Your search keyword '"segmentation clock"' showing total 77 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. 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

3. 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

4. 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

5. 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

6. 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

7. 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

8. 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

9. 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

10. 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

11. 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

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

Author

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

Subjects

Circadian clock, CLOCK, CLOCK Proteins, Biology, Mesoderm, Mice, Somitogenesis, circadian clock, Paraxial mesoderm, Transcriptional regulation, Basic Helix-Loop-Helix Transcription Factors, Animals, Gene Regulatory Networks, Circadian rhythm, segmentation clock, Induced pluripotent stem cell, Ultradian rhythm, Multidisciplinary, BMAL1, ARNTL Transcription Factors, Period Circadian Proteins, Biological Sciences, Embryo, Mammalian, Embryonic stem cell, Cell biology, Circadian Rhythm, Organoids, Somites, gastruloid, Developmental Biology

Abstract

Significance Although the circadian clock is essential for regulating the temporal order of physiological functions, circadian oscillation is strictly suppressed in the early-to-mid–stage embryos in mammalian developmental process. The biological significance controlling the suppression of the circadian clock and its delayed emergence in mammalian embryos has been unknown. Here, we show that the premature expression of the functional circadian components CLOCK/BMAL1 in mouse induced presomitic mesoderm and gastruloids can interfere with the segmentation clock Hes7 oscillation and somitogenesis through the Hes7 transcription and its regulatory pathways. This suggests that the CLOCK/BMAL1 function may need to be suppressed during somitogenesis., 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.

Published

2021

13. 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

14. 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

15. 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

16. 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

17. 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

18. 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

19. 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

20. 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

21. Imaging and manipulating the segmentation clock

Author

Kumiko Yoshioka-Kobayashi and Ryoichiro Kageyama

Subjects

Computer science, Design elements and principles, Embryonic Development, Mesoderm, Cellular and Molecular Neuroscience, Body axis, Live cell imaging, Biological Clocks, Somitogenesis, medicine, Paraxial mesoderm, Humans, Molecular Biology, Body Patterning, Pharmacology, Segmentation Clock, Abnormal embryogenesis, Gene Expression Regulation, Developmental, Cell Differentiation, Cell Biology, Models, Theoretical, Somite, medicine.anatomical_structure, Somites, Molecular Medicine, Neuroscience, Signal Transduction

Abstract

During embryogenesis, the processes that control how cells differentiate and interact to form particular tissues and organs with precise timing and shape are of fundamental importance. One prominent example of such processes is vertebrate somitogenesis, which is governed by a molecular oscillator called the segmentation clock. The segmentation clock system is initiated in the presomitic mesoderm in which a set of genes and signaling pathways exhibit coordinated spatiotemporal dynamics to establish regularly spaced boundaries along the body axis; these boundaries provide a blueprint for the development of segment-like structures such as spines and skeletal muscles. The highly complex and dynamic nature of this in vivo event and the design principles and their regulation in both normal and abnormal embryogenesis are not fully understood. Recently, live-imaging has been used to quantitatively analyze the dynamics of selected components of the circuit, particularly in combination with well-designed experiments to perturb the system. Here, we review recent progress from studies using live imaging and manipulation, including attempts to recapitulate the segmentation clock in vitro. In combination with mathematical modeling, these techniques have become essential for disclosing novel aspects of the clock.

Published

2020

22. A segmentation clock patterns cellular differentiation in a bacterial biofilm

Author

Kwang-Tao Chou, Dong-yeon D. Lee, Jian-geng Chiou, Leticia Galera-Laporta, San Ly, Jordi Garcia-Ojalvo, and Gürol M. Süel

Subjects

Spores, Bacterial, Clock and wavefront, Time Factors, Nitrogen, Biofilm, Biophysics, Gene Expression, Gene Expression Regulation, Developmental, Models, Biological, Article, General Biochemistry, Genetics and Molecular Biology, Kinetics, Somitogenesis, Somites, Stress, Physiological, Sporulation, Biofilms, Multicellularity, Pattern formation, Nitrogen stress response, Segmentation clock, Body Patterning, Signal Transduction, Bacillus subtilis

Abstract

Contrary to multicellular organisms that display segmentation during development, communities of unicellular organisms are believed to be devoid of such sophisticated patterning. Unexpectedly, we find that the gene expression underlying the nitrogen stress response of a developing Bacillus subtilis biofilm becomes organized into a ring-like pattern. Mathematical modeling and genetic probing of the underlying circuit indicate that this patterning is generated by a clock and wavefront mechanism, similar to that driving vertebrate somitogenesis. We experimentally validated this hypothesis by showing that predicted nutrient conditions can even lead to multiple concentric rings, resembling segments. We additionally confirmed that this patterning mechanism is driven by cell-autonomous oscillations. Importantly, we show that the clock and wavefront process also spatially patterns sporulation within the biofilm. Together, these findings reveal a biofilm segmentation clock that organizes cellular differentiation in space and time, thereby challenging the paradigm that such patterning mechanisms are exclusive to plant and animal development. We acknowledge Munehiro Asally, Tolga Çağatay, and Katherine Süel for helpful discussions. K.-T.C. acknowledges support from National Institutes of Health grant T32GM127235. J.G.-O. acknowledges support from the Spanish Ministry of Science, Innovation and Universities and FEDER (Project PGC2018-101251-B-I00 and CEX2018-000792-M), and from the Generalitat de Catalunya (ICREA Academia program). G.M.S. acknowledges support for this research from National Institute of General Medical Sciences grants R01 GM121888 and R35 GM139645. G.M.S. is a Howard Hughes Medical Institute - Simons Foundation Faculty Scholar.

Published

2022

23. A segmentation clock operating in blastoderm and germband stages of Tribolium development.

Author

El-Sherif, Ezzat, Averof, Michalis, and Brown, Susan J.

Subjects

*BLASTODERM, *TRIBOLIUM, *INSECT development, *GERM cells, *ARTHROPODA, *VERTEBRATES, *SEGMENTATION (Biology), *SOMITOGENESIS

Abstract

In Drosophila, all segments form in the blastoderm where morphogen gradients spanning the entire anterior-posterior axis of the embryo provide positional information. However, in the beetle Tribolium castaneum and most other arthropods, a number of anterior segments form in the blastoderm, and the remaining segments form sequentially from a posterior growth zone during germband elongation. Recently, the cyclic nature of the pair-rule gene Tc-odd-skipped was demonstrated in the growth zone of Tribolium, indicating that a vertebrate-like segmentation clock is employed in the germband stage of its development. This suggests that two mechanisms might function in the same organism: a Drosophila-like mechanism in the blastoderm, and a vertebrate-like mechanism in the germband. Here, we show that segmentation at both blastoderm and germband stages of Tribolium is based on a segmentation clock. Specifically, we show that the Tribolium primary pair-rule gene, Tc-even-skipped (Tc-eve), is expressed in waves propagating from the posterior pole and progressively slowing until they freeze into stripes; such dynamics are a hallmark of clockbased segmentation. Phase shifts between Tc-eve transcripts and protein confirm that these waves are due to expression dynamics. Moreover, by tracking cells in live embryos and by analyzing mitotic profiles, we found that neither cell movement nor oriented cell division could explain the observed wave dynamics of Tc-eve. These results pose intriguing evolutionary questions, as Drosophila and Tribolium segment their blastoderms using the same genes but different mechanisms. [ABSTRACT FROM AUTHOR]

