Your search keyword '"Jonathan D.W. Clarke"' showing total 24 results

1. Author response: Generation of the squamous epithelial roof of the 4th ventricle

Author

Jonathan D.W. Clarke, Richard J. T. Wingate, and Florent Campo-Paysaa

Subjects

Response generation, medicine.anatomical_structure, Ventricle, business.industry, medicine, Anatomy, business, Roof

Published

2019

2. Extracellular matrix couples the convergence movements of mesoderm and neural plate during the early stages of neurulation

Author

Jonathan D.W. Clarke, Claudio Araya, and Carlos Carmona-Fontaine

Subjects

0301 basic medicine, Mesoderm, Neural fold, animal structures, Neuroectoderm, Morphogenesis, Neural tube, Anatomy, Biology, biology.organism_classification, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Neurulation, embryonic structures, medicine, Neural plate, Neuroscience, Zebrafish, Developmental Biology

Abstract

Background During the initial stages zebrafish neurulation, neural plate cells undergo highly coordinated movements before they assemble into a multicellular solid neural rod. We have previously identified that the underlying mesoderm is critical to ensure such coordination and generate correct neural tube organization. However, how intertissue coordination is achieved in vivo during zebrafish neural tube morphogenesis is unknown. Results In this work, we use quantitative live imaging to study the coordinated movements of neural ectoderm and mesoderm during dorsal tissue convergence. We show the extracellular matrix components laminin and fibronectin that lie between mesoderm and neural plate act to couple the movements of neural plate and mesoderm during early stages of neurulation and to maintain the close apposition of these two tissues. Conclusions Our study highlights the importance of the extracellular matrix proteins laminin and libronectin in coupling the movements and spatial proximity of mesoderm and neuroectoderm during the morphogenetic movements of neurulation. Developmental Dynamics 245:580-589, 2016. © 2016 Wiley Periodicals, Inc.

Published

2016

3. Recruitment of postmitotic neurons into the regenerating spinal cord of urodeles

Author

Patrizia Ferretti, Jonathan D.W. Clarke, and Fang Zhang

Subjects

Neurons, Recruitment, Neurophysiological, Tail, Ependymal Cell, Cord, biology, Regeneration (biology), Mitosis, Anatomy, biology.organism_classification, Spinal cord, Ambystoma, Amputation, Surgical, Nerve Regeneration, Cell biology, medicine.anatomical_structure, Spinal Cord, Axolotl, Peripheral nervous system, Precursor cell, medicine, Animals, Cell aging, Cellular Senescence, Developmental Biology

Abstract

By using fluorescent tracers, we have investigated the origin of the cells that form the regenerating spinal cord after tail amputation in urodele amphibians. We show that spinal cord cells immediately adjacent to the amputation plane die and are removed by phagocytic cells. Spinal cells just anterior to these dying cells are destined to make the majority of the regenerating cord. The largest contribution is likely to come from the radial ependymal cells, but we also demonstrate that postmitotic neurons in this location can translocate into the regenerating cord. These neurons integrate into the regenerate structure and survive for at least 4 weeks. We find no evidence that these translocated neurons dedifferentiate and divide during this regeneration process. We discuss the possibility that these neurons survive long term in the regenerate cord and become part of the functional neuronal circuitry.

Published

2003

4. Stability and Plasticity of Neural Crest Patterning and Branchial Arch Hox Code after Extensive Cephalic Crest Rotation

Author

Paul Hunt, Paul Buxton, Jonathan D.W. Clarke, Peter Thorogood, and Patrizia Ferretti

Subjects

animal structures, Ectomesenchyme, Branchial arch, Chick Embryo, Biology, Mesoderm, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, Morphogenesis, Animals, Maxillofacial Development, 10. No inequality, Hox gene, Molecular Biology, Fluorescent Dyes, 030304 developmental biology, Homeodomain Proteins, 0303 health sciences, Histocytochemistry, Gene Expression Regulation, Developmental, Neural crest, Cell Biology, Anatomy, Neural Crest, Tissue Transplantation, embryonic structures, Crest, Neural crest cell migration, Branchial Region, Neural plate, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The extent to which the spatial organisation of craniofacial development is due to intrinsic properties of the neural crest is at present unclear. There is some experimental evidence supporting the concept of a prepattern established within crest while contiguous with the neural plate. In experiments in which the neural tube and premigratory crest are relocated within the branchial region, crest cells retain patterns of gene expression appropriate for their position of origin after migration into the branchial arches, resulting in skeletal abnormalities. But in apparent conflict with these findings, when crest is rerouted by late deletion of adjacent crest, infilling crest alters its pattern of gene expression to match its new location, and a normal facial skeleton results. In order to reconcile these findings and thus identify processes of relevance to the course of normal development, we have performed a series of neural tube and crest rotations producing a more extensive reorganisation of cephalic crest than has been previously described. Lineage analysis using DiI labelling of crest derived from the rotated hindbrain reveals that crest does not migrate into the branchial arch it would have colonised in normal development, rather it simply populates the nearest available branchial arches. We also find that crest adjacent to the grafted region contributes to a greater number of branchial arches than it would in normal development, resulting in branchial arches containing mixed cell populations not occurring in normal development. We find that after exchange of first and third arch crest by rotation of r1–7, crest alters its expression ofhoxa-2andhoxa-3to match its new location within the embryo resulting in the reestablishment of the normal branchial arch Hox code. A facial skeleton in which all the normal components are present, with some additional ectopic first arch structures, is formed in this situation. In contrast, when second and third arch crest are exchanged by rotation of r3 to 7, ectopic Hox gene expression is stable, resulting in the persistence of an abnormal branchial arch Hox code and extensive defects in the hyoid skeleton. We suggest that the intrinsic properties of crest have an effect on the spatial organisation of structures derived from the branchial arches, but that exposure to increasingly novel environments within the branchial region or “community effects” within mixed populations of cells can result in alterations to crest Hox code and morphogenetic fate. In both classes of operation we find that there is a tight link between the resulting branchial arch Hox code and a particular skeletal morphology.

