Your search keyword '"segmentation clock"' showing total 185 results

1. Cell-autonomous timing drives the vertebrate segmentation clock’s wave pattern

Author

Laurel A Rohde, Arianne Bercowsky-Rama, Guillaume Valentin, Sundar Ram Naganathan, Ravi A Desai, Petr Strnad, Daniele Soroldoni, and Andrew C Oates

Subjects

segmentation clock, zebrafish, somitogenesis, intrinsic timer, cell tracking, primary cell culture, Medicine, Science, Biology (General), QH301-705.5

Abstract

Rhythmic and sequential segmentation of the growing vertebrate body relies on the segmentation clock, a multi-cellular oscillating genetic network. The clock is visible as tissue-level kinematic waves of gene expression that travel through the presomitic mesoderm (PSM) and arrest at the position of each forming segment. Here, we test how this hallmark wave pattern is driven by culturing single maturing PSM cells. We compare their cell-autonomous oscillatory and arrest dynamics to those we observe in the embryo at cellular resolution, finding similarity in the relative slowing of oscillations and arrest in concert with differentiation. This shows that cell-extrinsic signals are not required by the cells to instruct the developmental program underlying the wave pattern. We show that a cell-autonomous timing activity initiates during cell exit from the tailbud, then runs down in the anterior-ward cell flow in the PSM, thereby using elapsed time to provide positional information to the clock. Exogenous FGF lengthens the duration of the cell-intrinsic timer, indicating extrinsic factors in the embryo may regulate the segmentation clock via the timer. In sum, our work suggests that a noisy cell-autonomous, intrinsic timer drives the slowing and arrest of oscillations underlying the wave pattern, while extrinsic factors in the embryo tune this timer’s duration and precision. This is a new insight into the balance of cell-intrinsic and -extrinsic mechanisms driving tissue patterning in development.

Published

2024

2. Atlanto-occipital assimilation: embryological basis and its clinical significance.

Author

N., Hari Hara Hanusun, Singh, Akanksha, Poddar, Pooja, J. P., Jessy, Rani, Neerja, Gurjar, Hitesh, and Singh, Seema

Abstract

Atlanto-occipital assimilation is an osseous embryological anomaly of the craniovertebral junction in which the atlas (C1) is fused to the occiput of skull. Embryologically, this assimilation may happen due to failure of the segmentation and separation of the caudal occipital and the cranial cervical sclerotome. The segmentation clock is maintained by NOTCH and WNT signalling pathways along with Hox genes and retinoic acid. This condition is likely to be a consequence of mutation in above mentioned genes. The knowledge of this assimilation may be crucial for the clinicians as it may lead to various neurovascular symptoms. The present case report involves the analysis of atlanto-occipital assimilation with its clinical significance and embryological basis. [ABSTRACT FROM AUTHOR]

Published

2024

3. Species-specific roles of the Notch ligands, receptors, and targets orchestrating the signaling landscape of the segmentation clock.

Author

Ramesh, Pranav S. and Li-Fang Chu

Subjects

COMPARATIVE biology, DEVELOPMENTAL biology, SPINE, CLOCK genes, LIGANDS (Biochemistry)

Abstract

Somitogenesis is a hallmark feature of all vertebrates and some invertebrate species that involves the periodic formation of block-like structures called somites. Somites are transient embryonic segments that eventually establish the entire vertebral column. A highly conserved molecular oscillator called the segmentation clock underlies this periodic event and the pace of this clock regulates the pace of somite formation. Although conserved signaling pathways govern the clock in most vertebrates, the mechanisms underlying the speciesspecific divergence in various clock characteristics remain elusive. For example, the segmentation clock in classical model species such as zebrafish, chick, and mouse embryos tick with a periodicity of ~30, ~90, and ~120 min respectively. This enables them to form the species-specific number of vertebrae during their overall timespan of somitogenesis. Here, we perform a systematic review of the species-specific features of the segmentation clock with a keen focus on mouse embryos. We perform this review using three different perspectives: Notchresponsive clock genes, ligand-receptor dynamics, and synchronization between neighboring oscillators. We further review reports that use non-classical model organisms and in vitro model systems that complement our current understanding of the segmentation clock. Our review highlights the importance of comparative developmental biology to further our understanding of this essential developmental process. [ABSTRACT FROM AUTHOR]

Published

2024

4. Species-specific roles of the Notch ligands, receptors, and targets orchestrating the signaling landscape of the segmentation clock

Author

Pranav S. Ramesh and Li-Fang Chu

Subjects

Notch signailing pathway, segmentation clock, gene oscillation, presomitic mesoderm (PSM), somitogenesis, somite, Biology (General), QH301-705.5

Abstract

Somitogenesis is a hallmark feature of all vertebrates and some invertebrate species that involves the periodic formation of block-like structures called somites. Somites are transient embryonic segments that eventually establish the entire vertebral column. A highly conserved molecular oscillator called the segmentation clock underlies this periodic event and the pace of this clock regulates the pace of somite formation. Although conserved signaling pathways govern the clock in most vertebrates, the mechanisms underlying the species-specific divergence in various clock characteristics remain elusive. For example, the segmentation clock in classical model species such as zebrafish, chick, and mouse embryos tick with a periodicity of ∼30, ∼90, and ∼120 min respectively. This enables them to form the species-specific number of vertebrae during their overall timespan of somitogenesis. Here, we perform a systematic review of the species-specific features of the segmentation clock with a keen focus on mouse embryos. We perform this review using three different perspectives: Notch-responsive clock genes, ligand-receptor dynamics, and synchronization between neighboring oscillators. We further review reports that use non-classical model organisms and in vitro model systems that complement our current understanding of the segmentation clock. Our review highlights the importance of comparative developmental biology to further our understanding of this essential developmental process.

Published

2024

5. The Role of Fibroblast Growth Factor Signaling in Somitogenesis.

Author

Chandel, Angad Singh, Stocker, Matthew, and Özbudak, Ertuğrul M.

Subjects

*FIBROBLAST growth factors, *SOMITOGENESIS, *EMBRYOLOGY, *SOMITE, *MESODERM, *WNT signal transduction, *SKELETAL muscle

Abstract

Fibroblast growth factor (FGF) signaling is conserved from cnidaria to mammals (Ornitz and Itoh, 2022) and it regulates several critical processes such as differentiation, proliferation, apoptosis, cell migration, and embryonic development. One pivotal process FGF signaling controls is the division of vertebrate paraxial mesoderm into repeated segmented units called somites (i.e., somitogenesis). Somite segmentation occurs periodically and sequentially in a head-to-tail manner, and lays down the plan for compartmentalized development of the vertebrate body axis (Gomez et al., 2008). These somites later give rise to vertebrae, tendons, and skeletal muscle. Somite segments form sequentially from the anterior end of the presomitic mesoderm (PSM). The periodicity of somite segmentation is conferred by the segmentation clock, comprising oscillatory expression of Hairy and enhancer-of-split (Her/Hes) genes in the PSM. The positional information for somite boundaries is instructed by the double phosphorylated extracellular signal-regulated kinase (ppERK) gradient, which is the relevant readout of FGF signaling during somitogenesis (Sawada et al., 2001; Delfini et al., 2005; Simsek and Ozbudak, 2018; Simsek et al., 2023). In this review, we summarize the crosstalk between the segmentation clock and FGF/ppERK gradient and discuss how that leads to periodic somite boundary formation. We also draw attention to outstanding questions regarding the interconnected roles of the segmentation clock and ppERK gradient, and close with suggested future directions of study. [ABSTRACT FROM AUTHOR]

Published

2023

6. Orchestration of tissue shape changes and gene expression patterns in development.

Author

Uriu, Koichiro and Morelli, Luis G.

Subjects

*GENE expression, *TISSUE mechanics, *CELL morphology, *TISSUES

Abstract

In development, tissue shape changes and gene expression patterns give rise to morphogenesis. Understanding tissue shape changes requires the analysis of mechanical properties of the tissue such as tissue rigidity, cell influx from neighboring tissues, cell shape changes and cell proliferation. Local and global gene expression patterns can be influenced by neighbor exchange and tissue shape changes. Here we review recent studies on the mechanisms for tissue elongation and its influences on dynamic gene expression patterns by focusing on vertebrate somitogenesis. We first introduce mechanical and biochemical properties of the segmenting tissue that drive tissue elongation. Then, we discuss patterning in the presence of cell mixing, scaling of signaling gradients, and dynamic phase waves of rhythmic gene expression under tissue shape changes. We also highlight the importance of theoretical approaches to address the relation between tissue shape changes and patterning. [ABSTRACT FROM AUTHOR]

Published

2023

7. Biological Significance of the Coupling Delay in Synchronized Oscillations.

Author

Kageyama, Ryoichiro, Isomura, Akihiro, and Shimojo, Hiromi

Subjects

*OSCILLATIONS, *MESODERM, *VERTEBRAE

Abstract

The significance of the coupling delay, which is the time required for interactions between coupled oscillators, in various oscillatory dynamics has been investigated mathematically for more than three decades, but its biological significance has been revealed only recently. In the segmentation clock, which regulates the periodic formation of somites in embryos, Hes7 expression oscillates synchronously between neighboring presomitic mesoderm (PSM) cells, and this synchronized oscillation is controlled by Notch signaling-mediated coupling between PSM cells. Recent studies have shown that inappropriate coupling delays dampen and desynchronize Hes7 oscillations, as simulated mathematically, leading to the severe fusion of somites and somite-derived tissues such as the vertebrae and ribs. These results indicate the biological significance of the coupling delay in synchronized Hes7 oscillations in the segmentation clock. The recent development of an in vitro PSM-like system will facilitate the detailed analysis of the coupling delay in synchronized oscillations. [ABSTRACT FROM AUTHOR]