Published

2012

24. Somitogenesis.

Author

Maroto, Miguel, Bone, Robert A., and Dale, J. Kim

Subjects

*SOMITOGENESIS, *ANIMAL species, *MOLECULAR models, *GASTRULATION, *SEGMENTATION (Biology), *CROSS-species amplification, *GEOMETRIC rigidity

Abstract

A segmented body plan is fundamental to all vertebrate species and this bestows both rigidity and flexibility on the body. Segmentation is initiated through the process of somitogenesis. This article aims to provide a broad and balanced cross-species overview of somitogenesis and to highlight the key molecular and cellular events involved in each stage of segmentation. We highlight where our understanding of this multifaceted process relies on strong experimental evidence as well as those aspects where our understanding still relies largely on models. [ABSTRACT FROM AUTHOR]

Published

2012

25. Lunatic fringe protein processing by proprotein convertases may contribute to the short protein half-life in the segmentation clock

Author

Shifley, Emily T. and Cole, Susan E.

Subjects

*PROTEINS, *LABORATORY mice, *GENETIC mutation, *EXTRACELLULAR space, *SOMITE, *VERTEBRATE embryology

Abstract

Abstract: During vertebrate segmentation, oscillatory activation of Notch signaling is important in the clock that regulates the timing of somitogenesis. In mice, the cyclic activation of NOTCH1 requires the periodic expression of Lunatic fringe (Lfng). For LFNG to play a role in the segmentation clock, its cyclic transcription must be coupled with post-translational mechanisms that confer a short protein half-life. LFNG protein is cleaved and released into the extracellular space, and here we examine the hypothesis that this secretion contributes to a short LFNG intracellular half-life, facilitating rapid oscillations within the segmentation clock. We localize N-terminal protein sequences that control the secretory behavior of fringe proteins and find that LFNG processing is promoted by specific proprotein convertases including furin and SPC6. Mutations that alter LFNG processing increase its intracellular half-life without preventing its secretion. These mutations do not affect the specificity of LFNG function in the Notch pathway, thus regulation of protein half-life affects the duration of LFNG activity without altering its function. Finally, the embryonic expression pattern of Spc6 suggests a role in terminating LFNG activity during somite patterning. These results have important implications for the mechanisms that contribute to the tight control of Notch signaling during vertebrate segmentation. [Copyright &y& Elsevier]

Published

2008

26. Completing the set of h/E(spl) cyclic genes in zebrafish: her12 and her15 reveal novel modes of expression and contribute to the segmentation clock

Author

Shankaran, Sunita S., Sieger, Dirk, Schröter, Christian, Czepe, Carmen, Pauly, Marie-Christin, Laplante, Mary A., Becker, Thomas S., Oates, Andrew C., and Gajewski, Martin

Subjects

*HEREDITY, *ZEBRA danio, *GENE expression, *MESODERM

Abstract

Abstract: Somitogenesis is the key developmental process that lays down the framework for a metameric body in vertebrates. Somites are generated from the un-segmented presomitic mesoderm (PSM) by a pre-patterning process driven by a molecular oscillator termed the segmentation clock. The Delta–Notch intercellular signaling pathway and genes belonging to the hairy (h) and Enhancer of split (E(spl))-related (h/E(spl)) family of transcriptional repressors are conserved components of this oscillator. A subset of these genes, called cyclic genes, is characterized by oscillating mRNA expression that sweeps anteriorly like a wave through the embryonic PSM. Periodic transcriptional repression by H/E(spl) proteins is thought to provide a critical part of a negative feedback loop in the oscillatory process, but it is an open question how many cyclic h/E(spl) genes are involved in the somitogenesis clock in any species, and what distinct roles they might play. From a genome-wide search for h/E(spl) genes in the zebrafish, we previously estimated a total of five cyclic members. Here we report that one of these, the mHes5 homologue her15 actually exists as a very recently duplicated gene pair. We investigate the expression of this gene pair and analyse its regulation and activity in comparison to the paralogous her12 gene, and the other cyclic h/E(spl) genes in the zebrafish. The her15 gene pair and her12 display novel and distinct expression features, including a caudally restricted oscillatory domain and dynamic stripes of expression in the rostral PSM that occur at the future segmental borders. her15 expression stripes demarcate a unique two-segment interval in the rostral PSM. Mutant, morpholino, and inhibitor studies show that her12 and her15 expression in the PSM is regulated by Delta–Notch signaling in a complex manner, and is dependent on her7, but not her1 function. Morpholino-mediated her12 knockdown disrupts cyclic gene expression, indicating that it is a non-redundant core component of the segmentation clock. Over-expression of her12, her15 or her7 disrupts cyclic gene expression and somite border formation, and structure function analysis of Her7 indicates that DNA binding, but not Groucho-recruitment seems to be important in this process. Thus, the zebrafish has five functional cyclic h/E(spl) genes, which are expressed in a distinct spatial configuration. We propose that this creates a segmentation oscillator that varies in biochemical composition depending on position in the PSM. [Copyright &y& Elsevier]

Published

2007

27. Unraveling the nature of the segmentation clock: Intrinsic disorder of clock proteins and their interaction map

Author

Roy, Sourav, Schnell, Santiago, and Radivojac, Predrag

Subjects

*MOLECULAR biology, *PROTEINS, *PROTEIN-protein interactions, *HEREDITY

Abstract

Abstract: Vertebrate segmentation has been proved to be under a strict temporal control governed by a biological clock, known as the segmentation clock. The present experimental evidence suggests that the segmentation clock initiates and maintains its periodic cycle by the periodic activation or inhibition of the Notch signaling pathway as well as the periodic autoregulation of the cyclic genes themselves. In this paper, we investigate the structural and evolutionary properties of the Notch pathway proteins involved in the mice segmentation clock and computationally identify the interaction map within the Notch signaling pathway. The results of our analysis strongly indicate that most of the pathway proteins are intrinsically disordered and that the mechanism of their interaction likely involves helical molecular recognition elements, short loosely structured segments within disordered regions which are directly involved in protein–protein interactions. Predicted interactions are in agreement with gene knock-out studies available in the literature. [Copyright &y& Elsevier]

Published

2006

28. A clock and wavefront mechanism for somite formation

Author

Baker, R.E., Schnell, S., and Maini, P.K.

