Horloges, gradients, et réseaux moléculaires: modèles mathématiques de la morphogenèse

Cinquin, Olivier

06 December 2005

L'acquisition d'une structure spatiale au cours du développement d'un embryon implique la différentiation de cellules, souvent suivant des informations positionnelles. La complexité des réseaux moléculaires régulant la différentiation et des mécanismes générant l'information positionnelle rend nécessaire leur modélisation mathématique. Les embryons de vertébrés acquièrent une structure segmentée lors de la somitogénèse; ce processus nécessite des variations spatiales et temporelles d'expression de gènes, que la modélisation mathématique peut également aider à comprendre.<br /><br />Un mécanisme moléculaire pour l'horloge de la somitogénèse est proposé, qui prend en compte la synchronisation inter-cellulaire, et qui est basé sur un système de rétrocontrôle positif, bien qu'il soit aussi compatible avec toutes les données expérimentales interprétées comme prouvant que l'horloge est basée sur un système de rétrocontrôle négatif. Des expériences proposées pour tester ce modèle comprennent des rapporteurs en temps réel de l'horloge, ainsi que des systemes inductibles, pour induire des perturbations contrôlées spatialement.<br /><br />Des résultats théoriques et expérimentaux ont mené à des idées contradictoires sur la manière dont de l'information positionnelle utile peut être établie. En particulier, il a été souligné que certains modèles de diffusion extracellulaire de morphogène donnent lieu à une saturation des récepteurs, qui est inadéquate à l'établissement d'information positionnelle. Deux modèles alternatifs (mais non mutellement exclusifs) sont proposés, qui sont basés sur des résultats expérimentaux récents mettant en valeur les rôles de glycoprotéines extracellulaires et de l'oligomérisation de morphogènes.<br /><br />La lecture de l'information positionnelle se traduit par l'établissement d'un ensemble discret de patrons d'expressions génétiques. De manière intriguante, il a été observé que, dans de nombreux contextes, des gènes régulant la différentiation sont initalement co-exprimés dans des progéniteurs malgré leur antagonisme. Nous caractérisons les conditions sous lesquelles trois classes de réseaux de régulation peuvent se conduire comme un "multi-switch", dirigeant la différentiation d'une maniére tout-ou-rien vers un type de cellule spécifique, choisi parmi plus de 2 possibles. Les réseaux de dimérisation bHLH peuvent facilement maintenir l'expression de plusieurs facteurs antagonistes quand la compétition est basse. La prise de décision peut être forcée par une augmentation de la compétition, qui pourrait correspondre à des observations expérimentales inexpliquées, liées aux protéines Id.

[MATH] Mathematics

[MATH] Mathématiques

morphogenese

differentiation cellulaire

somitogenese

Genetic Oscillations and Vertebrate Embryonic Development

Jörg, David Josef

14 January 2015

Recurrent processes are a general feature of living systems, from the cell cycle to circadian day-night rhythms to hibernation and flowering cycles. During development and life, numerous recurrent processes are controlled by genetic oscillators, a specific class of genetic regulatory networks that generates oscillations in the level of gene products. A vital mechanism controlled by genetic oscillators is the rhythmic and sequential segmentation of the elongating body axis of vertebrate embryos. During this process, a large collection of coupled genetic oscillators gives rise to spatio-temporal wave patterns of oscillating gene expression at tissue level, forming a dynamic prepattern for the precursors of the vertebrae. While such systems of genetic oscillators have been studied extensively over the past years, many fundamental questions about their collective behavior remain unanswered. In this thesis, we study the behavior and the properties of genetic oscillators from the single oscillator scale to the complex pattern forming system involved in vertebrate segmentation. Genetic oscillators are subject to fluctuations because of the stochastic nature of gene expression. To study the effects of noisy biochemical coupling on genetic oscillators, we propose a theory in which both the internal dynamics of the oscillators as well as the coupling process are inherently stochastic. We find that stochastic coupling of oscillators profoundly affects their precision and synchronization properties, key features for their viability as biological pacemakers. Moreover, stochasticity introduces phenomena not known from deterministic systems, such as stochastic switching between different modes of synchrony. During vertebrate segmentation, genetic oscillators play a key role in establishing a segmental prepattern on tissue scale. We study the spatio-temporal patterns of oscillating gene expression using a continuum theory of coupled phase oscillators. We investigate the effects of different biologically relevant factors such as delayed coupling due to complex signaling processes, local tissue growth, and tissue shortening on pattern formation and segmentation. We find that the decreasing tissue length induces a Doppler effect that contributes to the rate of segment formation in a hitherto unanticipated way. Comparison of our theoretical findings with experimental data reveals the occurrence of such a Doppler effect in vivo. To this end, we develop quantification methods for the spatio-temporal patterns of gene expression in developing zebrafish embryos. On a cellular level, tissues have a discrete structure. To study the interplay of cellular processes like cell division and random cell movement with pattern formation, we go beyond the coarse-grained continuum theories and develop a three-dimensional cell-based model of vertebrate segmentation, in which the dynamics of the segmenting tissue emerges from the collective behavior of individual cells. We show that this model is able to describe tissue formation and segmentation in a self-organized way. It provides the first step of theoretically describing pattern formation and tissue dynamics during vertebrate segmentation in a unified framework involving a three-dimensional tissue with cells as distinct mechanical entities. Finally, we study the synchronization dynamics of generic oscillator systems whose coupling is subject to phase shifts and time delays. Such phase shifts and time delays are induced by complex signaling processes as found, e.g., between genetic oscillators. We show how phase shifts and coupling delays can alter the synchronization dynamics while leaving the collective frequency of the synchronized oscillators invariant. We find that in globally coupled systems, fastest synchronization occurs for non-vanishing coupling delays while in spatially extended systems, fastest synchronization can occur on length scales larger than the coupling range, giving rise to novel synchronization scenarios. Beyond their potential relevance for biological systems, these results have implications for general oscillator systems, e.g., in physics and engineering. In summary, we use discrete and continuous theories of genetic oscillators to study their dynamic behavior, comparing our theoretical results to experimental data where available. We cover a wide range of different topics, contributing to the general understanding of genetic oscillators and synchronization and revealing a hitherto unknown mechanism regulating the timing of embryonic pattern formation.