Published

2023

8. Cell-autonomous timing drives the vertebrate segmentation clock's wave pattern.

Author

Rohde LA, Bercowsky-Rama A, Valentin G, Naganathan SR, Desai RA, Strnad P, Soroldoni D, and Oates AC

Subjects

Animals, Biological Clocks physiology, Zebrafish embryology, Zebrafish physiology, Mesoderm embryology, Mesoderm physiology, Embryo, Nonmammalian physiology, Embryo, Nonmammalian embryology, Vertebrates embryology, Vertebrates physiology, Cell Differentiation, Gene Expression Regulation, Developmental, Body Patterning physiology

Abstract

Rhythmic and sequential segmentation of the growing vertebrate body relies on the segmentation clock, a multi-cellular oscillating genetic network. The clock is visible as tissue-level kinematic waves of gene expression that travel through the presomitic mesoderm (PSM) and arrest at the position of each forming segment. Here, we test how this hallmark wave pattern is driven by culturing single maturing PSM cells. We compare their cell-autonomous oscillatory and arrest dynamics to those we observe in the embryo at cellular resolution, finding similarity in the relative slowing of oscillations and arrest in concert with differentiation. This shows that cell-extrinsic signals are not required by the cells to instruct the developmental program underlying the wave pattern. We show that a cell-autonomous timing activity initiates during cell exit from the tailbud, then runs down in the anterior-ward cell flow in the PSM, thereby using elapsed time to provide positional information to the clock. Exogenous FGF lengthens the duration of the cell-intrinsic timer, indicating extrinsic factors in the embryo may regulate the segmentation clock via the timer. In sum, our work suggests that a noisy cell-autonomous, intrinsic timer drives the slowing and arrest of oscillations underlying the wave pattern, while extrinsic factors in the embryo tune this timer's duration and precision. This is a new insight into the balance of cell-intrinsic and -extrinsic mechanisms driving tissue patterning in development., Competing Interests: LR, AB, GV, SN, RD, DS, AO No competing interests declared, PS Co-founder of Viventis Microscopy, (© 2024, Rohde, Bercowsky-Rama et al.)

Published

2024

9. Imaging the onset of oscillatory signaling dynamics during mouse embryo gastrulation.

Author

Falk, Henning J., Takehito Tomita, Mönke, Gregor, McDole, Katie, and Aulehla, Alexander

Subjects

*GASTRULATION, *EMBRYOS, *EMBRYOLOGY, *CLOCK genes, *SOMITOGENESIS, *MOLECULAR clock

Abstract

A fundamental requirement for embryonic development is the coordination of signaling activities in space and time. A notable example in vertebrate embryos is found during somitogenesis, where gene expression oscillations linked to the segmentation clock are synchronized across cells in the presomiticmesoderm (PSM) and result in tissue-level wave patterns. To examine their onset during mouse embryo development, we studied the dynamics of the segmentation clock gene Lfng during gastrulation. To this end, we established an imaging setup using selective plane illumination microscopy (SPIM) that enables culture and simultaneous imaging of up to four embryos ('SPIMfor-4'). Using SPIM-for-4, combined with genetically encoded signaling reporters, we detected the onset of Lfng oscillations within newly formed mesoderm at presomite stages. Functionally, we found that initial synchrony and the first ~6-8 oscillation cycles occurred even when Notch signaling was impaired, revealing similarities to previous findings made in zebrafish embryos. Finally, we show that a spatial period gradient is present at the onset of oscillatory activity, providing a potential mechanism accounting for our observation that wave patterns build up gradually over the first oscillation cycles. [ABSTRACT FROM AUTHOR]

Published

2022

10. Cell–Fibronectin Interactions and Actomyosin Contractility Regulate the Segmentation Clock and Spatio-Temporal Somite Cleft Formation during Chick Embryo Somitogenesis.

Author

Gomes de Almeida, Patrícia, Rifes, Pedro, Martins-Jesus, Ana P., Pinheiro, Gonçalo G., Andrade, Raquel P., and Thorsteinsdóttir, Sólveig

Subjects

*FIBRONECTINS, *SOMITE, *SOMITOGENESIS, *ACTOMYOSIN, *RHO-associated kinases, *CLOCK genes, *CHICKEN embryos

Abstract

Fibronectin is essential for somite formation in the vertebrate embryo. Fibronectin matrix assembly starts as cells emerge from the primitive streak and ingress in the unsegmented presomitic mesoderm (PSM). PSM cells undergo cyclic waves of segmentation clock gene expression, followed by Notch-dependent upregulation of meso1 in the rostral PSM which induces somite cleft formation. However, the relevance of the fibronectin matrix for these molecular processes remains unknown. Here, we assessed the role of the PSM fibronectin matrix in the spatio-temporal regulation of chick embryo somitogenesis by perturbing (1) extracellular fibronectin matrix assembly, (2) integrin–fibronectin binding, (3) Rho-associated protein kinase (ROCK) activity and (4) non-muscle myosin II (NM II) function. We found that integrin–fibronectin engagement and NM II activity are required for cell polarization in the nascent somite. All treatments resulted in defective somitic clefts and significantly perturbed meso1 and segmentation clock gene expression in the PSM. Importantly, inhibition of actomyosin-mediated contractility increased the period of hairy1/hes4 oscillations from 90 to 120 min. Together, our work strongly suggests that the fibronectin–integrin–ROCK–NM II axis regulates segmentation clock dynamics and dictates the spatio-temporal localization of somitic clefts. [ABSTRACT FROM AUTHOR]

Published

2022

11. The (unusual) heuristic value of Hox gene clusters; a matter of time?

Author

Duboule, Denis

Subjects

*HOMEOBOX genes, *GENETIC regulation, *GENE families, *ANIMAL species, *HEURISTIC, *GENE clusters

Abstract

Ever since their first report in 1984, Antennapedia-type homeobox (Hox) genes have been involved in such a series of interesting observations, in particular due to their conserved clustered organization between vertebrates and arthropods, that one may legitimately wonder about the origin of this heuristic value. In this essay, I first consider different examples where Hox gene clusters have been instrumental in providing conceptual advances, taken from various fields of research and mostly involving vertebrate embryos. These examples touch upon our understanding of genomic evolution, the revisiting of 19th century views on the relationships between development and evolution and the building of a new framework to understand long-range and pleiotropic gene regulation during development. I then discuss whether the high value of the Hox gene family, when considered as an epistemic object, is related to its clustered structure (and the absence thereof in some animal species) and, if so, what is it in such particular genetic oddities that made them so generous in providing the scientific community with interesting information. [Display omitted] • For years Hox clusters have been a rich source of concepts in developmental biology. •What is the reason for such a high heuristic value? •Gene clusters are natural playgrounds for evolving temporal regulations in-cis. •Iterative biological processes help understand basic principles. •Historical, genetic and epistemological oddities. [ABSTRACT FROM AUTHOR]

Published

2022

12. Circadian key component CLOCK/BMAL1 interferes with segmentation clock in mouse embryonic organoids.

Author

Yasuhiro Umemura, Nobuya Koike, Yoshiki Tsuchiya, Hitomi Watanabe, Gen Kondoh, Ryoichiro Kageyama, and Kazuhiro Yagita

Subjects

*PLURIPOTENT stem cells, *GENETIC transcription regulation, *SOMITOGENESIS, *ORGANOIDS, *ONTOGENY

Abstract

In mammals, circadian clocks are strictly suppressed during early embryonic stages, as well as in pluripotent stem cells, by the lack of CLOCK/BMAL1-mediated circadian feedback loops. During ontogenesis, the innate circadian clocks emerge gradually at a late developmental stage, and with these, the circadian temporal order is invested in each cell level throughout a body. Meanwhile, in the early developmental stage, a segmented body plan is essential for an intact developmental process, and somitogenesis is controlled by another cell-autonomous oscillator, the segmentation clock, in the posterior presomitic mesoderm (PSM). In the present study, focusing upon the interaction between circadian key components and the segmentation clock, we investigated the effect of the CLOCK/BMAL1 on the segmentation clock Hes7 oscillation, revealing that the expression of functional CLOCK/BMAL1 severely interferes with the ultradian rhythm of segmentation clock in induced PSM and gastruloids. RNA sequencing analysis implied that the premature expression of CLOCK/BMAL1 affects the Hes7 transcription and its regulatory pathways. These results suggest that the suppression of CLOCK/BMAL1-mediated transcriptional regulation during the somitogenesis may be inevitable for intact mammalian development. [ABSTRACT FROM AUTHOR]

Published

2022

13. Cell–Fibronectin Interactions and Actomyosin Contractility Regulate the Segmentation Clock and Spatio-Temporal Somite Cleft Formation during Chick Embryo Somitogenesis

Author

Patrícia Gomes de Almeida, Pedro Rifes, Ana P. Martins-Jesus, Gonçalo G. Pinheiro, Raquel P. Andrade, and Sólveig Thorsteinsdóttir