Subjects

*SOMITE, *EMBRYOLOGY, *DEVELOPMENTAL biology, *BIOCHEMISTRY

Abstract

Abstract: Somitogenesis, the sequential formation of a periodic pattern along the antero-posterior axis of vertebrate embryos, is one of the most obvious examples of the segmental patterning processes that take place during embryogenesis and also one of the major unresolved events in developmental biology. In this article, we develop a mathematical formulation of a new version of the Clock and Wavefront model proposed by Pourquié and co-workers (Dubrulle, J., McGrew, M.J., Pourquié, O., 2001. FGF signalling controls somite boundary position and regulates segmentation clock control of spatiotemporal Hox gene activation. Cell 106, 219–232). Dynamic expression of FGF8 in the presomitic mesoderm constitutes the wavefront of determination which sweeps along the body axis interacting as it moves with the segmentation clock to gate cells into somites. We also show that the model can mimic the anomalies formed when progression of the wavefront is disturbed and make some experimental predictions that can be used to test the hypotheses underlying the model. [Copyright &y& Elsevier]

Published

2006

29. Mouse Nkd1, a Wnt antagonist, exhibits oscillatory gene expression in the PSM under the control of Notch signaling

Author

Ishikawa, Aki, Kitajima, Satoshi, Takahashi, Yu, Kokubo, Hiroki, Kanno, Jun, Inoue, Tohru, and Saga, Yumiko

Subjects

*EMBRYOLOGY, *GENE expression, *MESODERM, *MICE

Abstract

During vertebrate embryogenesis, the formation of reiterated structures along the body axis is dependent upon the generation of the somite by segmentation of the presomitic mesoderm (PSM). Notch signaling plays a crucial role in both the generation and regulation of the molecular clock that provides the spatial information for PSM cells to form somites. In a screen for novel genes involved in somitogenesis, we identified a gene encoding a Wnt antagonist, Nkd1, which is transcribed in an oscillatory manner, and may represent a new member of the molecular clock constituents. The transcription of nkd1 is extremely downregulated in the PSM of vestigial tail (vt/vt), a hypomorphic mutant of Wnt3a, whereas nkd1 oscillations have a similar phase to lunatic fringe (L-fng) transcription and they are arrested in Hes7 (a negative regulator of Notch signaling) deficient embryos. These results suggest that the transcription of nkd1 requires Wnt3a, and that its oscillation patterns depend upon the function of Hes7. Wnt signaling has been postulated to be upstream of Notch signaling but we demonstrate in this study that a Wnt-signal-related gene may also be regulated by Notch signaling. Collectively, our data suggest that the reciprocal interaction of Notch and Wnt signals, and of their respective negative feedback loops, function to organize the segmentation clock required for somitogenesis. [Copyright &y& Elsevier]

Published

2004

30. Segmentation in vertebrates: clock and gradient finally joined.

Author

Aulehla, Alexander and Herrmann, Bernhard G.

Subjects

*SOMITE, *MESODERM, *MOLECULES, *SPINE, *EMBRYOLOGY

Abstract

The vertebral column is derived from somites formed by segmentation of presomitic mesoderm, a fundamental process of vertebrate embryogenesis. Models on the mechanism controlling this process date back some three to four decades. Access to understanding the molecular control of somitogenesis has been gained only recently by the discovery of molecular oscillators (segmentation clock) and gradients of signaling molecules, as predicted by early models. The Notch signaling pathway is linked to the oscillator and plays a decisive role in inter- and intrasomitic boundary formation. An Fgf8 signaling gradient is involved in somite size control. And the (canonical) Wnt signaling pathway, driven by Wnt3a, appears to integrate clock and gradient in a global mechanism controlling the segmentation process. In this review, we discuss recent advances in understanding the molecular mechanism controlling somitogenesis. [ABSTRACT FROM AUTHOR]

Published

2004

31. A Notch feeling of somite segmentation and beyond

Author

Rida, Padmashree C.G., Le Minh, Nguyet, and Jiang, Yun-Jin

Subjects

*SOMITE, *EMBRYOLOGY, *VERTEBRAE, *HOMEOSTASIS

Abstract

Vertebrate segmentation is manifested during embryonic development as serially repeated units termed somites that give rise to vertebrae, ribs, skeletal muscle and dermis. Many theoretical models including the “clock and wavefront” model have been proposed. There is compelling genetic evidence showing that Notch–Delta signaling is indispensable for somitogenesis. Notch receptor and its target genes, Hairy/E(spl) homologues, are known to be crucial for the ticking of the segmentation clock. Through the work done in mouse, chick, Xenopus and zebrafish, an oscillator operated by cyclical transcriptional activation and delayed negative feedback regulation is emerging as the fundamental mechanism underlying the segmentation clock. Ubiquitin-dependent protein degradation and probably other posttranslational regulations are also required. Fgf8 and Wnt3a gradients are important in positioning somite boundaries and, probably, in coordinating tail growth and segmentation. The circadian clock is another biochemical oscillator, which, similar to the segmentation clock, is operated with a negative transcription-regulated feedback mechanism. While the circadian clock uses a more complicated network of pathways to achieve homeostasis, it appears that the segmentation clock exploits the Notch pathway to achieve both signal generation and synchronization. We also discuss mathematical modeling and future directions in the end. [Copyright &y& Elsevier]

Published

2004

32. Formation of Vertebral Precursors: Past Models and Future Predictions.

Author

Baker, Ruth E., Schnell, Santiago, and Maini, Philip K.

Subjects

*VERTEBRATES, *SOMATIC embryogenesis, *MOLECULAR biology

Abstract

Disruption of normal vertebral development results from abnormal formation and segmentation of the vertebral precursors, called somites. Somitogenesis, the sequential formation of a periodic pattern along the antero-posterior axis of vertebrate embryos, is one of the most obvious examples of the segmental patterning processes that take place during embryogenesis and also one of the major unresolved events in developmental biology. We review the most popular models of somite formation: Cooke and Zeeman's clock and wavefront model, Meinhardt's reaction-diffusion model and the cell cycle model of Stern and co-workers, and discuss the consistency of each in the light of recent experimental findings concerning FGF-8 signalling in the presomitic mesoderm (PSM). We present an extension of the cell cycle model to take account of this new experimental evidence, which shows the existence of a determination front whose position in the PSM is controlled by FGF-8 signalling, and which controls the ability of cells to become competent to segment. We conclude that it is, at this stage, perhaps erroneous to favour one of these models over the others. [ABSTRACT FROM AUTHOR]

Published

2003

33. Models for pattern formation in somitogenesis: a marriage of cellular and molecular biology.

Author

Schnell, Santiago, Maini, Philip K., McInerney, Daragh, Gavaghan, David J., and Houston, Paul

Subjects

*MOLECULAR biology, *CELL cycle, *CELL motility

Abstract

Somitogenesis, the process by which a bilaterally symmetric pattern of cell aggregations is laid down in a cranio-caudal sequence in early vertebrate development, provides an excellent model study for the coupling of interactions at the molecular and cellular level. Here, we review some of the key experimental results and theoretical models related to this process. We extend a recent chemical pre-pattern model based on the cell cycle Journal of Theoretical Biology 207 (2000) 305-316, by including cell movement and show that the resultant model exhibits the correct spatio-temporal dynamics of cell aggregation. We also postulate a model to account for the recently observed spatio-temporal dynamics at the molecular level. [Copyright &y& Elsevier]