Published

1998

5. Fate map of the developing chick face: Analysis of expansion of facial primordia and establishment of the primary palate

Author

Imelda M. McGonnell, Jonathan D.W. Clarke, and Cheryll Tickle

Subjects

Primary palate, Cell division, Morphogenesis, Neural crest, Ectoderm, Anatomy, Biology, medicine.anatomical_structure, Fate mapping, embryonic structures, medicine, Primordium, Developmental biology, Developmental Biology

Abstract

Developing facial primordia change shape substantially in stages leading up to primary palate formation. We investigated expansion of cell populations within each of the four facial primordia of chick embryos between HH-stages 20 and 28, by using DiI labelling. Populations of cells centred around the nasal pits in the upper face, the midline of the paired mandibular primordia in the lower face, and at sites of fusion contribute most to overall expansion. Abundant Msx-1 transcripts are found in regions of high expansion, and Fgf-8 transcripts are seen in ectoderm associated with some of these regions. Many cell populations display preferential expansion along one axis. Maxillary and mandibular primordia cell populations expand along the proximodistal axis, whereas at the distal tip of the frontonasal mass, cell populations expand mediolaterally. Thus outgrowth occurs at the tips of mandibular and maxillary primordia, but at the base of the frontonasal mass. At regions where adjacent primordia abut each other, we found bidirectional movement of cells between primordia, unidirectional movement or could detect no movement at all. Regions of highest expansion in each primordium have the highest percentage of S phase labelled cells. Cell death occurs in some regions of low expansion but it seems likely that cell rearrangements and intercalations also contribute to shaping. These rearrangements could be associated with stretching of the primordia by neighbouring tissues. Treatment of chick embryos with retinoic acid causes clefts of the primary palate (Tamarin et al. [1984] J. Embryol. Exp. Morphol. 84:105-123). We found a decrease in expansion of cell populations that normally contribute to primary palate formation but surprisingly little ectopic cell death. Expansion of other cell populations in the treated upper face was more even rather than directed. This further supports the idea that tension exerted by neighbouring tissues plays a major role in global shaping of the upper face.

Published

1998

6. Late effects of retinoic acid on neural crest and aspects of rhombomere

Author

Malcolm Maden, Victoria E. Prince, Andrew Lumsden, Nigel Holder, Emily Gale, and Jonathan D.W. Clarke

Subjects

Cell type, Molecular Sequence Data, Retinoic acid, Rhombomere, Tretinoin, Hindbrain, Chick Embryo, Biology, chemistry.chemical_compound, Cell Movement, Morphogenesis, medicine, Animals, RNA, Messenger, Molecular Biology, Early Growth Response Protein 2, DNA Primers, Homeodomain Proteins, Base Sequence, Genes, Homeobox, Gene Expression Regulation, Developmental, Neural crest, Anatomy, Motor neuron, Cell biology, DNA-Binding Proteins, Rhombencephalon, Phenotype, medicine.anatomical_structure, chemistry, Neural Crest, Trans-Activators, Ectopic expression, Crest, Transcription Factors, Developmental Biology

Abstract

We exposed st.10 chicks to retinoic acid (RA), both globally, and locally to individual rhombomeres, to look at its role in specification of various aspects of hindbrain derived morphology. Previous studies have looked at RA exposure at earlier stages, during axial specification. Stage 10 is the time of morphological segmentation of the hindbrain and is just prior to neural crest migration. Rhombomere 4 localised RA injections result in specific alterations of pathways some crest cells that normally migrate to sites of differentiation of neurogenic derivatives. The r4 crest cells that give rise to mesenchymal derivatives are unaffected. In addition, r4 gene expression is also partially altered by RA; within 6 hours of r4 exposure to RA, ectopic expression of Krox-20 is seen in r4 and Hoxb-1 expression is lost while Hoxa-2 expression continues normally. When we examined these RA-treated animals later in development, they showed an anterior displacement of the facial ganglion in addition to a mis-direction of the extensions of its distal axons and a dramatic decrease in the number of contralateral vestibuloacoustic neurons normally seen in r4. Only this r4-specific neuronal type is affected in r4; the motor neuron projections seem normal in experimental animals. The specificity of this result, combined with the loss of Hoxb-1 expression in r4 and the work by Krumlauf and co-workers showing gain of contralateral neurons co-localised with ectopic Hoxb-1 expression, indicates a role for Hoxb-1 and RA in the specification of this cell type in normal development. These results suggest that RA, at st.10, is able to affect some aspects of segment identity while leaving others unchanged.

Published

1996

7. Dystrophin expression in the hair cells of the cochlea

Author

Rosalind M. Quinlivan, George Dickson, Jonathan D.W. Clarke, Hilary Dodson, and Tony A. Piper

Subjects

musculoskeletal diseases, congenital, hereditary, and neonatal diseases and abnormalities, mdx mouse, Pathology, medicine.medical_specialty, Histology, Blotting, Western, Guinea Pigs, Outer plexiform layer, Dystrophin, Mice, Hair Cells, Auditory, Utrophin, medicine, Animals, Muscular dystrophy, Cochlea, Retina, Microscopy, Confocal, biology, General Neuroscience, Cell Biology, Muscular Dystrophy, Animal, musculoskeletal system, medicine.disease, Cell biology, Molecular Weight, medicine.anatomical_structure, Synapses, biology.protein, Electrophoresis, Polyacrylamide Gel, sense organs, Hair cell, Anatomy

