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An ex vivo primary culture assay is developed that recapitulates mouse embryonic mesodermal patterning and segment formation; using this approach, it is shown that oscillating gene activity is central to maintain stable proportions during development. Embryo scaling via oscillating genes How does a developing organism maintain its proportions as it grows? The process is termed scaling, but it is little understood. This paper describes a novel model in which to address this fundamental problem in biology: an ex vivo mouse mesoderm cell culture in a Petri dish in which mesodermal patterning and segment formation take place, complete with scaling. Using this approach, the authors found that the embryo uses periodic (oscillating) gene activity to maintain its proportions. This periodic gene activity responds to changes in overall embryo size and in turn controls the formation of embryo structures. A fundamental feature of embryonic patterning is the ability to scale and maintain stable proportions despite changes in overall size, for instance during growth 1 , 2 , 3 , 4 , 5 , 6 . A notable example occurs during vertebrate segment formation: after experimental reduction of embryo size, segments form proportionally smaller, and consequently, a normal number of segments is formed 1 , 7 , 8 . Despite decades of experimental 1 , 7 and theoretical work 9 , 10 , 11 , the underlying mechanism remains unknown. More recently, ultradian oscillations in gene activity have been linked to the temporal control of segmentation 12 ; however, their implication in scaling remains elusive. Here we show that scaling of gene oscillation dynamics underlies segment scaling. To this end, we develop a new experimental model, an ex vivo primary cell culture assay that recapitulates mouse mesoderm patterning and segment scaling, in a quasi-monolayer of presomitic mesoderm cells (hereafter termed monolayer PSM or mPSM). Combined with real-time imaging of gene activity, this enabled us to quantify the gradual shift in the oscillation phase and thus determine the resulting phase gradient across the mPSM. Crucially, we show that this phase gradient scales by maintaining a fixed amplitude across mPSM of different lengths. We identify the slope of this phase gradient as a single predictive parameter for segment size, which functions in a size- and temperature-independent manner, revealing a hitherto unrecognized mechanism for scaling. Notably, in contrast to molecular gradients, a phase gradient describes the distribution of a dynamical cellular state. Thus, our phase-gradient scaling findings reveal a new level of dynamic information-processing, and provide evidence for the concept of phase-gradient encoding during embryonic patterning and scaling.

Gene expression oscillators can structure biological events temporally and spatially. Different biological functions benefit from distinct oscillator properties. Thus, finite developmental processes rely on oscillators that start and stop at specific times, a poorly understood behavior. Here, we have characterized a massive gene expression oscillator comprising > 3,700 genes in Caenorhabditis elegans larvae. We report that oscillations initiate in embryos, arrest transiently after hatching and in response to perturbation, and cease in adults. Experimental observation of the transitions between oscillatory and non‐oscillatory states at high temporal resolution reveals an oscillator operating near a Saddle Node on Invariant Cycle (SNIC) bifurcation. These findings constrain the architecture and mathematical models that can represent this oscillator. They also reveal that oscillator arrests occur reproducibly in a specific phase. Since we find oscillations to be coupled to developmental processes, including molting, this characteristic of SNIC bifurcations endows the oscillator with the potential to halt larval development at defined intervals, and thereby execute a developmental checkpoint function. Synopsis The authors investigate a putative developmental clock in C. elegans . Population‐ and single animal‐based analyses uncover a gene expression oscillator that may support a developmental checkpoint function. Extensive rhythmic gene expression in C. elegans larvae is initiated in embryos and is coupled to molting. The oscillator is arrested in a specific phase (normally observed at molt exit) in adults, early L1 and dauer larvae. A bifurcation of the oscillator constitutes a putative developmental checkpoint mechanism. Characteristics of oscillation onset and offset constrain potential oscillator mechanisms as well as mathematical models and their parameters. Graphical Abstract The authors investigate a putative developmental clock in C. elegans . Population‐ and single animal‐based analyses uncover a gene expression oscillator that may support a developmental checkpoint function.

Polarized Wnt signaling along the primary body axis is a conserved property of axial patterning in bilaterians and prebilaterians, and depends on localized sources of Wnt ligands. However, the mechanisms governing the localized Wnt expression that emerged early in evolution are poorly understood. Here we find in the cnidarian Hydra that two functionally distinct cis-regulatory elements control the head organizer-associated Hydra Wnt3 (HyWnt3). An autoregulatory element, which mediates direct inputs of Wnt/β-catenin signaling, highly activates HyWnt3 transcription in the head region. In contrast, a repressor element is necessary and sufficient to restrict the activity of the autoregulatory element, thereby allowing the organizer-specific expression. Our results reveal that a combination of autoregulation and repression is crucial for establishing a Wnt-expressing organizing center in a basal metazoan. We suggest that this transcriptional control is an evolutionarily old strategy in the formation of Wnt signaling centers and metazoan axial patterning.

