Your search keyword '"Somites growth & development"' showing total 62 results

51. [Notch pathway: from development to regeneration of skeletal muscle].

Author

Mayeuf A and Relaix F

Subjects

Aging physiology, Animals, Cell Differentiation, Cell Lineage, Embryonic Development physiology, Gene Expression Regulation, Developmental physiology, Humans, Mice, Models, Biological, Muscle Cells cytology, Muscle Cells physiology, Muscle, Skeletal embryology, Muscle, Skeletal growth & development, Protein Structure, Tertiary, Receptors, Notch chemistry, Signal Transduction physiology, Somites growth & development, Vertebrates embryology, Vertebrates physiology, Muscle Development physiology, Muscle, Skeletal physiology, Receptors, Notch physiology, Regeneration physiology

Abstract

In vertebrates, skeletal muscle is derived from mesodermal structures called somites. Myogenic progenitor cells that form skeletal muscles of the trunk and limbs are derived from the dermomyotome, the dorsal region of the somite. These cells enter the myogenic program by activating a set of four myogenic regulatory factors. During embryonic and fetal growth, muscle progenitor cells provide the source for muscle growth. Around birth, the muscle progenitor enters quiescence, and adopts a satellite cell position on muscle fibers, providing a pool of adult muscle stem cells. They are essential for the growth and regeneration of muscles. Among the mechanisms that control the maintenance of satellite cells properties, the Notch pathway plays a crucial role. In facts, this pathway is implicated from the early steps of somitogenesis and the development of skeletal muscles in the embryo. Furthermore, during ageing, Notch activity decreases which results in decreased muscle regeneration. Thus, the Notch pathway is a key regulator of muscle plasticity., (© 2011 médecine/sciences - Inserm / SRMS.)

Published

2011

52. Embryonic development of the emu, Dromaius novaehollandiae.

Author

Nagai H, Mak SS, Weng W, Nakaya Y, Ladher R, and Sheng G

Subjects

Animals, Cell Size, Chick Embryo, Cloning, Molecular, Dromaiidae genetics, Embryo, Nonmammalian, Embryonic Development genetics, Fetal Proteins genetics, Gene Expression Regulation, Developmental, Genes, Developmental, Glycoproteins genetics, Hedgehog Proteins genetics, Intercellular Signaling Peptides and Proteins genetics, Somites embryology, Somites growth & development, T-Box Domain Proteins genetics, Time-Lapse Imaging, Zygote cytology, Zygote growth & development, Dromaiidae embryology, Embryonic Development physiology

Abstract

The chick, Gallus gallus, is the traditional model in avian developmental studies. Data on other bird species are scarce. Here, we present a comparative study of the embryonic development of the chick and the emu Dromaius novaehollandiae, a member of Paleognathae, which also includes the ostrich, rhea, tinamou, kiwi, and cassowary. Emu embryos ranging from Hamburger and Hamilton (HH) equivalent stages 1 to 43 were collected and their gross morphology analyzed. Its early development was studied in detail with time-lapse imaging and molecular techniques. Emu embryos in general take 2-3 times longer incubation time to reach equivalent chicken stages, requiring 1 day for HH2, 2.5 days for HH4, 7 days for limb bud initiation, 23 days for feather germ appearance, and approximately 50-56 days for hatching. Chordin gene expression is similar in emu and chick embryos, and emu Brachyury is not expressed until HH3. Circulation is established at approximately the 27- to 30-somite stage. Forelimb buds are formed and patterned initially, but their growth is severely retarded. The size difference between an emu and a chick embryo only becomes apparent after limb bud formation. Overall, emu and chick embryogenesis proceeds through similar stages, but developmental heterochrony between these two species is widely observed., (© 2010 Wiley-Liss, Inc.)

Published

2011

53. Distinct Sonic Hedgehog signaling dynamics specify floor plate and ventral neuronal progenitors in the vertebrate neural tube.

Author

Ribes V, Balaskas N, Sasai N, Cruz C, Dessaud E, Cayuso J, Tozer S, Yang LL, Novitch B, Marti E, and Briscoe J

Subjects

Animals, Biomarkers metabolism, Chick Embryo, Down-Regulation, Embryo, Mammalian, Embryo, Nonmammalian, Female, Mice, Neurons cytology, Somites growth & development, Time Factors, Zebrafish, Body Patterning physiology, Hedgehog Proteins metabolism, Neural Tube cytology, Neural Tube growth & development, Signal Transduction, Stem Cells physiology

