Your search keyword '"Lateral plate mesoderm"' showing total 12 results

1. How the embryo makes a limb: determination, polarity and identity.

Author

Tickle, Cheryll

Subjects

*EXTREMITIES (Anatomy), *EMBRYOS, *FIBROBLAST growth factors, *WNT proteins, *BONE morphogenetic proteins, *HINDLIMB, *HOMEOBOX genes

Abstract

The vertebrate limb with its complex anatomy develops from a small bud of undifferentiated mesoderm cells encased in ectoderm. The bud has its own intrinsic polarity and can develop autonomously into a limb without reference to the rest of the embryo. In this review, recent advances are integrated with classical embryology, carried out mainly in chick embryos, to present an overview of how the embryo makes a limb bud. We will focus on how mesoderm cells in precise locations in the embryo become determined to form a limb and express the key transcription factors Tbx4 (leg/hindlimb) or Tbx5 (wing/forelimb). These Tbx transcription factors have equivalent functions in the control of bud formation by initiating a signalling cascade involving Wnts and fibroblast growth factors ( FGFs) and by regulating recruitment of mesenchymal cells from the coelomic epithelium into the bud. The mesoderm that will form limb buds and the polarity of the buds is determined with respect to both antero-posterior and dorso-ventral axes of the body. The position in which a bud develops along the antero-posterior axis of the body will also determine its identity - wing/forelimb or leg/hindlimb. Hox gene activity, under the influence of retinoic acid signalling, is directly linked with the initiation of Tbx5 gene expression in the region along the antero-posterior axis of the body that will form wings/forelimbs and determines antero-posterior polarity of the buds. In contrast, Tbx4 expression in the regions that will form legs/hindlimbs is regulated by the homeoprotein Pitx1 and there is no evidence that Hox genes determine antero-posterior polarity of the buds. Bone morphogenetic protein ( BMP) signalling determines the region along the dorso-ventral axis of the body in which both wings/forelimbs and legs/hindlimbs develop and dorso-ventral polarity of the buds. The polarity of the buds leads to the establishment of signalling regions - the dorsal and ventral ectoderm, producing Wnts and BMPs, respectively, the apical ectodermal ridge producing fibroblast growth factors and the polarizing region, Sonic hedgehog (Shh). These signals are the same in both wings/forelimbs and legs/hindlimbs and control growth and pattern formation by providing the mesoderm cells of the limb bud as it develops with positional information. The precise anatomy of the limb depends on the mesoderm cells in the developing bud interpreting positional information according to their identity - determined by Pitx1 in hindlimbs - and genotype. The competence to form a limb extends along the entire antero-posterior axis of the trunk - with Hox gene activity inhibiting the formation of forelimbs in the interlimb region - and also along the dorso-ventral axis. [ABSTRACT FROM AUTHOR]

Published

2015

2. Anterior migration of lateral plate mesodermal cells during embryogenesis of the pufferfish Takifugu niphobles: insight into the rostral positioning of pelvic fins.

Author

Tanaka, Mikiko, Yu, Reiko, and Kurokawa, Daisuke

Subjects

*FISH embryology, *MESODERM, *GENE expression, *OSTEICHTHYES, *TETRAODONTIFORMES, *PUFFERS (Fish)

Abstract

In vertebrates, paired appendages (limbs and fins) are derived from the somatic mesoderm subsequent to the separation of the lateral plate mesoderm into somatic and splanchnic layers. This is less clear for teleosts, however, because the developmental processes of separation into two layers and of extension over the yolk have rarely been studied. During teleost evolution, the position of pelvic fins has generally shifted rostrally ( Rosen; Nelson, 1982, 1994), although at the early embryonic stage the presumptive pelvic fin cells are initially located near the future anus region - the anterior border of hoxc10a expression in the spinal cord - regardless of their final destination. Our previous studies in zebrafish (abdominal pelvic fins) and Nile tilapia (thoracic pelvic fins) showed that the presumptive pelvic fin cells shift their position with respect to the body trunk after its protrusion from the yolk surface. Furthermore, in Nile tilapia, presumptive pelvic fin cells migrate anteriorly on the yolk surface. Here, we examined the embryonic development of the lateral plate mesoderm at histological levels in the pufferfish Takifugu niphobles, which belongs to the highly derived teleost order Tetraodontiformes, and lacks pelvic fins. Our results show that, in T. niphobles, the lateral plate mesoderm bulges out as two separate layers of cells alongside the body trunk prior to its further extension to cover the yolk sphere. Once the lateral plate mesoderm extends laterally, it rapidly covers the surface of the yolk. Furthermore, cells located near the anterior border of hoxc10a expression in the spinal cord reach the anterior-most region of the yolk surface. In light of our previous and current studies, we propose that anterior migration of presumptive pelvic fin cells might be required for them to reach the thoracic or more anterior positions as is seen in other highly derived teleost groups. [ABSTRACT FROM AUTHOR]