Abstract

Dystrophin is normally expressed in a number of tissues including muscle, brain and the outer plexiform layer of the retina. In Duchenne and Becker muscular dystrophy abnormal or deficient dystrophin expression leads to muscle degeneration and has been implicated in mental retardation and a form of night blindness. We have examined the expression of dystrophin immunoreactivity in cochlear tissues of normal guinea-pig and mouse, and whether expression is perturbed in the cochlea of the dystrophic MDX mouse. A single band of approximately 427 kDa, corresponding to a full-length isoform of dystrophin was detected in guinea-pig and normal mouse but was absent from the MDX mouse. Cochleae from guinea-pig, normal and MDX mouse also showed a second dystrophin isoform of 116 kDa molecular weight with the C-terminal specific antibody. Immunostained guinea pig cochlear half turns were examined by laser scanning confocal microscopy. Dystrophin was localized in both inner and outer hair cells with staining patterns which were qualitatively similar with both antibodies. In the outer hair cells labelling of the lateral wall was especially distinctive. The synaptic region of both hair cell types was also strongly labelled.

Published

1995

8. Morphogenesis underlying the development of the everted teleost telencephalon

Author

Pavla Navratilova, Thomas Becker, Philippa Bayley, Mónica Folgueira, Stephen W. Wilson, and Jonathan D.W. Clarke

Subjects

Telencephalon, Embryo, Nonmammalian, Neuropil, Time Factors, lcsh:RC346-429, Animals, Genetically Modified, Diencephalon, Olfactory bulb, 0302 clinical medicine, Neural Pathways, Morphogenesis, Zebrafish, Neurons, eversion, 0303 health sciences, Brain Mapping, Tela choroidea, Microscopy, Confocal, Cerebrum, Anatomy, Neuroepithelial cell, medicine.anatomical_structure, olfactory bulb, embryonic structures, Erratum, Research Article, ray-finned fishes, animal structures, Green Fluorescent Proteins, Biology, 03 medical and health sciences, Developmental Neuroscience, Fate mapping, medicine, Animals, RNA, Messenger, lcsh:Neurology. Diseases of the nervous system, 030304 developmental biology, Body Patterning, Ray-finned fishes, fungi, Zebrafish Proteins, zebrafish, Bromodeoxyuridine, nervous system, Forebrain, 030217 neurology & neurosurgery, telencephalon

Abstract

Background Although the mechanisms underlying brain patterning and regionalization are very much conserved, the morphology of different brain regions is extraordinarily variable across vertebrate phylogeny. This is especially manifest in the telencephalon, where the most dramatic variation is seen between ray-finned fish, which have an everted telencephalon, and all other vertebrates, which have an evaginated telencephalon. The mechanisms that generate these distinct morphologies are not well understood. Results Here we study the morphogenesis of the zebrafish telencephalon from 12 hours post fertilization (hpf) to 5 days post fertilization (dpf) by analyzing forebrain ventricle formation, evolving patterns of gene and transgene expression, neuronal organization, and fate mapping. Our results highlight two key events in telencephalon morphogenesis. First, the formation of a deep ventricular recess between telencephalon and diencephalon, the anterior intraencephalic sulcus (AIS), effectively creates a posterior ventricular wall to the telencephalic lobes. This process displaces the most posterior neuroepithelial territory of the telencephalon laterally. Second, as telencephalic growth and neurogenesis proceed between days 2 and 5 of development, the pallial region of the posterior ventricular wall of the telencephalon bulges into the dorsal aspect of the AIS. This brings the ventricular zone (VZ) into close apposition with the roof of the AIS to generate a narrow ventricular space and the thin tela choroidea (tc). As the pallial VZ expands, the tc also expands over the upper surface of the telencephalon. During this period, the major axis of growth and extension of the pallial VZ is along the anteroposterior axis. This second step effectively generates an everted telencephalon by 5 dpf. Conclusion Our description of telencephalic morphogenesis challenges the conventional model that eversion is simply due to a laterally directed outfolding of the telencephalic neuroepithelium. This may have significant bearing on understanding the eventual organization of the adult fish telencephalon.

Published

2012

9. Early phenotypic choices by neuronal precursors, revealed by clonal analysis of the chick embryo hindbrain

Author

Scott E. Fraser, Roger J. Keynes, Andrew Lumsden, and Jonathan D.W. Clarke

Subjects

Neurons, Stem Cells, Neurogenesis, Central nervous system, Rhombomere, Cell Differentiation, Hindbrain, Embryo, Chick Embryo, Anatomy, Biology, Phenotype, Clone Cells, Cell biology, Rhombencephalon, medicine.anatomical_structure, Microscopy, Fluorescence, nervous system, Precursor cell, medicine, Animals, Molecular Biology, Mitosis, Developmental Biology

Abstract

The mechanisms that generate diverse neuronal phenotypes within the central nervous system are thought to involve local cues or cell-cell interactions acting late in neurogenesis, perhaps as late as the last precursor cell division. We describe here a clonal analysis of neuronal development in the chick hindbrain, using an intracellular tracer to mark single precursor cells, that suggests the operation of an alternative strategy. The majority of clones, ranging from 1 to 46 cells, contained neurons of only one of several possible phenotypes. These single-phenotype clones were not positionally restricted within a rhombomere but were interspersed with other clones containing distinct phenotypes. The assignment of neuronal phenotype in this brain region may, therefore, be made in early precursors and remembered through several rounds of mitotic expansion and dispersal.