Abstract

The secreted ligand Sonic Hedgehog (Shh) organizes the pattern of cellular differentiation in the ventral neural tube. For the five neuronal subtypes, increasing levels and durations of Shh signaling direct progenitors to progressively more ventral identities. Here we demonstrate that this mode of action is not applicable to the generation of the most ventral cell type, the nonneuronal floor plate (FP). In chick and mouse embryos, FP specification involves a biphasic response to Shh signaling that controls the dynamic expression of key transcription factors. During gastrulation and early somitogenesis, FP induction depends on high levels of Shh signaling. Subsequently, however, prospective FP cells become refractory to Shh signaling, and this is a prerequisite for the elaboration of their identity. This prompts a revision to the model of graded Shh signaling in the neural tube, and provides insight into how the dynamics of morphogen signaling are deployed to extend the patterning capacity of a single ligand. In addition, we provide evidence supporting a common scheme for FP specification by Shh signaling that reconciles mechanisms of FP development in teleosts and amniotes.

Published

2010

54. Homeotic effects, somitogenesis and the evolution of vertebral numbers in recent and fossil amniotes.

Author

Müller J, Scheyer TM, Head JJ, Barrett PM, Werneburg I, Ericson PG, Pol D, and Sánchez-Villagra MR

Subjects

Animals, Body Patterning genetics, Ecosystem, Genes, Homeobox, Mammals anatomy & histology, Mammals classification, Mammals genetics, Mammals growth & development, Phylogeny, Reptiles anatomy & histology, Reptiles classification, Reptiles genetics, Reptiles growth & development, Somites anatomy & histology, Somites growth & development, Vertebrates anatomy & histology, Vertebrates classification, Vertebrates genetics, Vertebrates growth & development, Biological Evolution, Fossils, Spine anatomy & histology, Spine growth & development

Abstract

The development of distinct regions in the amniote vertebral column results from somite formation and Hox gene expression, with the adult morphology displaying remarkable variation among lineages. Mammalian regionalization is reportedly very conservative or even constrained, but there has been no study investigating vertebral count variation across Amniota as a whole, undermining attempts to understand the phylogenetic, ecological, and developmental factors affecting vertebral column variation. Here, we show that the mammalian (synapsid) and reptilian lineages show early in their evolutionary histories clear divergences in axial developmental plasticity, in terms of both regionalization and meristic change, with basal synapsids sharing the conserved axial configuration of crown mammals, and basal reptiles demonstrating the plasticity of extant taxa. We conducted a comprehensive survey of presacral vertebral counts across 436 recent and extinct amniote taxa. Vertebral counts were mapped onto a generalized amniote phylogeny as well as individual ingroup trees, and ancestral states were reconstructed by using squared-change parsimony. We also calculated the relationship between presacral and cervical numbers to infer the relative influence of homeotic effects and meristic changes and found no correlation between somitogenesis and Hox-mediated regionalization. Although conservatism in presacral numbers characterized early synapsid lineages, in some cases reptiles and synapsids exhibit the same developmental innovations in response to similar selective pressures. Conversely, increases in body mass are not coupled with meristic or homeotic changes, but mostly occur in concert with postembryonic somatic growth. Our study highlights the importance of fossils in large-scale investigations of evolutionary developmental processes.

Published

2010

55. Balancing segmentation and laterality during vertebrate development.

Author

Brend T and Holley SA

Subjects

Animals, Somites growth & development, Vertebrates, Body Patterning, Embryonic Development

Abstract

Somites are the mesodermal segments of vertebrate embryos that become the vertebral column, skeletal muscle and dermis. Somites arise within the paraxial mesoderm by the periodic, bilaterally symmetric process of somitogenesis. However, specification of left-right asymmetry occurs in close spatial and temporal proximity to somitogenesis and involves some of the same cell signaling pathways that govern segmentation. Here, we review recent evidence that identifies cross-talk between these processes and that demonstrates a role for retinoic acid in maintaining symmetrical somitogenesis by preventing impingement of left-right patterning signals upon the paraxial mesoderm.

Published

2009

56. EphrinB2 coordinates the formation of a morphological boundary and cell epithelialization during somite segmentation.

Author

Watanabe T, Sato Y, Saito D, Tadokoro R, and Takahashi Y

Subjects

Animals, Cell Polarity, Chick Embryo, Mice, Morphogenesis genetics, Receptor, EphA4 metabolism, Somites cytology, Somites metabolism, Basic Helix-Loop-Helix Transcription Factors metabolism, Ephrin-B2 genetics, Gene Expression Regulation, Developmental, Somites growth & development

Abstract

During early morphogenesis, tissue segregation is often accompanied by changes in cell shape. To understand how such coordination is regulated, somitogenesis was used as a model. When a somite forms in the anterior end of the presomitic mesoderm, an intersomitic boundary (gap) emerges, and it is rapidly followed by cell epithelialization at this border. It has been known that the gap formation is regulated by intercellular signals. We here demonstrate that cMeso-1, the chicken homolog of mouse Mesp2, up-regulates EphA4 in the cells located posteriorly to a forming boundary. This in turn activates EphrinB2-reverse signals in the anteriorly juxtaposed cells, where the EphrinB2 signal is sufficient to cause a gap formation and cell epithelialization cell-autonomously. During these processes, Cdc42 needs to be repressed via tyrosine phosphorylation of EphrinB2. This is the first demonstration that Ephrin-reverse signal acts as a platform that couples distinct morphogenetic changes in cell polarity and tissue shape.