Published

2002

34. The effect of Rosovitine on mPSM explants: a real time analysis

Author

Kim Dale, Philip J. Murray, L. J. Morales, and Charlotte Bailey

Subjects

Somite, Segmentation Clock, medicine.anatomical_structure, Chemistry, Somitogenesis, Period (gene), medicine, Clock and wavefront model, Chick embryos, Real time analysis, Explant culture, Cell biology

Abstract

Previously we showed, using fixed tissue techniques, that treatment of chick embryos with a family of pharmacological inhibitors yields increased levels of NICD, an increased NICD half life and longer segments (Wiederman et al., 2015). Here we measure the effect of one of the pharmacological perturbations (Roscovtine) using a real time reporter of the somitogenesis clock. After processing the reporter signal using empirical mode decomposition, we measure the oscillator period in mPSM explants and find, in agreement with the previous study, that the period of the segmentation clock increases upon Roscovitine treatment. However, we also make the novel discovery that the differentiation rate of the mPSM tissue also increases upon Roscovitine treatment. Returning to the previous study, we find that the measured increases in somite size and oscillator period are only consistent with the clock and wavefront model if the wavefront velocity also increased.

Published

2019

35. A segmentation clock patterns cellular differentiation in a bacterial biofilm.

Author

Chou, Kwang-Tao, Lee, Dong-yeon D., Chiou, Jian-geng, Galera-Laporta, Leticia, Ly, San, Garcia-Ojalvo, Jordi, and Süel, Gürol M.

Subjects

*ANIMAL development, *BIOFILMS, *UNICELLULAR organisms, *MULTICELLULAR organisms, *PLANT development, *GENETIC models, *MOLECULAR clock, *BACILLUS subtilis

Abstract

Contrary to multicellular organisms that display segmentation during development, communities of unicellular organisms are believed to be devoid of such sophisticated patterning. Unexpectedly, we find that the gene expression underlying the nitrogen stress response of a developing Bacillus subtilis biofilm becomes organized into a ring-like pattern. Mathematical modeling and genetic probing of the underlying circuit indicate that this patterning is generated by a clock and wavefront mechanism, similar to that driving vertebrate somitogenesis. We experimentally validated this hypothesis by showing that predicted nutrient conditions can even lead to multiple concentric rings, resembling segments. We additionally confirmed that this patterning mechanism is driven by cell-autonomous oscillations. Importantly, we show that the clock and wavefront process also spatially patterns sporulation within the biofilm. Together, these findings reveal a biofilm segmentation clock that organizes cellular differentiation in space and time, thereby challenging the paradigm that such patterning mechanisms are exclusive to plant and animal development. [Display omitted] • A bacterial segmentation clock patterns biofilm development • Biofilms organize their nitrogen stress response into concentric rings • The concentric ring pattern segments sporulation in space and time • Bacteria use a clock and wavefront mechanism thought exclusive to vertebrates Bacterial biofilms exhibit a clock and wavefront process that spatially patterns sporulation without requiring long-range diffusion of molecular signals and is reminiscent of patterning mechanisms previously thought to be exclusive to plants and animals. [ABSTRACT FROM AUTHOR]

Published

2022

36. A clock and wavefront mechanism for somite formation

Author

Philip K. Maini, Ruth E. Baker, and Santiago Schnell

Subjects

Biology, Models, Biological, FGF8, Somitogenesis, Biological Clocks, Mathematical formulation, medicine, Paraxial mesoderm, Animals, Humans, Hox gene, Molecular Biology, Body Patterning, Wavefront, Genetics, Clock and wavefront model, Clock and Wavefront model, Cell Biology, Somite, medicine.anatomical_structure, Somites, Segmentation clock, Developmental biology, Neuroscience, Developmental Biology

Abstract

Somitogenesis, the sequential formation of a periodic pattern along the antero-posterior axis of vertebrate embryos, is one of the most obvious examples of the segmental patterning processes that take place during embryogenesis and also one of the major unresolved events in developmental biology. In this article, we develop a mathematical formulation of a new version of the Clock and Wavefront model proposed by Pourquié and co-workers (Dubrulle, J., McGrew, M.J., Pourquié, O., 2001. FGF signalling controls somite boundary position and regulates segmentation clock control of spatiotemporal Hox gene activation. Cell 106, 219–232). Dynamic expression of FGF8 in the presomitic mesoderm constitutes the wavefront of determination which sweeps along the body axis interacting as it moves with the segmentation clock to gate cells into somites. We also show that the model can mimic the anomalies formed when progression of the wavefront is disturbed and make some experimental predictions that can be used to test the hypotheses underlying the model.

Published

2016

37. Topology and dynamics of the zebrafish segmentation clock core circuit

Author

Schröter, Christian, Ares, Saúl, Morelli, Luis G., Isakova, Alina, Hens, Korneel, Soroldoni, Daniele, Gajewski, Martin, Jülicher, Frank, Maerkl, Sebastian J., Deplancke, Bart, Oates, Andrew C., and University of Zurich

Subjects

core circuit, Transcription, Genetic, protein antibody, Biochemistry, Substrate Specificity, purl.org/becyt/ford/1 [https], somitogenesis, SX00 SystemsX.ch, 2400 General Immunology and Microbiology, zebra fish, Protein Interaction Mapping, Molecular Cell Biology, Basic Helix-Loop-Helix Transcription Factors, Protein Interaction Maps, SX05 DynamiX, Biology (General), segmentation clock, Promoter Regions, Genetic, Mathematical Computing, Zebrafish, embryonic structures, Feedback, Physiological, her7 gene, messenger RNA, Protein Stability, molecular clock, Gene Expression Regulation, Developmental, 2800 General Neuroscience, protein function, unclassified drug, Phenotype, Somites, messenger RNA synthesis, transcription factor Her1, Synopsis, transcription factor Her6, transcription regulation, transcription factor Her7, Dimerization, her1 gene, CIENCIAS NATURALES Y EXACTAS, SX20 Research, Technology and Development Projects, QH301-705.5, homodimer, transcription factor Her6 antibody, Otras Ciencias Biológicas, animal experiment, embryo, 1100 General Agricultural and Biological Sciences, Molecular dynamics, protein DNA binding, Models, Biological, Article, animal tissue, Ciencias Biológicas, Model Organisms, Biological Clocks, 1300 General Biochemistry, Genetics and Molecular Biology, Two-Hybrid System Techniques, Genetics, Animals, controlled study, mutant, RNA, Messenger, gene, purl.org/becyt/ford/1.6 [https], her6 gene, Biology, Body Patterning, Vertebrata, Danio rerio, nonhuman, embryo segmentation, genetic network, embryo development, Zebrafish Proteins, Repressor Proteins, basic helix loop helix transcription factor, 570 Life sciences, biology, Prediction, Mathematics, Transcription Factors, Developmental Biology