Subjects

fibronectin, fibronectin matrix assembly, actomyosin contractility, somitogenesis, segmentation clock, hairy1, Cytology, QH573-671

Abstract

Fibronectin is essential for somite formation in the vertebrate embryo. Fibronectin matrix assembly starts as cells emerge from the primitive streak and ingress in the unsegmented presomitic mesoderm (PSM). PSM cells undergo cyclic waves of segmentation clock gene expression, followed by Notch-dependent upregulation of meso1 in the rostral PSM which induces somite cleft formation. However, the relevance of the fibronectin matrix for these molecular processes remains unknown. Here, we assessed the role of the PSM fibronectin matrix in the spatio-temporal regulation of chick embryo somitogenesis by perturbing (1) extracellular fibronectin matrix assembly, (2) integrin–fibronectin binding, (3) Rho-associated protein kinase (ROCK) activity and (4) non-muscle myosin II (NM II) function. We found that integrin–fibronectin engagement and NM II activity are required for cell polarization in the nascent somite. All treatments resulted in defective somitic clefts and significantly perturbed meso1 and segmentation clock gene expression in the PSM. Importantly, inhibition of actomyosin-mediated contractility increased the period of hairy1/hes4 oscillations from 90 to 120 min. Together, our work strongly suggests that the fibronectin–integrin–ROCK–NM II axis regulates segmentation clock dynamics and dictates the spatio-temporal localization of somitic clefts.

Published

2022

14. In vitro systems: A new window to the segmentation clock.

Author

Diaz‐Cuadros, Margarete and Pourquie, Olivier

Subjects

*INDUCED pluripotent stem cells, *PLURIPOTENT stem cells, *SOMITE

Abstract

Segmental organization of the vertebrate body plan is established by the segmentation clock, a molecular oscillator that controls the periodicity of somite formation. Given the dynamic nature of the segmentation clock, in vivo studies in vertebrate embryos pose technical challenges. As an alternative, simpler models of the segmentation clock based on primary explants and pluripotent stem cells have recently been developed. These ex vivo and in vitro systems enable more quantitative analysis of oscillatory properties and expand the experimental repertoire applicable to the segmentation clock. Crucially, by eliminating the need for model organisms, in vitro models allow us to study the segmentation clock in new species, including our own. The human oscillator was recently recapitulated using induced pluripotent stem cells, providing a window into human development. Certainly, a combination of in vivo and in vitro work holds the most promising potential to unravel the mechanisms behind vertebrate segmentation. [ABSTRACT FROM AUTHOR]

Published

2021

15. Substrate Rigidity Modulates Segmentation Clock Dynamics in Isolated Presomitic Mesoderm Cells.

Author

Sung CY, Kadiyala U, Blanchard O, Yourston L, Walker D, Li L, Fu J, and Yang Q

Abstract

The segmentation clock, a genetic oscillator in the presomitic mesoderm (PSM), is known to be influenced by biochemical signals, yet its potential regulation by mechanical cues remains unclear. The complex PSM microenvironment has made it challenging to isolate the effects of mechanical perturbations on clock behavior. Here we investigated how mechanical stimuli affect clock oscillations by culturing zebrafish PSM cells on PDMS micropost arrays with tunable rigidities (0.6-1200 kPa). We observed an inverse sigmoidal relationship between surface rigidity and both the percentage of oscillating cells and the number of oscillation cycles, with a switching threshold between 3-6 kPa. The periods of oscillating cells showed a consistently broad distribution across rigidity changes. Moreover, these cells exhibited distinct biophysical properties, such as reduced motility, contractility, and sustained circularity. These findings highlight the crucial role of cell-substrate interactions in regulating segmentation clock behavior, providing insights into the mechanobiology of somitogenesis., Competing Interests: Declaration of Interests The authors declare no competing interests.

Published

2024

16. Oscillatory control of embryonic development.

Author

Chandel AS, Keseroglu K, and Özbudak EM

Subjects

Animals, Humans, Muscle Development genetics, Neurogenesis genetics, Neurogenesis physiology, Pancreas embryology, Pancreas metabolism, Cell Differentiation genetics, Embryonic Development genetics, Gene Expression Regulation, Developmental, Somites metabolism, Somites embryology

Abstract

Proper embryonic development depends on the timely progression of a genetic program. One of the key mechanisms for achieving precise control of developmental timing is to use gene expression oscillations. In this Review, we examine how gene expression oscillations encode temporal information during vertebrate embryonic development by discussing the gene expression oscillations occurring during somitogenesis, neurogenesis, myogenesis and pancreas development. These oscillations play important but varied physiological functions in different contexts. Oscillations control the period of somite formation during somitogenesis, whereas they regulate the proliferation-to-differentiation switch of stem cells and progenitor cells during neurogenesis, myogenesis and pancreas development. We describe the similarities and differences of the expression pattern in space (i.e. whether oscillations are synchronous or asynchronous across neighboring cells) and in time (i.e. different time scales) of mammalian Hes/zebrafish Her genes and their targets in different tissues. We further summarize experimental evidence for the functional role of their oscillations. Finally, we discuss the outstanding questions for future research., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

17. Fgf4 maintains Hes7 levels critical for normal somite segmentation clock function

Author

Matthew J Anderson, Valentin Magidson, Ryoichiro Kageyama, and Mark Lewandoski

Subjects

fibroblast growth factor, Notch, segmentation clock, somitogenesis, hybridization chain reaction, axis extension, Medicine, Science, Biology (General), QH301-705.5

Abstract

During vertebrate development, the presomitic mesoderm (PSM) periodically segments into somites, which will form the segmented vertebral column and associated muscle, connective tissue, and dermis. The periodicity of somitogenesis is regulated by a segmentation clock of oscillating Notch activity. Here, we examined mouse mutants lacking only Fgf4 or Fgf8, which we previously demonstrated act redundantly to prevent PSM differentiation. Fgf8 is not required for somitogenesis, but Fgf4 mutants display a range of vertebral defects. We analyzed Fgf4 mutants by quantifying mRNAs fluorescently labeled by hybridization chain reaction within Imaris-based volumetric tissue subsets. These data indicate that FGF4 maintains Hes7 levels and normal oscillatory patterns. To support our hypothesis that FGF4 regulates somitogenesis through Hes7, we demonstrate genetic synergy between Hes7 and Fgf4, but not with Fgf8. Our data indicate that Fgf4 is potentially important in a spectrum of human Segmentation Defects of the Vertebrae caused by defective Notch oscillations.

Published

2020

18. Patterning and mechanics of somite boundaries in zebrafish embryos.

Author

Naganathan, S.R. and Oates, A.C.

Subjects

*ZEBRA danio, *CELL determination, *EMBRYOS, *GEOGRAPHIC boundaries, *EXTRACELLULAR matrix, *SOMITE

Abstract

The body axis of vertebrates is subdivided into repetitive compartments called somites, which give rise primarily to the segmented architecture of the musculoskeletal system in the adult body. Somites form in a sequential and rhythmic manner in embryos and a physical boundary separates each somite from the rest of the unsegmented tissue and adjoining somites. Precise positioning of somite boundaries and determination of boundary cell fate in a select group of cells is thought to be driven by gene expression patterns and morphogen gradients. This pre-patterning step is followed by a mechanical process involving actomyosin activation in boundary cells and formation of an extracellular matrix that results in morphological boundary formation. While genes involved in somite boundary formation have been identified, there are many open questions about the underlying pre-patterning dynamics and mechanics and how these processes are coupled to generate a morphological boundary. Here, focusing on segmentation of zebrafish embryos as a model, we review pre-patterning processes critical for boundary formation and how cytoskeletal activity drives tissue separation. Our outlook is that this system holds exciting new avenues for unearthing general principles of boundary formation in developing embryos. [ABSTRACT FROM AUTHOR]

Published

2020

19. Atlanto-occipital assimilation: embryological basis and its clinical significance.

Author

Hanusun N HH, Singh A, Poddar P, J P J, Rani N, Gurjar H, and Singh S

Abstract

Atlanto-occipital assimilation is an osseous embryological anomaly of the craniovertebral junction in which the atlas (C1) is fused to the occiput of skull. Embryologically, this assimilation may happen due to failure of the segmentation and separation of the caudal occipital and the cranial cervical sclerotome. The segmentation clock is maintained by NOTCH and WNT signalling pathways along with Hox genes and retinoic acid. This condition is likely to be a consequence of mutation in above mentioned genes. The knowledge of this assimilation may be crucial for the clinicians as it may lead to various neurovascular symptoms. The present case report involves the analysis of atlanto-occipital assimilation with its clinical significance and embryological basis.