Genetische Oszillationen

Embryonalentwicklung

Wirbeltiersegmentierung

Somitogenese

Musterbildung

genetic oscillations

embryonic development

vertebrate segmentation

somitogenesis

pattern formation

ddc:570

rvk:WG 7000

Genetic Oscillations and Vertebrate Embryonic Development

Jörg, David Josef

17 December 2014

Recurrent processes are a general feature of living systems, from the cell cycle to circadian day-night rhythms to hibernation and flowering cycles. During development and life, numerous recurrent processes are controlled by genetic oscillators, a specific class of genetic regulatory networks that generates oscillations in the level of gene products. A vital mechanism controlled by genetic oscillators is the rhythmic and sequential segmentation of the elongating body axis of vertebrate embryos. During this process, a large collection of coupled genetic oscillators gives rise to spatio-temporal wave patterns of oscillating gene expression at tissue level, forming a dynamic prepattern for the precursors of the vertebrae. While such systems of genetic oscillators have been studied extensively over the past years, many fundamental questions about their collective behavior remain unanswered. In this thesis, we study the behavior and the properties of genetic oscillators from the single oscillator scale to the complex pattern forming system involved in vertebrate segmentation. Genetic oscillators are subject to fluctuations because of the stochastic nature of gene expression. To study the effects of noisy biochemical coupling on genetic oscillators, we propose a theory in which both the internal dynamics of the oscillators as well as the coupling process are inherently stochastic. We find that stochastic coupling of oscillators profoundly affects their precision and synchronization properties, key features for their viability as biological pacemakers. Moreover, stochasticity introduces phenomena not known from deterministic systems, such as stochastic switching between different modes of synchrony. During vertebrate segmentation, genetic oscillators play a key role in establishing a segmental prepattern on tissue scale. We study the spatio-temporal patterns of oscillating gene expression using a continuum theory of coupled phase oscillators. We investigate the effects of different biologically relevant factors such as delayed coupling due to complex signaling processes, local tissue growth, and tissue shortening on pattern formation and segmentation. We find that the decreasing tissue length induces a Doppler effect that contributes to the rate of segment formation in a hitherto unanticipated way. Comparison of our theoretical findings with experimental data reveals the occurrence of such a Doppler effect in vivo. To this end, we develop quantification methods for the spatio-temporal patterns of gene expression in developing zebrafish embryos. On a cellular level, tissues have a discrete structure. To study the interplay of cellular processes like cell division and random cell movement with pattern formation, we go beyond the coarse-grained continuum theories and develop a three-dimensional cell-based model of vertebrate segmentation, in which the dynamics of the segmenting tissue emerges from the collective behavior of individual cells. We show that this model is able to describe tissue formation and segmentation in a self-organized way. It provides the first step of theoretically describing pattern formation and tissue dynamics during vertebrate segmentation in a unified framework involving a three-dimensional tissue with cells as distinct mechanical entities. Finally, we study the synchronization dynamics of generic oscillator systems whose coupling is subject to phase shifts and time delays. Such phase shifts and time delays are induced by complex signaling processes as found, e.g., between genetic oscillators. We show how phase shifts and coupling delays can alter the synchronization dynamics while leaving the collective frequency of the synchronized oscillators invariant. We find that in globally coupled systems, fastest synchronization occurs for non-vanishing coupling delays while in spatially extended systems, fastest synchronization can occur on length scales larger than the coupling range, giving rise to novel synchronization scenarios. Beyond their potential relevance for biological systems, these results have implications for general oscillator systems, e.g., in physics and engineering. In summary, we use discrete and continuous theories of genetic oscillators to study their dynamic behavior, comparing our theoretical results to experimental data where available. We cover a wide range of different topics, contributing to the general understanding of genetic oscillators and synchronization and revealing a hitherto unknown mechanism regulating the timing of embryonic pattern formation.

info:eu-repo/classification/ddc/570

ddc:570