Abstract

During vertebrate embryogenesis, the rhythmic and sequential segmentation of the body axis is regulated by an oscillating genetic network termed the segmentation clock. We describe a new dynamic model for the core pace-making circuit of the zebrafish segmentation clock based on a systematic biochemical investigation of the network's topology and precise measurements of somitogenesis dynamics in novel genetic mutants. We show that the core pace-making circuit consists of two distinct negative feedback loops, one with Her1 homodimers and the other with Her7:Hes6 heterodimers, operating in parallel. To explain the observed single and double mutant phenotypes of her1, her7, and hes6 mutant embryos in our dynamic model, we postulate that the availability and effective stability of the dimers with DNA binding activity is controlled in a "dimer cloud" that contains all possible dimeric combinations between the three factors. This feature of our model predicts that Hes6 protein levels should oscillate despite constant hes6 mRNA production, which we confirm experimentally using novel Hes6 antibodies. The control of the circuit's dynamics by a population of dimers with and without DNA binding activity is a new principle for the segmentation clock and may be relevant to other biological clocks and transcriptional regulatory networks. © 2012 Schröter et al. Fil: Schroter, Christian. University of Cambridge; Estados Unidos Fil: Ares, Saúl. Max Planck Institute For The Physics Of Complex Systems; Alemania Fil: Morelli, Luis Guillermo. Universidad de Buenos Aires; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Instituto de Física de Buenos Aires. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Instituto de Física de Buenos Aires; Argentina Fil: Isakova, Alina. Ecole Polytechnique Federale de Lausanne; Francia Fil: Hens, Korneel. Ecole Polytechnique Federale de Lausanne; Francia Fil: Soroldoni, Daniele. Max Planck Institute Of Molecular Cell Biology And Genetics; Alemania Fil: Gajewski, Martin. Universitat zu Köln; Alemania Fil: Jülicher, Frank. Max Planck Institute For The Physics Of Complex Systems; Alemania Fil: Maerkl, Sebastian J.. Ecole Polytechnique Federale de Lausanne; Francia Fil: Deplancke, Bart. Ecole Polytechnique Federale de Lausanne; Francia Fil: Oates, Andrew C.. Max Planck Institute Of Molecular Cell Biology And Genetics; Alemania

Published

2016

38. A Lattice model on somitogenesis of zebrafish

Author

Chih-Wen Shih and Kang Ling Liao

Subjects

Physics, Segmentation Clock, biology, Applied Mathematics, Crystal system, biology.organism_classification, Quantitative Biology::Cell Behavior, Synchronous oscillations, Lattice (order), Negative feedback, Somitogenesis, Traveling wave, Discrete Mathematics and Combinatorics, Biological system, Zebrafish

Abstract

Somitogenesis is the process of the development of somites which are segmental structure in vertebrate embryos. This process depends on the expression of segmentation clock genes. In this investigation, we consider lattice systems which describe the kinetics of the chief segmentation clock genes in zebrafish under negative feedback regulation with delay through interaction with the Delta-Notch signaling among neighboring cells. We first derive the analytical theories for the oscillation-arrested and synchronous oscillation in an autonomous lattice model. Based on the parameter regimes in the theories, we design suitable gradients of degradation rates and delays in a non-autonomous lattice model. Such a lattice system can generate synchronous oscillations, oscillatory traveling waves, oscillation slowing down, oscillation-arrested, and high-low expression levels. We further distinguish between different gradient structures which lead to normal and abnormal segmentations respectively and connect these structures to the dynamical regimes in the cell-cell model.

Published

2012

39. Intronic delay is essential for oscillatory expression in the segmentation clock

Author

Toshiyuki Ohtsuka, Ryoichiro Kageyama, Yoshiki Takashima, Hitoshi Miyachi, Aitor González, Department of Systems and Science, Graduate School of Informatics, Kyoto University-Kyoto University, and Kyoto University

Subjects

Gene Expression, Locus (genetics), Biology, Models, Biological, Mice, somitogenesis, intronic delay, Biological Clocks, Somitogenesis, Negative feedback, Gene expression, Basic Helix-Loop-Helix Transcription Factors, medicine, Paraxial mesoderm, Animals, segmentation clock, Gene, ComputingMilieux_MISCELLANEOUS, Feedback, Physiological, Genetics, Multidisciplinary, Intron, negative feedback, oscillation, Biological Sciences, Introns, Cell biology, Somite, medicine.anatomical_structure, Somites, [INFO.INFO-BI]Computer Science [cs]/Bioinformatics [q-bio.QM], Hes7

Abstract

Proper timing of gene expression is essential for many biological events, but the molecular mechanisms that control timing remain largely unclear. It has been suggested that introns contribute to the timing mechanisms of gene expression, but this hypothesis has not been tested with natural genes. One of the best systems for examining the significance of introns is the oscillator network in the somite segmentation clock, because mathematical modeling predicted that oscillating expression depends on negative feedback with a delayed timing. The basic helix–loop–helix repressor gene Hes7 is cyclically expressed in the presomitic mesoderm (PSM) and regulates the somite segmentation. Here, we found that introns lead to an ∼19-min delay in the Hes7 gene expression, and mathematical modeling suggested that without such a delay, Hes7 oscillations would be abolished. To test this prediction, we generated mice carrying the Hes7 locus whose introns were removed. In these mice, Hes7 expression did not oscillate but occurred steadily, leading to severe segmentation defects. These results indicate that introns are indeed required for Hes7 oscillations and point to the significance of intronic delays in dynamic gene expression.

Published

2011

40. Hox collinearity

Author

Anthony J. Durston, Michiel H. W. Hooiveld, Hans J. Jansen, Paul M. J. In der Rieden, and Research Institute Brain and Cognition (B&C)

Subjects

Models, Anatomic, Embryology, Time Factors, animal structures, Transcription, Genetic, Xenopus, collinearity, ECTOPIC EXPRESSION, Biology, HOMEOTIC GENES, CROSS-REGULATION, Models, Biological, hox, TEMPORAL COLINEARITY, Species Specificity, biology.animal, Somitogenesis, evolution, Animals, Humans, Hox gene, DROSOPHILA EMBRYOS, GENE-EXPRESSION, Genetics, Homeodomain Proteins, Models, Genetic, Genes, Homeobox, Vertebrate, Gene Expression Regulation, Developmental, Collinearity, Chromatin, Protein Structure, Tertiary, REGULATES SEGMENTATION, XENOPUS EMBRYOS, Evolutionary biology, BITHORAX COMPLEX, Bithorax complex, embryonic structures, SEGMENTATION CLOCK, Ectopic expression, Drosophila, Homeotic gene, Developmental Biology, Signal Transduction

Abstract

Hox collinearity is a spectacular phenomenon that has excited life scientists since its discovery in 1978. Two mechanisms have been proposed to explain the spatially sequential pattern of Hox gene expression in animal embryonic development: interactions among Hox genes, or the progressive opening of chromatin in the Hox clusters, from 3' to 5'. A review of the evidence across different species and developmental stages points to the universal involvement of trans-acting factors and cell-cell interactions. The evidence focuses attention on interactions between Hox genes and on the vertebrate somitogenesis clock. These novel conclusions open new perspectives for the field.