Published

1994

10. Segmental repetition of neuronal phenotype sets in the chick embryo hindbrain

Author

Jonathan D.W. Clarke and Andrew Lumsden

Subjects

Cell type, Central nervous system, Rhombomere, Hindbrain, Chick Embryo, Biology, Neural Pathways, medicine, Animals, Molecular Biology, Horseradish Peroxidase, Neurons, Histocytochemistry, Embryogenesis, Embryo, Anatomy, Phenotype, Axons, Rhombencephalon, medicine.anatomical_structure, Microscopy, Fluorescence, nervous system, Neuron, Neuroscience, Developmental Biology

Abstract

The neurons within the segmented hindbrain of the early chick embryo have been mapped with the neuronal tracers HRP and fluorescent lysinated dextran. We have categorised neurons according to their axonal pathways and have then compared rhombomeres with respect to the number and class of neurons present. The results indicate that most rhombomeres are similar in that they contain the same set of basic neuronal types but differ in that particular neuronal types are more abundant in some rhombomeres than others. The data support the concept that the hindbrain develops according to ‘variations on a segmental theme’ rather than ‘each segment is unique’. Many of the cell types occupy distinct mediolateral domains that are probably established by both the differential migration of some neuronal classes and the spatial segregation of distinct precursors. The caudal rhombomeres 7 and 8 are exceptional in that they do not have the full set of basic neuronal types and also contain two additional medial cell types that are not present rostrally. The mechanisms that may generate the regional diversity apparent in the more mature hindbrain are discussed.

Published

1993

11. Local tissue interactions across the dorsal midline of the forebrain establish cns laterality

Author

Darren Gilmour, Lauro Sumoy, Miguel L. Concha, Stefan Gründer, Stephen W. Wilson, Marcel Tawk, Enrique Amaya, Claire Russell, Teresa Nicolson, Jonathan D.W. Clarke, Samuel Sidi, David Kimelman, Miranda Gomperts, Kim Goldstone, Jennifer C. Regan, Marika Kapsimali, University of Zurich, and Concha, Miguel L

Subjects

Central Nervous System, Neuroscience(all), Central nervous system, Molecular Sequence Data, Nodal signaling, Biology, Functional Laterality, Animals, Genetically Modified, 03 medical and health sciences, 0302 clinical medicine, Prosencephalon, Cell Movement, medicine, Epithalamus, Animals, Zebrafish, 030304 developmental biology, 0303 health sciences, General Neuroscience, 2800 General Neuroscience, Anatomy, Parietal eye, 10124 Institute of Molecular Life Sciences, medicine.anatomical_structure, Habenula, Forebrain, Laterality, 570 Life sciences, biology, NODAL, Neuroscience, 030217 neurology & neurosurgery

Abstract

The mechanisms that establish behavioral, cognitive, and neuroanatomical asymmetries are poorly understood. In this study, we analyze the events that regulate development of asymmetric nuclei in the dorsal forebrain. The unilateral parapineal organ has a bilateral origin, and some parapineal precursors migrate across the midline to form this left-sided nucleus. The parapineal subsequently innervates the left habenula, which derives from ventral epithalamic cells adjacent to the parapineal precursors. Ablation of cells in the left ventral epithalamus can reverse laterality in wild-type embryos and impose the direction of CNS asymmetry in embryos in which laterality is usually randomized. Unilateral modulation of Nodal activity by Lefty1 can also impose the direction of CNS laterality in embryos with bilateral expression of Nodal pathway genes. From these data, we propose that laterality is determined by a competitive interaction between the left and right epithalamus and that Nodal signaling biases the outcome of this competition.

Published

2003

12. A reciprocal relationship between cutaneous nerves and repairing skin wounds in the developing chick embryo

Author

Jonathan D.W. Clarke, Steven Harsum, and Paul Martin

Subjects

animal structures, Time Factors, sensory nerves, Ultraviolet Rays, embryo, Stimulation, Hindlimb, Chick Embryo, Biology, Animals, Process (anatomy), Molecular Biology, hyperinnervation, Skin, Skin repair, Inflammation, Neurons, Wound Healing, integumentary system, Neural crest, Embryo, Anatomy, Cell Biology, chick, Neural Crest, Microscopy, Electron, Scanning, Cutaneous innervation, Wound healing, Developmental Biology

Abstract

Various studies have suggested that the rate of adult skin healing may be in some way dependent on signals emanating from cutaneous nerves. Further, it appears that adult wounds become hyperinnervated by sensory nerves during the process of healing. In order to investigate this reciprocal relationship further, we have used a simple embryonic model to look at the effect of wounds on nerves, and conversely, the effect of nerves on wounds. We find that wounds made to the dorsum of the chick wing bud, at a stage prior to normal innervation (at E4), or soon after the normal establishment of cutaneous innervation (at E7), subtly alter the pattern of branching by perturbing developmental guidance cues, but do not cause hyperinnervation, whereas wounding at E14 does cause hyperinnervation. By creating chicks with nerveless wings, we show that from E7, wound healing in the absence of nerves is significantly impaired. These observations suggest that, from the earliest stages of skin innervation, the presence of nerves is beneficial to the healing process, but that, in contrast to neonatal and adult tissues, wound healing in the embryo and early foetus does not trigger hyperinnervation.

Published

2002

13. In vivo imaging indicates muscle fiber dedifferentiation is a major contributor to the regenerating tail blastema

Author

Karen Echeverri, Jonathan D.W. Clarke, and Elly M. Tanaka

Subjects

Tail, Cell type, Time Factors, Microinjections, Muscle Fibers, Skeletal, Ambystoma, Models, Biological, Axolotl, Multinucleate, Dermis, medicine, Myocyte, Animals, Regeneration, blastema, Molecular Biology, Cell Nucleus, biology, Regeneration (biology), Cartilage, Muscles, dedifferentiation, Cell Differentiation, Dextrans, Cell Biology, Anatomy, biology.organism_classification, Cell biology, Ambystoma mexicanum, muscle fibers, medicine.anatomical_structure, Microscopy, Fluorescence, Blastema, Developmental Biology