Published

2009

57. Normal forebrain development may require continual Wnt antagonism until mid-somitogenesis in zebrafish.

Author

Kim JD, Chun HS, Kim SH, Kim HS, Kim YS, Kim MJ, Shin J, Rhee M, Yeo SY, and Huh TL

Subjects

Animals, Animals, Genetically Modified, Homeodomain Proteins metabolism, Prosencephalon metabolism, Somites metabolism, Transcription Factors metabolism, Wnt Proteins metabolism, Zebrafish genetics, Zebrafish metabolism, Frizzled Receptors biosynthesis, Prosencephalon growth & development, Receptors, G-Protein-Coupled biosynthesis, Somites growth & development, Wnt Proteins antagonists & inhibitors, Zebrafish growth & development, Zebrafish Proteins biosynthesis

Abstract

During normal forebrain development in vertebrates, rostral neural tissue must be protected from Wnt signals via the actions of locally expressed Wnt antagonistic factors. In zebrafish zygotic oep (Zoep) mutants, forebrain structure is severely disrupted with reduced expression of the Wnt antagonists secreted frizzled related protein1 and dickkopf1. To analyze the temporal effects of Wnt antagonism on forebrain development, we generated transgenic zebrafish that overexpressed the dominant negative form of frizzled8a (DNfz8a) in wild-type and Zoep mutants under the control of a heat-inducible promoter. This model allowed for assessment of the dynamics of Wnt antagonistic signaling during forebrain development. Our results demonstrated that overexpression of DNfz8a in Zoep embryos between 7 and 16hpf increased putative forebrain region demarcated by anf and distal-less2 expressions. These results suggest that normal forebrain development requires continual Wnt antagonism from the early gastrula to the mid-somitogenesis stage.

Published

2009

58. Trim36/Haprin plays a critical role in the arrangement of somites during Xenopus embryogenesis.

Author

Yoshigai E, Kawamura S, Kuhara S, and Tashiro K

Subjects

Animals, Carrier Proteins genetics, Embryo, Nonmammalian, Embryonic Development genetics, Gene Knockdown Techniques, Intracellular Signaling Peptides and Proteins, Oligonucleotides, Antisense genetics, Somites metabolism, Somites ultrastructure, Xenopus Proteins, Xenopus laevis genetics, Xenopus laevis metabolism, Carrier Proteins physiology, Somites growth & development, Xenopus laevis embryology

Abstract

The TRIM family members contain a tripartite motif (TRIM), which includes RING, B-box, and coiled-coil domains, or collectively RBCC. They have been implicated in a variety of biological processes, such as the regulation of differentiation and development, and oncogenesis. In this study, we discovered a novel function of the TRIM family in early development. We report the expression of Trim36/Haprin during Xenopus laevis early embryogenesis and its involvement in somite formation. Temporal expression analysis indicated that Trim36/Haprin was present throughout embryogenesis. Spatial expression analysis showed that its expression was mainly confined to the nervous system and a portion of the posterior somite. Morpholino-mediated knockdown of Trim36/Haprin markedly and specifically inhibited the somite formation. We conclude that Trim36/Haprin plays an important role in the arrangement of somites during their formation.

Published

2009

59. Adding adhesion to a chemical signaling model for somite formation.

Author

Armstrong NJ, Painter KJ, and Sherratt JA

Subjects

Embryonic Induction physiology, Somites embryology, Somites growth & development, Cell Adhesion physiology, Models, Biological, Second Messenger Systems physiology, Somites cytology