Published

2011

41. Lunatic fringe protein processing by proprotein convertases may contribute to the short protein half-life in the segmentation clock

Author

Emily T. Shifley and Susan E. Cole

Subjects

Notch, Lunatic fringe, Blotting, Western, Notch signaling pathway, Fluorescent Antibody Technique, Biology, LFNG, Somitogenesis, Mice, Transcription (biology), medicine, Animals, Serrate-Jagged Proteins, Secretion, Cycloheximide, Receptor, Notch1, Molecular Biology, Furin, In Situ Hybridization, Body Patterning, Genetics, Calcium-Binding Proteins, Glycosyltransferases, Membrane Proteins, Cell Biology, Alkaline Phosphatase, Cell biology, Somite, medicine.anatomical_structure, Somites, Mutation, Proprotein Convertase 5, biology.protein, Intercellular Signaling Peptides and Proteins, Segmentation clock, Proprotein Convertases, Protein Processing, Post-Translational, Glycosyltransferase, Half-Life

Abstract

During vertebrate segmentation, oscillatory activation of Notch signaling is important in the clock that regulates the timing of somitogenesis. In mice, the cyclic activation of NOTCH1 requires the periodic expression of Lunatic fringe (Lfng). For LFNG to play a role in the segmentation clock, its cyclic transcription must be coupled with post-translational mechanisms that confer a short protein half-life. LFNG protein is cleaved and released into the extracellular space, and here we examine the hypothesis that this secretion contributes to a short LFNG intracellular half-life, facilitating rapid oscillations within the segmentation clock. We localize N-terminal protein sequences that control the secretory behavior of fringe proteins and find that LFNG processing is promoted by specific proprotein convertases including furin and SPC6. Mutations that alter LFNG processing increase its intracellular half-life without preventing its secretion. These mutations do not affect the specificity of LFNG function in the Notch pathway, thus regulation of protein half-life affects the duration of LFNG activity without altering its function. Finally, the embryonic expression pattern of Spc6 suggests a role in terminating LFNG activity during somite patterning. These results have important implications for the mechanisms that contribute to the tight control of Notch signaling during vertebrate segmentation.

Published

2008

42. A Notch feeling of somite segmentation and beyond

Author

Nguyet Le Minh, Padmashree C.G. Rida, and Yun Jin Jiang

Subjects

Notch, Cleavage Stage, Ovum, Circadian clock, Notch signaling pathway, Protein degradation, Biology, Models, Biological, Wnt, Her1, Somitogenesis, Negative feedback, Morphogenesis, medicine, Fgf, Animals, Segmentation, Molecular Biology, Her7, Receptors, Notch, Modeling, Gene Expression Regulation, Developmental, Membrane Proteins, Clock and wavefront model, Lfng, Anatomy, Cell Biology, Models, Theoretical, Biological Evolution, Circadian Rhythm, Hes1, Somite, medicine.anatomical_structure, Somites, Delta, Vertebrates, Gradient, Segmentation clock, Neuroscience, Hes7, Signal Transduction, Developmental Biology

Abstract

Vertebrate segmentation is manifested during embryonic development as serially repeated units termed somites that give rise to vertebrae, ribs, skeletal muscle and dermis. Many theoretical models including the “clock and wavefront” model have been proposed. There is compelling genetic evidence showing that Notch–Delta signaling is indispensable for somitogenesis. Notch receptor and its target genes, Hairy/E(spl) homologues, are known to be crucial for the ticking of the segmentation clock. Through the work done in mouse, chick, Xenopus and zebrafish, an oscillator operated by cyclical transcriptional activation and delayed negative feedback regulation is emerging as the fundamental mechanism underlying the segmentation clock. Ubiquitin-dependent protein degradation and probably other posttranslational regulations are also required. Fgf8 and Wnt3a gradients are important in positioning somite boundaries and, probably, in coordinating tail growth and segmentation. The circadian clock is another biochemical oscillator, which, similar to the segmentation clock, is operated with a negative transcription-regulated feedback mechanism. While the circadian clock uses a more complicated network of pathways to achieve homeostasis, it appears that the segmentation clock exploits the Notch pathway to achieve both signal generation and synchronization. We also discuss mathematical modeling and future directions in the end.

Published

2004

43. A Hes1-based oscillator in cultured cells and its potential implications for the segmentation clock

Author

J. Kim Dale and Miguel Maroto

Subjects

Cell type, Time Factors, Transcription, Genetic, Notch signaling pathway, Gene Expression, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Biological Clocks, Oscillometry, Somitogenesis, Morphogenesis, Animals, Segmentation, HES1, Cells, Cultured, Homeodomain Proteins, Genetics, Segmentation Clock, Receptors, Notch, Mechanism (biology), Gene Expression Regulation, Developmental, Membrane Proteins, CLOCK, Somites, Vertebrates, Calcium, Neuroscience, Signal Transduction

Abstract

During somitogenesis an oscillatory mechanism termed the “segmentation” clock generates periodic waves of gene expression, which translate into the periodic spatial pattern manifest as somites. The dynamic expression of the clock genes shares the same periodicity as somitogenesis. Notch signaling is believed to play a role in the segmentation clock mechanism. The paper by Hirata et al.(1) identifies a biological clock in cultured cells that is dependent upon the Notch target gene Hes1, and which shows a periodicity similar to that of the segmentation clock. This finding opens the possibility that the same oscillator mechanism might also operate in other tissues or cell types. BioEssays 25:200–203, 2003. © 2003 Wiley Periodicals, Inc.

Published

2003

44. Recent advances in understanding vertebrate segmentation

Author

Isabel Palmeirim, Isabel Duarte, Tomás Pais-de-Azevedo, and Ramiro Magno

Subjects

0301 basic medicine, Computer science, Review, Machine learning, computer.software_genre, General Biochemistry, Genetics and Molecular Biology, Somitogenesis, 03 medical and health sciences, Segmentation, Expression pattern, Clock, Wavefront, biology.animal, Pattern Formation, General Pharmacology, Toxicology and Pharmaceutics, Spatial analysis, Segmentation Clock, General Immunology and Microbiology, biology, Vertebrate, business.industry, Clock and wavefront model, Articles, General Medicine, Oscillation, 030104 developmental biology, Body plan, Embryo, Artificial intelligence, business, computer

Abstract

Segmentation is the partitioning of the body axis into a series of repeating units or segments. This widespread body plan is found in annelids, arthropods, and chordates, showing it to be a successful developmental strategy for growing and generating diverse morphology and anatomy. Segmentation has been extensively studied over the years. Forty years ago, Cooke and Zeeman published the Clock and Wavefront model, creating a theoretical framework of how developing cells could acquire and keep temporal and spatial information in order to generate a segmented pattern. Twenty years later, in 1997, Palmeirim and co-workers found the first clock gene whose oscillatory expression pattern fitted within Cooke and Zeeman’s model. Currently, in 2017, new experimental techniques, such as new ex vivo experimental models, real-time imaging of gene expression, live single cell tracking, and simplified transgenics approaches, are revealing some of the fine details of the molecular processes underlying the inner workings of the segmentation mechanisms, bringing new insights into this fundamental process. Here we review and discuss new emerging views that further our understanding of the vertebrate segmentation clock, with a particular emphasis on recent publications that challenge and/or complement the currently accepted Clock and Wavefront model.