Multicellular systems grow over the course of weeks from single cells to tissues or even full organisms, making live imaging challenging. To bridge spatiotemporal scales, we present an open-top dual-view and dual-illumination light-sheet microscope dedicated to live imaging of large specimens at single-cell resolution. The configuration of objectives together with a customizable multiwell mounting system combines dual view with high-throughput multiposition imaging. We use this microscope to image a wide variety of samples and highlight its capabilities to gain quantitative single-cell information in large specimens such as mature intestinal organoids and gastruloids. This work presents a highly versatile open-top, dual-view and dual-illumination light-sheet microscope for live imaging of large specimens.

Through regeneration various species replace lost parts of their body. This is achieved either by growth of new structures at the amputation side (epimorphosis), as is the case of axolotl limb regeneration, or through remodeling of the remaining tissue (morphallaxis), as happens in Hydra. Whereas work on epimorphic regeneration support a gradual proximal to distal establishment of cell identities, morphallactic regeneration is believed to rely on initial establishment of boundary conditions that organize the re-adjustment of the pattern. Performing single cell RNA sequencing during regeneration in Hydra, we revealed the sequence of cells' transdifferentiation into the missing identities. We provide evidence that morphallaxis proceeds with progressive specification of cell fates, unifying its mechanism with the one found for epimorphosis.Competing Interest StatementThe authors have declared no competing interest.

In Hydra, a simple cnidarian model, epithelio-muscular cells play a crucial role in shaping and maintaining the body architecture. These cells are continuously renewed as undifferentiated cells from the body's mid-region get displaced toward the extremities, replacing shed, differentiated cells and adopting specific identities. This ongoing differentiation, coupled with the maintenance of distinct anatomical regions, provides an ideal system to explore the relationship between cell type specification and axial patterning. However, the molecular mechanisms governing epithelial cell identity in Hydra remain largely unknown. In this study, we describe a double-negative feedback loop between the transcription factors Zic4 and Gata3 that functions as a toggle switch to control epidermal cell fate. Zic4 is activated by Wnt signaling from the mouth organizer and triggers battery cell specification in tentacles. In contrast, Gata3 promotes basal disk cell identity at the aboral end. Functional analyses demonstrate that Zic4 and Gata3 are mutually antagonistic; suppression of one leads to the dominance of the other, and vice versa, resulting in ectopic cell specification. Notably, simultaneous knockdown of both factors rescues the phenotype, indicating that it is the balance between these transcription factors, rather than their absolute levels, that dictates cell identity. This study highlights the mechanisms by which distinct cellular identities are established at Hydra body termini and reveals how cell fate decisions are coordinated with axial patterning.Competing Interest StatementThe authors have declared no competing interest.

Abstract Multiple natural and artificial oscillator systems achieve synchronisation when oscillators are coupled. The coupling mechanism, essentially the communication between oscillators, is often assumed to be continuous and bidirectional. However, the cells of the presomitic mesoderm synchronise their gene expression oscillations through Notch signalling, which is intermittent and directed from a ligand-presenting to a receptor-presenting cell. Motivated by this mode of communication we present a phase-gated and unidirectional coupling mechanism. We identify conditions under which it can successfully bring two or more oscillators to cycle in-phase. In the presomitic mesoderm we observed the oscillatory dynamics of two synchronizing cell populations and record one population halting its pace while the other keeps undisturbed, as would be predicted from our model. For the same system another important prediction, convergence to a specific range of phases upon synchronisation is also confirmed. Thus, the proposed mechanism accurately describes the coordinated oscillations of the presomitic mesoderm cells and provides an alternative framework for deciphering synchronisation. Competing Interest Statement The authors have declared no competing interest.

Abstract Mechanical forces shape cell fate decisions during development and regeneration in many systems. Epithelial lumen volume changes, for example, generate mechanical forces that can be perceived by the surrounding tissue and integrated into cell fate decisions. Similar behavior occurs in regenerating Hydra tissue spheroids, where periodic osmotically driven inflation and deflation cycles generate mechanical stimuli in the form of tissue stretching. Using this model, we investigate how such mechanical input guides the de novo formation of differentiated body parts. We show that the expression of the organizer-defining factor Wnt3 functions as a quantitative readout of cellular stretching and, when supplied externally, enables successful regeneration without mechanical stimulation. This finding represents a previously undescribed cellular mechanism for converting mechanical stimuli to a biochemical signaling readout and guiding cell fate transitions. It also elucidates the role of mechanical oscillations in Hydra regeneration, which long remained unclear. The presence the Wnt/mechanics interplay in Hydra and its relatives underscores the ancient evolutionary history of this crosstalk, possibly extending back to the first metazoans. Since Wnt signaling crosstalks with cellular mechanics in various developmental and disease contexts, it can also represent a conserved feature of this signaling pathway. Competing Interest Statement The authors have declared no competing interest.