Published

2015

3. Development of the lateral plate mesoderm in medaka Oryzias latipes and Nile tilapia Oreochromis niloticus: insight into the diversification of pelvic fin position.

Author

Kaneko, Hiroki, Nakatani, Yuki, Fujimura, Koji, and Tanaka, Mikiko

Subjects

*MESODERM, *NILE tilapia, *FISH embryology, *FINS (Anatomy), *ORYZIAS latipes, *OSTEICHTHYES

Abstract

The position of the pelvic fins among teleost fishes has tended to shift rostrally during evolution. This positional shift seems to have led to the diversification of feeding behavior and allowed adaptation to new environments. To understand the developmental basis of this shift in pelvic fin position among teleosts, we investigated the embryonic development of the lateral plate mesoderm, which gives rise to the pelvic fins, at histological levels in the medaka Oryzias latipes (abdominal pelvic fins) and Nile tilapia Oreochromis niloticus (thoracic pelvic fins). Our histological analyses revealed that the lateral plate mesodermal cells expand not only ventrally but also rostrally to cover the yolk during embryogenesis of both medaka and Nile tilapia. In medaka, we also found that the lateral plate mesoderm completely covered the yolk prior to the initiation of the pelvic fin buds, whereas in Nile tilapia the pelvic fin buds appeared in the body wall from the lateral plate mesoderm at the thoracic level when the lateral plate mesodermal cells only covered one-third of the yolk. We discuss the relevance of such differences in the rate of the lateral plate mesoderm expansion on the yolk surface and the position of the pelvic fins. [ABSTRACT FROM AUTHOR]

Published

2014

4. Evolution and development of the vertebrate neck.

Author

Ericsson, Rolf, Knight, Robert, and Johanson, Zerina

Subjects

*NECK, *ZEBRA danio, *VERTEBRATES, *BIOLOGICAL evolution, *SKELETON

Abstract

Muscles of the vertebrate neck include the cucullaris and hypobranchials. Although a functional neck first evolved in the lobe-finned fishes (Sarcopterygii) with the separation of the pectoral/shoulder girdle from the skull, the neck muscles themselves have a much earlier origin among the vertebrates. For example, lampreys possess hypobranchial muscles, and may also possess the cucullaris. Recent research in chick has established that these two muscles groups have different origins, the hypobranchial muscles having a somitic origin but the cucullaris muscle deriving from anterior lateral plate mesoderm associated with somites 1-3. Additionally, the cucullaris utilizes genetic pathways more similar to the head than the trunk musculature. Although the latter results are from experiments in the chick, cucullaris homologues occur in a variety of more basal vertebrates such as the sharks and zebrafish. Data are urgently needed from these taxa to determine whether the cucullaris in these groups also derives from lateral plate mesoderm or from the anterior somites, and whether the former or the latter represent the basal vertebrate condition. Other lateral plate mesoderm derivatives include the appendicular skeleton (fins, limbs and supporting girdles). If the cucullaris is a definitive lateral plate-derived structure it may have evolved in conjunction with the shoulder/limb skeleton in vertebrates and thereby provided a greater degree of flexibility to the heads of predatory vertebrates. [ABSTRACT FROM AUTHOR]