Abstract

Somites are condensations of mesodermal cells that form along the two sides of the neural tube during early vertebrate development. They are one of the first instances of a periodic pattern, and give rise to repeated structures such as the vertebrae. A number of theories for the mechanisms underpinning somite formation have been proposed. For example, in the "clock and wavefront" model (Cooke and Zeeman in J. Theor. Biol. 58:455-476, 1976), a cellular oscillator coupled to a determination wave progressing along the anterior-posterior axis serves to group cells into a presumptive somite. More recently, a chemical signaling model has been developed and analyzed by Maini and coworkers (Collier et al. in J. Theor. Biol. 207:305-316, 2000; Schnell et al. in C. R. Biol. 325:179-189, 2002; McInerney et al. in Math. Med. Biol. 21:85-113, 2004), with equations for two chemical regulators with entrained dynamics. One of the chemicals is identified as a somitic factor, which is assumed to translate into a pattern of cellular aggregations via its effect on cell-cell adhesion. Here, the authors propose an extension to this model that includes an explicit equation for an adhesive cell population. They represent cell adhesion via an integral over the sensing region of the cell, based on a model developed previously for adhesion driven cell sorting (Armstrong et al. in J. Theor. Biol. 243:98-113, 2006). The expanded model is able to reproduce the observed pattern of cellular aggregates, but only under certain parameter restrictions. This provides a fuller understanding of the conditions required for the chemical model to be applicable. Moreover, a further extension of the model to include separate subpopulations of cells is able to reproduce the observed differentiation of the somite into separate anterior and posterior halves.

Published

2009

60. Teasing out T-box targets in early mesoderm.

Author

Wardle FC and Papaioannou VE

Subjects

Animals, Cell Differentiation genetics, Fetal Proteins genetics, Fetal Proteins metabolism, Fetal Proteins physiology, Gene Expression Regulation, Developmental, Mesoderm metabolism, Mice, Models, Genetic, Signal Transduction, Somites growth & development, T-Box Domain Proteins genetics, T-Box Domain Proteins metabolism, Zebrafish genetics, Zebrafish metabolism, Zebrafish Proteins genetics, Zebrafish Proteins metabolism, Zebrafish Proteins physiology, Body Patterning genetics, Mesoderm growth & development, T-Box Domain Proteins physiology, Zebrafish embryology

Abstract

T-box transcription factor genes are widely conserved in metazoan development and widely involved in developmental processes. With the phase of T-box gene discovery winding down, the phase of transcriptional target discovery for T-box transcription factors is finally taking off and yielding rich rewards. Mutant phenotypes in mouse and zebrafish as well as morpholino studies in zebrafish have helped to link the T-box genes to a variety of signaling pathways through diverse target genes and feedback loops. Particularly in early mesoderm development, it is emerging that a network of T-box genes interacts with Wnt/beta-catenin and Notch/Delta signaling pathways, among others, to control the important processes of mesoderm specification, somite segmentation, and left/right body axis determination.

Published

2008

61. Development of the carapacial ridge: implications for the evolution of genetic networks in turtle shell development.

Author

Moustakas JE

Subjects

Animals, Embryo, Nonmammalian cytology, Extremities growth & development, Gene Expression Profiling, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Osteogenesis genetics, Paired Box Transcription Factors genetics, Paired Box Transcription Factors metabolism, Somites growth & development, Turtles genetics, Turtles growth & development, Biological Evolution, Embryonic Development, Turtles embryology

Abstract

Paleontologists and neontologists have long looked to development to understand the homologies of the dermal bones that form the "armor" of turtles, crocodiles, armadillos, and other vertebrates. This study shows molecular evidence supporting a dermomyotomal identity for the mesenchyme of the turtle carapacial ridge. The mesenchyme of the carapace primordium expresses Pax3, Twist1, Dermo1, En1, Sim1, and Gremlin at early stages and before overt ossification expresses Pax1. A hypothesis is proposed that this mesenchyme forms dermal bone in the turtle carapace. A comparison of regulatory gene expression in the primordia of the turtle carapace, the vertebrate limb, and the vertebral column implies the exaptation of key genetic networks in the development of the turtle shell. This work establishes a new role for this mesodermal compartment and highlights the importance of changes in genetic regulation in the evolution of morphology.

Published

2008

62. [Somitogenesis models and related genes in animals].

Author

Liu J, Wang N, and Zhu ZY

Subjects

Animals, Cell Differentiation, Humans, Models, Biological, Somites cytology, Somites metabolism, Vertebrates growth & development, Vertebrates metabolism, Embryonic Development, Somites growth & development, Vertebrates embryology, Vertebrates genetics

Abstract

During embryonic development, many animals form a number of temporary structures along their anterior-posterior axis-somites. Cells in somites differentiate into sclerotome, which gives rise to vertebral column, dermatome, which gives rise to dermis, and myotome, which gives rise to skeletal muscle. During the past three decades, several models have been proposed to explain the formation of somites, including the clock and wavefront model, the reaction-diffusion type model, the clock and induction model, the clock and trail model, and others. These models, albeit not perfect, serve to explain different aspects of somitogenesis. Most of these models propose the concept of segmental clock. Studies on expression patterns of c-hairy 1 and c-hairy 2 in chick, l-fng in chick and mouse, and her 1 and Delta C in zebrafish have provided evidence for the existence of segmental clock.

Published

2006