Published

2024

20. Information flow in the presence of cell mixing and signaling delays during embryonic development.

Author

Petrungaro, Gabriela, Morelli, Luis G., and Uriu, Koichiro

Subjects

*EMBRYOLOGY, *CELL motility, *MIXING, *COLLECTIVE behavior, *CELLS

Abstract

Embryonic morphogenesis is organized by an interplay between intercellular signaling and cell movements. Both intercellular signaling and cell movement involve multiple timescales. A key timescale for signaling is the time delay caused by preparation of signaling molecules and integration of received signals into cells' internal state. Movement of cells relative to their neighbors may introduce exchange of positions between cells during signaling. When cells change their relative positions in a tissue, the impact of signaling delays on intercellular signaling increases because the delayed information that cells receive may significantly differ from the present state of the tissue. The time it takes to perform a neighbor exchange sets a timescale of cell mixing that may be important for the outcome of signaling. Here we review recent theoretical work on the interplay of timescales between cell mixing and signaling delays adopting the zebrafish segmentation clock as a model system. We discuss how this interplay can lead to spatial patterns of gene expression that could disrupt the normal formation of segment boundaries in the embryo. The effect of cell mixing and signaling delays highlights the importance of theoretical and experimental frameworks to understand collective cellular behaviors arising from the interplay of multiple timescales in embryonic developmental processes. [ABSTRACT FROM AUTHOR]

Published

2019

21. Theory of time delayed genetic oscillations with external noisy regulation

Author

Jose Negrete Jr, Iván M Lengyel, Laurel Rohde, Ravi A Desai, Andrew C Oates, and Frank Jülicher

Subjects

transient noisy dynamics, genetic oscillations, delay differential equations, circadian rhythm, segmentation clock, analytical calculations, Science, Physics, QC1-999

Abstract

We present a general theory of noisy genetic oscillators with externally regulated production rate and multiplicative noise. The observables that characterize the genetic oscillator are discussed, and it is shown how their statistics depend on the externally regulated production rate. We show that these observables have generic features that are observed in two different experimental systems: the expression of the circadian clock genes in fibroblasts, and in the transient and oscillatory dynamics of the segmentation clock genes observed in cells disassociated from zebrafish embryos. Our work shows that genetic oscillations with diverse biological contexts can be understood in a common framework based on a delayed negative feedback system, and regulator dynamics.

Published

2021

22. Patterning the spine

Author

Matthew P Harris and Gloria Arratia

Subjects

Notochord, segmentation clock, somite, Entpd5, evolution, vertebrae, Medicine, Science, Biology (General), QH301-705.5

Abstract

The patterning of the spine of a zebrafish is controlled by the notochord, a rod-like structure that supports and instructs the developing embryo.

Published

2018

23. Generation of patterns in the paraxial mesoderm.

Author

Loureiro C, Venzin OF, and Oates AC

Subjects

Animals, Zebrafish embryology, Zebrafish genetics, Signal Transduction, Biological Clocks genetics, Body Patterning genetics, Gene Expression Regulation, Developmental, Somites embryology, Somites metabolism, Mesoderm embryology, Mesoderm metabolism, Mesoderm cytology

Abstract

The Segmentation Clock is a tissue-level patterning system that enables the segmentation of the vertebral column precursors into transient multicellular blocks called somites. This patterning system comprises a set of elements that are essential for correct segmentation. Under the so-called "Clock and Wavefront" model, the system consists of two elements, a genetic oscillator that manifests itself as traveling waves of gene expression, and a regressing wavefront that transforms the temporally periodic signal encoded in the oscillations into a permanent spatially periodic pattern of somite boundaries. Over the last twenty years, every new discovery about the Segmentation Clock has been tightly linked to the nomenclature of the "Clock and Wavefront" model. This constrained allocation of discoveries into these two elements has generated long-standing debates in the field as what defines molecularly the wavefront and how and where the interaction between the two elements establishes the future somite boundaries. In this review, we propose an expansion of the "Clock and Wavefront" model into three elements, "Clock", "Wavefront" and signaling gradients. We first provide a detailed description of the components and regulatory mechanisms of each element, and we then examine how the spatiotemporal integration of the three elements leads to the establishment of the presumptive somite boundaries. To be as exhaustive as possible, we focus on the Segmentation Clock in zebrafish. Furthermore, we show how this three-element expansion of the model provides a better understanding of the somite formation process and we emphasize where our current understanding of this patterning system remains obscure., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

24. Efficient derivation of transgene-free porcine induced pluripotent stem cells enables in vitro modeling of species-specific developmental timing.

Author

Conrad JV, Meyer S, Ramesh PS, Neira JA, Rusteika M, Mamott D, Duffin B, Bautista M, Zhang J, Hiles E, Higgins EM, Steill J, Freeman J, Ni Z, Liu S, Ungrin M, Rancourt D, Clegg DO, Stewart R, Thomson JA, and Chu LF

Subjects

Humans, Animals, Mice, Swine, Cellular Reprogramming, Cell Differentiation, Transgenes, Mammals, Induced Pluripotent Stem Cells, Pluripotent Stem Cells

Abstract

Sus scrofa domesticus (pig) has served as a superb large mammalian model for biomedical studies because of its comparable physiology and organ size to humans. The derivation of transgene-free porcine induced pluripotent stem cells (PiPSCs) will, therefore, benefit the development of porcine-specific models for regenerative biology and its medical applications. In the past, this effort has been hampered by a lack of understanding of the signaling milieu that stabilizes the porcine pluripotent state in vitro. Here, we report that transgene-free PiPSCs can be efficiently derived from porcine fibroblasts by episomal vectors along with microRNA-302/367 using optimized protocols tailored for this species. PiPSCs can be differentiated into derivatives representing the primary germ layers in vitro and can form teratomas in immunocompromised mice. Furthermore, the transgene-free PiPSCs preserve intrinsic species-specific developmental timing in culture, known as developmental allochrony. This is demonstrated by establishing a porcine in vitro segmentation clock model that, for the first time, displays a specific periodicity at ∼3.7 h, a timescale recapitulating in vivo porcine somitogenesis. We conclude that the transgene-free PiPSCs can serve as a powerful tool for modeling development and disease and developing transplantation strategies. We also anticipate that they will provide insights into conserved and unique features on the regulations of mammalian pluripotency and developmental timing mechanisms., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

25. ES cell-derived presomitic mesoderm-like tissues for analysis of synchronized oscillations in the segmentation clock.

Author

Matsumiya, Marina, Takehito Tomita, Kumiko Yoshioka-Kobayashi, Akihiro Isomura, and Ryoichiro Kageyama

Subjects

*MESODERM, *EMBRYONIC stem cells, *LABORATORY mice

Abstract

Somites are periodically formed by segmentation of the anterior parts of the presomitic mesoderm (PSM). In the mouse embryo, this periodicity is controlled by the segmentation clock gene Hes7, which exhibits wave-like oscillatory expression in the PSM. Despite intensive studies, the exact mechanism of such synchronous oscillatory dynamics of Hes7 expression still remains to be analyzed. Detailed analysis of the segmentation clock has been hampered because it requires the use of live embryos, and establishment of an in vitro culture system would facilitate such analyses. Here, we established a simple and efficient method to generate mouse ES cell-derived PSM-like tissues, in which Hes7 expression oscillates like traveling waves. In these tissues, Hes7 oscillation is synchronized between neighboring cells, and the posterior-anterior axis is self-organized as the central-peripheral axis. This method is applicable to chemical-library screening and will facilitate the analysis of the molecular nature of the segmentation clock. [ABSTRACT FROM AUTHOR]

Published

2018

26. Evaluation of heuristic reductions of a model for the segmentation clock in zebrafish.

Author

Shimono, Yuki, Yamaguchi, Ikuhiro, Ishimatsu, Kana, Akao, Akihiko, Ogawa, Yutaro, Jimbo, Yasuhiko, and Kotani, Kiyoshi

Subjects

*HEURISTIC programming, *IMAGE segmentation, *ZEBRA danio, *PROTEINS, *DNA, *MESSENGER RNA

Abstract

Time-delayed interactions between DNA, mRNA, and proteins play an important role in the periodic somite segmentation of vertebrates. A mathematical model of the segmentation clock in zebrafish that illustrates the dynamics between proteins and mRNA has recently been proposed; however, the complexity of the model makes solving it analytically unrealistic. In this study, we derived a first-order delay-differential equation (DDE) model by following two heuristic reduction approaches: simplifying protein-mRNA interactions and protein dimerization. Then, we calculated the eigenvalues of the model and found that the maximum eigenvalue and the oscillatory dynamics are qualitatively equivalent when some parameters are varied. This result enabled us to illustrate the effectiveness of using eigenvalues to assess the dynamics of the reduced model. Further, we extended the reduction methods to a complete model of somite segmentation considering the interaction of four genes, and derived a reduced model with four variables and four delay terms. Although the oscillation period of our reduced model decreased by ∼10% compared to the original model, the amplitude differed by less than 10%. The dynamic features for genetic conditions are also qualitatively reproduced by the reduced model. Our model demonstrates that it is possible to identify key parameters and to reveal the interactions among the parameters. © 2017 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc. [ABSTRACT FROM AUTHOR]

Published

2018

27. Cambrian Chordates and Vetulicolians

Author

Mark A. S. McMenamin

Subjects

chordates, vetulicolians, cephalochordates, vertebrates, tunicates, Cambrian, Banffia, Vetulicolia, Myllokunmingia, Metaspriggina, Shenzianyuloma, agnathans, notochord, gut diverticula, myomeres, deuterostomes, all-trans-retinoic acid (ATRA), segmentation clock, morphogen gradients, Geology, QE1-996.5

Abstract

Deuterostomes make a sudden appearance in the fossil record during the early Cambrian. Two bilaterian groups, the chordates and the vetulicolians, are of particular interest for understanding early deuterostome evolution, and the main objective of this review is to examine the Cambrian diversity of these two deuterostome groups. The subject is of particular interest because of the link to vertebrates, and because of the enigmatic nature of vetulicolians. Lagerstätten in China and elsewhere have dramatically improved our understanding of the range of variation in these ancient animals. Cephalochordate and vertebrate body plans are well established at least by Cambrian Series 2. Taken together, roughly a dozen chordate genera and fifteen vetulicolian genera document part of the explosive radiation of deuterostomes at the base of the Cambrian. The advent of deuterostomes near the Cambrian boundary involved both a reversal of gut polarity and potentially a two-sided retinoic acid gradient, with a gradient discontinuity at the midpoint of the organism that is reflected in the sharp division of vetulicolians into anterior and posterior sections. A new vetulicolian (Shenzianyuloma yunnanense nov. gen. nov. sp.) with a laterally flattened, polygonal anterior section provides significant new data regarding vetulicolians. Its unsegmented posterior region (‘tail’) bears a notochord and a gut trace with diverticula, both surrounded by myotome cones.