Abstract

During tail regeneration in urodele amphibians such as axolotls, all of the tissue types, including muscle, dermis, spinal cord, and cartilage, are regenerated. It is not known how this diversity of cell types is reformed with such precision. In particular, the number and variety of mature cell types in the remaining stump that contribute to the blastema is unclear. Using Nomarski imaging, we followed the process of regeneration in the larval axolotl tail. Combining this with in vivo fluorescent labeling of single muscle fibers, we show that mature muscle dedifferentiates. Muscle dedifferentiation occurs by the synchronous fragmentation of the multinucleate muscle fiber into mononucleate cells followed by rapid cell proliferation and the extension of cell processes. We further show that direct clipping of the muscle fiber and severe tissue damage around the fiber are both required to initiate dedifferentiation. Our observations also make it possible to estimate for the first time how many of the blastema cells arise specifically from muscle dedifferentiation. Calculations based on our data suggest that up to 29% of nondermal-derived cells in the blastema come from dedifferentiation of mature muscle fibers. Overall, these results show that endogenous multinucleate muscle fibers can dedifferentiate into mononucleate cells and contribute significantly to the blastema.

Published

2001

14. Differential patterning of ventral midline cells by axial mesoderm is regulated by BMP7 and chordin

Author

Jonathan D.W. Clarke, Jane Dodd, Marysia Placzek, N. Sattar, J. Heemskerk, and K. Dale

Subjects

Mesoderm, Prechordal plate, animal structures, Embryo, Nonmammalian, Bone Morphogenetic Protein 7, Embryonic Development, Chick Embryo, Biology, FGF and mesoderm formation, Cell Movement, Transforming Growth Factor beta, Notochord, medicine, Paraxial mesoderm, Animals, Hedgehog Proteins, RNA, Messenger, Molecular Biology, In Situ Hybridization, Body Patterning, Glycoproteins, Lateral plate mesoderm, Gene Expression Regulation, Developmental, Proteins, Cell Differentiation, Anatomy, Immunohistochemistry, Cell biology, medicine.anatomical_structure, Spinal Cord, embryonic structures, Bone Morphogenetic Proteins, Microscopy, Electron, Scanning, Trans-Activators, Intercellular Signaling Peptides and Proteins, NODAL, Intermediate mesoderm, Developmental Biology, Signal Transduction

Abstract

Ventral midline cells in the neural tube have distinct properties at different rostrocaudal levels, apparently in response to differential signalling by axial mesoderm. Floor plate cells are induced by sonic hedgehog (SHH) secreted from the notochord whereas ventral midline cells of the rostral diencephalon (RDVM cells) appear to be induced by the dual actions of SHH and bone morphogenetic protein 7 (BMP7) from prechordal mesoderm. We have examined the cellular and molecular events that govern the program of differentiation of RDVM cells under the influence of the axial mesoderm. By fate mapping, we show that prospective RDVM cells migrate rostrally within the neural plate, passing over rostral notochord before establishing register with prechordal mesoderm at stage 7. Despite the co-expression of SHH and BMP7 by rostral notochord, prospective RDVM cells appear to be specified initially as caudal ventral midline neurectodermal cells and to acquire RDVM properties only at stage 7. We provide evidence that the signalling properties of axial mesoderm over this period are regulated by the BMP antagonist, chordin. Chordin is expressed throughout the axial mesoderm as it extends, but is downregulated in prechordal mesoderm coincident with the onset of RDVM cell differentiation. Addition of chordin to conjugate explant cultures of prechordal mesoderm and neural tissue prevents the rostralization of ventral midline cells by prechordal mesoderm. Chordin may thus act to refine the patterning of the ventral midline along the rostrocaudal axis.

Published

1998

15. Differential progenitor dispersal and the spatial origin of early neurons can explain the predominance of single-phenotype clones in the chick hindbrain

Author

Lynda Erskine, Jonathan D.W. Clarke, and Andrew Lumsden

Subjects

Intracellular Fluid, Hindbrain, Chick Embryo, Biology, Cell Movement, medicine, Animals, Sonic hedgehog, Floor plate, Fluorescent Dyes, Neurons, Rhodamines, Stem Cells, Neurogenesis, Neural tube, Cell Differentiation, Dextrans, Epithelial Cells, Anatomy, Carbocyanines, Iontophoresis, Fluoresceins, Phenotype, Neural stem cell, Cell biology, Neuroepithelial cell, Rhombencephalon, medicine.anatomical_structure, nervous system, biology.protein, Developmental Biology

Abstract

Clonal analysis of the chick embryo hindbrain has shown that during the first 48 hr of neurogenesis the large majority of neural progenitor cells generate clones of neurons of only a single major phenotype or of only closely related phenotypes. This is despite considerable spatial intermixing of diverse neuronal phenotypes at these stages of development and suggests that phenotype may be decided early in mitotic precursors and remembered through several subsequent rounds of division and dispersal (Lumsden et al. [1994] Development 120:1581-1589). Here we have used fate-mapping and clonal analysis to study neuroepithelial cell dispersal and mixing in the early hindbrain and discuss this data in relation to the generation of single phenotype neuronal clones. We find that dispersal is not uniform throughout the dorsoventral axis of the neural tube, but is highly dependent on position along that axis. Neuronal identity is related to the spatial origin and, hence, environment of the cell, and the spatial intermixing of diverse neuronal phenotypes at HH stage 20 is largely the result of circumferential neuronal migration as medially born branchial motor neurons migrate laterally while the more laterally born mlf neurons migrate medially. Constraints on the dispersal of clonally related progenitors, in particular those that lie adjacent to the floor plate, may serve to restrict the fate of these cells to the generation of only one major neuronal phenotype, i.e., motor neurons.