Published

2018

45. A mathematical investigation of a Clock and Wavefront model for somitogenesis

Author

Baker, R.E., Schnell, S., and Maini, P.K.

Published

2006

46. Wnt-regulated dynamics of positional information in zebrafish somitogenesis

Author

Luis G. Morelli, Jacques Pecreaux, Saúl Ares, Frank Jülicher, Lola Bajard, Andrew C. Oates, Max Planck Institute of Molecular Cell Biology and Genetics (MPI-CBG), Max-Planck-Gesellschaft, and Max-Planck-Institut für Physik (Werner-Heisenberg-Institut) (MPI-P)

Subjects

Body Patterning, Matemáticas, Bioinformatics, Fibroblast growth factor, Animals, Genetically Modified, purl.org/becyt/ford/1 [https], somite, somitogenesis, Models, Somitogenesis, zebra fish, Basic Helix-Loop-Helix Transcription Factors, Developmental, Zebrafish, Wnt Signaling Pathway, Research Articles, Biología del Desarrollo, Embryonic elongation, Wnt signaling pathway, Time-lapse microscopy, Gene Expression Regulation, Developmental, Clock and wavefront model, notochord, oscillation, heat shock, Cell biology, medicine.anatomical_structure, priority journal, Somites, immunohistochemistry, Intercellular Signaling Peptides and Proteins, flow rate, fluorescence, Segmentation clock, CIENCIAS NATURALES Y EXACTAS, Signaling Gradients, regulatory mechanism, Fgf signaling, animal experiment, Morphogenesis, embryo, morphogenesis, Genetically Modified, Biology, Models, Biological, Article, Ciencias Biológicas, medicine, Animals, controlled study, purl.org/becyt/ford/1.6 [https], Molecular Biology, [SDV.GEN]Life Sciences [q-bio]/Genetics, nonhuman, Zebrafish Proteins, biology.organism_classification, Biological, Wnt protein, Wnt signaling, Fibroblast Growth Factors, Wnt Proteins, Somite, Gene Expression Regulation, Gene expression, in situ hybridization, sense organs, T-Box Domain Proteins, Signal gradient, Heat-Shock Response, Developmental Biology

Abstract

How signaling gradients supply positional information in a field of moving cells is an unsolved question in patterning and morphogenesis. Here, we ask how a Wnt signaling gradient regulates the dynamics of a wavefront of cellular change in a flow of cells during somitogenesis. Using time-controlled perturbations of Wnt signaling in the zebrafish embryo, we changed segment length without altering the rate of somite formation or embryonic elongation. This result implies specific Wnt regulation of the wavefront velocity. The observed Wnt signaling gradient dynamics and timing of downstream events support a model for wavefront regulation in which cell flow plays a dominant role in transporting positional information. Fil: Bajard, Lola. Max Planck Institute of Molecular Cell Biology and Genetics; Alemania Fil: Morelli, Luis Guillermo. Max Planck Institute of Molecular Cell Biology and Genetics; Alemania. Max Planck Institute for the Physics of Complex Systems; Alemania. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina Fil: Ares, Saúl. Max Planck Institute for the Physics of Complex Systems; Alemania Fil: Pécréaux, Jacques. Max Planck Institute of Molecular Cell Biology and Genetics; Alemania Fil: Jülicher, Frank. Max Planck Institute for the Physics of Complex Systems; Alemania Fil: Oates, Andrew C.. Max Planck Institute of Molecular Cell Biology and Genetics; Alemania

Published

2014

47. A large-scale view of the evolution of amniote development: insights from somitogenesis in reptiles

Author

Kenro Kusumi, Catherine M. May, and Walter L. Eckalbar

Subjects

Scale (anatomy), Gene regulatory network, Zoology, Embryonic Development, Mice, Biological Clocks, Somitogenesis, biology.animal, Genetics, medicine, Morphogenesis, Animals, Body Patterning, Segmentation Clock, biology, Lizard, Gene Expression Regulation, Developmental, Reptiles, biology.organism_classification, Biological Evolution, Somite, medicine.anatomical_structure, Somites, Evolutionary biology, Amniote, Developmental Biology

Abstract

Uncovering the genetic and developmental changes that generate morphological diversity is one of the longstanding challenges in biology. The developmental process generating the spine, one of the defining features of vertebrates, constitutes one of these core questions. The vertebral column is patterned in early development through the formation of segments, called somites, regulated by gene networks collectively called the segmentation clock. While previous studies of somite development in amniotes have focused almost exclusively on the mouse and chick model systems, the growing availability of genomic sequences in other taxa has opened up the possibility of comparative developmental studies in nontraditional reptilian models, such as the anole lizard, alligator, and snake. These studies have identified conserved features of the segmentation clock, but they have also challenged previous assumptions and identified divergence in the genetic networks. Ongoing work will help to elucidate which of these morphological changes may be explained by divergences in development in amniote evolution.

Published

2013

48. Sonic hedgehog in temporal control of somite formation

Author

Ana Teresa Tavares, Mónica Ferreira, Isabel Palmeirim, Raquel P. Andrade, Marie-Aimée Teillet, Tatiana P. Resende, and Universidade do Minho

Subjects

Signaling pathways, Time Factors, Chick Embryo, Induction, Mesoderm, 0302 clinical medicine, somitogenesis, Somitogenesis, Gene-expression, Sonic hedgehog, 0303 health sciences, Multidisciplinary, biology, Clock and wavefront model, molecular clock, Gene Expression Regulation, Developmental, Biological Sciences, Cell biology, medicine.anatomical_structure, Somites, embryonic structures, Presomitic mesoderm, Segmentation clock, Chick limb, Signal Transduction, medicine.medical_specialty, Homolog, animal structures, Notochord, Tretinoin, 03 medical and health sciences, Biological Clocks, Internal medicine, GLI3, medicine, Paraxial mesoderm, Retinoic acid, Animals, Hedgehog Proteins, 030304 developmental biology, Body Patterning, Science & Technology, fungi, Somite, Endocrinology, biology.protein, Smoothened, 030217 neurology & neurosurgery