Published

2019

28. Somite formation in the chicken embryo.

Author

POURQUIÉ, OLIVIER

Subjects

SOMITE, CHICKEN embryos, CYTOLOGY, DEVELOPMENTAL biology, SEGMENTATION (Biology)

Abstract

Somites are epithelial blocks of paraxial mesoderm that define the vertebrate embryonic segments. They are responsible for imposing the metameric pattern observed in many tissues of the adult such as the vertebrae, and they give rise to most of the axial skeleton and skeletal muscles of the trunk. Due to its easy accessibility in the egg, the chicken embryo has provided an ideal model to study somite development. Somites were first described in the chicken embryo by Malpighi in the 17th century, soon after the invention of the microscope. Most of the major concepts relating to somite segmentation and differentiation result from studies performed in the chicken embryo (Brand-Saberi and Christ, 2000). In this review, we will discuss how studies on somites in avian embryos have contributed to our understanding of key developmental processes such as segmentation, control of bilateral symmetry or axis regionalization. [ABSTRACT FROM AUTHOR]

Published

2018

29. Putative binding sites for mir-125 family miRNAs in the mouse Lfng 3′UTR affect transcript expression in the segmentation clock, but mir-125a-5p is dispensable for normal somitogenesis.

Author

Wahi, Kanu, Friesen, Sophia, Coppola, Vincenzo, and Cole, Susan E.

Abstract

Background: In vertebrate embryos, a 'segmentation clock' times somitogenesis. Clock-linked genes, including Lunatic fringe ( Lfng), exhibit cyclic expression in the presomitic mesoderm (PSM), with a period matching the rate of somite formation. The clock period varies widely across species, but the mechanisms that underlie this variability are not clear. The half-lives of clock components are proposed to influence the rate of clock oscillations, and are tightly regulated in the PSM. Interactions between Lfng and mir-125a-5p in the embryonic chicken PSM promote Lfng transcript instability, but the conservation of this mechanism in other vertebrates has not been tested. Here, we examine whether this interaction affects clock activity in a mammalian species. Results: Mutation of mir-125 binding sites in the Lfng 3′UTR leads to persistent, nonoscillatory reporter transcript expression in the caudal-most mouse PSM, although dynamic transcript expression recovers in the central PSM. Despite this, expression of endogenous mir-125a-5p is dispensable for mouse somitogenesis. Conclusions: These results suggest that mir-125a sites in the Lfng 3′ untranslated region influence transcript turnover in both mouse and chicken embryos, and support the existence of position-dependent regulatory mechanisms in the PSM. They further suggest the existence of compensatory mechanisms that can rescue the loss of mir-125a-5p in mice. Developmental Dynamics 246:740-748, 2017. © 2017 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2017

30. Modelling asymmetric somitogenesis: Deciphering the mechanisms behind species differences.

Author

Vroomans, Renske M.A. and ten Tusscher, Kirsten H.W.J.

Subjects

*SOMITOGENESIS, *TRETINOIN, *PHENOTYPES, *CELLULAR signal transduction, *MESODERM

Abstract

Somitogenesis is one of the major hallmarks of bilateral symmetry in vertebrates. This symmetry is lost when retinoic acid (RA) signalling is inhibited, allowing the left-right determination pathway to influence somitogenesis. In all three studied vertebrate model species, zebrafish, chicken and mouse, the frequency of somite formation becomes asymmetric, with slower gene expression oscillations driving somitogenesis on the right side. Still, intriguingly, the resulting left-right asymmetric phenotypes differ significantly between these model species. While somitogenesis is generally considered as functionally equivalent among different vertebrates, substantial differences exist in the subset of oscillating genes between different vertebrate species. Variation also appears to exist in the way oscillations cease and somite boundaries become patterned. In addition, in absence of RA, the FGF8 gradient thought to constitute the determination wavefront becomes asymmetric in zebrafish and mouse, extending more anteriorly to the right, while remaining symmetric in chicken. Here we use a computational modelling approach to decipher the causes underlying species differences in asymmetric somitogenesis. Specifically, we investigate to what extent differences can be explained from observed differences in FGF asymmetry and whether differences in somite determination dynamics may also be involved. We demonstrate that a simple clock-and-wavefront model incorporating the observed left-right differences in somitogenesis frequency readily reproduces asymmetric somitogenesis in chicken. However, incorporating asymmetry in FGF signalling was insufficient to robustly reproduce mouse or zebrafish asymmetry phenotypes. In order to explain these phenoptypes we needed to extend the basic model, incorporating species-specific details of the somitogenesis determination mechanism. Our results thus demonstrate that a combination of differences in FGF dynamics and somite determination cause species differences in asymmetric somitogenesis. In addition,they highlight the power of using computational models as well as studying left-right asymmetry to obtain more insight in somitogenesis. [ABSTRACT FROM AUTHOR]

Published

2017

31. Symmetry OUT, Asymmetry IN

Author

Raquel Lourenço and Leonor Saúde

Subjects

segmentation clock, bilateral synchronization, left-right asymmetry, organ laterality, Mathematics, QA1-939

Abstract

The formation of a perfect vertebrate body plan poses many questions that thrill developmental biologists. Special attention has been given to the symmetric segmental patterning that allows the formation of the vertebrae and skeletal muscles. These segmented structures derive from bilaterally symmetric units called somites, which are formed under the control of a segmentation clock. At the same time that these symmetric units are being formed, asymmetric signals are establishing laterality in nearby embryonic tissues, allowing the asymmetric placement of the internal organs. More recently, a “shield” that protects symmetric segmentation from the influence of laterality cues was uncovered. Here we review the mechanisms that control symmetric versus asymmetric development along the left-right axis among vertebrates. We also discuss the impact that these studies might have in the understanding of human congenital disorders characterized by congenital vertebral malformations and abnormal laterality phenotypes.

Published

2010

32. A stem cell zoo uncovers intracellular scaling of developmental tempo across mammals.

Author

Lázaro J, Costanzo M, Sanaki-Matsumiya M, Girardot C, Hayashi M, Hayashi K, Diecke S, Hildebrandt TB, Lazzari G, Wu J, Petkov S, Behr R, Trivedi V, Matsuda M, and Ebisuya M

Subjects

Animals, Mice, Humans, Cattle, Rabbits, Biological Clocks, Cell Differentiation, Mammals metabolism, Gene Expression Regulation, Developmental, Basic Helix-Loop-Helix Transcription Factors metabolism, Pluripotent Stem Cells

Abstract

Differential speeds in biochemical reactions have been proposed to be responsible for the differences in developmental tempo between mice and humans. However, the underlying mechanism controlling the species-specific kinetics remains to be determined. Using in vitro differentiation of pluripotent stem cells, we recapitulated the segmentation clocks of diverse mammalian species varying in body weight and taxa: marmoset, rabbit, cattle, and rhinoceros. Together with mouse and human, the segmentation clock periods of the six species did not scale with the animal body weight, but with the embryogenesis length. The biochemical kinetics of the core clock gene HES7 displayed clear scaling with the species-specific segmentation clock period. However, the cellular metabolic rates did not show an evident correlation. Instead, genes involving biochemical reactions showed an expression pattern that scales with the segmentation clock period. Altogether, our stem cell zoo uncovered general scaling laws governing species-specific developmental tempo., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

33. Hunchback knockdown induces supernumerary segment formation in Bombyx.

Author

Nakao, Hajime

Subjects

*KYPHOSIS patients, *INSECT populations, *DROSOPHILA, *INSECT embryology, *INSECT genetics, *GENE expression

Abstract

Insect segment number within species appears to be fixed irrespective of germ types: long vs. short/intermediate. The present study showed induction of supernumerary segment formation by the knockdown of Bombyx hunchback ( Bm-hb ), presumably by terminal segment addition, a short/intermediate-like-segmentation mode that is not observed in normal Bombyx embryogenesis. This suggests that Bm-hb suppresses segmentation. The results obtained also suggest that the gap gene Bm-Kr ( Bombyx Krüppel ) provides a permissive environment for the progression of segmentation by suppressing the expression Bm-hb , which terminates segmentation. This indicates a novel mechanism by which the gap gene is involved in segmentation. It appears that Bm-Kr and Bm-hb are involved in segment counting and their interplay contributes to the correct number of segments being formed in Bombyx . Similar mechanisms may be operating in insects that employ the non- Drosophilan mode of segmentation such as in short/intermediate-germ insects. [ABSTRACT FROM AUTHOR]

Published

2016

34. Disruption of somitogenesis by a novel dominant allele of Lfng suggests important roles for protein processing and secretion.