Published

2013

5. Development of the lateral plate mesoderm in medakaOryzias latipesand Nile tilapiaOreochromis niloticus: insight into the diversification of pelvic fin position

Author

Mikiko Tanaka, Yuki Nakatani, Koji Fujimura, and Hiroki Kaneko

Subjects

animal structures, Histology, food.ingredient, Oryzias, Mesoderm, Nile tilapia, Feeding behavior, food, Yolk, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, biology, Pelvic fin, Lateral plate mesoderm, Embryogenesis, Cichlids, Cell Biology, Anatomy, biology.organism_classification, Biological Evolution, body regions, Oreochromis, embryonic structures, Animal Fins, Erratum, human activities, Developmental Biology

Abstract

The position of the pelvic fins among teleost fishes has tended to shift rostrally during evolution. This positional shift seems to have led to the diversification of feeding behavior and allowed adaptation to new environments. To understand the developmental basis of this shift in pelvic fin position among teleosts, we investigated the embryonic development of the lateral plate mesoderm, which gives rise to the pelvic fins, at histological levels in the medaka Oryzias latipes (abdominal pelvic fins) and Nile tilapia Oreochromis niloticus (thoracic pelvic fins). Our histological analyses revealed that the lateral plate mesodermal cells expand not only ventrally but also rostrally to cover the yolk during embryogenesis of both medaka and Nile tilapia. In medaka, we also found that the lateral plate mesoderm completely covered the yolk prior to the initiation of the pelvic fin buds, whereas in Nile tilapia the pelvic fin buds appeared in the body wall from the lateral plate mesoderm at the thoracic level when the lateral plate mesodermal cells only covered one-third of the yolk. We discuss the relevance of such differences in the rate of the lateral plate mesoderm expansion on the yolk surface and the position of the pelvic fins.

Published

2014

6. Evolution and development of the vertebrate neck

Author

Rob Knight, Rolf Ericsson, and Zerina Johanson

Subjects

Sarcopterygii, animal structures, Histology, Flexibility (anatomy), biology, Appendicular skeleton, Lateral plate mesoderm, Vertebrate, Cell Biology, Anatomy, biology.organism_classification, Skull, medicine.anatomical_structure, biology.animal, embryonic structures, medicine, Shoulder girdle, Molecular Biology, Zebrafish, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

Muscles of the vertebrate neck include the cucullaris and hypobranchials. Although a functional neck first evolved in the lobe-finned fishes (Sarcopterygii) with the separation of the pectoral/shoulder girdle from the skull, the neck muscles themselves have a much earlier origin among the vertebrates. For example, lampreys possess hypobranchial muscles, and may also possess the cucullaris. Recent research in chick has established that these two muscles groups have different origins, the hypobranchial muscles having a somitic origin but the cucullaris muscle deriving from anterior lateral plate mesoderm associated with somites 1–3. Additionally, the cucullaris utilizes genetic pathways more similar to the head than the trunk musculature. Although the latter results are from experiments in the chick, cucullaris homologues occur in a variety of more basal vertebrates such as the sharks and zebrafish. Data are urgently needed from these taxa to determine whether the cucullaris in these groups also derives from lateral plate mesoderm or from the anterior somites, and whether the former or the latter represent the basal vertebrate condition. Other lateral plate mesoderm derivatives include the appendicular skeleton (fins, limbs and supporting girdles). If the cucullaris is a definitive lateral plate-derived structure it may have evolved in conjunction with the shoulder/limb skeleton in vertebrates and thereby provided a greater degree of flexibility to the heads of predatory vertebrates.