Published

1998

16. Segmentation, crest prespecification and the control of facial form

Author

Peter Thorogood, Jonathan D.W. Clarke, Paul Buxton, Paul Hunt, and Patrizia Ferretti

Subjects

Neural fold, animal structures, Ectomesenchyme, Rhombomere, Genes, Homeobox, Neural crest, Gene Expression Regulation, Developmental, Anatomy, Biology, Models, Biological, Rhombencephalon, Branchial Region, Neural Crest, Face, embryonic structures, Vertebrates, Rhombomere formation, Animals, Pharynx, Neural crest cell migration, General Dentistry, Neural plate, Head, Face and neck development of the embryo

Abstract

The early development of the vertebrate head is dependent on the formation of two series of segmented structures, the rhombomeres of the hindbrain and the branchial arch series. The initial formation of these two systems is closely linked, as the principal source of branchial arch mesenchyme is the neural crest, which derives from the lateral edge of the neural plate at the time of rhombomere formation. The subsequent development of the two systems maintains a close level of integration, as specific spatial relationships between skeletal, muscle and neural elements arising from the same axial level are established. Given the level of conservation of these anatomical relationships in vertebrates, it is likely that they are a reflection of a key mechanism in early facial and pharyngeal development. One model, in part based on these findings, proposed that the neural crest acquires an axial-level specific combination of gene expression while part of the neural plate. This prepattern is then maintained throughout the crest's subsequent development. In the model, this combination of gene expression would then specify the form of the facial and pharyngeal structures that the crest would give rise to. In this review we evaluate recent evidence on whether early facial development involves a crest prespecification of this type, and conclude that it is not the case.

Published

1998

17. Dorso-ventral ectodermal compartments and origin of apical ectodermal ridge in developing chick limb

Author

Muriel Altabef, Jonathan D.W. Clarke, and Cheryll Tickle

Subjects

Apical ectodermal ridge, Embryonic Induction, Mesoderm, animal structures, Genes, Homeobox, Ectoderm, Extremities, Anatomy, Chick Embryo, Biology, Models, Biological, Limb bud, medicine.anatomical_structure, Zone of polarizing activity, embryonic structures, medicine, Eye development, Limb development, Compartment (development), Animals, Molecular Biology, Developmental Biology, Signal Transduction

Abstract

We wish to understand how limbs are positioned with respect to the dorso-ventral axis of the body in vertebrate embryos, and how different regions of limb bud ectoderm, i.e. dorsal ectoderm, apical ridge and ventral ectoderm, originate. Signals from dorsal and ventral ectoderm control dorso-ventral patterning while the apical ectodermal ridge (AER) controls bud outgrowth and patterning along the proximo-distal axis. We show, using cell-fate tracers, the existence of two distinct ectodermal compartments, dorsal versus ventral, in both presumptive limb and flank of early chick embryos. This organisation of limb ectoderm is the first direct evidence, in vertebrates, of compartments in non-neural ectoderm. Since the apical ridge appears to be confined to this compartment boundary, this positions the limb. The mesoderm, unlike the ectoderm, does not contain two separate dorsal and ventral cell lineages, suggesting that dorsal and ventral ectoderm compartments may be important to ensure appropriate control of mesodermal cell fate. Surprisingly, we also show that cells which form the apical ridge are initially scattered in a wide region of early ectoderm and that both dorsal and ventral ectoderm cells contribute to the apical ridge, intermingling to some extent within it.

Published

1997

18. Relationship between dose, distance and time in Sonic Hedgehog-mediated regulation of anteroposterior polarity in the chick limb

Author

Delphine Duprez, Yingzi Yang, Pao-Tien Chuang, Neil Vargesson, David Bumcrot, Cheryll Tickle, Jonathan D.W. Clarke, Elisa Martí, G Drossopoulou, Lee Niswander, and Andrew P. McMahon

Subjects

animal structures, Body Patterning, Mesenchyme, Chick Embryo, Limb bud, medicine, Animals, Wings, Animal, Hedgehog Proteins, Sonic hedgehog, Molecular Biology, Regulation of gene expression, biology, Dose-Response Relationship, Drug, Cell Membrane, Gene Expression Regulation, Developmental, Proteins, Transfection, Anatomy, Recombinant Proteins, Cell biology, medicine.anatomical_structure, Zone of polarizing activity, embryonic structures, CD4 Antigens, COS Cells, biology.protein, Trans-Activators, Signal transduction, Developmental Biology, Signal Transduction

Abstract

Anteroposterior polarity in the vertebrate limb is thought to be regulated in response to signals derived from a specialized region of distal posterior mesenchyme, the zone of polarizing activity. Sonic Hedgehog (Shh) is expressed in the zone of polarizing activity and appears to mediate the action of the zone of polarizing activity. Here we have manipulated Shh signal in the limb to assess whether it acts as a longrange signal to directly pattern all the digits. Firstly, we demonstrate that alterations in digit development are dependent upon the dose of Shh applied. DiI-labeling experiments indicate that cells giving rise to the extra digits lie within a 300 μm radius of a Shh bead and that the most posterior digits come from cells that lie very close to the bead. A response to Shh involves a 12-16 hour period in which no irreversible changes in digit pattern occur. Increasing the time of exposure to Shh leads to specification of additional digits, firstly digit 2, then 3, then 4. Cell marking experiments demonstrate that cells giving rise to posterior digits are first specified as anterior digits and later adopt a more posterior character. To monitor the direct range of Shh signalling, we developed sensitive assays for localizing Shh by attaching alkaline phosphatase to Shh and introducing cells expressing these forms into the limb bud. These experiments demonstrate that long-range diffusion across the anteroposterior axis of the limb is possible. However, despite a dramatic difference in their diffusibility in the limb mesenchyme, the two forms of alkaline phosphatase-tagged Shh proteins share similar polarizing activity. Moreover, Shh-N (aminoterminal peptide of Shh)-coated beads and Shh-expressing cells also exhibit similar patterning activity despite a significant difference in the diffusibility of Shh from these two sources. Finally, we demonstrate that when Shh-N is attached to an integral membrane protein, cells transfected with this anchored signal also induce mirror-image pattern duplications in a dose-dependent fashion similar to the zone of polarizing activity itself. These data suggest that it is unlikely that Shh itself signals digit formation at a distance. Beads soaked in Shh-N do not induce Shh in anterior limb mesenchyme ruling out direct propagation of a Shh signal. However, Shh induces dose-dependent expression of Bmp genes in anterior mesenchyme at the start of the promotion phase. Taken together, these results argue that the dose-dependent effects of Shh in the regulation of anteroposterior pattern in the limb may be mediated by some other signal(s). BMPs are plausible candidates.