Author

Williams, Dustin R., Shifley, Emily T., Braunreiter, Kara M., and Cole, Susan E.

Subjects

*SOMITOGENESIS, *CELLULAR signal transduction, *PROTEIN research, *NOTCH signaling pathway, *BIOLOGICAL research

Abstract

Vertebrate somitogenesis is regulated by a segmentation clock. Clock-linked genes exhibit cyclic expression, with a periodicity matching the rate of somite production. In mice, lunatic fringe (Lfng) expression oscillates, and LFNG protein contributes to periodic repression of Notch signaling. We hypothesized that rapid LFNG turnover could be regulated by protein processing and secretion. Here, we describe a novel Lfng allele (LfngRLFNG), replacing the N-terminal sequences of LFNG, which allow for protein processing and secretion, with the N-terminus of radical fringe (a Golgi-resident protein). This allele is predicted to prevent protein secretion without altering the activity of LFNG, thus increasing the intracellular half-life of the protein. This allele causes dominant skeletal and somite abnormalities that are distinct fromthose seen in Lfng loss-of-function embryos. Expression of clock-linked genes is perturbed and mature Hes7 transcripts are stabilized in the presomitic mesoderm of mutant mice, suggesting that both transcriptional and post-transcriptional regulation of clock components are perturbed by RLFNG expression. Contrasting phenotypes in the segmentation clock and somite patterning of mutant mice suggest that LFNG protein may have context-dependent effects on Notch activity. [ABSTRACT FROM AUTHOR]

Published

2016

35. Congenital Cervical Spinal Deformities.

Author

Courvoisier A

Subjects

Child, Humans, Cervical Vertebrae diagnostic imaging, Cervical Vertebrae surgery, Klippel-Feil Syndrome diagnostic imaging, Klippel-Feil Syndrome surgery, Spinal Diseases

Abstract

Malformations of the cervical spine are a challenge in pediatric orthopedic surgery since the treatment options are limited. These congenital anomalies are often syndrome-related and have multiple repercussions on the function and statics of the cervical spine in all three planes. They are related to developmental abnormalities during the somite segmentation that occurs during the third week of embryonic development. Successful somitogenesis requires proper functioning of a clock regulated by complex signaling pathways that guide the steps needed to form the future spine. There is no specific classification for vertebral malformations at the cervical level. To characterize the progressive nature of a malformation, one must use general classifications. In the specific case of Klippel-Feil syndrome, these malformations can affect several vertebral levels in a continuous or discontinuous manner, but also the vertebral body and vertebral arch in a variable way. Thus, establishing a reliable prognosis in the coronal and sagittal planes is a complex undertaking. While technical mastery of certain osteotomy procedures has led to advances in the surgical treatment of rigid deformities of the cervical spine, the indications are still very rare. Nevertheless, the procedure has become safer and more accurate because of technical aids such as surgical navigation, robotics and 3D printed models or patient-specific guides. Occipitocervical transitional anomalies have embryological specificities that can explain the bony malformations seen at this level. However, most are rare, and the main concern is identifying any instability that justifies surgical stabilization. The presence of a cervical spine anomaly should trigger the search for occipitocervical instability and vice-versa., (Copyright © 2022 Elsevier Masson SAS. All rights reserved.)

Published

2023

36. The many roles of Notch signaling during vertebrate somitogenesis.

Author

Wahi, Kanu, Bochter, Matthew S., and Cole, Susan E.

Subjects

*VERTEBRATE development, *NOTCH genes, *SOMITOGENESIS, *MESODERM, *DYSOSTOSIS, *CELL communication

Abstract

The embryonic vertebrate body axis contains serially repeated elements, somites, which form sequentially by budding from a posterior tissue called the presomitic mesoderm (PSM). Somites are the embryonic precursors of the vertebrae, ribs and other adult structures. Many inherited human diseases are characterized by dysregulated somitogenesis, resulting in skeletal abnormalities that are evident at birth. Several of these conditions, including some cases of autosomal recessive familial spondylocostal dysostosis (SCDO), arise from mutations in the Notch signaling pathway, which has been demonstrated to be a key player in the regulation of somitogenesis. Here, we review the functional roles of the Notch pathway in vertebrate segmentation, focusing on its activities in a clock that times the formation of somites, as well as in the patterning and production of epithelial somites. [ABSTRACT FROM AUTHOR]

Published

2016

37. Timing by rhythms: Daily clocks and developmental rulers.

Author

Webb, Alexis B. and Oates, Andrew C.

Subjects

*CIRCADIAN rhythms, *OSCILLATIONS, *ANATOMICAL axis, *CHRONOBIOLOGY, *SEGMENTATION (Biology), *BIOLOGISTS

Abstract

Biological rhythms are widespread, allowing organisms to temporally organize their behavior and metabolism in advantageous ways. Such proper timing of molecular and cellular events is critical to their development and health. This is best understood in the case of the circadian clock that orchestrates the daily sleep/wake cycle of organisms. Temporal rhythms can also be used for spatial organization, if information from an oscillating system can be recorded within the tissue in a manner that leaves a permanent periodic pattern. One example of this is the 'segmentation clock' used by the vertebrate embryo to rhythmically and sequentially subdivide its elongating body axis. The segmentation clock moves with the elongation of the embryo, such that its period sets the segment length as the tissue grows outward. Although the study of this system is still relatively young compared to the circadian clock, outlines of molecular, cellular, and tissue-level regulatory mechanisms of timing have emerged. The question remains, however, is it truly a clock? Here we seek to introduce the segmentation clock to a wider audience of chronobiologists, focusing on the role and control of timing in the system. We compare and contrast the segmentation clock with the circadian clock, and propose that the segmentation clock is actually an oscillatory ruler, with a primary function to measure embryonic space. [ABSTRACT FROM AUTHOR]

Published

2016

38. Molecular mechanism for cyclic generation of somites: Lessons from mice and zebrafish.

Author

Yabe, Taijiro and Takada, Shinji

Subjects

*SOMITE, *ZEBRA danio, *METAMERISM, *VERTEBRATE embryology, *MESODERM, MICE anatomy

Abstract

The somite is the most prominent metameric structure observed during vertebrate embryogenesis, and its metamerism preserves the characteristic structures of the vertebrae and muscles in the adult body. During vertebrate somitogenesis, sequential formation of epithelialized cell boundaries generates the somites. According to the 'clock and wavefront model,' the periodical and sequential generation of somites is achieved by the integration of spatiotemporal information provided by the segmentation clock and wavefront. In the anterior region of the presomitic mesoderm, which is the somite precursor, the orchestration between the segmentation clock and the wavefront achieves morphogenesis of somites through multiple processes such as determination of somite boundary position, generation of morophological boundary, and establishment of the rostrocaudal polarity within a somite. Recently, numerous studies using various model animals including mouse, zebrafish, and chick have gradually revealed the molecular aspect of the 'clock and wavefront' model and the molecular mechanism connecting the segmentation clock and the wavefront to the multiple processes of somite morphogenesis. In this review, we first summarize the current knowledge about the molecular mechanisms underlying the clock and the wavefront and then describe those of the three processes of somite morphogenesis. Especially, we will discuss the conservation and diversification in the molecular network of the somitigenesis among vertebrates, focusing on two typical model animals used for genetic analyses, i.e., the mouse and zebrafish. In this review, we described molecular mechanism for the generation of somites based on the spatiotemporal information provided by 'segmentation clock' and 'wavefront' focusing on the evidences obtained from mouse and zebrafish. [ABSTRACT FROM AUTHOR]

Published

2016

39. Multiple roles of timing in somite formation.

Author

Stern, Claudio D. and Piatkowska, Agnieszka M.

Subjects

*SOMITE, *VERTEBRATE embryology, *SKELETAL muscle physiology, *DERMIS, *CELL communication, *PATTERN formation (Biology), *PHYSIOLOGY

Abstract

During development, vertebrate embryos produce serially repeated elements, the somites, on each side of the midline. These generate the vertebral column, skeletal musculature and dermis. They form sequentially, one pair at a time, from mesenchymal tissue near the tail. Somite development is a complex process. The embryo must control the number, size, and timing of somite formation, their subdivision into functional regions along three axes, regional identity such that somites develop in a region-specific way, and interactions with neighbouring tissues that coordinate them with nearby structures. Here we discuss many timing-related mechanisms that contribute to set up the spatial pattern. [ABSTRACT FROM AUTHOR]

Published

2015

40. Dynamics of the slowing segmentation clock reveal alternating two-segment periodicity.

Author

Shih, Nathan P., François, Paul, Delaune, Emilie A., and Amacher, Sharon L.