Published

2012

7. Temporal sequence in the formation of midline dermis and dorsal vertebral elements in avian embryos

Author

Ruijin Huang, Bodo Christ, and Qin Pu

Subjects

animal structures, Histology, Mesenchyme, Lateral plate mesoderm, Cartilage, Neural tube, Dermomyotome, Cell Biology, Anatomy, Biology, Chondrogenesis, Somite, medicine.anatomical_structure, Dermis, embryonic structures, medicine, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

Somites compartmentalize into a dorsal epithelial dermomyotome and a ventral mesenchymal sclerotome. While sclerotomes give rise to vertebrae and intervertebral discs, dermomyotomes contribute to skeletal muscle and epaxial dermis. Bone morphogenetic protein (BMP)-signals from the lateral mesoderm induce the lateral portion of the dermomyotome to form chondrogenic precursor cells, forming the cartilage of the scapula blade. The fact that BMPs are expressed in the roof plate of the neural tube where they induce cartilage formation led to the question why cells migrating from the medial part of the dermomyotome do not undergo chondrogenic differentiation and do not contribute to the dorsal part of the vertebrae. In the present study, we traced dermomyotomal derivatives by using the quail–chick marker technique. Our study reveals a temporal sequence in the formation of the vertebral cartilage and the midline dermis. The dorsal mesenchyme overlying the roof plate of the neural tube is formed prior to the de-epithelialization of the dermomyotome. Dermomyotomal cells start to migrate medially into the sub-ectodermal space to form the midline dermis after chondrogenesis of the dorsal mesenchyme has occurred. This time delay between chondrogenesis of the dorsal vertebra and dermal formation allows an undisturbed development of these two tissue components within a narrow region of the embryo.

Published

2012

8. How the embryo makes a limb: determination, polarity and identity

Author

Cheryll Tickle

Subjects

Apical ectodermal ridge, Mesoderm, Histology, animal structures, Limb Buds, Ectoderm, Review Article, Biology, Limb bud, medicine, Morphogenesis, Limb development, Animals, Humans, Hedgehog Proteins, Hox gene, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Body Patterning, Lateral plate mesoderm, Gene Expression Regulation, Developmental, Extremities, Cell Biology, Anatomy, body regions, medicine.anatomical_structure, Zone of polarizing activity, embryonic structures, Developmental Biology, Signal Transduction, Transcription Factors

Abstract

The vertebrate limb with its complex anatomy develops from a small bud of undifferentiated mesoderm cells encased in ectoderm. The bud has its own intrinsic polarity and can develop autonomously into a limb without reference to the rest of the embryo. In this review, recent advances are integrated with classical embryology, carried out mainly in chick embryos, to present an overview of how the embryo makes a limb bud. We will focus on how mesoderm cells in precise locations in the embryo become determined to form a limb and express the key transcription factors Tbx4 (leg/hindlimb) or Tbx5 (wing/forelimb). These Tbx transcription factors have equivalent functions in the control of bud formation by initiating a signalling cascade involving Wnts and fibroblast growth factors (FGFs) and by regulating recruitment of mesenchymal cells from the coelomic epithelium into the bud. The mesoderm that will form limb buds and the polarity of the buds is determined with respect to both antero-posterior and dorso-ventral axes of the body. The position in which a bud develops along the antero-posterior axis of the body will also determine its identity - wing/forelimb or leg/hindlimb. Hox gene activity, under the influence of retinoic acid signalling, is directly linked with the initiation of Tbx5 gene expression in the region along the antero-posterior axis of the body that will form wings/forelimbs and determines antero-posterior polarity of the buds. In contrast, Tbx4 expression in the regions that will form legs/hindlimbs is regulated by the homeoprotein Pitx1 and there is no evidence that Hox genes determine antero-posterior polarity of the buds. Bone morphogenetic protein (BMP) signalling determines the region along the dorso-ventral axis of the body in which both wings/forelimbs and legs/hindlimbs develop and dorso-ventral polarity of the buds. The polarity of the buds leads to the establishment of signalling regions - the dorsal and ventral ectoderm, producing Wnts and BMPs, respectively, the apical ectodermal ridge producing fibroblast growth factors and the polarizing region, Sonic hedgehog (Shh). These signals are the same in both wings/forelimbs and legs/hindlimbs and control growth and pattern formation by providing the mesoderm cells of the limb bud as it develops with positional information. The precise anatomy of the limb depends on the mesoderm cells in the developing bud interpreting positional information according to their identity - determined by Pitx1 in hindlimbs - and genotype. The competence to form a limb extends along the entire antero-posterior axis of the trunk - with Hox gene activity inhibiting the formation of forelimbs in the interlimb region - and also along the dorso-ventral axis.