Abstract

Vertebrate embryo somite formation is temporally controlled by the cyclic expression of somitogenesis clock genes in the presomitic mesoderm (PSM). The somitogenesis clock is believed to be an intrinsic property of this tissue, operating independently of embryonic midline structures and the signaling molecules produced therein, namely Sonic hedgehog (Shh). This work revisits the notochord signaling contribution to temporal control of PSM segmentation by assessing the rate and number of somites formed and somitogenesis molecular clock gene expression oscillations upon notochord ablation. The absence of the notochord causes a delay in somite formation, accompanied by an increase in the period of molecular clock oscillations. Shh is the notochord-derived signal responsible for this effect, as these alterations are recapitulated by Shh signaling inhibitors and rescued by an external Shh supply. We have characterized chick smoothened expression pattern and have found that the PSM expresses both patched1 and smoothened Shh signal transducers. Upon notochord ablation, patched1, gli1, and fgf8 are down-regulated, whereas gli2 and gli3 are overexpressed. Strikingly, notochord-deprived PSM segmentation rate recovers over time, concomitant with raldh2 overexpression. Accordingly, exogenous RA supplement rescues notochord ablation effects on somite formation. A model is presented in which Shh and RA pathways converge to inhibit PSM Gli activity, ensuring timely somite formation. Altogether, our data provide evidence that a balance between different pathways ensures the robustness of timely somite formation and that notochord-derived Shh is a component of the molecular network regulating the pace of the somitogenesis clock., We thank R. Moura, C.J. Sheeba, F. Bajanca, and O. Martinho for helpful input regarding this work, and N. Le Dourain and L. Sa de for critical reading of the manuscript. We also wish to acknowledge stimulating insights provided by the Reviewers. T.P.R was supported by Fundacao para a Ciencia e a Tecnologia (FCT), Portugal (SFRH/BD/27796/2006); R.P.A. is funded by a Ciencia2007 Program Contract (Portuguese Government). This work was supported by FCT, Portugal (Projects PTDC/SAU-OBD/099758/2008 and PTDC/SAU-OBD/105111/2008), the EU/FP6-Network of Excellence-"Cells into Organs" and IBB/CBME, LA, FEDER/POCI 2010.

Published

2010

49. Interfering with Wnt signalling alters the periodicity of the segmentation clock

Author

Kristin R. Melton, Anna Zagórska, Gennady Tenin, Paul A. Trainor, Sarah Gibb, J. Kim Dale, Irene Vacca, and Miguel Maroto

Subjects

Mesoderm, animal structures, Notch, Mouse, Period (gene), Chick Embryo, Biology, Chick, Article, 03 medical and health sciences, Mice, Wnt, 0302 clinical medicine, Biological Clocks, Somitogenesis, medicine, Paraxial mesoderm, Animals, Somite, Molecular Biology, 030304 developmental biology, Body Patterning, Genetics, 0303 health sciences, Receptors, Notch, Wnt signaling pathway, Clock and wavefront model, Gene Expression Regulation, Developmental, Cell Biology, Embryo, Mammalian, Cell biology, CLOCK, Wnt Proteins, medicine.anatomical_structure, Somites, Embryo, embryonic structures, Female, Segmentation clock, 030217 neurology & neurosurgery, Developmental Biology, Signal Transduction

Abstract

Somites are embryonic precursors of the ribs, vertebrae and certain dermis tissue. Somite formation is a periodic process regulated by a molecular clock which drives cyclic expression of a number of clock genes in the presomitic mesoderm. To date the mechanism regulating the period of clock gene oscillations is unknown. Here we show that chick homologues of the Wnt pathway genes that oscillate in mouse do not cycle across the chick presomitic mesoderm. Strikingly we find that modifying Wnt signalling changes the period of Notch driven oscillations in both mouse and chick but these oscillations continue. We propose that the Wnt pathway is a conserved mechanism that is involved in regulating the period of cyclic gene oscillations in the presomitic mesoderm.

Published

2008

50. Completing the set of h/E(spl) cyclic genes in zebrafish: her12 and her15 reveal novel modes of expression and contribute to the segmentation clock

Author

Dirk Sieger, Thomas Becker, Marie-Christin Pauly, Christian Schröter, Andrew C. Oates, Martin Gajewski, Sunita S. Shankaran, Mary Laplante, and Carmen Czepe

Subjects

Morpholino, Molecular Sequence Data, Biology, Mesoderm, Somitogenesis, Biological Clocks, Gene expression, medicine, Basic Helix-Loop-Helix Transcription Factors, Animals, Amino Acid Sequence, RNA, Messenger, Enhancer, Molecular Biology, Zebrafish, Body Patterning, Regulation of gene expression, Genetics, Gene knockdown, Genome, fungi, Cyclic h/E(spl) genes, Gene Expression Regulation, Developmental, Cell Biology, Zebrafish Proteins, biology.organism_classification, Cell biology, Repressor Proteins, Somite, medicine.anatomical_structure, bHLH transcription factor, Segmentation clock, Developmental Biology

Abstract

Somitogenesis is the key developmental process that lays down the framework for a metameric body in vertebrates. Somites are generated from the un-segmented presomitic mesoderm (PSM) by a pre-patterning process driven by a molecular oscillator termed the segmentation clock. The Delta–Notch intercellular signaling pathway and genes belonging to the hairy (h) and Enhancer of split (E(spl))-related (h/E(spl)) family of transcriptional repressors are conserved components of this oscillator. A subset of these genes, called cyclic genes, is characterized by oscillating mRNA expression that sweeps anteriorly like a wave through the embryonic PSM. Periodic transcriptional repression by H/E(spl) proteins is thought to provide a critical part of a negative feedback loop in the oscillatory process, but it is an open question how many cyclic h/E(spl) genes are involved in the somitogenesis clock in any species, and what distinct roles they might play. From a genome-wide search for h/E(spl) genes in the zebrafish, we previously estimated a total of five cyclic members. Here we report that one of these, the mHes5 homologue her15 actually exists as a very recently duplicated gene pair. We investigate the expression of this gene pair and analyse its regulation and activity in comparison to the paralogous her12 gene, and the other cyclic h/E(spl) genes in the zebrafish. The her15 gene pair and her12 display novel and distinct expression features, including a caudally restricted oscillatory domain and dynamic stripes of expression in the rostral PSM that occur at the future segmental borders. her15 expression stripes demarcate a unique two-segment interval in the rostral PSM. Mutant, morpholino, and inhibitor studies show that her12 and her15 expression in the PSM is regulated by Delta–Notch signaling in a complex manner, and is dependent on her7, but not her1 function. Morpholino-mediated her12 knockdown disrupts cyclic gene expression, indicating that it is a non-redundant core component of the segmentation clock. Over-expression of her12, her15 or her7 disrupts cyclic gene expression and somite border formation, and structure function analysis of Her7 indicates that DNA binding, but not Groucho-recruitment seems to be important in this process. Thus, the zebrafish has five functional cyclic h/E(spl) genes, which are expressed in a distinct spatial configuration. We propose that this creates a segmentation oscillator that varies in biochemical composition depending on position in the PSM.

Published

2006