Published

1997

19. Cell movements, neuronal organisation and gene expression in hindbrains lacking morphological boundaries

Author

David G. Wilkinson, Ronald Nittenberg, Cheryll Tickle, Jonathan D.W. Clarke, Ketan Patel, Robb Krumlauf, Paul M. Brickell, and Yogish Joshi

Subjects

Retinoic acid, Rhombomere, Hindbrain, Tretinoin, Chick Embryo, Biology, chemistry.chemical_compound, Cell Movement, Precursor cell, Animals, Hox gene, Molecular Biology, Early Growth Response Protein 2, Boundary cell, Regulation of gene expression, Embryonic Induction, Homeodomain Proteins, Motor Neurons, Neurons, Neuropeptides, Cranial Nerves, Receptor, EphA4, Gene Expression Regulation, Developmental, Receptor Protein-Tyrosine Kinases, Anatomy, Cell biology, DNA-Binding Proteins, Rhombencephalon, chemistry, embryonic structures, Developmental Biology, Transcription Factors

Abstract

Rhombomeres are segmental units of the hindbrain that are separated from each other by a specialised zone of boundary cells. Retinoic acid application to a recently segmented hindbrain leads to disappearance of posterior rhombomere boundaries. Boundary loss is preceded by changes in segmental expression of Krox-20 and Cek-8 and followed by alterations in Hox gene expression. The characteristic morphology of boundary cells, their expression of follistatin and the periodic accumulation of axons normally associated with boundaries are all lost. In the absence of boundaries, we detect no change in anteroposterior dispersal of precursor cells and, in most cases, no substantial cell mixing between former rhombomeric units. This is consistent with the idea that lineage restriction can be maintained by processes other than a mechanical barrier composed of boundary cells. Much of the early organisation of the motor nuclei appears normal despite the loss of boundaries and altered Hox expression.

Published

1997

20. Neuroanatomical and functional analysis of neural tube formation in notochordless Xenopus embryos; laterality of the ventral spinal cord is lost

Author

J. Storm-Mathisen, Jonathan D.W. Clarke, Nigel Holder, and S.R. Soffe

Subjects

Central Nervous System, Motor Neurons, Cord, Central nervous system, Notochord, Anatomy, Motor neuron, Biology, Spinal cord, Immunohistochemistry, Axons, Electrophysiology, Microscopy, Electron, Xenopus laevis, medicine.anatomical_structure, Neurulation, nervous system, Spinal Cord, Ventral nerve cord, medicine, Animals, Molecular Biology, Developmental Biology, Floor plate

Abstract

Notochordless Xenopus embryos were produced by u.v. irradiation of the uncleaved fertilized egg. The spinal cords were examined using intermediate filament staining for glial cells, retrograde HRP staining for neuronal morphology and an anti-glycinergic antibody to reveal commissural cells and axons. The floorplate cells of the normal cord appear to be absent and their position along the ventral midline of the cord is occupied by motor neurones, Kolmer-Agduhr cells, radial glial cells and a ventrally placed marginal zone containing the longitudinal axons. Motor neurone number is reduced to 15 % of control values, and the sensory extramedullary cell number is increased twentyfold. Commissural axons are still able to cross the ventral cord but do so at abnormal angles and some commissural axons continue to grow circumferentially up the contralateral side of the cord rather than turning to grow longitudinally. Extracellular electrophysiological recordings from motor axons reveal that the normal alternation of locomotor activity on the left and right side of the embryo is lost in notochordless animals. These results suggest that the notochord and/or the normal floor plate structure are important for the development of the laterality of spinal cord connections and may influence motor neurone proliferation or differentiation.

Published

1991

21. Continuous growth of the motor system in the axolotl

Author

Claudia Orsi, Stephen W. Wilson, Nigel Stephens, Nigel Holder, Jonathan D.W. Clarke, Timothy Bloomer, and David Tonge

Subjects

Nervous system, Population, Muscle Development, Tritium, Ambystoma, Axolotl, Motor system, medicine, Animals, education, Horseradish Peroxidase, Myelin Sheath, Motor Neurons, education.field_of_study, biology, General Neuroscience, Muscles, Lumbosacral Region, Anatomy, Motor neuron, biology.organism_classification, Spinal cord, Axons, Nerve Regeneration, Microscopy, Electron, medicine.anatomical_structure, Spinal Cord, Peripheral nervous system, Ependyma, Spinal Nerve Roots, Thymidine

Abstract

During growth of the axolotl, motor neurons, and muscle fibres are added to the motor system. By double labelling neurons with tritiated thymidine and retrogradely transported HRP, we show that some motor neurons are born at postembryonic stages. Further analysis of motor neurons with the aid of HRP reveals this population of newly born cells relatively frequently in small (5-7 cm long) axolotls, but only rarely in large (7-13 cm long) axolotls. Evidence is presented that suggests that these immature cells are in the process of migrating from close to the ependyma out to the ventral horn. HRP transport also reveals growth cones of advancing axons within spinal nerves in animals up to 6 cm in length. Cell counts by light and electron microscopic methods show that muscle fibres are generated throughout larval life in the iliotibialis, a typical limb muscle. This analysis provides data consistent with the notion that new muscle fibres are added from a localised growth zone situated at the superficial edge of the muscle. These results are discussed in terms of the correlation between continuous growth of the motor system and the ability of the axolotl to functionally repair lesions to the peripheral nervous system.