Published

2015

9. Anterior migration of lateral plate mesodermal cells during embryogenesis of the pufferfish Takifugu niphobles: insight into the rostral positioning of pelvic fins

Author

Reiko Yu, Daisuke Kurokawa, and Mikiko Tanaka

Subjects

Histology, food.ingredient, animal structures, Molecular Sequence Data, Embryonic Development, Takifugu, Mesoderm, food, Yolk, medicine, Animals, Molecular Biology, Zebrafish, Ecology, Evolution, Behavior and Systematics, Appendage, Early embryonic stage, biology, Tetraodontiformes, Lateral plate mesoderm, Embryogenesis, Cell Biology, Anatomy, Original Articles, biology.organism_classification, Spinal cord, Biological Evolution, body regions, medicine.anatomical_structure, embryonic structures, Animal Fins, Developmental Biology

Abstract

In vertebrates, paired appendages (limbs and fins) are derived from the somatic mesoderm subsequent to the separation of the lateral plate mesoderm into somatic and splanchnic layers. This is less clear for teleosts, however, because the developmental processes of separation into two layers and of extension over the yolk have rarely been studied. During teleost evolution, the position of pelvic fins has generally shifted rostrally (Rosen; Nelson, 1982, 1994), although at the early embryonic stage the presumptive pelvic fin cells are initially located near the future anus region - the anterior border of hoxc10a expression in the spinal cord - regardless of their final destination. Our previous studies in zebrafish (abdominal pelvic fins) and Nile tilapia (thoracic pelvic fins) showed that the presumptive pelvic fin cells shift their position with respect to the body trunk after its protrusion from the yolk surface. Furthermore, in Nile tilapia, presumptive pelvic fin cells migrate anteriorly on the yolk surface. Here, we examined the embryonic development of the lateral plate mesoderm at histological levels in the pufferfish Takifugu niphobles, which belongs to the highly derived teleost order Tetraodontiformes, and lacks pelvic fins. Our results show that, in T. niphobles, the lateral plate mesoderm bulges out as two separate layers of cells alongside the body trunk prior to its further extension to cover the yolk sphere. Once the lateral plate mesoderm extends laterally, it rapidly covers the surface of the yolk. Furthermore, cells located near the anterior border of hoxc10a expression in the spinal cord reach the anterior-most region of the yolk surface. In light of our previous and current studies, we propose that anterior migration of presumptive pelvic fin cells might be required for them to reach the thoracic or more anterior positions as is seen in other highly derived teleost groups.

Published

2015

10. Tendon morphogenesis in the developing avian limb: plasticity of fetal tendon fibroblasts

Author

S. F. Oldfield and Darrell J. R. Evans

Subjects

musculoskeletal diseases, Histology, Mesenchyme, Morphogenesis, Chick Embryo, Biology, Transfection, Birds, Tendons, Limb bud, Tendon cell, medicine, Animals, Cell Lineage, Progenitor cell, Molecular Biology, Research Articles, Ecology, Evolution, Behavior and Systematics, Fetus, Lateral plate mesoderm, Cell Differentiation, Cell Biology, Anatomy, Fibroblasts, musculoskeletal system, Tendon, medicine.anatomical_structure, Lac Operon, Stem Cell Transplantation, Developmental Biology

Abstract

The differentiation and patterning of tendon fibroblasts is at present a poorly understood aspect of musculoskeletal development in the vertebrate limb. Precursors of tendon fibroblasts originate in the somatic mesoderm adjacent to the early limb bud and gradually become incorporated into the limb mesenchyme as development proceeds. It is unclear whether these progenitor cells are committed to the tendon lineage at this early stage, or whether cells become committed only as they are incorporated into a developing tendon. Following a review of our current knowledge of early tendon development, we present recent results from our preliminary studies looking at tendon cell commitment. Using a lacZ encoding replication-deficient retrovirus, we have mapped regions of the early limb bud that contain presumptive tendon progenitor cells, and later used these sites for implanting labelled fetal tendon fibroblasts into developing limbs. Following implantation, we found that these cells successfully re-incorporated into developing proximal and distal tendons, but also surprisingly contributed to other tissue lineages within the limb. Our results suggest that fetal tendon fibroblasts may not be irreversibly committed to a tendon cell fate in the limb and may be somewhat plastic in their ability to integrate into other tissue lineages during development.