Subjects

*MESODERM, *SEGMENTATION (Biology), *FORCE & energy, *ZEBRA danio, *MICRODIALYSIS, *SOMITE, *OSCILLATIONS

Abstract

The formation of reiterated somites along the vertebrate body axis is controlled by the segmentation clock, a molecular oscillator expressed within presomitic mesoderm (PSM) cells. Although PSM cells oscillate autonomously, they coordinate with neighboring cells to generate a sweeping wave of cyclic gene expression through the PSM that has a periodicity equal to that of somite formation. The velocity of each wave slowsas itmoves anteriorly through thePSM, although thedynamics of clock slowing have not been well characterized. Here, we investigate segmentation clock dynamics in the anterior PSM in developing zebrafish embryos using an in vivo clock reporter, her1:her1-venus. The her1:her1-venus reporter has single-cell resolution, allowing us to followsegmentation clock oscillations in individual cells in real-time. By retrospectively tracking oscillations of future somite boundary cells,we find that clock reporter signal increases in anterior PSM cells and that the periodicity of reporter oscillations slows to about ~1.5 times the periodicity in posterior PSM cells. This gradual slowing of the clock in the anterior PSM creates peaks of clock expression that are separated at a two-segment periodicity both spatially and temporally, a phenomenon we observe in single cells and in tissue-wide analyses. These results differ from previous predictions that clock oscillations stop or are stabilized in the anterior PSM. Instead, PSM cells oscillate until they incorporate into somites. Our findings suggest that the segmentation clock may signal somite formation using a phase gradient with a two-somite periodicity. [ABSTRACT FROM AUTHOR]

Published

2015

41. From local resynchronization to global pattern recovery in the zebrafish segmentation clock

Author

Bo-Kai Liao, Andrew C. Oates, Koichiro Uriu, and Luis G. Morelli

Subjects

0301 basic medicine, Physics of Living Systems, Synchronization, 0302 clinical medicine, somitogenesis, pattern formation, Somitogenesis, Segmentation, Tissue mechanics, Biology (General), Zebrafish, Physics, 0303 health sciences, Segmentation Clock, Receptors, Notch, biology, General Neuroscience, Delta-Notch, Gene Expression Regulation, Developmental, General Medicine, tissue mechanics, Medicine, Biological system, Signal Transduction, Research Article, QH301-705.5, Science, Morphogenesis, Pattern formation, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Rhythm, Biological Clocks, Animals, congenital scoliosis, Body Patterning, 030304 developmental biology, genetic oscillators, General Immunology and Microbiology, Zebrafish Proteins, Pattern generation, biology.organism_classification, Coupling (electronics), 030104 developmental biology, Developmental biology, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Rhythmic spatial gene expression patterns termed the segmentation clock regulate vertebrate body axis segmentation during embryogenesis. The integrity of these patterns requires local synchronization between neighboring cells by Delta-Notch signaling and its inhibition results in defective segment boundaries. The oscillating tissue deforms substantially throughout development, but whether such tissue-scale morphogenesis complements local synchronization during pattern generation and segment formation is not understood. Here, we investigate pattern recovery in the zebrafish segmentation clock by washing out a Notch inhibitor, allowing resynchronization at different developmental stages, and analyzing the recovery of normal segments. Although from previous work no defects are expected after recovery, we find that washing out at early stages causes a distinctive intermingling of normal and defective segments, suggesting unexpectedly large fluctuations of synchrony before complete recovery. To investigate this recovery behavior, we develop a new model of the segmentation clock combining key ingredients motivated by prior experimental observations: coupling between neighboring oscillators, a frequency profile, a gradient of cell mixing, tissue length change, and cell advection pattern. This model captures the experimental observation of intermingled normal and defective segments through the formation of persistent phase vortices of the genetic oscillators. Experimentally observed recovery patterns at different developmental stages are predicted by temporal changes of tissue-level properties, such as tissue length and cell advection pattern in the model. These results suggest that segmental pattern recovery occurs at two scales: local pattern formation and transport of these patterns through tissue morphogenesis, highlighting a generic mechanism of pattern dynamics within developing tissues.SIGNIFICANCEInteracting genetic oscillators can generate a coherent rhythm and a tissue-level pattern from an initially desynchronized state. Using experiment and theory we study resynchronization and pattern recovery of the zebrafish segmentation clock, which makes the embryonic body segments. Experimental perturbation of intercellular signaling with an inhibitor results in intermingled normal and defective segments. According to theory, this behavior may be caused by persistent local vortices scattered in the tissue during pattern recovery. Full pattern recovery follows dynamic global properties, such as tissue length and advection pattern, in contrast to other genetic oscillators in a static tissue such as circadian clocks. Our work highlights how dynamics of tissue level properties may couple to biochemical pattern formation in tissues and developing embryos.

Published

2021

42. A reflux-and-growth mechanism explains oscillatory patterning of lateral root branching sites

Author

van den Berg, Thea, Yalamanchili, Kavya, de Gernier, Hugues, Santos Teixeira, Joana, Beeckman, Tom, Scheres, Ben, Willemsen, Viola, Ten Tusscher, Kirsten, Theoretical Biology and Bioinformatics, Sub Theoretical Biology, Theoretical Biology and Bioinformatics, and Sub Theoretical Biology

Subjects

computational modeling, Periodicity, Arabidopsis, Gene Expression, Plant Developmental Biology, lateral root priming, Biochemistry, Plant Roots, INITIATION, Plant Growth Regulators, Gene Expression Regulation, Plant, Somitogenesis, NETWORK, periodic developmental patterning, root growth dynamics, food and beverages, Phyllotaxis, ARABIDOPSIS, SEGMENTATION CLOCK, Laboratory of Molecular Biology, Signal Transduction, EXPRESSION, oscillatory priming dynamics, Meristem, CELL-DIVISION, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, experimental validation, Laboratorium voor Moleculaire Biologie, Molecular Biology, Body Patterning, Indoleacetic Acids, Mechanism (biology), Biochemistry, Genetics and Molecular Biology(all), Arabidopsis Proteins, Lateral root, Root meristem growth, auxin transport, Biology and Life Sciences, Computational Biology, BASAL MERISTEM, Cell Biology, SELF-ORGANIZATION, plant root branching, GENE, Multicellular organism, Biophysics, Lateral root branching, EPS, Developmental biology, Genetics and Molecular Biology(all), Developmental Biology

Abstract

Modular, repetitive structures are a key component of complex multicellular body plans across the tree of life. Typically, these structures are prepatterned by temporal oscillations in gene expression or signaling. Although a clock-and-wavefront mechanism was identified and plant leaf phyllotaxis arises from a Turing-type patterning for vertebrate somitogenesis and arthropod segmentation, the mechanism underlying lateral root patterning has remained elusive. To resolve this enigma, we combined computational modeling with in planta experiments. Intriguingly, auxin oscillations automatically emerge in our model from the interplay between a reflux-loop-generated auxin loading zone and stem-cell-driven growth dynamics generating periodic cell-size variations. In contrast to the clock-and-wavefront mechanism and Turing patterning, the uncovered mechanism predicts both frequency and spacing of lateral-root-forming sites to positively correlate with root meristem growth. We validate this prediction experimentally. Combined, our model and experimental results support that a reflux-and-growth patterning mechanism underlies lateral root priming.

Published

2021

43. Keeping development on time: Insights into post-transcriptional mechanisms driving oscillatory gene expression during vertebrate segmentation.

Author

Blatnik MC, Gallagher TL, and Amacher SL

Subjects

Animals, Somites metabolism, RNA metabolism, Gene Expression, Gene Expression Regulation, Developmental, Biological Clocks genetics, Vertebrates genetics

Abstract

Biological time keeping, or the duration and tempo at which biological processes occur, is a phenomenon that drives dynamic molecular and morphological changes that manifest throughout many facets of life. In some cases, the molecular mechanisms regulating the timing of biological transitions are driven by genetic oscillations, or periodic increases and decreases in expression of genes described collectively as a "molecular clock." In vertebrate animals, molecular clocks play a crucial role in fundamental patterning and cell differentiation processes throughout development. For example, during early vertebrate embryogenesis, the segmentation clock regulates the patterning of the embryonic mesoderm into segmented blocks of tissue called somites, which later give rise to axial skeletal muscle and vertebrae. Segmentation clock oscillations are characterized by rapid cycles of mRNA and protein expression. For segmentation clock oscillations to persist, the transcript and protein molecules of clock genes must be short-lived. Faithful, rhythmic, genetic oscillations are sustained by precise regulation at many levels, including post-transcriptional regulation, and such mechanisms are essential for proper vertebrate development. This article is categorized under: RNA Export and Localization > RNA Localization RNA Turnover and Surveillance > Regulation of RNA Stability Translation > Regulation., (© 2022 The Authors. WIREs RNA published by Wiley Periodicals LLC.)

Published

2023

44. Spatial gradients of protein-level time delays set the pace of the traveling segmentation clock waves.

Author

Ay, Ahmet, Holland, Jack, Sperlea, Adriana, Devakanmalai, Gnanapackiam Sheela, Knierer, Stephan, Sangervasi, Sebastian, Stevenson, Angel, and Özbudak, Ertuğrul M.

