Fluorescence Correlation Spectroscopy (FCS), we demonstrate that Fgf8a, produced at the embryonic margin, propagates by free diffusion through the extracellular space and forms a graded distribution towards the animal pole. Overlaying the Fgf8a gradient curve with expression profiles of its downstream targets determines the precise input-output relationship of Fgf8a mediated patterning. Manipulation of the Fgf8a input alters the signaling outcome, thereby establishing Fgf8a as a bona fide morphogen during zebrafish gastrulation. Furthermore, using diffusion-hindered versions of Fgf8a, we demonstrate that extracellular diffusion of the protein from the source is critical for it to achieve its morphogenic potential.

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Optogenetic inhibition of Delta reveals digital Notch signaling output during tissue differentiation

Viswanathan

Necakov

Trylinski

et al. 2019

Preprint

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Spatio-temporal regulation of signalling pathways plays a key role in generating diverse responses during the development of multicellular organisms. The role of signal dynamics in transferring signalling information in vivo is incompletely understood. Here we employ genome engineering in Drosophila melanogaster to generate a functional optogenetic allele of the Notch ligand Delta (opto-Delta), which replaces both copies of the endogenous wild type locus. Using clonal analysis, we show that optogenetic activation blocks Notch activation through cisinhibition in signal-receiving cells. Signal perturbation in combination with quantitative analysis of a live transcriptional reporter of Notch pathway activity reveals differential tissue-and cell-scale regulatory modes. While at the tissuelevel the duration of Notch signalling determines the probability with which a cellular response will occur, in individual cells Notch activation acts through a switch-like mechanism. Thus, time confers regulatory properties to Notch signalling that exhibit integrative digital behaviours during tissue differentiation.We thank all members of the De Renzis laboratory for helpful discussion. We thank C. Tischer for helping with image analysis and the data pipeline developed in Cell Profiler for quantifying Delta clustering kinetics. We thank A. Aulehla, J.Crocker, J. Hartmann, and T. Hiiragi for helpful discussions and critical reading of the manuscript. We thank the advanced light microscopy for their advice and assistance. We thank the Bloomington Drosophila Stock Center and the Drosophila Genomics Resource Center for providing fly stocks and cDNAs. We thank M. Levine for providing fly stocks. Author contributionsThe experiments were conceived and designed by R.V., A.N., P.N. and S.D.R.

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