Published

2003

11. Visualizing the lateral somitic frontier in the Prx1Cre transgenic mouse

Author

Ann C. Burke, Malcolm Logan, Matteo Sferlazzo, and J. Logan Durland

Subjects

Mesoderm, Histology, Axial skeleton, animal structures, Morphogenesis, Embryonic Development, Gestational Age, Mice, Transgenic, Biology, Mice, Paraxial mesoderm, medicine, Animals, Transgenes, Promoter Regions, Genetic, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Homeodomain Proteins, Integrases, Histocytochemistry, Lateral plate mesoderm, Gene Expression Regulation, Developmental, Cell Biology, Anatomy, Original Articles, Alkaline Phosphatase, Cell biology, Body plan, medicine.anatomical_structure, Lac Operon, Somites, embryonic structures, NODAL, Intermediate mesoderm, Developmental Biology

Abstract

Changes in the organization of the musculoskeletal system have accounted for many evolutionary adaptations in the vertebrate body plan. The musculoskeletal system develops from two mesodermal populations: somitic mesoderm gives rise to the axial skeleton and all of the skeletal muscle of the body, and lateral plate mesoderm gives rise to the appendicular skeleton. The recognition of embryonic domains resulting from the dynamics of morphogenesis has inspired new terminology based on developmental criteria. Two mesodermal domains are defined, primaxial and abaxial. The primaxial domain includes musculoskeletal structures comprising just somitic cells. The abaxial domain contains somitic myoblasts in connective tissue derived from lateral plate mesoderm, as well as lateral plate-derived skeletal structures. The boundary between these two domains is the lateral somitic frontier. Recent studies have described the developmental relationship between these two domains in the chick. In the present study, we describe the labelling pattern in the body of the Prx1/Cre/Z/AP compound transgenic mouse. The enhancer employed in this transgenic leads to reporter expression in the postcranial, somatic lateral plate mesoderm. The boundary between labelled and unlabelled cell populations is described at embryonic day (E)13.5 and E15.5. We argue that the distribution of labelled cells is consistent with the somatic lateral plate lineage, and therefore provides an estimate of the position of the lateral somitic frontier. The role of the frontier in both development and evolution is discussed.

Published

2008

12. Regulation of myogenic differentiation in the developing limb bud

Author

Laurent Antoni, Philippa Francis-West, and Kelly Anakwe

Subjects

Histology, Dermomyotome, Gene Expression, Reviews, Biology, MyoD, Limb bud, Morphogenesis, Animals, Hedgehog Proteins, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Regulation of gene expression, Embryonic Induction, Lateral plate mesoderm, Muscles, Wnt signaling pathway, Gene Expression Regulation, Developmental, Extremities, Cell Biology, Anatomy, Cell biology, Muscle Fibers, Slow-Twitch, Myogenic Regulatory Factors, Myogenic regulatory factors, Muscle Fibers, Fast-Twitch, Vertebrates, Trans-Activators, MYF5, Developmental Biology

Abstract

The limb myogenic precursors arise by delamination from the lateral dermomyotome in response to signals from the lateral plate mesoderm. They subsequently migrate into the developing limb bud where they switch on the expression of the myogenic regulatory factors, MyoD and Myf5, and coalese to form the dorsal and ventral muscle masses. The myogenic cells subsequently undergo terminal differentiation into slow or fast fibres which have distinct contractile properties determining how a muscle will function. In general, fast fibres contract rapidly with high force and are characterized by the expression of fast myosin heavy chains (MyHC). These fibres are needed for movement. In contrast, slow fibres express slow MyHC, contract slowly and are required for maintenance of posture. This review focuses on the molecular signals that control limb myogenic development from the initial delamination and migration of the premyogenic cells to the ultimate formation of the complex muscle pattern and differentiation of slow and fast fibres.

Published

2003