Published

1991

22. Progenitor Dispersal and the Origin of Early Neuronal Phenotypes in the Chick Embryo Spinal Cord

Author

Jonathan D.W. Clarke, Ketan Patel, and Lynda Erskine

Subjects

Cell type, Time Factors, Cellular differentiation, Chick Embryo, Biology, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, medicine, Animals, Paired Box Transcription Factors, Cell Lineage, Progenitor cell, PAX3 Transcription Factor, Molecular Biology, Body Patterning, Fluorescent Dyes, 030304 developmental biology, Neurons, 0303 health sciences, Stem Cells, Neural tube, Cell Differentiation, Cell Biology, Anatomy, Carbocyanines, Spinal cord, Cell biology, DNA-Binding Proteins, Neuroepithelial cell, Phenotype, medicine.anatomical_structure, Spinal Cord, Biological dispersal, Neural plate, 030217 neurology & neurosurgery, Transcription Factors, Developmental Biology

Abstract

Using DiI and fluorescent dextrans, we have created fate maps of the neural plate and early neural tube describing the extent of progenitor cell dispersal and the spatial origin of morphologically distinct neuronal cell types along the dorsoventral axis of the developing chick spinal cord. Nonuniform dispersal and mixing of progenitors occur within the early neuroepithelium, with the degree of dispersal being determined by the initial position of the cells along the mediolateral axis of the neural plate. Dispersal is greatest in the midregions of the ventricular epithelium and decreases toward the dorsal and ventral midlines. Phenotypically diverse classes of neurons are born at specific dorsoventral locations in the neural tube. Motor neurons are the most ventral cell type generated followed, at progressively more dorsal positions, by distinct classes of interneurons. Several genes show dorsoventrally restricted patterns of expression within the neural tube and the fate maps were used to investigate the relationship between one of these genes, Pax3, and progenitor cell dispersal and fate. The results indicate that the dorsoventral pattern of Pax3 expression is not maintained by restrictions to cell mixing and are consistent with a role for this transcription factor in specifying the identity of neurons with contralateral descending axons.

23. Regeneration of descending axons in the spinal cord of the axolotl

Author

Nigel Holder, Jonathan D.W. Clarke, and Ruth Alexander

Subjects

biology, General Neuroscience, Regeneration (biology), Brain, Cell Count, Anatomy, biology.organism_classification, Spinal cord, Horseradish peroxidase, Ambystoma, Efferent Pathways, Axons, Nerve Regeneration, Lumbar Spinal Cord, medicine.anatomical_structure, nervous system, Spinal Cord, Axolotl, biology.protein, medicine, Animals, Efferent Pathway, Horseradish Peroxidase

Abstract

Horseradish peroxidase was used to describe the positions and approximate numbers of neurones with axons that descend to the lumbar spinal cord in normal axolotls and axolotls whose spinal cord had been transected 3–23 months previously. Three to 4 months after the transection approximately 10% of the axons had grown across the cut and returned to the lumbar spinal cord whereas 23 months after the transection the number and distribution of these cells were approaching those of the controls.

Published

1988

24. Cell fate in the chick limb bud and relationship to gene expression

Author

Neil Vargesson, Katherine Vincent, Clare Coles, Cheryll Tickle, Lewis Wolpert, and Jonathan D.W. Clarke

Subjects

Apical ectodermal ridge, Mesoderm, Limb Buds, Mesenchyme, Fibroblast Growth Factor 4, Pyridinium Compounds, Chick Embryo, Biology, Cell fate determination, Limb bud, Proto-Oncogene Proteins, Ectoderm, medicine, Limb development, Animals, Wings, Animal, Molecular Biology, Body Patterning, Fluorescent Dyes, Homeodomain Proteins, Gene Expression Regulation, Developmental, Anatomy, Carbocyanines, Fibroblast Growth Factors, medicine.anatomical_structure, Zone of polarizing activity, Ridge (meteorology), Developmental Biology, Transcription Factors

Abstract

We have produced detailed fate maps for mesenchyme and apical ridge of a stage 20 chick wing bud. The fate maps of the mesenchyme show that most of the wing arises from the posterior half of the bud. Subapical mesenchyme gives rise to digits. Cell populations beneath the ridge in the mid apical region fan out into the anterior tip of the handplate, while posterior cell populations extend right along the posterior margin. Subapical mesenchyme of the leg bud behaves similarly. The absence of anterior bending of posterior cell populations has implications when considering models of vertebrate limb evolution. The fatemaps of the apical ridge show that there is also a marked anterior expansion and cells that were in anterior apical ridge later become incorporated into non-ridge ectoderm along the margin of the bud. Mesenchyme and apical ridge do not expand in concert - the apical ridge extends more anteriorly. We used the fatemaps to investigate the relation-ship between cell lineage and elaboration of Hoxd-13 and Fgf-4 domains. Hoxd-13 and Fgf-4 are initially expressed posteriorly until about the mid-point of the early wing bud in mesenchyme and apical ridge respectively. Later in development, the genes come to be expressed throughout most of the handplate and apical ridge respectively. We found that at the proximal edge of the Hoxd-13 domain, cell populations stopped expressing the gene as development proceeded and found no evidence that the changes in extent of the domains were due to initiation of gene expression in anterior cells. Instead the changes in extent of expression fit with the fate maps and can be attributed to expansion and fanning out of cell populations initially expressing the genes.