From genes to patterns: five key dynamical systems concepts to decode developmental regulatory mechanisms

Usha Kadiyala; David Sprinzak; Nicholas A M Monk; Shannon E Taylor; Berta Verd; Katharina F Sonnen; Lauren Moon; Adrienne H K Roeder; Ruben Perez-Carrasco; Pau Formosa-Jordan

doi:10.1242/dev.204617

From genes to patterns: five key dynamical systems concepts to decode developmental regulatory mechanisms

Usha Kadiyala, David Sprinzak, Nicholas A M Monk, Shannon E Taylor, Berta Verd, Katharina F Sonnen, Lauren Moon, Adrienne H K Roeder^*, Ruben Perez-Carrasco^*, Pau Formosa-Jordan^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

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Abstract

Developmental biology seeks to unravel the intricate regulatory mechanisms orchestrating the transformation of a single cell into a complex, multicellular organism. Dynamical systems theory provides a powerful quantitative, visual and intuitive framework for understanding this complexity. This Primer examines five core dynamical systems theory concepts and their applications to pattern formation during development: (1) analysis of phase portraits, (2) bistable switches, (3) stochasticity, (4) response to time-dependent signals, and (5) oscillations. We explore how these concepts shed light onto cell fate decision making and provide insights into the dynamic nature of developmental processes driven by signals and gradients, as well as the role of noise in shaping developmental outcomes. Selected examples highlight how integrating dynamical systems with experimental approaches has significantly advanced our understanding of the regulatory logic underlying development across scales, from molecular networks to tissue-level dynamics.

Original language	English
Article number	dev204617
Number of pages	14
Journal	Development (Cambridge, England)
Volume	152
Issue number	14
DOIs	https://doi.org/10.1242/dev.204617
Publication status	Published - 15 Jul 2025
Externally published	Yes

Keywords

Animals
Body Patterning/genetics
Developmental Biology/methods
Gene Expression Regulation, Developmental
Gene Regulatory Networks
Humans
Models, Biological
Signal Transduction
Stochastic Processes

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From genes to patterns five key dynamical systems concepts to decode developmental regulatory mechanismsFinal published version, 2.78 MBLicence: CC BY

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title = "From genes to patterns: five key dynamical systems concepts to decode developmental regulatory mechanisms",

abstract = "Developmental biology seeks to unravel the intricate regulatory mechanisms orchestrating the transformation of a single cell into a complex, multicellular organism. Dynamical systems theory provides a powerful quantitative, visual and intuitive framework for understanding this complexity. This Primer examines five core dynamical systems theory concepts and their applications to pattern formation during development: (1) analysis of phase portraits, (2) bistable switches, (3) stochasticity, (4) response to time-dependent signals, and (5) oscillations. We explore how these concepts shed light onto cell fate decision making and provide insights into the dynamic nature of developmental processes driven by signals and gradients, as well as the role of noise in shaping developmental outcomes. Selected examples highlight how integrating dynamical systems with experimental approaches has significantly advanced our understanding of the regulatory logic underlying development across scales, from molecular networks to tissue-level dynamics.",

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year = "2025",

month = jul,

day = "15",

doi = "10.1242/dev.204617",

language = "English",

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AU - Kadiyala, Usha

AU - Sprinzak, David

AU - Monk, Nicholas A M

AU - Taylor, Shannon E

AU - Verd, Berta

AU - Sonnen, Katharina F

AU - Moon, Lauren

AU - Roeder, Adrienne H K

AU - Perez-Carrasco, Ruben

AU - Formosa-Jordan, Pau

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Y1 - 2025/7/15

N2 - Developmental biology seeks to unravel the intricate regulatory mechanisms orchestrating the transformation of a single cell into a complex, multicellular organism. Dynamical systems theory provides a powerful quantitative, visual and intuitive framework for understanding this complexity. This Primer examines five core dynamical systems theory concepts and their applications to pattern formation during development: (1) analysis of phase portraits, (2) bistable switches, (3) stochasticity, (4) response to time-dependent signals, and (5) oscillations. We explore how these concepts shed light onto cell fate decision making and provide insights into the dynamic nature of developmental processes driven by signals and gradients, as well as the role of noise in shaping developmental outcomes. Selected examples highlight how integrating dynamical systems with experimental approaches has significantly advanced our understanding of the regulatory logic underlying development across scales, from molecular networks to tissue-level dynamics.

AB - Developmental biology seeks to unravel the intricate regulatory mechanisms orchestrating the transformation of a single cell into a complex, multicellular organism. Dynamical systems theory provides a powerful quantitative, visual and intuitive framework for understanding this complexity. This Primer examines five core dynamical systems theory concepts and their applications to pattern formation during development: (1) analysis of phase portraits, (2) bistable switches, (3) stochasticity, (4) response to time-dependent signals, and (5) oscillations. We explore how these concepts shed light onto cell fate decision making and provide insights into the dynamic nature of developmental processes driven by signals and gradients, as well as the role of noise in shaping developmental outcomes. Selected examples highlight how integrating dynamical systems with experimental approaches has significantly advanced our understanding of the regulatory logic underlying development across scales, from molecular networks to tissue-level dynamics.

KW - Animals

KW - Body Patterning/genetics

KW - Developmental Biology/methods

KW - Gene Expression Regulation, Developmental

KW - Gene Regulatory Networks

KW - Humans

KW - Models, Biological

KW - Signal Transduction

KW - Stochastic Processes

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DO - 10.1242/dev.204617

M3 - Review article

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SN - 0950-1991

VL - 152

JO - Development (Cambridge, England)

JF - Development (Cambridge, England)

IS - 14

M1 - dev204617

ER -

From genes to patterns: five key dynamical systems concepts to decode developmental regulatory mechanisms

Abstract

Keywords

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