Subjects

*ZEBRA danio, *GENE expression, *PROTEINS, *ANIMAL models in research, *WAVE mechanics

Abstract

The vertebrate segmentation clock is a gene expression oscillator controlling rhythmic segmentation of the vertebral column during embryonic development. The period of oscillations becomes longer as cells are displaced along the posterior to anterior axis, which results in traveling waves of clock gene expression sweeping in the unsegmented tissue. Although various hypotheses necessitating the inclusion of additional regulatory genes into the core clock network at different spatial locations have been proposed, the mechanism underlying traveling waves has remained elusive. Here, we combined molecular level computational modeling and quantitative experimentation to solve this puzzle. Our model predicts the existence of an increasing gradient of gene expression time delays along the posterior to anterior direction to recapitulate spatiotemporal profiles of the traveling segmentation clock waves in different genetic backgrounds in zebrafish. We validated this prediction by measuring an increased time delay of oscillatory Her1 protein production along the unsegmented tissue. Our results refuted the need for spatial expansion of the core feedback loop to explain the occurrence of traveling waves. Spatial regulation of gene expression time delays is a novel way of creating dynamic patterns; this is the first report demonstrating such a control mechanism in any tissue and future investigations will explore the presence of analogous examples in other biological systems. [ABSTRACT FROM AUTHOR]

Published

2014

45. Interplay between intercellular signaling and cell movement in development.

Author

Uriu, Koichiro, Morelli, Luis G., and Oates, Andrew C.

Subjects

*CELL motility, *ANIMAL development, *CELLULAR signal transduction, *MORPHOGENESIS, *CELL populations, *NEURAL crest, *ZEBRA danio, *PHYSIOLOGY

Abstract

Cell movement and local intercellular signaling are crucial components of morphogenesis during animal development. Intercellular signaling regulates the collective movement of a cell population via direct cell–cell contact. Cell movement, conversely, can influence local intercellular signaling by rearranging neighboring cells. Here, we first discuss theoretical models that address how intercellular signaling regulates collective cell movement during development. Examples include neural crest cell migration, convergent extension, and cell movement during vertebrate axis elongation. Second, we review theoretical studies on how cell movement may affect intercellular signaling, using the segmentation clock in zebrafish as an example. We propose that interplay between cell movement and intercellular signaling must be considered when studying morphogenesis in embryonic development. [ABSTRACT FROM AUTHOR]

Published

2014

46. The roles and mechanism of ultradian oscillatory expression of the mouse Hes genes.

Author

Harima, Yukiko, Imayoshi, Itaru, Shimojo, Hiromi, Kobayashi, Taeko, and Kageyama, Ryoichiro

Subjects

*ULTRADIAN rhythms, *GENE expression, *LABORATORY mice, *SKELETAL muscle, *MESODERM, *INTRONS

Abstract

Somites, metameric structures, give rise to the vertebral column, ribs, skeletal muscles and subcutaneous tissues. In mouse embryos, a pair of somites is formed every 2 h by segmentation of the anterior parts of the presomitic mesoderm. This periodic event is regulated by a biological clock called the segmentation clock, which involves cyclic expression of the basic helix-loop-helix gene Hes7 . Hes7 oscillation is regulated by negative feedback with a delayed timing. This process has been mathematically simulated by differential-delay equations, which predict that negative feedback with shorter delays would abolish oscillations or produce dampened but more rapid oscillations. We found that reducing the number of introns within the Hes7 gene shortens the delay and abolishes Hes7 oscillation or results in a more rapid tempo of Hes7 oscillation, increasing the number of somites and vertebrae in the cervical and upper thoracic region. We also found that Hes1 , a Hes7-related gene, is expressed in an oscillatory manner by many cell types, including fibroblasts and neural stem cells. In these cells, Hes1 expression oscillates with a period of about 2–3 h, and this oscillation is important for cell cycle progression. Furthermore, in neural stem cells, Hes1 oscillation drives cyclic expression of the proneural genes Ascl1 and Neurogenin2 and regulates multipotency. Hes1 expression oscillates more slowly in embryonic stem cells, and Hes1 oscillation regulates their fate preferences. Taken together, these results suggest that oscillatory expression with short periods (ultradian oscillation) is important for many biological events. [ABSTRACT FROM AUTHOR]

Published

2014

47. Fgf4 maintains Hes7 levels critical for normal somite segmentation clock function

Author

Ryoichiro Kageyama, Mark Lewandoski, Matthew J. Anderson, and Valentin Magidson

Subjects

0301 basic medicine, Notch, Mouse, axis extension, QH301-705.5, Science, Connective tissue, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, FGF8, somitogenesis, Somitogenesis, fibroblast growth factor, Paraxial mesoderm, medicine, Segmentation, segmentation clock, Biology (General), General Immunology and Microbiology, General Neuroscience, General Medicine, hybridization chain reaction, Cell biology, Somite, 030104 developmental biology, medicine.anatomical_structure, Medicine, Developmental biology, 030217 neurology & neurosurgery, Vertebral column, Research Article, Developmental Biology

Abstract

During vertebrate development, the presomitic mesoderm (PSM) periodically segments into somites, which will form the segmented vertebral column and associated muscle, connective tissue, and dermis. The periodicity of somitogenesis is regulated by a segmentation clock of oscillating Notch activity. Here, we examined mouse mutants lacking onlyFgf4orFgf8, which we previously demonstrated act redundantly to prevent PSM differentiation.Fgf8is not required for somitogenesis, butFgf4mutants display a range of vertebral defects. We analyzedFgf4mutants by quantifying mRNAs fluorescently labeled by hybridization chain reaction within Imaris-based volumetric tissue subsets. These data indicate that FGF4 maintainsHes7levels and normal oscillatory patterns. To support our hypothesis that FGF4 regulates somitogenesis throughHes7, we demonstrate genetic synergy betweenHes7andFgf4, but not withFgf8. Our data indicate thatFgf4is potentially important in a spectrum of human Segmentation Defects of the Vertebrae caused by defective Notch oscillations.

Published

2020

48. Pulses of Notch activation synchronise oscillating somite cells and entrain the zebrafish segmentation clock.

Author

Soza-Ried, Cristian, Emre Öztürk, Ish-Horowicz, David, and Lewis, Julian

Subjects

*NOTCH genes, *ZEBRA danio, *SOMITE, *CELLS, *SEGMENTATION (Biology)

Abstract

Formation of somites, the rudiments of vertebrate body segments, is an oscillatory process governed by a gene-expression oscillator, the segmentation clock. This operates in each cell of the presomitic mesoderm (PSM), but the individual cells drift out of synchrony when Delta/Notch signalling fails, causing gross anatomical defects. We and others have suggested that this is because synchrony is maintained by pulses of Notch activation, delivered cyclically by each cell to its neighbours, that serve to adjust or reset the phase of the intracellular oscillator. This, however, has never been proved. Here, we provide direct experimental evidence, using zebrafish containing a heat-shock-driven transgene that lets us deliver artificial pulses of expression of the Notch ligand DeltaC. In DeltaC-defective embryos, in which endogenous Notch signalling fails, the artificial pulses restore synchrony, thereby rescuing somite formation. The spacing of segment boundaries produced by repetitive heat-shocking varies according to the time interval between one heat-shock and the next. The induced synchrony is manifest both morphologically and at the level of the oscillations of her1, a core component of the intracellular oscillator. Thus, entrainment of intracellular clocks by periodic activation of the Notch pathway is indeed the mechanism maintaining cell synchrony during somitogenesis. [ABSTRACT FROM AUTHOR]

Published

2014

49. Posterior skeletal development and the segmentation clock period are sensitive to Lfng dosage during somitogenesis.

Author

Williams, Dustin R., Shifley, Emily T., Lather, Jason D., and Cole, Susan E.

Subjects

*SKELETON physiology, *BONE growth, *SEGMENTATION (Biology), *SOMITOGENESIS, *SOMITE, *COMPARATIVE studies, *LABORATORY mice

Abstract

Abstract: The segmental structure of the axial skeleton is formed during somitogenesis. During this process, paired somites bud from the presomitic mesoderm (PSM), in a process regulated by a genetic clock called the segmentation clock. The Notch pathway and the Notch modulator Lunatic fringe (Lfng) play multiple roles during segmentation. Lfng oscillates in the posterior PSM as part of the segmentation clock, but is stably expressed in the anterior PSM during presomite patterning. We previously found that mice lacking overt oscillatory Lfng expression in the posterior PSM (Lfng ∆FCE) exhibit abnormal anterior development but relatively normal posterior development. This suggests distinct requirements for segmentation clock activity during the formation of the anterior skeleton (primary body formation), compared to the posterior skeleton and tail (secondary body formation). To build on these findings, we created an allelic series that progressively lowers Lfng levels in the PSM. Interestingly, we find that further reduction of Lfng expression levels in the PSM does not increase disruption of anterior development. However tail development is increasingly compromised as Lfng levels are reduced, suggesting that primary body formation is more sensitive to Lfng dosage than is secondary body formation. Further, we find that while low levels of oscillatory Lfng in the posterior PSM are sufficient to support relatively normal posterior development, the period of the segmentation clock is increased when the amplitude of Lfng oscillations is low. These data support the hypothesis that there are differential requirements for oscillatory Lfng during primary and secondary body formation and that posterior development is less sensitive to overall Lfng levels. Further, they suggest that modulation of the Notch signaling by Lfng affects the clock period during development. [Copyright &y& Elsevier]

Published

2014

50. 多能性幹細胞を用いたヒト分節時計の再現

Author

Yamanaka, Yoshihiro, 影山, 龍一郎, 妻木, 範行, and 長船, 健二

Subjects

mesoderm development, somitogenesis, disease modeling, pluripotent stem cells, segmentation clock, CRISPR/Cas9, stepwise induction

Published

2020